{"id":294,"date":"2024-01-28T22:21:53","date_gmt":"2024-01-28T22:21:53","guid":{"rendered":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/?post_type=chapter&#038;p=294"},"modified":"2026-07-12T16:27:52","modified_gmt":"2026-07-12T16:27:52","slug":"vascular-sonography","status":"publish","type":"chapter","link":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/chapter\/vascular-sonography\/","title":{"raw":"Vascular Sonography","rendered":"Vascular Sonography"},"content":{"raw":"<div class=\"textbox textbox--learning-objectives\"><header class=\"textbox__header\">\r\n<p class=\"textbox__title\">10.1 Learning Objectives<\/p>\r\n\r\n<\/header>\r\n<div class=\"textbox__content\">\r\n<p class=\"import-pf\">After reviewing this chapter, you should be able to do the following:<\/p>\r\n\r\n<ol>\r\n \t<li>View and identify the anatomical structures of the venous systems and the corresponding ultrasound images.<\/li>\r\n \t<li>Explore the arterial system and the corresponding ultrasound images.<\/li>\r\n<\/ol>\r\n<\/div>\r\n<\/div>\r\n<h2 class=\"import-ah\">10.2 Introduction<\/h2>\r\n<p class=\"import-paft\">The topics covered in this section will include some of the ultrasound basics of the venous and arterial systems, including transcranial, carotid, aorta, and lower-extremity ultrasound imaging.<\/p>\r\n\r\n<h3 class=\"import-ah\">10.3 The Venous System<\/h3>\r\n<p class=\"import-paft\">The primary physiologic functions of the venous system are to return the deoxygenated blood to the heart, thermoregulate, store blood (at any instance, the venous system contains up to 70% of the circulating blood), and regulate the cardiac output. It is divided into three systems: superficial, perforating, and deep veins. Figure 10-1 shows the anatomy of the venous system. Blood flows from the superficial to deep veins through branching perforating veins. The deep veins usually follow the arteries in the same areas and often have similar names. For example, the femoral vein is beside the femoral artery. The deep venous system eventually returns blood to the right side of the heart. Since the venous system is usually a low-pressure system, veins have bicuspid valves to allow flow in one direction from superficial to deep (the foot is the exception) and from distal to proximal. Muscular contraction helps with venous flow, such as in the calf muscle pump in the leg.[footnote]Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561.[\/footnote]<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"849\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D1,and%20%E2%80%9CDorsal%20Digital.%E2%80%9D\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image1-15.png\" alt=\"Click image for long description.\" width=\"849\" height=\"1097\" \/><\/a> Figure 10-1: Anatomy of the venous system.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"349\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D2,directing%20flow%20upward.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image16.png\" alt=\"Anatomy of venous system in the leg. Click image for long description.\" width=\"349\" height=\"524\" \/><\/a> Figure 10-2: Valves in the venous system of the leg.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Venous pathophysiology has many etiologies, such as trauma and genetic predisposition, and can occur when outflow is impaired by dysfunctional valves, resulting in retrograde flow and causing a condition known as chronic venous insufficiency. Vein thrombosis is another condition with many hereditary and acquired etiologies, such as trauma or prolonged immobilization. Deep vein thrombosis is especially important to evaluate and treat.[footnote]Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\">https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92<\/a>[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The great saphenous vein (GSV) is the longest vein in the human body, as shown in Figure 10-2. It originates in the medial aspect of the foot as part of the dorsal arch. It continues proximally along the medial aspect of the foot and passes anterior to the medial malleolus on the tibia. It ascends along the medial aspect of the leg between the superficial and deep fascia. It typically has 10\u201320 valves and terminates at the saphenofemoral junction (SFJ). Once flow enters the femoral vein, it is in the deep venous system. Venous anatomy can vary from individual to individual. However, the GSV typically has branching superficial veins, such as the anterior and posterior accessory saphenous veins in the thigh.[footnote]Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\">https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92<\/a>[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The small saphenous vein (SSV) is the second most significant superficial vein that joins the dorsal venous arch in the lateral aspect of the foot. It ascends proximally behind the lateral malleolus and terminates into the deep popliteal vein, although this is highly variable and can extend into the thigh. The SSV typically has 9\u201312 valves. Like the GSV, the SSV lies between the superficial and deep fascia and can have many branching superficial veins. Perforating veins connect superficial to deep veins. They usually contain a bicuspid valve.[footnote]Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\">https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92<\/a>[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The deep venous system includes the common femoral vein, profunda femoral vein, deep femoral vein, popliteal vein, gastrocnemius veins, soleus veins, anterior tibial veins, posterior tibial veins, and peroneal veins. The direction of venous flow is described as antegrade, retrograde, or absent. In both the deep and superficial venous systems, it is essential to check for the following characteristics: compressibility, spontaneous flow, respiratory variation, augmentation, intraluminal defects, and venous reflux.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Compressibility evaluates if the vein collapses by applying downward pressure with the transducer. Typically, it should compress, since it is a low-pressure vessel. A thrombus can occlude the lumen and prevent compression. Spontaneous flow is observed when the blood flow moves actively without external influences, such as an augmentation maneuver. Respiratory variation, also known as phasicity, refers to regular venous flow changes that occur secondary to intrathoracic pressure during breathing cycles. Augmentation is a maneuver that is used to evaluate possible abnormal flow patterns. For example, by squeezing a distal portion in the calf, an increase in venous flow should be observed just proximal to this area. Absent or diminished flow could suggest obstruction, such as in a thrombus formation, and reversal of flow could indicate incompetent venous valves, such as in venous reflux disease.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Intraluminal defects usually describe a thrombus formation within the lumen of the vein. It is crucial to describe the details of the thrombus formation and whether it is obstructive.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Finally, venous reflux describes blood flow going in the wrong direction, usually from incompetent valves. Maneuvers are usually done to augment blood flow to test for reflux, which is significant if it exceeds 0.5 seconds in the superficial venous system, 0.35 seconds in perforators, and 1 second in the deep venous system.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">A complete venous duplex ultrasound of the lower extremities starts with a proximal to distal evaluation of the deep venous system in a transverse (TRV) side-by-side image without compression and with compression (COMP). This is followed by a sagittal (SAG) view with augmentation (AUG) using the color Doppler. The veins that are evaluated in succession include the common femoral vein (CFV), profunda femoral vein (PROF V), femoral vein (FV), popliteal vein (POP V), gastrocnemius vein (GASTROC V), posterior tibial vein (PTV), peroneal vein (PERO V), anterior tibial vein (ATV), great saphenous vein (GSV), and small saphenous vein (SSV). The abbreviations given in parentheses in the last few sentences have been labeled in some of the following ultrasound images for venous system discussion. Figure 10-3 shows a side-by-side transverse ultrasound view of the right common femoral vein without compression and with compression, while Figure 10-4 represents the sagittal view of the right common femoral vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image17-1.png\" alt=\"Two-panel grayscale ultrasound image of the right common femoral vein in transverse view. The left panel, labeled 'RIGHT CFV TRV,' shows a transverse cross-sectional view of the right common femoral vein appearing as a rounded anechoic structure without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse or deformation of the vessel lumen.\" width=\"600\" height=\"450\" \/> Figure 10-3: Side-by-side transverse ultrasound views of the right common femoral vein without compression and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image18.jpg\" alt=\"The upper panel displays a color Doppler image with a large area of orange and yellow flow signal within a blue background, indicating robust venous flow within the vessel lumen in response to augmentation. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform, displaying phasic flow with augmentation peaks visible as downward deflections below the baseline, consistent with normal venous flow pattern.\" width=\"600\" height=\"450\" \/> Figure 10-4: Right common femoral vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-5 shows a side-by-side transverse ultrasound view of the right profunda femoral vein without compression and with compression, while Figure 10-6 represents the sagittal view of the right profunda femoral vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"430\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image19.jpg\" alt=\"Two-panel grayscale ultrasound image of the right profunda femoris vein in transverse view. The left panel, labeled 'RIGHT PROF V TRV,' shows a transverse cross-sectional view of the right profunda femoris vein appearing as a rounded anechoic structure adjacent to surrounding soft tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen. \" width=\"430\" height=\"322\" \/> Figure 10-5: Side-by-side transverse image of the right profunda femoral vein without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"423\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image20.jpg\" alt=\"The upper panel displays a color Doppler image with prominent red and orange flow signals in the upper portion of the color box indicating arterial flow, and blue flow signal in the lower portion indicating venous flow in the profunda femoris vein. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform displayed with inverted orientation, showing phasic flow with augmentation peaks visible both above and below the baseline, consistent with venous flow response to augmentation maneuver. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"423\" height=\"317\" \/> Figure 10-6: Right profunda femoral vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-7 shows a side-by-side transverse ultrasound view of the right femoral vein without compression and with compression, while Figure 10-8 represents the sagittal view of the right femoral vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image21.jpg\" alt=\"The left panel, labeled 'RIGHT FV TRV,' shows a transverse cross-sectional view of the right femoral vein appearing as a rounded anechoic structure adjacent to the femoral artery, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating partial collapse of the femoral vein lumen while the adjacent femoral artery remains round and non-compressible.\" width=\"600\" height=\"450\" \/> Figure 10-7: Side-by-side right femoral vein transverse view without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image22.jpg\" alt=\"The upper panel displays a color Doppler image with a large band of red and orange flow signal in the upper portion of the color box indicating arterial flow in the femoral artery, and a parallel band of blue flow signal in the lower portion indicating venous flow in the femoral vein. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with flow deflecting below the baseline, displaying rhythmic phasic waveforms with augmentation peaks consistent with normal venous flow response. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-8: Right femoral vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-9 shows a side-by-side transverse ultrasound view of the right popliteal vein without compression and with compression, while Figure 10-10 represents the sagittal view of the right popliteal vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image23-1.png\" alt=\"The left panel, labeled 'RIGHT POP V TRV,' shows a transverse cross-sectional view of the right popliteal vein appearing as a rounded anechoic structure adjacent to the popliteal artery within the popliteal fossa, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the popliteal vein lumen while the adjacent popliteal artery remains round and non-compressible.\" width=\"601\" height=\"451\" \/> Figure 10-9: Side-by-side right popliteal vein transverse view without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image24.jpg\" alt=\"The upper panel displays a color Doppler image with a large band of blue flow signal spanning the upper portion of the color box indicating venous flow in the popliteal vein, and a focal area of red and orange flow signal in the lower right portion indicating the adjacent popliteal artery. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with flow deflecting above and below the baseline, displaying phasic waveforms with a prominent augmentation peak visible as a tall upward deflection, consistent with normal venous flow response to augmentation maneuver. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-10: Right popliteal vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-11 shows a side-by-side transverse ultrasound view of the right gastrocnemius vein without compression and with compression, while Figure 10-12 represents the sagittal view of the right gastrocnemius vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image25-1.png\" alt=\"Two-panel grayscale ultrasound image of the right gastrocnemius vein in transverse view. The left panel, labeled 'RIGHT GASTROC V TRV,' shows a transverse cross-sectional view of the right gastrocnemius vein appearing as a small anechoic structure within the gastrocnemius muscle tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen within the surrounding muscle.\" width=\"601\" height=\"450\" \/> Figure 10-11: Side-by-side right gastrocnemius vein transverse view without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image26.jpg\" alt=\"The upper panel displays a color Doppler image with a focal area of blue flow signal and a small adjacent red signal within the gastrocnemius muscle, indicating venous flow in the gastrocnemius vein with minimal surrounding vascularity. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform displayed near the baseline, with low-amplitude phasic flow and a visible augmentation response toward the right side of the waveform, consistent with spontaneous and augmented venous flow in a small muscular vein. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"601\" height=\"451\" \/> Figure 10-12: Right gastrocnemius vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-13 shows a side-by-side transverse ultrasound view of the right posterior tibial vein without compression and with compression, while Figure 10-14 represents the sagittal view of the right posterior tibial vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image27-1.png\" alt=\"The left panel, labeled 'RIGHT PTV TRV,' shows a transverse cross-sectional view of the right posterior tibial vein appearing as small anechoic structures within the surrounding soft tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen.\" width=\"600\" height=\"450\" \/> Figure 10-13: Side-by-side right posterior tibial veins transverse view without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"609\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image28.jpg\" alt=\"The upper panel displays a color Doppler image with mixed orange, red, and blue flow signals filling the color box, indicating adjacent arterial and venous flow in the posterior tibial vessels. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform deflecting below the baseline, displaying continuous phasic venous flow with a prominent deep augmentation peak visible in the center of the waveform, consistent with a robust venous flow response to augmentation maneuver in the posterior tibial vein. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"609\" height=\"457\" \/> Figure 10-14: Right posterior tibial veins sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-15 shows a side-by-side transverse ultrasound view of the right peroneal vein without compression and with compression, while Figure 10-16 represents the sagittal view of the right peroneal vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image29-1.png\" alt=\"Two-panel ultrasound image of the right peroneal vein in transverse view. The left panel, labeled 'RIGHT PERO V TRV,' shows a transverse cross-sectional view of the right peroneal vein appearing as small anechoic structures within the surrounding deep soft tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen within the surrounding tissue.\" width=\"601\" height=\"451\" \/> Figure 10-15: Side-by-side right peroneal veins transverse view without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"602\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image30.jpg\" alt=\"The upper panel displays a color Doppler image with a small focal area of blue flow signal within a color box positioned at approximately 3 to 4 cm depth, indicating venous flow in the peroneal vein within the deep soft tissue. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with low-amplitude flow near the baseline and a prominent augmentation peak deflecting below the baseline in the center of the waveform, consistent with venous flow response to augmentation maneuver in the peroneal vein. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"602\" height=\"452\" \/> Figure 10-16: Right peroneal vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-17 shows a side-by-side transverse ultrasound view of the anterior tibial vein without compression and with compression, while Figure 10-18 represents the sagittal view of the right anterior tibial vein with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image31-1.png\" alt=\"Two-panel ultrasound image of the right anterior tibial vein in transverse view. The left panel, labeled 'RIGHT ATV TRV,' shows a transverse cross-sectional view of the right anterior tibial vein appearing as small anechoic structures within the surrounding deep soft tissue at approximately 2.5 to 3 cm depth, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen within the surrounding tissue.\" width=\"601\" height=\"451\" \/> Figure 10-17: Side-by-side right anterior tibial vein transverse view without and with compression.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D18,4.8%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image32.jpg\" alt=\"Click image for long description.\" width=\"601\" height=\"451\" \/><\/a> Figure 10-18: Right anterior tibial vein sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Next, in the complete venous duplex ultrasound, we look at the superficial venous system from proximal to distal, starting with the GSV at the SFJ in the transverse plane with a side-by-side image without and with color Doppler, followed by a sagittal image with augmentation with color Doppler. Figure 10-19 shows a side-by-side transverse ultrasound view of the right GSV at the SFJ, while Figure 10-20 represents the sagittal view of the right GSV at the SFJ with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image33.jpg\" alt=\"Duplex ultrasound image labeled 'RIGHT GSV SFJ TRV' showing the right great saphenous vein at the saphenofemoral junction in transverse view. The left portion of the image displays a grayscale view showing two adjacent anechoic vascular structures within the surrounding soft tissue. The right portion displays the corresponding color Doppler image with a large round red and orange structure in the upper left indicating the femoral artery in cross-section, and a larger adjacent blue flow-filled structure representing the common femoral vein with the great saphenous vein junction, showing mixed blue and yellow-orange color signals indicating venous flow at the saphenofemoral junction. A Doppler angle correction line is visible on the right side of the color image. Depth markers range from 0 to 3 cm.\" width=\"600\" height=\"450\" \/> Figure 10-19: Side-by-side right great saphenous vein at the saphenofemoral junction transverse view without and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D20,4.8%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image34.jpg\" alt=\"Right great saphenous vein ultrasound. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-20: Right great saphenous vein at the saphenofemoral junction sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Next, we continue to follow and evaluate the GSV distally from above the knee (AK) to below the knee (BK) in the transverse plane without color, followed by the sagittal plane with augmentation with color Doppler. The abbreviations AK and BK have been used in the ultrasound images discussed here. Figure 10-21 shows a side-by-side transverse ultrasound view of the right GSV above the knee. Figure 10-22 represents the sagittal view of the right GSV above the knee with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"602\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image35-1.png\" alt=\"Ultrasound labeled 'R GSV AK DIAM 0.27 cm AK TRV' showing a transverse view of the right great saphenous vein above the knee with a diameter measurement. A small round anechoic structure near the top center of the image represents the great saphenous vein in cross-section, with caliper markers placed across its lumen recording a diameter of 0.27 cm. A larger adjacent anechoic structure below and to the right represents a deeper vessel or tissue plane.\" width=\"602\" height=\"451\" \/> Figure 10-21: Right great saphenous vein transverse view above the knee.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image36.jpg\" alt=\"The upper panel displays a color Doppler image with a thin band of blue flow signal running horizontally near the top of the color box, indicating venous flow within the superficial great saphenous vein at approximately 0.5 cm depth. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with low-amplitude flow deflecting below the baseline, displaying continuous phasic venous flow consistent with spontaneous and augmented flow in the great saphenous vein above the knee. No prominent augmentation peak is visible.\" width=\"600\" height=\"450\" \/> Figure 10-22: Right great saphenous vein above the knee sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-23 shows a transverse ultrasound view of the right GSV below the knee, while Figure 10-24 represents the sagittal view of the right GSV below the knee with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image37.jpg\" alt=\"Ultrasound image labeled 'R GSV BK DIAM 0.20 cm BK TRV' showing a transverse view of the right great saphenous vein below the knee with a diameter measurement. A small round anechoic structure near the top center of the image represents the great saphenous vein in cross-section, with caliper markers placed across its lumen recording a diameter of 0.20 cm. Additional small anechoic structures are visible adjacent to the measured vessel. Surrounding soft tissue planes are visible throughout the image with color overlay artifact. Depth markers on the right range from 0 to 3 cm.\" width=\"601\" height=\"450\" \/> Figure 10-23: Right great saphenous vein below the knee transverse view.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image38-1.jpg\" alt=\"The upper panel displays a color Doppler image with a thin band of blue flow signal running horizontally near the top of the color box, indicating venous flow within the superficial great saphenous vein at approximately 0.4 cm depth. A hyperechoic linear structure is visible in the lower portion of the image. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with low-amplitude continuous flow deflecting below the baseline in the left portion of the waveform, and a brief augmentation peak deflecting above the baseline near the center. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-24: Right great saphenous vein below the knee sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The next superficial vein to be evaluated is the SSV, starting in the popliteal area of the lower extremity and using the same approach as the great saphenous vein. We first start with a transverse image at the saphenopopliteal junction (SPJ) without color Doppler, followed by a sagittal image with augmentation with color Doppler. Figure 10-25 shows a side-by-side transverse ultrasound view of the right SSV at the SPJ, while Figure 10-26 represents the sagittal view of the right SSV at the SPJ with augmentation.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image39-1.png\" alt=\"Ultrasound labeled 'R SSV SPJ DIAM 0.33 cm SPJ TRV' showing a transverse view of the right small saphenous vein at the saphenopopliteal junction with a diameter measurement. A round anechoic structure near the top center of the image represents the small saphenous vein in cross-section, with caliper markers placed across its lumen recording a diameter of 0.33 cm. Additional adjacent anechoic structures are visible in the surrounding tissue representing nearby vessels at the saphenopopliteal junction. Depth markers on the right range from 0 to 3 cm.\" width=\"600\" height=\"450\" \/> Figure 10-25: Right small saphenous vein at the saphenopopliteal junction transverse view.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D26,4.8%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image40.jpg\" alt=\"Doppler of small saphenous vein. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-26: Right small saphenous vein at the saphenopopliteal junction sagittal view with augmentation.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Also, anterior and posterior accessory saphenous veins are often evaluated as part of the superficial venous system, and perforating veins that connect superficial to deep veins are often evaluated during the study.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The template shown in the next couple of pages can be used to perform a complete venous duplex Doppler ultrasound examination of the lower extremities.<\/p>\r\n\r\n<div class=\"textbox\">\r\n<p class=\"import-exf\">Date ________________ U\/S technician _________________ Physician _______________<\/p>\r\n<p class=\"import-ex\" style=\"text-indent: 36pt\">Complaint ____________________________ Comparative study ___________________<\/p>\r\n<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/04\/image1.png\" alt=\"image\" width=\"617.466666666667px\" height=\"261.866666666667px\" \/>\r\n<p class=\"import-exf\"><span class=\"import-u\">DEEP VENOUS SYSTEM<\/span><\/p>\r\n<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/04\/image4.png\" alt=\"image\" width=\"623.6px\" height=\"506.866666666667px\" \/>\r\n<p class=\"import-exf\"><span class=\"import-u\">SUPERFICIAL VENOUS SYSTEM<\/span><\/p>\r\n<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/04\/image3.png\" alt=\"image\" width=\"621.333333333333px\" height=\"421.6px\" \/>\r\n<p class=\"import-exf\">Describe significant perforating veins, including size, location, and reflux: ______________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________<\/p>\r\n\r\n<\/div>\r\n&nbsp;\r\n\r\n&nbsp;\r\n\r\n&nbsp;\r\n\r\n&nbsp;\r\n<h3 class=\"import-exf\"><span style=\"font-family: 'Cormorant Garamond', serif;font-size: 1.80225em;font-weight: bold\">10.4 The Arterial System<\/span><\/h3>\r\n<p class=\"import-paft\">Figure 10-27 shows the anatomy of the arterial system, which will be helpful in discussing and understanding various ultrasonography images of the arteries.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"701\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D27,Dorsal%20Pedis%20arteries.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image2-5.png\" alt=\"Click image for long description.\" width=\"701\" height=\"967\" \/><\/a> Figure 10-27: Anatomy of the arterial system.[\/caption]\r\n<h4 class=\"import-bh\">10.4.1 Transcranial Doppler<\/h4>\r\n[caption id=\"\" align=\"aligncenter\" width=\"450\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image42.jpg\" alt=\"A clinician is holding a small curved ultrasound transducer against the lateral neck of a patient who is lying on an exam table with their head turned to the side. Ultrasound gel is visible at the probe-to-skin interface.\" width=\"450\" height=\"337\" \/> Figure 10-28: Transcranial Doppler probe.[\/caption]\r\n<p class=\"import-paft\">Norwegian physicist Rune Aaslid developed intracranial ultrasound in 1982. Transcranial imaging was subsequently developed by a German neurologist, Ulrich Bogdahn, in 1990. It was the first noninvasive way to evaluate the circle of Willis using a low-frequency transducer (2 MHz).[footnote]Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.[\/footnote],[footnote]Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Transcranial Doppler (TCD) can detect intracranial stenosis, vasospasm secondary to subarachnoid hemorrhage, and arteriovenous malformations and assess suspected brain death. A TCD system usually has a 2 MHz pulsed Doppler with a spectrum analyzer. A typical TCD probe is shown in Figure 10-28. Blood flow in TCD is usually measured in cm\/sec, and Figure 10-29 represents a TCD velocity distribution. When evaluating intracranial vessels, it is vital to know the acoustic window, depth, direction of blood flow, velocity, and angle of insonation. One important principle when evaluating pathology is the pulsatility index (PI).<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image43-1.png\" alt=\"Line diagram illustrating a spectral Doppler arterial waveform with Velocity on the y-axis and time on the x-axis. The waveform displays a repeating pattern of sharp systolic peaks and lower diastolic troughs. The highest point of the first waveform is labeled 'Systolic Velocity (Vs),' indicating peak systolic velocity. A shaded blue-gray rectangular region spans the interval between the systolic and diastolic phases, with the lower plateau labeled 'Diastolic Velocity (Vd),' indicating end-diastolic velocity. The letters 'S' and 'D' are marked along the x-axis below the waveform, corresponding to the systolic and diastolic phases respectively.\" width=\"600\" height=\"325\" \/> Figure 10-29: The transcranial Doppler velocity distribution.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">A high PI (&gt;1.2) can indicate increased intracranial pressure, microvascular disease, or distal vasospasm. Also, a low PI (&lt;0.8) can be seen with carotid stenosis or occlusion as well as arteriovenous malformations.[footnote]Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.[\/footnote],[footnote]Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.[\/footnote]<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image44-1.png\" alt=\"Acoustic windows illustration. The cerebral arterial circulation is depicted in red at the center of the brain, showing the circle of Willis and its major branches. Three ultrasound transducers are shown approaching the skull from different angles: the 'Transorbital' window is shown in the upper right with the probe directed through the orbit; the 'Transtemporal' window is shown on the left with the probe directed through the temporal bone; and the 'Transforaminal' window is shown in the lower right with the probe directed through the foramen magnum.\" width=\"600\" height=\"459\" \/> Figure 10-30: The three most common acoustic windows that provide direction to evaluate the intracranial vessels are the transtemporal, transorbital, and transforaminal windows.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The three most common acoustic windows that provide direction to evaluate the intracranial vessels are the transtemporal, transorbital, and transforaminal windows, as shown in Figure 10-30. The transcranial evaluation begins with the transtemporal approach on each side to identify the anterior, middle, and posterior cerebral arteries, and sometimes, the most distal aspect of the internal carotid artery (ICA) may also be evaluated.[footnote]Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.[\/footnote],[footnote]Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">When evaluating the anterior cerebral artery, normal flow is away from the probe, the depth is 60\u201370 mm, and the velocity ranges from 41\u201376 cm\/sec. The middle cerebral artery has normal flow toward the probe, a depth of 30\u201360 mm, and a velocity that ranges from 46\u201386 cm\/sec. The posterior cerebral artery typically has flow toward the probe, a depth of 60\u201370 mm, and a velocity range of 33\u201364 cm\/sec, as shown in Figure 10-31.[footnote]Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.[\/footnote],[footnote]Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.[\/footnote],[footnote]Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4th ed. [place unknown]: Davies publishing; 2011. p. 442.[\/footnote]<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"504\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image44.png\" alt=\"\" width=\"504\" height=\"154\" \/> Figure 10-31: Side-by-side flow patterns and velocities of the anterior cerebral artery, middle cerebral artery, and posterior cerebral artery on transcranial Doppler.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The transorbital approach is followed and used to evaluate the ophthalmic artery and carotid siphon on each side, as shown in Figure 10-32. The location for of obtaining flow patterns is essential in this window, since it is difficult to determine the anatomic structure, as in the transtemporal approach demonstrating the circle of Willis. Comparisons can be made between different flow patterns.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"420\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image45.png\" alt=\"The left panel displays a spectral waveform with measured Doppler indices listed below the waveform: Mean 23.1 cm\/s, Peak 42.7 cm\/s, End Diastolic Velocity (EDV) 13.7 cm\/s, Pulsatility Index (PI) 1.24, and Heart Rate (HR) 61 beats per minute. A color Doppler image is visible below the spectral display. The right panel displays a spectral waveform with higher velocity measurements listed below: Mean 24.6 cm\/s, Peak 34.6 cm\/s, EDV 17.2 cm\/s, PI 0.64, and HR 175 beats per minute. A color Doppler image is visible below the right spectral display. Both panels show bidirectional flow with waveforms displayed above and below the baseline. There is a lower pulsatility index and higher heart rate in the right panel.\" width=\"420\" height=\"189\" \/> Figure 10-32: Side-by-side velocities and flow patterns of the right ophthalmic artery and carotid siphon on transcranial Doppler.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The transforaminal approach is then used to evaluate the intracranial vertebral arteries and the basilar arteries, as shown in Figure 10-33.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"484\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image46.png\" alt=\"\" width=\"484\" height=\"216\" \/> Figure 10-33: Side-by-side velocities and flow patterns of the left vertebral artery and basilar artery on transcranial Doppler.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">In the vertebral arteries, normal blood flow is away from the probe, the depth is 60\u201370 mm, and the velocity ranges from 27\u201355 cm\/sec. In the basilar arteries, normal blood flow is away from the probe, the depth is 80\u2013120 mm, and the velocity is 30\u201357 cm\/sec.<\/p>\r\n\r\n<h4 class=\"import-bh\">10.4.2 Sonography of the Carotid Arteries<\/h4>\r\n<p class=\"import-paft\">Figure 10-34 shows the positioning of the ultrasound probe for carotid artery evaluations. A high-frequency linear transducer (7.5\u201310 MHz) is most appropriate for carotid sonography. Transverse and longitudinal views are both imaged in B-mode, color, and spectral Doppler. In the sagittal plane, the ICA, external carotid artery (ECA), and right common carotid artery (CCA) are followed from the clavicle to the mandible with anterior, oblique, lateral, and posterior projections to identify plaque formation. Comparison flow characteristics are made from one side to the other as well as from proximal to distal segments of the ICA, ECA, and CCA.[footnote]Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561.[\/footnote] In the transverse plane, the ICA and CCA are followed to evaluate plaque formations. The percentage of stenosis can then be evaluated by looking at the diameter reduction. Plaque characteristics can be evaluated for calcification, thrombosis, and fibrosis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"500\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image52-1.png\" alt=\"\" width=\"500\" height=\"359\" \/> Figure 10-34: Carotid Doppler probe.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-35 shows the CCA in the proximal transverse plane with the jugular vein on top, demonstrating blood flow in the opposite direction following the BART principle. <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Prox<\/em><\/span> is the abbreviation used for <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">proximal<\/em><\/span> in the image for Figure 10-35 and some of the other following ones. Pulsed Doppler with spectral analysis is the primary tool for evaluating blood flow in the vascular study.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"602\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image53.jpg\" alt=\"\" width=\"602\" height=\"451\" \/> Figure 10-35: Right common carotid artery in the proximal transverse plane with the jugular vein on top, demonstrating blood flow in opposite directions.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-36 shows the pulsed wave (PW) Doppler with spectral analysis of the right CCA in the distal sagittal plane. Spectral analysis is a method of displaying the variety of frequencies of blood flow during systole and diastole. The scanner technology automatically analyzes and displays the individual frequencies of the returned signals, creating a velocity profile consisting of time on the horizontal axis, frequency shifts on the vertical axis, and amplitude as brightness. This combination of blood flow analysis and anatomic information is the basis of duplex ultrasonography,[footnote]Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4th ed. [place unknown]: Davies publishing; 2011. p. 442.[\/footnote] as discussed in Chapter 2.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D36,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image54.jpg\" alt=\"Doppler of carotid artery. Click image for long description.\" width=\"601\" height=\"451\" \/><\/a> Figure 10-36: Pulsed wave Doppler with spectral analysis of the common carotid artery in the distal sagittal plane.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D37,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image55-1.jpg\" alt=\"Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-37: Normal waveform of the right internal carotid artery.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D38,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image56-1.jpg\" alt=\"Doppler of carotid artery. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-38: Normal waveform of the right common carotid artery.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The Doppler characteristics of the carotid artery system are different. The ICA and CCA usually have low flow resistance, as shown in Figures 10-37 and 10-38, respectively. Flow occurs throughout the cardiac cycle. The diastolic segment does not touch the baseline. The ECA has high flow resistance with little or no diastolic or reversed diastolic flow. Reproducible and consistent velocity measurements require an angle of 60 degrees or less. Although a zero-degree angle of insonation provides the most remarkable Doppler shift because this depends on the angle\u2019s cosine, this would be difficult with most vessels. The criteria used for the interpretation of velocity measurements were established using a 60-degree angle.[footnote]Green L, Jorgensen T, Schroedter B, Bendick P. Carotid Duplex and Color Flow Imaging [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2012 Feb 20\u201322.[\/footnote],[footnote]Bandyk D, Armstrong PA, Neumyer MJ. Vascular Ultrasound Interpretation [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2012 August 9\u201310.[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Since the brain is a low-resistance vascular bed, the ICA is less pulsatile with increased flow during diastole. The typical waveform of the ICA has a rapid upstroke during systole and a high diastolic component with a possible dicrotic notch and gradual downslope.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">With the common carotid artery in the longitudinal plane, the transducer <ins>is <\/ins>angled more posterolaterally to identify the vertebral artery. Vertical shadows will appear running through the vertebral arteries, which are the transverse processes of the vertebrae, as shown in Figure 10-39. <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Vert<\/em><\/span> in the image represents the vertebral artery. Flow direction is documented.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D39,to%203%20cm.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image57-1.jpg\" alt=\"Right vertebral artery Doppler. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-39: Sagittal view of the right vertebral artery with color flow.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The ECA supplies blood to vascular areas with higher resistance, such as the scalp. It has a rapid upstroke in systole and rapid downstroke in diastole with a dicrotic notch, as shown in Figure 10-40.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D40,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image58.jpg\" alt=\"Right external carotid artery Doppler. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-40: Normal waveform of the right external carotid artery.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Both the CCA and vertebral arteries have low flow resistance. The flow characteristics are similar to the ICA. Multiple guidelines and trials are used to determine the percentage of diameter stenosis and clinically relevant stenosis. The ICA is of the most importance for surgical intervention. The Society of Radiologists in Ultrasound Consensus, one of the most widely used guidelines to assess ICA stenosis, is presented in Table 10-1 the table below.[footnote]Grant EG, Benson CB, Moneta GL, Alexandrov AV, Baker JD, Bluth EI, Carroll BA, Eliasziw M, Gocke J, Hertzberg BS, Katanick S, Needleman L, Pellerito J, Polak JF, Rholl KS, Wooster DL, Zierler RE. Carotid artery stenosis: Gray-scale and Doppler US diagnosis\u2014Society of Radiologists in Ultrasound Consensus Conference. Radiology. 2003 Nov;229(2):340\u20136. doi: 10.1148\/radiol.2292030516. Epub 2003 Sep 18. PMID: 14500855.[\/footnote]<\/p>\r\n<p class=\"import-th\" style=\"text-align: left\"><span style=\"text-decoration: underline\"><strong><span class=\"import-thn\">Table <\/span><span class=\"import-thn\">10<\/span><span class=\"import-thn\">-1:<\/span> Criteria for assessing Internal Carotid Artery Stenosis.<\/strong><\/span><\/p>\r\n<p class=\"import-fig\"><img class=\"alignnone\" src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image59.png\" alt=\"image\" width=\"850\" height=\"358\" \/><\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The North American Symptomatic Endarterectomy Trial was published in the journal <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Stroke<\/em><\/span> in 1991.[footnote]North American Symptomatic Carotid Endarterectomy Trial. Methods, patient characteristics, and progress. Stroke. 1991 Jun;22(6):711\u201320. doi: 10.1161\/01.str.22.6.711. PMID: 2057968.[\/footnote] The results concluded that patients with 70\u201399% stenosis of the ICA benefit from surgical intervention in the appropriate clinical setting.<\/p>\r\n\r\n<h4 class=\"import-bh\">10.4.3 Sonography of the Aorta<\/h4>\r\n<p class=\"import-paft\">The aorta is the largest artery in humans. It branches off the heart\u2019s left ventricle into the thoracic and abdominal cavities, as shown in Figure 10-41. The abdominal aorta branches into the right and left iliac arteries at the level of the umbilicus, where it carries oxygenated blood to each lower extremity. When the wall of the aorta weakens and expands, an aneurysm develops (with an increased risk of rupture under this high-pressure system).<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"586\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image3-2.png\" alt=\"\" width=\"586\" height=\"536\" \/> Figure 10-41: Schematic of the abdominal aorta showing that it branches into the right and left iliac arteries.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Each year, 200,000 people in the United States are diagnosed with an abdominal aortic aneurysm (AAA). Of these, nearly 7.5% have a life-threatening risk of rupture. The majority of patients with AAA are asymptomatic. The aorta\u2019s diameter must be greater less than 3 cm to be diagnosed as an aneurysm. When it reaches 5 cm or greater, very close monitoring and surgical options are entertained. Risk factors for an AAA include hypertension, smoking, and genetic factors, especially involving immediate relatives with AAA. Men over the age of 60 are also at greater risk.[footnote]Chaikof EL, Dalman RL, Eskandari MK, Jackson BM, Lee WA, Mansour MA, Mastracci TM, Mell M, Murad MH, Nguyen LL, Oderich GS, Patel MS, Schermerhorn ML, Starnes BW. The Society for Vascular Surgery practice guidelines on the care of patients with an abdominal aortic aneurysm. J Vasc Surg. 2018 Jan;67(1):2\u201377.e2. doi: 10.1016\/j.jvs.2017.10.044. PMID: 29268916.[\/footnote]<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">The ultrasound evaluation of the abdominal aorta (A or AA) should include the proximal, mid, and distal aorta to the bifurcation in the transverse and longitudinal planes, as shown in Figure 10-42. Evaluation of the branches of the aorta should include the celiac artery (C), superior mesenteric artery (SMA), and renal artery branches, as shown in Figures 10-43 and 10-44, without and with color Doppler, respectively.[footnote]Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561.[\/footnote] The abbreviations given in parentheses in this paragraph have been labeled in some of the ultrasound images discussed below.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"400\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image47.png\" alt=\"\" width=\"400\" height=\"320\" \/> Figure 10-42: Transducer position in the transverse and sagittal planes to evaluate the abdominal aorta.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image63-1.jpg\" alt=\"Abdominal ultrasound showing a sagittal view of the upper abdomen with three labeled structures. 'AA' in the lower left indicates the abdominal aorta, visible as a large anechoic tubular structure. 'C' in the center indicates the celiac artery origin, seen as a small vessel branching anteriorly from the aorta. 'SMA' to the right of center indicates the superior mesenteric artery, visible as a hyperechoic-walled tubular structure running parallel and anterior to the aorta. Surrounding echogenic and hypoechoic soft tissue structures are visible throughout the image.\" width=\"600\" height=\"450\" \/> Figure 10-43: Sagittal image of proximal aorta without Doppler showing the abdominal aorta, celiac artery, and superior mesenteric artery.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image64.jpg\" alt=\"Abdominal vascular ultrasound image with color Doppler overlay showing a sagittal or oblique view of the upper abdominal aorta and its major branches. Three structures are labeled within the color flow box: 'A' in the lower center indicates the abdominal aorta, displayed as a large red flow-filled vessel; 'C' to the upper left indicates the celiac artery, shown as a red flow-filled vessel branching anteriorly from the aorta; and 'SMA' to the upper right indicates the superior mesenteric artery, also shown in red branching anteriorly and running parallel to the aorta. Scattered blue flow signals are visible adjacent to the labeled vessels, representing surrounding venous structures. A color flow velocity scale on the right ranges from positive 46.2 to negative 46.2 cm\/s.\" width=\"601\" height=\"450\" \/> Figure 10-44: Sagittal image with color Doppler showing the abdominal aorta, celiac artery, and superior mesenteric artery.[\/caption]\r\n<h3 class=\"import-ah\">10.5 Arterial Sonography of the Lower Extremities<\/h3>\r\n<p class=\"import-paft\">Figure 10-45 shows the normal anatomical branches of the arterial system in the lower extremity. Peripheral artery disease (PAD) is a condition in which the arteries of the lower extremities are narrowed primarily from atherosclerosis. Approximately 8 million people in the United States have PAD. Men and women are affected equally. Risk factors include smoking, diabetes, hypertension, high cholesterol, and being over 60 years of age. A classic symptom of PAD is claudication, or pain when walking. Lower-extremity arterial duplex scanning is a noninvasive way to identify the presence and severity of arterial occlusive disease.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"631\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image4-1.png\" alt=\"Anatomical illustration of the lower extremity arterial system shown in anterior view from the pelvis to the foot, with arteries depicted in red. At the top, the Common Iliac Artery bifurcates into the Internal Iliac Artery and the External Iliac Artery. A green horizontal band marks the Groin Crease, below which the External Iliac Artery becomes the Common Femoral Artery. The Common Femoral Artery bifurcates into the Profunda Femoral Artery branching laterally and the Superficial Femoral Artery continuing distally. A second green horizontal band marks the Knee Crease, below which the vessel continues as the Popliteal Artery. The Popliteal Artery then bifurcates into the Tibioperoneal Trunk and the Anterior Tibial Artery. The Tibioperoneal Trunk further divides into the Posterior Tibial Artery and the Peroneal Artery at the bottom of the illustration.\" width=\"631\" height=\"542\" \/> Figure 10-45: Schematic showing normal anatomical branches of the arterial system in the lower extremity.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">It can also be used to follow the progression of the disease. The patient must rest for at least 20 minutes before testing, since this can affect the results, especially if the patient has PAD. The patient is then positioned supine with the lower extremities at the heart level so the hydrostatic pressure cannot falsely elevate the measurements.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">During an arterial Doppler exam, various cuffs are placed on the patient\u2019s legs and arms. This exam uses color wave (CW) Doppler. CW Doppler employs two crystals contained in the same probe<ins>:<\/ins> one that transmits the signal and one that receives the reflected sound wave of the blood cells. The reflected frequency is either higher or lower than the transmitted frequency, depending on the flow direction. This change in frequency is called the Doppler shift. The ankle brachial index (ABI) is recorded, and the waveforms are analyzed. The ABI is a simple test that compares the blood pressure in the upper and lower limbs. The ABI is calculated by dividing the blood pressure in an ankle artery by the blood pressure in an arm artery. An ABI value of less than 0.9 indicates PAD.<\/p>\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">An arterial duplex is another type of evaluation that uses ultrasound. It starts proximally at the common femoral artery with a side-by-side transverse image without and with color Doppler, followed by a sagittal image of the artery in red and sometimes the corresponding vein(s) in blue<ins>,<\/ins> and finally, a sagittal image of the artery with waveform analysis, which includes peak systolic velocity (PSV) and end-diastolic velocity (EDV). As the arterial study is performed from proximal to distal, the same approach is obtained with each artery, including, in succession, the common femoral artery (CFA), profunda femoral artery (Prof A), superficial femoral artery (SFA), popliteal artery (Pop A), posterior tibial artery (PTA), peroneal artery (Pero A), anterior tibial artery (ATA)<ins>,<\/ins> and dorsalis pedis artery (DPA). The abbreviations given in parentheses in the previous sentence have been labeled in some of the ultrasound images discussed below. The abbreviation <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Trans<\/em><\/span> used in some of these images is for <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">transverse<\/em><\/span>. Figures 10-46 and 10-47 show the transverse and sagittal views, respectively, of the side-by-side images of the right common femoral artery without and with color Doppler. Figure 10-48 shows the sagittal view of the right common femoral artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"599\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image66.jpg\" alt=\"Two-panel ultrasound image labeled 'Right CFA Trans' showing the right common femoral artery in transverse view. The left panel displays a grayscale image with two adjacent circular anechoic structures visible at approximately 1.5 to 2 cm depth, representing the common femoral artery and common femoral vein in cross-section, without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the common femoral artery is shown in red and orange indicating arterial flow toward the transducer, and the common femoral vein is shown in solid blue indicating venous flow away from the transducer. Small blue foci within the arterial signal may represent aliasing or small adjacent vessels. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"599\" height=\"449\" \/> Figure 10-46: Side-by-side transverse images of the right common femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D47,24.1%20cm\/s\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image67-1.jpg\" alt=\"Right common femoral artery Doppler. Click image for long description.\" width=\"601\" height=\"451\" \/><\/a> Figure 10-47: Side-by-side sagittal images of the right common femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D48,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image68-1.png\" alt=\"Right sagittal common femoral artery Doppler. Click image for long description.\" width=\"600\" height=\"463\" \/><\/a> Figure 10-48: Sagittal image of the right common femoral artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-49 and 10-50 show the transverse and sagittal views, respectively, of the right profunda femoral artery without and with color Doppler. Figure 10-51 shows the sagittal view of the right profunda femoral artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image69-1.jpg\" alt=\"Two-panel ultrasound image labeled 'Right Prof A Trans' showing the right profunda femoris artery in transverse view. The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 1 to 2 cm depth, representing the profunda femoris artery and an accompanying vein in cross-section, without color Doppler applied. The right panel displays the corresponding color Doppler image with the same structures now color-coded: two adjacent rounded structures are shown in red and orange indicating arterial flow toward the transducer, with a small focal area of blue signal between them, and a separate blue structure visible in the lower right representing a deeper venous structure. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/> Figure 10-49: Side-by-side transverse images of the right profunda femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D50,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image70.jpg\" alt=\"Sagittal right profunda femoral artery Doppler. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-50: Side-by-side sagittal images of the right profunda femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D51,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image71-1.jpg\" alt=\"Right profunda femoral artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-51: Sagittal image of the right profunda femoral artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-52 and 10-53 show the transverse and sagittal views, respectively, of the right proximal superficial femoral artery without and with color Doppler. Figure 10-54 shows the sagittal view of the right proximal superficial femoral artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image72.jpg\" alt=\"The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 1.5 to 2 cm depth, representing the superficial femoral artery and superficial femoral vein in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superficial femoral artery is shown as a smaller round red structure in the upper right indicating arterial flow toward the transducer, and the superficial femoral vein is shown as a larger round blue structure in the lower left indicating venous flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/> Figure 10-52: Side-by-side transverse images of the right proximal superficial femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image73.jpg\" alt=\"The left panel displays a grayscale image with two parallel anechoic tubular structures running horizontally at approximately 1.5 to 2.5 cm depth, representing the superficial femoral artery above and the superficial femoral vein below in longitudinal section, without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superior vessel, the superficial femoral artery, is shown as a broad band of red and orange flow signal indicating arterial flow toward the transducer, and the inferior vessel, the superficial femoral vein, is shown as a broad band of blue flow signal indicating venous flow away from the transducer. A thin anechoic separation is visible between the two color-coded vessels. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-53: Side-by-side sagittal images of the right proximal superficial femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D54,depth%20of%201.9cm.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image74.jpg\" alt=\"Sagittal of the right proximal superficial femoral artery Doppler. Click image for long description.\" width=\"601\" height=\"450\" \/><\/a> Figure 10-54: Sagittal image of the right proximal superficial femoral artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-55 and 10-56 show the transverse and sagittal views, respectively, of the right middle superficial femoral artery without and with color Doppler. Figure 10-57 shows the sagittal view of the right middle superficial femoral artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image75.jpg\" alt=\"The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 1.5 to 2 cm depth, representing the superficial femoral artery and superficial femoral vein in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superficial femoral artery is shown as a smaller round red structure in the upper right indicating arterial flow toward the transducer, and the superficial femoral vein is shown as a larger round blue structure in the lower left indicating venous flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-55: Side-by-side transverse images of the right middle superficial femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D56,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image76.jpg\" alt=\"Sagittal of the right middle superficial femoral artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-56: Sagittal image of the right middle superficial femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D57,depth%20of%202.0cm.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image77.jpg\" alt=\"Sagittal of the right middle superficial femoral artery Doppler comparison. Click on image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-57: Sagittal image of the right middle superficial femoral artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-58 and 10-59 show the transverse and sagittal views of the right distal superficial femoral artery without and with color Doppler. Figure 10-60 shows the sagittal view of the right distal superficial femoral artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image78.jpg\" alt=\"The left panel displays a grayscale image with two adjacent anechoic structures visible at approximately 2 to 3 cm depth, representing the distal superficial femoral artery and accompanying vein in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superficial femoral artery is shown as a smaller round red structure in the upper portion indicating arterial flow toward the transducer, and the accompanying vein is shown as an elongated blue structure below indicating venous flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-58: Side-by-side transverse images of the right distal superficial femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D59,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image79-1.jpg\" alt=\"Sagittal of the right distal superficial femoral artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-59: Sagittal images of the right distal superficial femoral artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image80.jpg\" alt=\"A medical ultrasound scan screen displaying a duplex Doppler evaluation of the right distal superficial femoral artery (Right SFA Dist SAG). The top half shows a grayscale B-mode ultrasound image with a color Doppler box highlighting a blood vessel filled with orange-red flow. The bottom half displays a pulsed-wave Doppler spectral waveform showing a triphasic arterial flow pattern with prominent peaks. Text on the screen indicates measurements including a Peak Systolic Velocity (PSV) of 133 cm\/s and an End Diastolic Velocity (EDV) of 18.2 cm\/s.\" width=\"601\" height=\"450\" \/> Figure 10-60: Sagittal image of the right distal superficial femoral artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-61 and 10-62 show the transverse and sagittal views, respectively, of the right popliteal artery without and with color Doppler. Figure 10-63 shows the sagittal view of the right popliteal artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image81.jpg\" alt=\"The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 2.5 to 3 cm depth within the popliteal fossa, representing the popliteal vein and popliteal artery in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the popliteal vein is shown as a larger irregular blue structure in the upper portion indicating venous flow away from the transducer, and the popliteal artery is shown as a smaller round red structure in the lower portion indicating arterial flow toward the transducer. A small additional red focal signal is visible below the artery representing a small adjacent vessel. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/> Figure 10-61: Side-by-side transverse images of the right popliteal artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image82-1.jpg\" alt=\"The left panel displays a grayscale image with a single anechoic tubular structure running horizontally at approximately 2 cm depth within the popliteal fossa, representing the popliteal artery in longitudinal section without color Doppler applied. The right panel displays the corresponding color Doppler image with the popliteal artery now shown as a broad band of solid red flow signal indicating arterial flow toward the transducer, and a small focal blue structure visible below the artery representing the adjacent popliteal vein or a small tributary. A small red signal is visible at the top of the color box representing a superficial vessel. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-62: Side-by-side sagittal images of the right popliteal artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"602\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D63,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image83.jpg\" alt=\"Sagittal of the right popliteal artery Doppler comparison. Click image for long description.\" width=\"602\" height=\"451\" \/><\/a> Figure 10-63: Sagittal image of the right popliteal artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-64 and 10-65 show the transverse and sagittal views, respectively, of the right posterior tibial artery without and with color Doppler. Figure 10-66 shows the sagittal view of the right posterior tibial artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image84.png\" alt=\"The left panel displays a grayscale image with multiple small anechoic structures visible at approximately 1 cm depth, representing the posterior tibial artery and accompanying paired veins in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same structures now color-coded: a small red structure in the upper left indicates the posterior tibial artery with flow toward the transducer, and two adjacent blue structures to the right indicate the paired posterior tibial veins with flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-64: Side-by-side transverse images of the right posterior tibial artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D65,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image85.jpg\" alt=\"Side-by-side sagittal of the right posterior tibial artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-65: Side-by-side sagittal images of the right posterior tibial artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D66,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image86-1.jpg\" alt=\"Sagittal of the right posterior tibial artery Doppler and analysis. Click image for long description.\" width=\"601\" height=\"451\" \/><\/a> Figure 10-66: Sagittal image of the right posterior tibial artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-67 and 10-68 show the transverse and sagittal views, respectively, of the right peroneal artery without and with color Doppler. Figure 10-69 shows the sagittal view of the right peroneal artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image87.jpg\" alt=\"The left panel displays a grayscale image with soft tissue structures visible at depth ranging from 1 to 6 cm, with small anechoic structures visible at approximately 4 cm depth representing the peroneal artery and accompanying veins in cross-section within the deep posterior compartment, without color Doppler applied. The right panel displays the corresponding color Doppler image with a color flow box positioned at approximately 3.5 to 5 cm depth, showing a small focal red signal indicating the peroneal artery with flow toward the transducer, deep within the surrounding muscle tissue. No venous flow signal is visible adjacent to the arterial signal in this view. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/> Figure 10-67: Side-by-side transverse images of the right peroneal artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"602\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D68,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image88.jpg\" alt=\"Sagittal images of the right peroneal artery Doppler comparison. Click image for long description.\" width=\"602\" height=\"451\" \/><\/a> Figure 10-68: Side-by-side sagittal images of the right peroneal artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D69,20%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image89-1.jpg\" alt=\"Sagittal of the right peroneal artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-69: Sagittal image of the right peroneal artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-70 shows the side-by-side sagittal view of the right anterior tibial artery without and with color Doppler. Figure 10-71 shows the sagittal view of the right anterior tibial artery with color Doppler and waveform analysis.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D70,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image90.jpg\" alt=\"Sagittal images of the right anterior tibial artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-70: Side-by-side sagittal images of the right anterior tibial artery without color Doppler and with color Doppler.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D71,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image91.jpg\" alt=\"Sagittal of the right anterior tibial artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-71: Sagittal image of the right anterior tibial artery with color Doppler and waveform analysis.[\/caption]\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"601\"]<img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image92.jpg\" alt=\"The left panel displays a grayscale image with a small anechoic structure visible at approximately 1 cm depth within the superficial soft tissue of the dorsal foot, representing the dorsalis pedis artery in cross-section without color Doppler applied. Hyperechoic bony structures are visible in the deeper tissue. The right panel displays the corresponding color Doppler image with the dorsalis pedis artery now shown as a small round red structure at approximately 1 cm depth, indicating arterial flow toward the transducer within the superficial dorsal foot tissue. No adjacent venous signal is visible in this view. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/> Figure 10-72: Side-by-side transverse images of the right dorsalis pedis artery without color Doppler and with color Doppler.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-72 shows the transverse view of the right dorsalis pedis artery without and with color Doppler. Figure 10-73 shows the sagittal view of the right dorsalis pedis artery with color Doppler and waveform analysis.<\/p>\r\n<p class=\"import-figh\"><span class=\"import-fighn\">Figure 10-73:<\/span> Sagittal image of the right dorsalis pedis artery with color Doppler.<\/p>\r\n\r\n\r\n[caption id=\"\" align=\"aligncenter\" width=\"600\"]<a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D73,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image94.jpg\" alt=\"Sagittal of the right dorsalis pedis artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a> Figure 10-73: Sagittal image of the right dorsalis pedis artery with color Doppler and waveform analysis.[\/caption]\r\n<p class=\"import-p\" style=\"text-indent: 36pt\">When evaluating the lower extremities for diagnostic criteria for PAD, the PSV and velocity ratio (VR) are often used. The VR is defined as the ratio of the PSV of the stenotic area to the PSV of the standard proximal segment. The degree of stenosis is determined by these values of the PSV and VR, as illustrated in Table 10-2.[footnote]Hodgkiss-Harlow KD, Bandyk DF. Interpretation of arterial duplex testing of lower-extremity arteries and interventions. Semin Vasc Surg. 2013 Jun\u2013Sep;26(2\u20133):95\u2013104. doi: 10.1053\/j.semvascsurg.2013.11.002. Epub 2013 Nov 14. PMID: 24636606.[\/footnote]<\/p>\r\n<p class=\"import-th\"><span style=\"text-decoration: underline\"><strong><span class=\"import-thn\">Table <\/span><span class=\"import-thn\">10<\/span><span class=\"import-thn\">-<\/span><span class=\"import-thn\">2<\/span><span class=\"import-thn\">:<\/span> Guidelines for determining the degree of stenosis.<\/strong><\/span><\/p>\r\n\r\n<table>\r\n<tbody>\r\n<tr class=\"TableGrid-R\">\r\n<th class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\" scope=\"col\">\r\n<p class=\"import-tch\">Degree of stenosis<\/p>\r\n<\/th>\r\n<th class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\" scope=\"col\">\r\n<p class=\"import-tch\">Peak systolic velocity (cm\/s)<\/p>\r\n<\/th>\r\n<th class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\" scope=\"col\">\r\n<p class=\"import-tch\">Velocity ratio<\/p>\r\n<\/th>\r\n<\/tr>\r\n<tr class=\"TableGrid-R\">\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">&lt;20%<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">&lt;150<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">&lt;1.5<\/p>\r\n<\/td>\r\n<\/tr>\r\n<tr class=\"TableGrid-R\">\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">20\u201349%<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">150\u2013200<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">1.5\u20132.0<\/p>\r\n<\/td>\r\n<\/tr>\r\n<tr class=\"TableGrid-R\">\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">50\u201380%<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">200\u2013300<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">2.0\u20134.0<\/p>\r\n<\/td>\r\n<\/tr>\r\n<tr class=\"TableGrid-R\">\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">&gt;80%<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">&gt;300<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">&gt;4.0<\/p>\r\n<\/td>\r\n<\/tr>\r\n<tr class=\"TableGrid-R\">\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">Occlusion<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">No flow detected in lumen<\/p>\r\n<\/td>\r\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\r\n<p class=\"import-td\">N\/A<\/p>\r\n<\/td>\r\n<\/tr>\r\n<tr>\r\n<td><\/td>\r\n<td><\/td>\r\n<td><\/td>\r\n<\/tr>\r\n<\/tbody>\r\n<\/table>\r\n<div class=\"textbox textbox--exercises\"><header class=\"textbox__header\">\r\n<p class=\"textbox__title\">10.6 Self-Assessment<\/p>\r\n\r\n<\/header>\r\n<div class=\"textbox__content\">\r\n<ol>\r\n \t<li>What happens to ultrasound imaging of normal veins when you apply downward pressure with the transducer?<\/li>\r\n \t<li>What frequency transducer would you typically use to evaluate the circle of Willis?<\/li>\r\n \t<li>What kind of Doppler is used to evaluate the arterial system of the lower extremities?<\/li>\r\n<\/ol>\r\n<\/div>\r\n<\/div>\r\n<div class=\"textbox textbox--examples\"><header class=\"textbox__header\">\r\n<p class=\"textbox__title\">10.7 Further Readings<\/p>\r\n\r\n<\/header>\r\n<div class=\"textbox__content\">\r\n<ol>\r\n \t<li>Pugsley MK, Tabrizchi R. The vascular system. An overview of structure and function. J Pharmacol Toxicol Methods. 2000 Sep\u2013Oct;44(2):333\u201340. doi: 10.1016\/s1056-8719(00)00125-8. PMID: 11325577.<\/li>\r\n \t<li>Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4<span style=\"border: none windowtext 0pt;padding: 0\"><sup class=\"import-sup\">th<\/sup><\/span> ed. [place unknown]: Davies publishing; 2011. p. 442.<\/li>\r\n \t<li>Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.<\/li>\r\n \t<li>Zemaitis MR, Boll JM, Dreyer MA. Peripheral Arterial Disease. [Updated 2023 May 23]. In: StatPearls [internet]. Treasure Island (FL): StatPearls Publishing; 2023 Jan\u2013. Available from: <span style=\"border: none windowtext 0pt;padding: 0\"><a class=\"rId117\" href=\"https:\/\/www.ncbi.nlm.nih.gov\/books\/NBK430745\/\"><span class=\"import-url\">https:\/\/www.ncbi.nlm.nih.gov\/books\/NBK430745\/<\/span><\/a><\/span><\/li>\r\n<\/ol>\r\n<\/div>\r\n<\/div>","rendered":"<div class=\"textbox textbox--learning-objectives\">\n<header class=\"textbox__header\">\n<p class=\"textbox__title\">10.1 Learning Objectives<\/p>\n<\/header>\n<div class=\"textbox__content\">\n<p class=\"import-pf\">After reviewing this chapter, you should be able to do the following:<\/p>\n<ol>\n<li>View and identify the anatomical structures of the venous systems and the corresponding ultrasound images.<\/li>\n<li>Explore the arterial system and the corresponding ultrasound images.<\/li>\n<\/ol>\n<\/div>\n<\/div>\n<h2 class=\"import-ah\">10.2 Introduction<\/h2>\n<p class=\"import-paft\">The topics covered in this section will include some of the ultrasound basics of the venous and arterial systems, including transcranial, carotid, aorta, and lower-extremity ultrasound imaging.<\/p>\n<h3 class=\"import-ah\">10.3 The Venous System<\/h3>\n<p class=\"import-paft\">The primary physiologic functions of the venous system are to return the deoxygenated blood to the heart, thermoregulate, store blood (at any instance, the venous system contains up to 70% of the circulating blood), and regulate the cardiac output. It is divided into three systems: superficial, perforating, and deep veins. Figure 10-1 shows the anatomy of the venous system. Blood flows from the superficial to deep veins through branching perforating veins. The deep veins usually follow the arteries in the same areas and often have similar names. For example, the femoral vein is beside the femoral artery. The deep venous system eventually returns blood to the right side of the heart. Since the venous system is usually a low-pressure system, veins have bicuspid valves to allow flow in one direction from superficial to deep (the foot is the exception) and from distal to proximal. Muscular contraction helps with venous flow, such as in the calf muscle pump in the leg.<a class=\"footnote\" title=\"Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561.\" id=\"return-footnote-294-1\" href=\"#footnote-294-1\" aria-label=\"Footnote 1\"><sup class=\"footnote\">[1]<\/sup><\/a><\/p>\n<figure style=\"width: 849px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D1,and%20%E2%80%9CDorsal%20Digital.%E2%80%9D\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image1-15.png\" alt=\"Click image for long description.\" width=\"849\" height=\"1097\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-1: Anatomy of the venous system.<\/figcaption><\/figure>\n<figure style=\"width: 349px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D2,directing%20flow%20upward.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image16.png\" alt=\"Anatomy of venous system in the leg. Click image for long description.\" width=\"349\" height=\"524\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-2: Valves in the venous system of the leg.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Venous pathophysiology has many etiologies, such as trauma and genetic predisposition, and can occur when outflow is impaired by dysfunctional valves, resulting in retrograde flow and causing a condition known as chronic venous insufficiency. Vein thrombosis is another condition with many hereditary and acquired etiologies, such as trauma or prolonged immobilization. Deep vein thrombosis is especially important to evaluate and treat.<a class=\"footnote\" title=\"Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\" id=\"return-footnote-294-2\" href=\"#footnote-294-2\" aria-label=\"Footnote 2\"><sup class=\"footnote\">[2]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The great saphenous vein (GSV) is the longest vein in the human body, as shown in Figure 10-2. It originates in the medial aspect of the foot as part of the dorsal arch. It continues proximally along the medial aspect of the foot and passes anterior to the medial malleolus on the tibia. It ascends along the medial aspect of the leg between the superficial and deep fascia. It typically has 10\u201320 valves and terminates at the saphenofemoral junction (SFJ). Once flow enters the femoral vein, it is in the deep venous system. Venous anatomy can vary from individual to individual. However, the GSV typically has branching superficial veins, such as the anterior and posterior accessory saphenous veins in the thigh.<a class=\"footnote\" title=\"Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\" id=\"return-footnote-294-3\" href=\"#footnote-294-3\" aria-label=\"Footnote 3\"><sup class=\"footnote\">[3]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The small saphenous vein (SSV) is the second most significant superficial vein that joins the dorsal venous arch in the lateral aspect of the foot. It ascends proximally behind the lateral malleolus and terminates into the deep popliteal vein, although this is highly variable and can extend into the thigh. The SSV typically has 9\u201312 valves. Like the GSV, the SSV lies between the superficial and deep fascia and can have many branching superficial veins. Perforating veins connect superficial to deep veins. They usually contain a bicuspid valve.<a class=\"footnote\" title=\"Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\" id=\"return-footnote-294-4\" href=\"#footnote-294-4\" aria-label=\"Footnote 4\"><sup class=\"footnote\">[4]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The deep venous system includes the common femoral vein, profunda femoral vein, deep femoral vein, popliteal vein, gastrocnemius veins, soleus veins, anterior tibial veins, posterior tibial veins, and peroneal veins. The direction of venous flow is described as antegrade, retrograde, or absent. In both the deep and superficial venous systems, it is essential to check for the following characteristics: compressibility, spontaneous flow, respiratory variation, augmentation, intraluminal defects, and venous reflux.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Compressibility evaluates if the vein collapses by applying downward pressure with the transducer. Typically, it should compress, since it is a low-pressure vessel. A thrombus can occlude the lumen and prevent compression. Spontaneous flow is observed when the blood flow moves actively without external influences, such as an augmentation maneuver. Respiratory variation, also known as phasicity, refers to regular venous flow changes that occur secondary to intrathoracic pressure during breathing cycles. Augmentation is a maneuver that is used to evaluate possible abnormal flow patterns. For example, by squeezing a distal portion in the calf, an increase in venous flow should be observed just proximal to this area. Absent or diminished flow could suggest obstruction, such as in a thrombus formation, and reversal of flow could indicate incompetent venous valves, such as in venous reflux disease.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Intraluminal defects usually describe a thrombus formation within the lumen of the vein. It is crucial to describe the details of the thrombus formation and whether it is obstructive.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Finally, venous reflux describes blood flow going in the wrong direction, usually from incompetent valves. Maneuvers are usually done to augment blood flow to test for reflux, which is significant if it exceeds 0.5 seconds in the superficial venous system, 0.35 seconds in perforators, and 1 second in the deep venous system.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">A complete venous duplex ultrasound of the lower extremities starts with a proximal to distal evaluation of the deep venous system in a transverse (TRV) side-by-side image without compression and with compression (COMP). This is followed by a sagittal (SAG) view with augmentation (AUG) using the color Doppler. The veins that are evaluated in succession include the common femoral vein (CFV), profunda femoral vein (PROF V), femoral vein (FV), popliteal vein (POP V), gastrocnemius vein (GASTROC V), posterior tibial vein (PTV), peroneal vein (PERO V), anterior tibial vein (ATV), great saphenous vein (GSV), and small saphenous vein (SSV). The abbreviations given in parentheses in the last few sentences have been labeled in some of the following ultrasound images for venous system discussion. Figure 10-3 shows a side-by-side transverse ultrasound view of the right common femoral vein without compression and with compression, while Figure 10-4 represents the sagittal view of the right common femoral vein with augmentation.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image17-1.png\" alt=\"Two-panel grayscale ultrasound image of the right common femoral vein in transverse view. The left panel, labeled 'RIGHT CFV TRV,' shows a transverse cross-sectional view of the right common femoral vein appearing as a rounded anechoic structure without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse or deformation of the vessel lumen.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-3: Side-by-side transverse ultrasound views of the right common femoral vein without compression and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image18.jpg\" alt=\"The upper panel displays a color Doppler image with a large area of orange and yellow flow signal within a blue background, indicating robust venous flow within the vessel lumen in response to augmentation. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform, displaying phasic flow with augmentation peaks visible as downward deflections below the baseline, consistent with normal venous flow pattern.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-4: Right common femoral vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-5 shows a side-by-side transverse ultrasound view of the right profunda femoral vein without compression and with compression, while Figure 10-6 represents the sagittal view of the right profunda femoral vein with augmentation.<\/p>\n<figure style=\"width: 430px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image19.jpg\" alt=\"Two-panel grayscale ultrasound image of the right profunda femoris vein in transverse view. The left panel, labeled 'RIGHT PROF V TRV,' shows a transverse cross-sectional view of the right profunda femoris vein appearing as a rounded anechoic structure adjacent to surrounding soft tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen.\" width=\"430\" height=\"322\" \/><figcaption class=\"wp-caption-text\">Figure 10-5: Side-by-side transverse image of the right profunda femoral vein without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 423px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image20.jpg\" alt=\"The upper panel displays a color Doppler image with prominent red and orange flow signals in the upper portion of the color box indicating arterial flow, and blue flow signal in the lower portion indicating venous flow in the profunda femoris vein. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform displayed with inverted orientation, showing phasic flow with augmentation peaks visible both above and below the baseline, consistent with venous flow response to augmentation maneuver. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"423\" height=\"317\" \/><figcaption class=\"wp-caption-text\">Figure 10-6: Right profunda femoral vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-7 shows a side-by-side transverse ultrasound view of the right femoral vein without compression and with compression, while Figure 10-8 represents the sagittal view of the right femoral vein with augmentation.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image21.jpg\" alt=\"The left panel, labeled 'RIGHT FV TRV,' shows a transverse cross-sectional view of the right femoral vein appearing as a rounded anechoic structure adjacent to the femoral artery, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating partial collapse of the femoral vein lumen while the adjacent femoral artery remains round and non-compressible.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-7: Side-by-side right femoral vein transverse view without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image22.jpg\" alt=\"The upper panel displays a color Doppler image with a large band of red and orange flow signal in the upper portion of the color box indicating arterial flow in the femoral artery, and a parallel band of blue flow signal in the lower portion indicating venous flow in the femoral vein. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with flow deflecting below the baseline, displaying rhythmic phasic waveforms with augmentation peaks consistent with normal venous flow response. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-8: Right femoral vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-9 shows a side-by-side transverse ultrasound view of the right popliteal vein without compression and with compression, while Figure 10-10 represents the sagittal view of the right popliteal vein with augmentation.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image23-1.png\" alt=\"The left panel, labeled 'RIGHT POP V TRV,' shows a transverse cross-sectional view of the right popliteal vein appearing as a rounded anechoic structure adjacent to the popliteal artery within the popliteal fossa, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the popliteal vein lumen while the adjacent popliteal artery remains round and non-compressible.\" width=\"601\" height=\"451\" \/><figcaption class=\"wp-caption-text\">Figure 10-9: Side-by-side right popliteal vein transverse view without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image24.jpg\" alt=\"The upper panel displays a color Doppler image with a large band of blue flow signal spanning the upper portion of the color box indicating venous flow in the popliteal vein, and a focal area of red and orange flow signal in the lower right portion indicating the adjacent popliteal artery. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with flow deflecting above and below the baseline, displaying phasic waveforms with a prominent augmentation peak visible as a tall upward deflection, consistent with normal venous flow response to augmentation maneuver. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-10: Right popliteal vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-11 shows a side-by-side transverse ultrasound view of the right gastrocnemius vein without compression and with compression, while Figure 10-12 represents the sagittal view of the right gastrocnemius vein with augmentation.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image25-1.png\" alt=\"Two-panel grayscale ultrasound image of the right gastrocnemius vein in transverse view. The left panel, labeled 'RIGHT GASTROC V TRV,' shows a transverse cross-sectional view of the right gastrocnemius vein appearing as a small anechoic structure within the gastrocnemius muscle tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen within the surrounding muscle.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-11: Side-by-side right gastrocnemius vein transverse view without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image26.jpg\" alt=\"The upper panel displays a color Doppler image with a focal area of blue flow signal and a small adjacent red signal within the gastrocnemius muscle, indicating venous flow in the gastrocnemius vein with minimal surrounding vascularity. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform displayed near the baseline, with low-amplitude phasic flow and a visible augmentation response toward the right side of the waveform, consistent with spontaneous and augmented venous flow in a small muscular vein. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"601\" height=\"451\" \/><figcaption class=\"wp-caption-text\">Figure 10-12: Right gastrocnemius vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-13 shows a side-by-side transverse ultrasound view of the right posterior tibial vein without compression and with compression, while Figure 10-14 represents the sagittal view of the right posterior tibial vein with augmentation.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image27-1.png\" alt=\"The left panel, labeled 'RIGHT PTV TRV,' shows a transverse cross-sectional view of the right posterior tibial vein appearing as small anechoic structures within the surrounding soft tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-13: Side-by-side right posterior tibial veins transverse view without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 609px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image28.jpg\" alt=\"The upper panel displays a color Doppler image with mixed orange, red, and blue flow signals filling the color box, indicating adjacent arterial and venous flow in the posterior tibial vessels. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform deflecting below the baseline, displaying continuous phasic venous flow with a prominent deep augmentation peak visible in the center of the waveform, consistent with a robust venous flow response to augmentation maneuver in the posterior tibial vein. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"609\" height=\"457\" \/><figcaption class=\"wp-caption-text\">Figure 10-14: Right posterior tibial veins sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-15 shows a side-by-side transverse ultrasound view of the right peroneal vein without compression and with compression, while Figure 10-16 represents the sagittal view of the right peroneal vein with augmentation.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image29-1.png\" alt=\"Two-panel ultrasound image of the right peroneal vein in transverse view. The left panel, labeled 'RIGHT PERO V TRV,' shows a transverse cross-sectional view of the right peroneal vein appearing as small anechoic structures within the surrounding deep soft tissue, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen within the surrounding tissue.\" width=\"601\" height=\"451\" \/><figcaption class=\"wp-caption-text\">Figure 10-15: Side-by-side right peroneal veins transverse view without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 602px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image30.jpg\" alt=\"The upper panel displays a color Doppler image with a small focal area of blue flow signal within a color box positioned at approximately 3 to 4 cm depth, indicating venous flow in the peroneal vein within the deep soft tissue. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with low-amplitude flow near the baseline and a prominent augmentation peak deflecting below the baseline in the center of the waveform, consistent with venous flow response to augmentation maneuver in the peroneal vein. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"602\" height=\"452\" \/><figcaption class=\"wp-caption-text\">Figure 10-16: Right peroneal vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-17 shows a side-by-side transverse ultrasound view of the anterior tibial vein without compression and with compression, while Figure 10-18 represents the sagittal view of the right anterior tibial vein with augmentation.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image31-1.png\" alt=\"Two-panel ultrasound image of the right anterior tibial vein in transverse view. The left panel, labeled 'RIGHT ATV TRV,' shows a transverse cross-sectional view of the right anterior tibial vein appearing as small anechoic structures within the surrounding deep soft tissue at approximately 2.5 to 3 cm depth, without compression applied. The right panel, labeled 'COMP,' shows the same view with compression applied, demonstrating collapse of the vessel lumen within the surrounding tissue.\" width=\"601\" height=\"451\" \/><figcaption class=\"wp-caption-text\">Figure 10-17: Side-by-side right anterior tibial vein transverse view without and with compression.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D18,4.8%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image32.jpg\" alt=\"Click image for long description.\" width=\"601\" height=\"451\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-18: Right anterior tibial vein sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Next, in the complete venous duplex ultrasound, we look at the superficial venous system from proximal to distal, starting with the GSV at the SFJ in the transverse plane with a side-by-side image without and with color Doppler, followed by a sagittal image with augmentation with color Doppler. Figure 10-19 shows a side-by-side transverse ultrasound view of the right GSV at the SFJ, while Figure 10-20 represents the sagittal view of the right GSV at the SFJ with augmentation.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image33.jpg\" alt=\"Duplex ultrasound image labeled 'RIGHT GSV SFJ TRV' showing the right great saphenous vein at the saphenofemoral junction in transverse view. The left portion of the image displays a grayscale view showing two adjacent anechoic vascular structures within the surrounding soft tissue. The right portion displays the corresponding color Doppler image with a large round red and orange structure in the upper left indicating the femoral artery in cross-section, and a larger adjacent blue flow-filled structure representing the common femoral vein with the great saphenous vein junction, showing mixed blue and yellow-orange color signals indicating venous flow at the saphenofemoral junction. A Doppler angle correction line is visible on the right side of the color image. Depth markers range from 0 to 3 cm.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-19: Side-by-side right great saphenous vein at the saphenofemoral junction transverse view without and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D20,4.8%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image34.jpg\" alt=\"Right great saphenous vein ultrasound. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-20: Right great saphenous vein at the saphenofemoral junction sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Next, we continue to follow and evaluate the GSV distally from above the knee (AK) to below the knee (BK) in the transverse plane without color, followed by the sagittal plane with augmentation with color Doppler. The abbreviations AK and BK have been used in the ultrasound images discussed here. Figure 10-21 shows a side-by-side transverse ultrasound view of the right GSV above the knee. Figure 10-22 represents the sagittal view of the right GSV above the knee with augmentation.<\/p>\n<figure style=\"width: 602px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image35-1.png\" alt=\"Ultrasound labeled 'R GSV AK DIAM 0.27 cm AK TRV' showing a transverse view of the right great saphenous vein above the knee with a diameter measurement. A small round anechoic structure near the top center of the image represents the great saphenous vein in cross-section, with caliper markers placed across its lumen recording a diameter of 0.27 cm. A larger adjacent anechoic structure below and to the right represents a deeper vessel or tissue plane.\" width=\"602\" height=\"451\" \/><figcaption class=\"wp-caption-text\">Figure 10-21: Right great saphenous vein transverse view above the knee.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image36.jpg\" alt=\"The upper panel displays a color Doppler image with a thin band of blue flow signal running horizontally near the top of the color box, indicating venous flow within the superficial great saphenous vein at approximately 0.5 cm depth. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with low-amplitude flow deflecting below the baseline, displaying continuous phasic venous flow consistent with spontaneous and augmented flow in the great saphenous vein above the knee. No prominent augmentation peak is visible.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-22: Right great saphenous vein above the knee sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-23 shows a transverse ultrasound view of the right GSV below the knee, while Figure 10-24 represents the sagittal view of the right GSV below the knee with augmentation.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image37.jpg\" alt=\"Ultrasound image labeled 'R GSV BK DIAM 0.20 cm BK TRV' showing a transverse view of the right great saphenous vein below the knee with a diameter measurement. A small round anechoic structure near the top center of the image represents the great saphenous vein in cross-section, with caliper markers placed across its lumen recording a diameter of 0.20 cm. Additional small anechoic structures are visible adjacent to the measured vessel. Surrounding soft tissue planes are visible throughout the image with color overlay artifact. Depth markers on the right range from 0 to 3 cm.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-23: Right great saphenous vein below the knee transverse view.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image38-1.jpg\" alt=\"The upper panel displays a color Doppler image with a thin band of blue flow signal running horizontally near the top of the color box, indicating venous flow within the superficial great saphenous vein at approximately 0.4 cm depth. A hyperechoic linear structure is visible in the lower portion of the image. A Doppler angle correction line is visible crossing the color flow box. The lower panel shows the corresponding pulsed wave spectral Doppler waveform with low-amplitude continuous flow deflecting below the baseline in the left portion of the waveform, and a brief augmentation peak deflecting above the baseline near the center. A color flow velocity scale on the right ranges from positive 4.8 to negative 4.8 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-24: Right great saphenous vein below the knee sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The next superficial vein to be evaluated is the SSV, starting in the popliteal area of the lower extremity and using the same approach as the great saphenous vein. We first start with a transverse image at the saphenopopliteal junction (SPJ) without color Doppler, followed by a sagittal image with augmentation with color Doppler. Figure 10-25 shows a side-by-side transverse ultrasound view of the right SSV at the SPJ, while Figure 10-26 represents the sagittal view of the right SSV at the SPJ with augmentation.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image39-1.png\" alt=\"Ultrasound labeled 'R SSV SPJ DIAM 0.33 cm SPJ TRV' showing a transverse view of the right small saphenous vein at the saphenopopliteal junction with a diameter measurement. A round anechoic structure near the top center of the image represents the small saphenous vein in cross-section, with caliper markers placed across its lumen recording a diameter of 0.33 cm. Additional adjacent anechoic structures are visible in the surrounding tissue representing nearby vessels at the saphenopopliteal junction. Depth markers on the right range from 0 to 3 cm.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-25: Right small saphenous vein at the saphenopopliteal junction transverse view.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D26,4.8%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image40.jpg\" alt=\"Doppler of small saphenous vein. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-26: Right small saphenous vein at the saphenopopliteal junction sagittal view with augmentation.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Also, anterior and posterior accessory saphenous veins are often evaluated as part of the superficial venous system, and perforating veins that connect superficial to deep veins are often evaluated during the study.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The template shown in the next couple of pages can be used to perform a complete venous duplex Doppler ultrasound examination of the lower extremities.<\/p>\n<div class=\"textbox\">\n<p class=\"import-exf\">Date ________________ U\/S technician _________________ Physician _______________<\/p>\n<p class=\"import-ex\" style=\"text-indent: 36pt\">Complaint ____________________________ Comparative study ___________________<\/p>\n<p><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/04\/image1.png\" alt=\"image\" width=\"617.466666666667px\" height=\"261.866666666667px\" \/><\/p>\n<p class=\"import-exf\"><span class=\"import-u\">DEEP VENOUS SYSTEM<\/span><\/p>\n<p><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/04\/image4.png\" alt=\"image\" width=\"623.6px\" height=\"506.866666666667px\" \/><\/p>\n<p class=\"import-exf\"><span class=\"import-u\">SUPERFICIAL VENOUS SYSTEM<\/span><\/p>\n<p><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/04\/image3.png\" alt=\"image\" width=\"621.333333333333px\" height=\"421.6px\" \/><\/p>\n<p class=\"import-exf\">Describe significant perforating veins, including size, location, and reflux: ______________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________<\/p>\n<\/div>\n<p>&nbsp;<\/p>\n<p>&nbsp;<\/p>\n<p>&nbsp;<\/p>\n<p>&nbsp;<\/p>\n<h3 class=\"import-exf\"><span style=\"font-family: 'Cormorant Garamond', serif;font-size: 1.80225em;font-weight: bold\">10.4 The Arterial System<\/span><\/h3>\n<p class=\"import-paft\">Figure 10-27 shows the anatomy of the arterial system, which will be helpful in discussing and understanding various ultrasonography images of the arteries.<\/p>\n<figure style=\"width: 701px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D27,Dorsal%20Pedis%20arteries.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image2-5.png\" alt=\"Click image for long description.\" width=\"701\" height=\"967\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-27: Anatomy of the arterial system.<\/figcaption><\/figure>\n<h4 class=\"import-bh\">10.4.1 Transcranial Doppler<\/h4>\n<figure style=\"width: 450px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image42.jpg\" alt=\"A clinician is holding a small curved ultrasound transducer against the lateral neck of a patient who is lying on an exam table with their head turned to the side. Ultrasound gel is visible at the probe-to-skin interface.\" width=\"450\" height=\"337\" \/><figcaption class=\"wp-caption-text\">Figure 10-28: Transcranial Doppler probe.<\/figcaption><\/figure>\n<p class=\"import-paft\">Norwegian physicist Rune Aaslid developed intracranial ultrasound in 1982. Transcranial imaging was subsequently developed by a German neurologist, Ulrich Bogdahn, in 1990. It was the first noninvasive way to evaluate the circle of Willis using a low-frequency transducer (2 MHz).<a class=\"footnote\" title=\"Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.\" id=\"return-footnote-294-5\" href=\"#footnote-294-5\" aria-label=\"Footnote 5\"><sup class=\"footnote\">[5]<\/sup><\/a>,<a class=\"footnote\" title=\"Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.\" id=\"return-footnote-294-6\" href=\"#footnote-294-6\" aria-label=\"Footnote 6\"><sup class=\"footnote\">[6]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Transcranial Doppler (TCD) can detect intracranial stenosis, vasospasm secondary to subarachnoid hemorrhage, and arteriovenous malformations and assess suspected brain death. A TCD system usually has a 2 MHz pulsed Doppler with a spectrum analyzer. A typical TCD probe is shown in Figure 10-28. Blood flow in TCD is usually measured in cm\/sec, and Figure 10-29 represents a TCD velocity distribution. When evaluating intracranial vessels, it is vital to know the acoustic window, depth, direction of blood flow, velocity, and angle of insonation. One important principle when evaluating pathology is the pulsatility index (PI).<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image43-1.png\" alt=\"Line diagram illustrating a spectral Doppler arterial waveform with Velocity on the y-axis and time on the x-axis. The waveform displays a repeating pattern of sharp systolic peaks and lower diastolic troughs. The highest point of the first waveform is labeled 'Systolic Velocity (Vs),' indicating peak systolic velocity. A shaded blue-gray rectangular region spans the interval between the systolic and diastolic phases, with the lower plateau labeled 'Diastolic Velocity (Vd),' indicating end-diastolic velocity. The letters 'S' and 'D' are marked along the x-axis below the waveform, corresponding to the systolic and diastolic phases respectively.\" width=\"600\" height=\"325\" \/><figcaption class=\"wp-caption-text\">Figure 10-29: The transcranial Doppler velocity distribution.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">A high PI (&gt;1.2) can indicate increased intracranial pressure, microvascular disease, or distal vasospasm. Also, a low PI (&lt;0.8) can be seen with carotid stenosis or occlusion as well as arteriovenous malformations.<a class=\"footnote\" title=\"Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.\" id=\"return-footnote-294-7\" href=\"#footnote-294-7\" aria-label=\"Footnote 7\"><sup class=\"footnote\">[7]<\/sup><\/a>,<a class=\"footnote\" title=\"Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.\" id=\"return-footnote-294-8\" href=\"#footnote-294-8\" aria-label=\"Footnote 8\"><sup class=\"footnote\">[8]<\/sup><\/a><\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image44-1.png\" alt=\"Acoustic windows illustration. The cerebral arterial circulation is depicted in red at the center of the brain, showing the circle of Willis and its major branches. Three ultrasound transducers are shown approaching the skull from different angles: the 'Transorbital' window is shown in the upper right with the probe directed through the orbit; the 'Transtemporal' window is shown on the left with the probe directed through the temporal bone; and the 'Transforaminal' window is shown in the lower right with the probe directed through the foramen magnum.\" width=\"600\" height=\"459\" \/><figcaption class=\"wp-caption-text\">Figure 10-30: The three most common acoustic windows that provide direction to evaluate the intracranial vessels are the transtemporal, transorbital, and transforaminal windows.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The three most common acoustic windows that provide direction to evaluate the intracranial vessels are the transtemporal, transorbital, and transforaminal windows, as shown in Figure 10-30. The transcranial evaluation begins with the transtemporal approach on each side to identify the anterior, middle, and posterior cerebral arteries, and sometimes, the most distal aspect of the internal carotid artery (ICA) may also be evaluated.<a class=\"footnote\" title=\"Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.\" id=\"return-footnote-294-9\" href=\"#footnote-294-9\" aria-label=\"Footnote 9\"><sup class=\"footnote\">[9]<\/sup><\/a>,<a class=\"footnote\" title=\"Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.\" id=\"return-footnote-294-10\" href=\"#footnote-294-10\" aria-label=\"Footnote 10\"><sup class=\"footnote\">[10]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">When evaluating the anterior cerebral artery, normal flow is away from the probe, the depth is 60\u201370 mm, and the velocity ranges from 41\u201376 cm\/sec. The middle cerebral artery has normal flow toward the probe, a depth of 30\u201360 mm, and a velocity that ranges from 46\u201386 cm\/sec. The posterior cerebral artery typically has flow toward the probe, a depth of 60\u201370 mm, and a velocity range of 33\u201364 cm\/sec, as shown in Figure 10-31.<a class=\"footnote\" title=\"Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21.\" id=\"return-footnote-294-11\" href=\"#footnote-294-11\" aria-label=\"Footnote 11\"><sup class=\"footnote\">[11]<\/sup><\/a>,<a class=\"footnote\" title=\"Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.\" id=\"return-footnote-294-12\" href=\"#footnote-294-12\" aria-label=\"Footnote 12\"><sup class=\"footnote\">[12]<\/sup><\/a>,<a class=\"footnote\" title=\"Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4th ed. [place unknown]: Davies publishing; 2011. p. 442.\" id=\"return-footnote-294-13\" href=\"#footnote-294-13\" aria-label=\"Footnote 13\"><sup class=\"footnote\">[13]<\/sup><\/a><\/p>\n<figure style=\"width: 504px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image44.png\" alt=\"\" width=\"504\" height=\"154\" \/><figcaption class=\"wp-caption-text\">Figure 10-31: Side-by-side flow patterns and velocities of the anterior cerebral artery, middle cerebral artery, and posterior cerebral artery on transcranial Doppler.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The transorbital approach is followed and used to evaluate the ophthalmic artery and carotid siphon on each side, as shown in Figure 10-32. The location for of obtaining flow patterns is essential in this window, since it is difficult to determine the anatomic structure, as in the transtemporal approach demonstrating the circle of Willis. Comparisons can be made between different flow patterns.<\/p>\n<figure style=\"width: 420px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image45.png\" alt=\"The left panel displays a spectral waveform with measured Doppler indices listed below the waveform: Mean 23.1 cm\/s, Peak 42.7 cm\/s, End Diastolic Velocity (EDV) 13.7 cm\/s, Pulsatility Index (PI) 1.24, and Heart Rate (HR) 61 beats per minute. A color Doppler image is visible below the spectral display. The right panel displays a spectral waveform with higher velocity measurements listed below: Mean 24.6 cm\/s, Peak 34.6 cm\/s, EDV 17.2 cm\/s, PI 0.64, and HR 175 beats per minute. A color Doppler image is visible below the right spectral display. Both panels show bidirectional flow with waveforms displayed above and below the baseline. There is a lower pulsatility index and higher heart rate in the right panel.\" width=\"420\" height=\"189\" \/><figcaption class=\"wp-caption-text\">Figure 10-32: Side-by-side velocities and flow patterns of the right ophthalmic artery and carotid siphon on transcranial Doppler.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The transforaminal approach is then used to evaluate the intracranial vertebral arteries and the basilar arteries, as shown in Figure 10-33.<\/p>\n<figure style=\"width: 484px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image46.png\" alt=\"\" width=\"484\" height=\"216\" \/><figcaption class=\"wp-caption-text\">Figure 10-33: Side-by-side velocities and flow patterns of the left vertebral artery and basilar artery on transcranial Doppler.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">In the vertebral arteries, normal blood flow is away from the probe, the depth is 60\u201370 mm, and the velocity ranges from 27\u201355 cm\/sec. In the basilar arteries, normal blood flow is away from the probe, the depth is 80\u2013120 mm, and the velocity is 30\u201357 cm\/sec.<\/p>\n<h4 class=\"import-bh\">10.4.2 Sonography of the Carotid Arteries<\/h4>\n<p class=\"import-paft\">Figure 10-34 shows the positioning of the ultrasound probe for carotid artery evaluations. A high-frequency linear transducer (7.5\u201310 MHz) is most appropriate for carotid sonography. Transverse and longitudinal views are both imaged in B-mode, color, and spectral Doppler. In the sagittal plane, the ICA, external carotid artery (ECA), and right common carotid artery (CCA) are followed from the clavicle to the mandible with anterior, oblique, lateral, and posterior projections to identify plaque formation. Comparison flow characteristics are made from one side to the other as well as from proximal to distal segments of the ICA, ECA, and CCA.<a class=\"footnote\" title=\"Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561.\" id=\"return-footnote-294-14\" href=\"#footnote-294-14\" aria-label=\"Footnote 14\"><sup class=\"footnote\">[14]<\/sup><\/a> In the transverse plane, the ICA and CCA are followed to evaluate plaque formations. The percentage of stenosis can then be evaluated by looking at the diameter reduction. Plaque characteristics can be evaluated for calcification, thrombosis, and fibrosis.<\/p>\n<figure style=\"width: 500px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image52-1.png\" alt=\"\" width=\"500\" height=\"359\" \/><figcaption class=\"wp-caption-text\">Figure 10-34: Carotid Doppler probe.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-35 shows the CCA in the proximal transverse plane with the jugular vein on top, demonstrating blood flow in the opposite direction following the BART principle. <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Prox<\/em><\/span> is the abbreviation used for <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">proximal<\/em><\/span> in the image for Figure 10-35 and some of the other following ones. Pulsed Doppler with spectral analysis is the primary tool for evaluating blood flow in the vascular study.<\/p>\n<figure style=\"width: 602px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image53.jpg\" alt=\"\" width=\"602\" height=\"451\" \/><figcaption class=\"wp-caption-text\">Figure 10-35: Right common carotid artery in the proximal transverse plane with the jugular vein on top, demonstrating blood flow in opposite directions.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-36 shows the pulsed wave (PW) Doppler with spectral analysis of the right CCA in the distal sagittal plane. Spectral analysis is a method of displaying the variety of frequencies of blood flow during systole and diastole. The scanner technology automatically analyzes and displays the individual frequencies of the returned signals, creating a velocity profile consisting of time on the horizontal axis, frequency shifts on the vertical axis, and amplitude as brightness. This combination of blood flow analysis and anatomic information is the basis of duplex ultrasonography,<a class=\"footnote\" title=\"Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4th ed. [place unknown]: Davies publishing; 2011. p. 442.\" id=\"return-footnote-294-15\" href=\"#footnote-294-15\" aria-label=\"Footnote 15\"><sup class=\"footnote\">[15]<\/sup><\/a> as discussed in Chapter 2.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D36,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image54.jpg\" alt=\"Doppler of carotid artery. Click image for long description.\" width=\"601\" height=\"451\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-36: Pulsed wave Doppler with spectral analysis of the common carotid artery in the distal sagittal plane.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D37,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image55-1.jpg\" alt=\"Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-37: Normal waveform of the right internal carotid artery.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D38,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image56-1.jpg\" alt=\"Doppler of carotid artery. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-38: Normal waveform of the right common carotid artery.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The Doppler characteristics of the carotid artery system are different. The ICA and CCA usually have low flow resistance, as shown in Figures 10-37 and 10-38, respectively. Flow occurs throughout the cardiac cycle. The diastolic segment does not touch the baseline. The ECA has high flow resistance with little or no diastolic or reversed diastolic flow. Reproducible and consistent velocity measurements require an angle of 60 degrees or less. Although a zero-degree angle of insonation provides the most remarkable Doppler shift because this depends on the angle\u2019s cosine, this would be difficult with most vessels. The criteria used for the interpretation of velocity measurements were established using a 60-degree angle.<a class=\"footnote\" title=\"Green L, Jorgensen T, Schroedter B, Bendick P. Carotid Duplex and Color Flow Imaging [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2012 Feb 20\u201322.\" id=\"return-footnote-294-16\" href=\"#footnote-294-16\" aria-label=\"Footnote 16\"><sup class=\"footnote\">[16]<\/sup><\/a>,<a class=\"footnote\" title=\"Bandyk D, Armstrong PA, Neumyer MJ. Vascular Ultrasound Interpretation [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2012 August 9\u201310.\" id=\"return-footnote-294-17\" href=\"#footnote-294-17\" aria-label=\"Footnote 17\"><sup class=\"footnote\">[17]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Since the brain is a low-resistance vascular bed, the ICA is less pulsatile with increased flow during diastole. The typical waveform of the ICA has a rapid upstroke during systole and a high diastolic component with a possible dicrotic notch and gradual downslope.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">With the common carotid artery in the longitudinal plane, the transducer <ins>is <\/ins>angled more posterolaterally to identify the vertebral artery. Vertical shadows will appear running through the vertebral arteries, which are the transverse processes of the vertebrae, as shown in Figure 10-39. <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Vert<\/em><\/span> in the image represents the vertebral artery. Flow direction is documented.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D39,to%203%20cm.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image57-1.jpg\" alt=\"Right vertebral artery Doppler. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-39: Sagittal view of the right vertebral artery with color flow.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The ECA supplies blood to vascular areas with higher resistance, such as the scalp. It has a rapid upstroke in systole and rapid downstroke in diastole with a dicrotic notch, as shown in Figure 10-40.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D40,is%2066mm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image58.jpg\" alt=\"Right external carotid artery Doppler. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-40: Normal waveform of the right external carotid artery.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Both the CCA and vertebral arteries have low flow resistance. The flow characteristics are similar to the ICA. Multiple guidelines and trials are used to determine the percentage of diameter stenosis and clinically relevant stenosis. The ICA is of the most importance for surgical intervention. The Society of Radiologists in Ultrasound Consensus, one of the most widely used guidelines to assess ICA stenosis, is presented in Table 10-1 the table below.<a class=\"footnote\" title=\"Grant EG, Benson CB, Moneta GL, Alexandrov AV, Baker JD, Bluth EI, Carroll BA, Eliasziw M, Gocke J, Hertzberg BS, Katanick S, Needleman L, Pellerito J, Polak JF, Rholl KS, Wooster DL, Zierler RE. Carotid artery stenosis: Gray-scale and Doppler US diagnosis\u2014Society of Radiologists in Ultrasound Consensus Conference. Radiology. 2003 Nov;229(2):340\u20136. doi: 10.1148\/radiol.2292030516. Epub 2003 Sep 18. PMID: 14500855.\" id=\"return-footnote-294-18\" href=\"#footnote-294-18\" aria-label=\"Footnote 18\"><sup class=\"footnote\">[18]<\/sup><\/a><\/p>\n<p class=\"import-th\" style=\"text-align: left\"><span style=\"text-decoration: underline\"><strong><span class=\"import-thn\">Table <\/span><span class=\"import-thn\">10<\/span><span class=\"import-thn\">-1:<\/span> Criteria for assessing Internal Carotid Artery Stenosis.<\/strong><\/span><\/p>\n<div class=\"wp-nocaption alignnone\"><img class=\"alignnone\" src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image59.png\" alt=\"image\" width=\"850\" height=\"358\" \/><\/div>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The North American Symptomatic Endarterectomy Trial was published in the journal <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Stroke<\/em><\/span> in 1991.<a class=\"footnote\" title=\"North American Symptomatic Carotid Endarterectomy Trial. Methods, patient characteristics, and progress. Stroke. 1991 Jun;22(6):711\u201320. doi: 10.1161\/01.str.22.6.711. PMID: 2057968.\" id=\"return-footnote-294-19\" href=\"#footnote-294-19\" aria-label=\"Footnote 19\"><sup class=\"footnote\">[19]<\/sup><\/a> The results concluded that patients with 70\u201399% stenosis of the ICA benefit from surgical intervention in the appropriate clinical setting.<\/p>\n<h4 class=\"import-bh\">10.4.3 Sonography of the Aorta<\/h4>\n<p class=\"import-paft\">The aorta is the largest artery in humans. It branches off the heart\u2019s left ventricle into the thoracic and abdominal cavities, as shown in Figure 10-41. The abdominal aorta branches into the right and left iliac arteries at the level of the umbilicus, where it carries oxygenated blood to each lower extremity. When the wall of the aorta weakens and expands, an aneurysm develops (with an increased risk of rupture under this high-pressure system).<\/p>\n<figure style=\"width: 586px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image3-2.png\" alt=\"\" width=\"586\" height=\"536\" \/><figcaption class=\"wp-caption-text\">Figure 10-41: Schematic of the abdominal aorta showing that it branches into the right and left iliac arteries.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Each year, 200,000 people in the United States are diagnosed with an abdominal aortic aneurysm (AAA). Of these, nearly 7.5% have a life-threatening risk of rupture. The majority of patients with AAA are asymptomatic. The aorta\u2019s diameter must be greater less than 3 cm to be diagnosed as an aneurysm. When it reaches 5 cm or greater, very close monitoring and surgical options are entertained. Risk factors for an AAA include hypertension, smoking, and genetic factors, especially involving immediate relatives with AAA. Men over the age of 60 are also at greater risk.<a class=\"footnote\" title=\"Chaikof EL, Dalman RL, Eskandari MK, Jackson BM, Lee WA, Mansour MA, Mastracci TM, Mell M, Murad MH, Nguyen LL, Oderich GS, Patel MS, Schermerhorn ML, Starnes BW. The Society for Vascular Surgery practice guidelines on the care of patients with an abdominal aortic aneurysm. J Vasc Surg. 2018 Jan;67(1):2\u201377.e2. doi: 10.1016\/j.jvs.2017.10.044. PMID: 29268916.\" id=\"return-footnote-294-20\" href=\"#footnote-294-20\" aria-label=\"Footnote 20\"><sup class=\"footnote\">[20]<\/sup><\/a><\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">The ultrasound evaluation of the abdominal aorta (A or AA) should include the proximal, mid, and distal aorta to the bifurcation in the transverse and longitudinal planes, as shown in Figure 10-42. Evaluation of the branches of the aorta should include the celiac artery (C), superior mesenteric artery (SMA), and renal artery branches, as shown in Figures 10-43 and 10-44, without and with color Doppler, respectively.<a class=\"footnote\" title=\"Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561.\" id=\"return-footnote-294-21\" href=\"#footnote-294-21\" aria-label=\"Footnote 21\"><sup class=\"footnote\">[21]<\/sup><\/a> The abbreviations given in parentheses in this paragraph have been labeled in some of the ultrasound images discussed below.<\/p>\n<figure style=\"width: 400px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/03\/image47.png\" alt=\"\" width=\"400\" height=\"320\" \/><figcaption class=\"wp-caption-text\">Figure 10-42: Transducer position in the transverse and sagittal planes to evaluate the abdominal aorta.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image63-1.jpg\" alt=\"Abdominal ultrasound showing a sagittal view of the upper abdomen with three labeled structures. 'AA' in the lower left indicates the abdominal aorta, visible as a large anechoic tubular structure. 'C' in the center indicates the celiac artery origin, seen as a small vessel branching anteriorly from the aorta. 'SMA' to the right of center indicates the superior mesenteric artery, visible as a hyperechoic-walled tubular structure running parallel and anterior to the aorta. Surrounding echogenic and hypoechoic soft tissue structures are visible throughout the image.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-43: Sagittal image of proximal aorta without Doppler showing the abdominal aorta, celiac artery, and superior mesenteric artery.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image64.jpg\" alt=\"Abdominal vascular ultrasound image with color Doppler overlay showing a sagittal or oblique view of the upper abdominal aorta and its major branches. Three structures are labeled within the color flow box: 'A' in the lower center indicates the abdominal aorta, displayed as a large red flow-filled vessel; 'C' to the upper left indicates the celiac artery, shown as a red flow-filled vessel branching anteriorly from the aorta; and 'SMA' to the upper right indicates the superior mesenteric artery, also shown in red branching anteriorly and running parallel to the aorta. Scattered blue flow signals are visible adjacent to the labeled vessels, representing surrounding venous structures. A color flow velocity scale on the right ranges from positive 46.2 to negative 46.2 cm\/s.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-44: Sagittal image with color Doppler showing the abdominal aorta, celiac artery, and superior mesenteric artery.<\/figcaption><\/figure>\n<h3 class=\"import-ah\">10.5 Arterial Sonography of the Lower Extremities<\/h3>\n<p class=\"import-paft\">Figure 10-45 shows the normal anatomical branches of the arterial system in the lower extremity. Peripheral artery disease (PAD) is a condition in which the arteries of the lower extremities are narrowed primarily from atherosclerosis. Approximately 8 million people in the United States have PAD. Men and women are affected equally. Risk factors include smoking, diabetes, hypertension, high cholesterol, and being over 60 years of age. A classic symptom of PAD is claudication, or pain when walking. Lower-extremity arterial duplex scanning is a noninvasive way to identify the presence and severity of arterial occlusive disease.<\/p>\n<figure style=\"width: 631px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/02\/image4-1.png\" alt=\"Anatomical illustration of the lower extremity arterial system shown in anterior view from the pelvis to the foot, with arteries depicted in red. At the top, the Common Iliac Artery bifurcates into the Internal Iliac Artery and the External Iliac Artery. A green horizontal band marks the Groin Crease, below which the External Iliac Artery becomes the Common Femoral Artery. The Common Femoral Artery bifurcates into the Profunda Femoral Artery branching laterally and the Superficial Femoral Artery continuing distally. A second green horizontal band marks the Knee Crease, below which the vessel continues as the Popliteal Artery. The Popliteal Artery then bifurcates into the Tibioperoneal Trunk and the Anterior Tibial Artery. The Tibioperoneal Trunk further divides into the Posterior Tibial Artery and the Peroneal Artery at the bottom of the illustration.\" width=\"631\" height=\"542\" \/><figcaption class=\"wp-caption-text\">Figure 10-45: Schematic showing normal anatomical branches of the arterial system in the lower extremity.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">It can also be used to follow the progression of the disease. The patient must rest for at least 20 minutes before testing, since this can affect the results, especially if the patient has PAD. The patient is then positioned supine with the lower extremities at the heart level so the hydrostatic pressure cannot falsely elevate the measurements.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">During an arterial Doppler exam, various cuffs are placed on the patient\u2019s legs and arms. This exam uses color wave (CW) Doppler. CW Doppler employs two crystals contained in the same probe<ins>:<\/ins> one that transmits the signal and one that receives the reflected sound wave of the blood cells. The reflected frequency is either higher or lower than the transmitted frequency, depending on the flow direction. This change in frequency is called the Doppler shift. The ankle brachial index (ABI) is recorded, and the waveforms are analyzed. The ABI is a simple test that compares the blood pressure in the upper and lower limbs. The ABI is calculated by dividing the blood pressure in an ankle artery by the blood pressure in an arm artery. An ABI value of less than 0.9 indicates PAD.<\/p>\n<p class=\"import-p\" style=\"text-indent: 36pt\">An arterial duplex is another type of evaluation that uses ultrasound. It starts proximally at the common femoral artery with a side-by-side transverse image without and with color Doppler, followed by a sagittal image of the artery in red and sometimes the corresponding vein(s) in blue<ins>,<\/ins> and finally, a sagittal image of the artery with waveform analysis, which includes peak systolic velocity (PSV) and end-diastolic velocity (EDV). As the arterial study is performed from proximal to distal, the same approach is obtained with each artery, including, in succession, the common femoral artery (CFA), profunda femoral artery (Prof A), superficial femoral artery (SFA), popliteal artery (Pop A), posterior tibial artery (PTA), peroneal artery (Pero A), anterior tibial artery (ATA)<ins>,<\/ins> and dorsalis pedis artery (DPA). The abbreviations given in parentheses in the previous sentence have been labeled in some of the ultrasound images discussed below. The abbreviation <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">Trans<\/em><\/span> used in some of these images is for <span style=\"border: none windowtext 0pt;padding: 0\"><em class=\"import-i\">transverse<\/em><\/span>. Figures 10-46 and 10-47 show the transverse and sagittal views, respectively, of the side-by-side images of the right common femoral artery without and with color Doppler. Figure 10-48 shows the sagittal view of the right common femoral artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 599px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image66.jpg\" alt=\"Two-panel ultrasound image labeled 'Right CFA Trans' showing the right common femoral artery in transverse view. The left panel displays a grayscale image with two adjacent circular anechoic structures visible at approximately 1.5 to 2 cm depth, representing the common femoral artery and common femoral vein in cross-section, without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the common femoral artery is shown in red and orange indicating arterial flow toward the transducer, and the common femoral vein is shown in solid blue indicating venous flow away from the transducer. Small blue foci within the arterial signal may represent aliasing or small adjacent vessels. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"599\" height=\"449\" \/><figcaption class=\"wp-caption-text\">Figure 10-46: Side-by-side transverse images of the right common femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D47,24.1%20cm\/s\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image67-1.jpg\" alt=\"Right common femoral artery Doppler. Click image for long description.\" width=\"601\" height=\"451\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-47: Side-by-side sagittal images of the right common femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D48,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image68-1.png\" alt=\"Right sagittal common femoral artery Doppler. Click image for long description.\" width=\"600\" height=\"463\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-48: Sagittal image of the right common femoral artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-49 and 10-50 show the transverse and sagittal views, respectively, of the right profunda femoral artery without and with color Doppler. Figure 10-51 shows the sagittal view of the right profunda femoral artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image69-1.jpg\" alt=\"Two-panel ultrasound image labeled 'Right Prof A Trans' showing the right profunda femoris artery in transverse view. The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 1 to 2 cm depth, representing the profunda femoris artery and an accompanying vein in cross-section, without color Doppler applied. The right panel displays the corresponding color Doppler image with the same structures now color-coded: two adjacent rounded structures are shown in red and orange indicating arterial flow toward the transducer, with a small focal area of blue signal between them, and a separate blue structure visible in the lower right representing a deeper venous structure. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-49: Side-by-side transverse images of the right profunda femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D50,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image70.jpg\" alt=\"Sagittal right profunda femoral artery Doppler. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-50: Side-by-side sagittal images of the right profunda femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D51,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image71-1.jpg\" alt=\"Right profunda femoral artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-51: Sagittal image of the right profunda femoral artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-52 and 10-53 show the transverse and sagittal views, respectively, of the right proximal superficial femoral artery without and with color Doppler. Figure 10-54 shows the sagittal view of the right proximal superficial femoral artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image72.jpg\" alt=\"The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 1.5 to 2 cm depth, representing the superficial femoral artery and superficial femoral vein in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superficial femoral artery is shown as a smaller round red structure in the upper right indicating arterial flow toward the transducer, and the superficial femoral vein is shown as a larger round blue structure in the lower left indicating venous flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-52: Side-by-side transverse images of the right proximal superficial femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image73.jpg\" alt=\"The left panel displays a grayscale image with two parallel anechoic tubular structures running horizontally at approximately 1.5 to 2.5 cm depth, representing the superficial femoral artery above and the superficial femoral vein below in longitudinal section, without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superior vessel, the superficial femoral artery, is shown as a broad band of red and orange flow signal indicating arterial flow toward the transducer, and the inferior vessel, the superficial femoral vein, is shown as a broad band of blue flow signal indicating venous flow away from the transducer. A thin anechoic separation is visible between the two color-coded vessels. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-53: Side-by-side sagittal images of the right proximal superficial femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D54,depth%20of%201.9cm.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image74.jpg\" alt=\"Sagittal of the right proximal superficial femoral artery Doppler. Click image for long description.\" width=\"601\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-54: Sagittal image of the right proximal superficial femoral artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-55 and 10-56 show the transverse and sagittal views, respectively, of the right middle superficial femoral artery without and with color Doppler. Figure 10-57 shows the sagittal view of the right middle superficial femoral artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image75.jpg\" alt=\"The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 1.5 to 2 cm depth, representing the superficial femoral artery and superficial femoral vein in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superficial femoral artery is shown as a smaller round red structure in the upper right indicating arterial flow toward the transducer, and the superficial femoral vein is shown as a larger round blue structure in the lower left indicating venous flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-55: Side-by-side transverse images of the right middle superficial femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D56,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image76.jpg\" alt=\"Sagittal of the right middle superficial femoral artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-56: Sagittal image of the right middle superficial femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D57,depth%20of%202.0cm.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image77.jpg\" alt=\"Sagittal of the right middle superficial femoral artery Doppler comparison. Click on image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-57: Sagittal image of the right middle superficial femoral artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-58 and 10-59 show the transverse and sagittal views of the right distal superficial femoral artery without and with color Doppler. Figure 10-60 shows the sagittal view of the right distal superficial femoral artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image78.jpg\" alt=\"The left panel displays a grayscale image with two adjacent anechoic structures visible at approximately 2 to 3 cm depth, representing the distal superficial femoral artery and accompanying vein in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the superficial femoral artery is shown as a smaller round red structure in the upper portion indicating arterial flow toward the transducer, and the accompanying vein is shown as an elongated blue structure below indicating venous flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-58: Side-by-side transverse images of the right distal superficial femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D59,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image79-1.jpg\" alt=\"Sagittal of the right distal superficial femoral artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-59: Sagittal images of the right distal superficial femoral artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image80.jpg\" alt=\"A medical ultrasound scan screen displaying a duplex Doppler evaluation of the right distal superficial femoral artery (Right SFA Dist SAG). The top half shows a grayscale B-mode ultrasound image with a color Doppler box highlighting a blood vessel filled with orange-red flow. The bottom half displays a pulsed-wave Doppler spectral waveform showing a triphasic arterial flow pattern with prominent peaks. Text on the screen indicates measurements including a Peak Systolic Velocity (PSV) of 133 cm\/s and an End Diastolic Velocity (EDV) of 18.2 cm\/s.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-60: Sagittal image of the right distal superficial femoral artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-61 and 10-62 show the transverse and sagittal views, respectively, of the right popliteal artery without and with color Doppler. Figure 10-63 shows the sagittal view of the right popliteal artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image81.jpg\" alt=\"The left panel displays a grayscale image with two adjacent rounded anechoic structures visible at approximately 2.5 to 3 cm depth within the popliteal fossa, representing the popliteal vein and popliteal artery in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same two structures now color-coded: the popliteal vein is shown as a larger irregular blue structure in the upper portion indicating venous flow away from the transducer, and the popliteal artery is shown as a smaller round red structure in the lower portion indicating arterial flow toward the transducer. A small additional red focal signal is visible below the artery representing a small adjacent vessel. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-61: Side-by-side transverse images of the right popliteal artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image82-1.jpg\" alt=\"The left panel displays a grayscale image with a single anechoic tubular structure running horizontally at approximately 2 cm depth within the popliteal fossa, representing the popliteal artery in longitudinal section without color Doppler applied. The right panel displays the corresponding color Doppler image with the popliteal artery now shown as a broad band of solid red flow signal indicating arterial flow toward the transducer, and a small focal blue structure visible below the artery representing the adjacent popliteal vein or a small tributary. A small red signal is visible at the top of the color box representing a superficial vessel. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-62: Side-by-side sagittal images of the right popliteal artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 602px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D63,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image83.jpg\" alt=\"Sagittal of the right popliteal artery Doppler comparison. Click image for long description.\" width=\"602\" height=\"451\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-63: Sagittal image of the right popliteal artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-64 and 10-65 show the transverse and sagittal views, respectively, of the right posterior tibial artery without and with color Doppler. Figure 10-66 shows the sagittal view of the right posterior tibial artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image84.png\" alt=\"The left panel displays a grayscale image with multiple small anechoic structures visible at approximately 1 cm depth, representing the posterior tibial artery and accompanying paired veins in cross-section without color Doppler applied. The right panel displays the corresponding color Doppler image with the same structures now color-coded: a small red structure in the upper left indicates the posterior tibial artery with flow toward the transducer, and two adjacent blue structures to the right indicate the paired posterior tibial veins with flow away from the transducer. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-64: Side-by-side transverse images of the right posterior tibial artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D65,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image85.jpg\" alt=\"Side-by-side sagittal of the right posterior tibial artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-65: Side-by-side sagittal images of the right posterior tibial artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D66,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image86-1.jpg\" alt=\"Sagittal of the right posterior tibial artery Doppler and analysis. Click image for long description.\" width=\"601\" height=\"451\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-66: Sagittal image of the right posterior tibial artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figures 10-67 and 10-68 show the transverse and sagittal views, respectively, of the right peroneal artery without and with color Doppler. Figure 10-69 shows the sagittal view of the right peroneal artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image87.jpg\" alt=\"The left panel displays a grayscale image with soft tissue structures visible at depth ranging from 1 to 6 cm, with small anechoic structures visible at approximately 4 cm depth representing the peroneal artery and accompanying veins in cross-section within the deep posterior compartment, without color Doppler applied. The right panel displays the corresponding color Doppler image with a color flow box positioned at approximately 3.5 to 5 cm depth, showing a small focal red signal indicating the peroneal artery with flow toward the transducer, deep within the surrounding muscle tissue. No venous flow signal is visible adjacent to the arterial signal in this view. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"600\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-67: Side-by-side transverse images of the right peroneal artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 602px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D68,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image88.jpg\" alt=\"Sagittal images of the right peroneal artery Doppler comparison. Click image for long description.\" width=\"602\" height=\"451\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-68: Side-by-side sagittal images of the right peroneal artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D69,20%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image89-1.jpg\" alt=\"Sagittal of the right peroneal artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-69: Sagittal image of the right peroneal artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-70 shows the side-by-side sagittal view of the right anterior tibial artery without and with color Doppler. Figure 10-71 shows the sagittal view of the right anterior tibial artery with color Doppler and waveform analysis.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D70,24.1%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image90.jpg\" alt=\"Sagittal images of the right anterior tibial artery Doppler comparison. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-70: Side-by-side sagittal images of the right anterior tibial artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D71,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image91.jpg\" alt=\"Sagittal of the right anterior tibial artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-71: Sagittal image of the right anterior tibial artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<figure style=\"width: 601px\" class=\"wp-caption aligncenter\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image92.jpg\" alt=\"The left panel displays a grayscale image with a small anechoic structure visible at approximately 1 cm depth within the superficial soft tissue of the dorsal foot, representing the dorsalis pedis artery in cross-section without color Doppler applied. Hyperechoic bony structures are visible in the deeper tissue. The right panel displays the corresponding color Doppler image with the dorsalis pedis artery now shown as a small round red structure at approximately 1 cm depth, indicating arterial flow toward the transducer within the superficial dorsal foot tissue. No adjacent venous signal is visible in this view. A color flow velocity scale on the right ranges from positive 24.1 to negative 24.1 cm\/s.\" width=\"601\" height=\"450\" \/><figcaption class=\"wp-caption-text\">Figure 10-72: Side-by-side transverse images of the right dorsalis pedis artery without color Doppler and with color Doppler.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">Figure 10-72 shows the transverse view of the right dorsalis pedis artery without and with color Doppler. Figure 10-73 shows the sagittal view of the right dorsalis pedis artery with color Doppler and waveform analysis.<\/p>\n<p class=\"import-figh\"><span class=\"import-fighn\">Figure 10-73:<\/span> Sagittal image of the right dorsalis pedis artery with color Doppler.<\/p>\n<figure style=\"width: 600px\" class=\"wp-caption aligncenter\"><a href=\"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/back-matter\/alt-text-long-description\/#:~:text=Figure%2010%2D73,40%20cm\/s.\"><img src=\"http:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-content\/uploads\/sites\/65\/2024\/01\/image94.jpg\" alt=\"Sagittal of the right dorsalis pedis artery Doppler and analysis. Click image for long description.\" width=\"600\" height=\"450\" \/><\/a><figcaption class=\"wp-caption-text\">Figure 10-73: Sagittal image of the right dorsalis pedis artery with color Doppler and waveform analysis.<\/figcaption><\/figure>\n<p class=\"import-p\" style=\"text-indent: 36pt\">When evaluating the lower extremities for diagnostic criteria for PAD, the PSV and velocity ratio (VR) are often used. The VR is defined as the ratio of the PSV of the stenotic area to the PSV of the standard proximal segment. The degree of stenosis is determined by these values of the PSV and VR, as illustrated in Table 10-2.<a class=\"footnote\" title=\"Hodgkiss-Harlow KD, Bandyk DF. Interpretation of arterial duplex testing of lower-extremity arteries and interventions. Semin Vasc Surg. 2013 Jun\u2013Sep;26(2\u20133):95\u2013104. doi: 10.1053\/j.semvascsurg.2013.11.002. Epub 2013 Nov 14. PMID: 24636606.\" id=\"return-footnote-294-22\" href=\"#footnote-294-22\" aria-label=\"Footnote 22\"><sup class=\"footnote\">[22]<\/sup><\/a><\/p>\n<p class=\"import-th\"><span style=\"text-decoration: underline\"><strong><span class=\"import-thn\">Table <\/span><span class=\"import-thn\">10<\/span><span class=\"import-thn\">&#8211;<\/span><span class=\"import-thn\">2<\/span><span class=\"import-thn\">:<\/span> Guidelines for determining the degree of stenosis.<\/strong><\/span><\/p>\n<table>\n<tbody>\n<tr class=\"TableGrid-R\">\n<th class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\" scope=\"col\">\n<p class=\"import-tch\">Degree of stenosis<\/p>\n<\/th>\n<th class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\" scope=\"col\">\n<p class=\"import-tch\">Peak systolic velocity (cm\/s)<\/p>\n<\/th>\n<th class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\" scope=\"col\">\n<p class=\"import-tch\">Velocity ratio<\/p>\n<\/th>\n<\/tr>\n<tr class=\"TableGrid-R\">\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">&lt;20%<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">&lt;150<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">&lt;1.5<\/p>\n<\/td>\n<\/tr>\n<tr class=\"TableGrid-R\">\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">20\u201349%<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">150\u2013200<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">1.5\u20132.0<\/p>\n<\/td>\n<\/tr>\n<tr class=\"TableGrid-R\">\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">50\u201380%<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">200\u2013300<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">2.0\u20134.0<\/p>\n<\/td>\n<\/tr>\n<tr class=\"TableGrid-R\">\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">&gt;80%<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">&gt;300<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">&gt;4.0<\/p>\n<\/td>\n<\/tr>\n<tr class=\"TableGrid-R\">\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">Occlusion<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">No flow detected in lumen<\/p>\n<\/td>\n<td class=\"TableGrid-C\" style=\"border: solid windowtext 0.5pt\">\n<p class=\"import-td\">N\/A<\/p>\n<\/td>\n<\/tr>\n<tr>\n<td><\/td>\n<td><\/td>\n<td><\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<div class=\"textbox textbox--exercises\">\n<header class=\"textbox__header\">\n<p class=\"textbox__title\">10.6 Self-Assessment<\/p>\n<\/header>\n<div class=\"textbox__content\">\n<ol>\n<li>What happens to ultrasound imaging of normal veins when you apply downward pressure with the transducer?<\/li>\n<li>What frequency transducer would you typically use to evaluate the circle of Willis?<\/li>\n<li>What kind of Doppler is used to evaluate the arterial system of the lower extremities?<\/li>\n<\/ol>\n<\/div>\n<\/div>\n<div class=\"textbox textbox--examples\">\n<header class=\"textbox__header\">\n<p class=\"textbox__title\">10.7 Further Readings<\/p>\n<\/header>\n<div class=\"textbox__content\">\n<ol>\n<li>Pugsley MK, Tabrizchi R. The vascular system. An overview of structure and function. J Pharmacol Toxicol Methods. 2000 Sep\u2013Oct;44(2):333\u201340. doi: 10.1016\/s1056-8719(00)00125-8. PMID: 11325577.<\/li>\n<li>Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4<span style=\"border: none windowtext 0pt;padding: 0\"><sup class=\"import-sup\">th<\/sup><\/span> ed. [place unknown]: Davies publishing; 2011. p. 442.<\/li>\n<li>Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158.<\/li>\n<li>Zemaitis MR, Boll JM, Dreyer MA. Peripheral Arterial Disease. [Updated 2023 May 23]. In: StatPearls [internet]. Treasure Island (FL): StatPearls Publishing; 2023 Jan\u2013. Available from: <span style=\"border: none windowtext 0pt;padding: 0\"><a class=\"rId117\" href=\"https:\/\/www.ncbi.nlm.nih.gov\/books\/NBK430745\/\"><span class=\"import-url\">https:\/\/www.ncbi.nlm.nih.gov\/books\/NBK430745\/<\/span><\/a><\/span><\/li>\n<\/ol>\n<\/div>\n<\/div>\n<hr class=\"before-footnotes clear\" \/><div class=\"footnotes\"><ol><li id=\"footnote-294-1\">Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561. <a href=\"#return-footnote-294-1\" class=\"return-footnote\" aria-label=\"Return to footnote 1\">&crarr;<\/a><\/li><li id=\"footnote-294-2\">Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\">https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92<\/a> <a href=\"#return-footnote-294-2\" class=\"return-footnote\" aria-label=\"Return to footnote 2\">&crarr;<\/a><\/li><li id=\"footnote-294-3\">Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\">https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92<\/a> <a href=\"#return-footnote-294-3\" class=\"return-footnote\" aria-label=\"Return to footnote 3\">&crarr;<\/a><\/li><li id=\"footnote-294-4\">Schellong S, Schwarz T. Peripheral Venous Anatomy and Physiology. In: Lanzer P, Topol EJ, editors. Pan Vascular Medicine. Berlin, Heidelberg: Springer; 2002. p. 1489\u20131491. Available from: <a href=\"https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92\">https:\/\/doi.org\/10.1007\/978-3-642-56225-9_92<\/a> <a href=\"#return-footnote-294-4\" class=\"return-footnote\" aria-label=\"Return to footnote 4\">&crarr;<\/a><\/li><li id=\"footnote-294-5\">Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21. <a href=\"#return-footnote-294-5\" class=\"return-footnote\" aria-label=\"Return to footnote 5\">&crarr;<\/a><\/li><li id=\"footnote-294-6\">Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158. <a href=\"#return-footnote-294-6\" class=\"return-footnote\" aria-label=\"Return to footnote 6\">&crarr;<\/a><\/li><li id=\"footnote-294-7\">Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21. <a href=\"#return-footnote-294-7\" class=\"return-footnote\" aria-label=\"Return to footnote 7\">&crarr;<\/a><\/li><li id=\"footnote-294-8\">Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158. <a href=\"#return-footnote-294-8\" class=\"return-footnote\" aria-label=\"Return to footnote 8\">&crarr;<\/a><\/li><li id=\"footnote-294-9\">Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21. <a href=\"#return-footnote-294-9\" class=\"return-footnote\" aria-label=\"Return to footnote 9\">&crarr;<\/a><\/li><li id=\"footnote-294-10\">Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158. <a href=\"#return-footnote-294-10\" class=\"return-footnote\" aria-label=\"Return to footnote 10\">&crarr;<\/a><\/li><li id=\"footnote-294-11\">Davis D. Introduction to Transcranial Doppler Ultrasound [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2013 Feb 28\u2013Mar 21. <a href=\"#return-footnote-294-11\" class=\"return-footnote\" aria-label=\"Return to footnote 11\">&crarr;<\/a><\/li><li id=\"footnote-294-12\">Katz ML, Alexandrov AV. A Practical Guide to Transcranial Doppler Examinations. [place unknown]: Summer publishing; 2003. p. 158. <a href=\"#return-footnote-294-12\" class=\"return-footnote\" aria-label=\"Return to footnote 12\">&crarr;<\/a><\/li><li id=\"footnote-294-13\">Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4th ed. [place unknown]: Davies publishing; 2011. p. 442. <a href=\"#return-footnote-294-13\" class=\"return-footnote\" aria-label=\"Return to footnote 13\">&crarr;<\/a><\/li><li id=\"footnote-294-14\">Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561. <a href=\"#return-footnote-294-14\" class=\"return-footnote\" aria-label=\"Return to footnote 14\">&crarr;<\/a><\/li><li id=\"footnote-294-15\">Rumwell C. McPharlin M. Vascular Technology: An illustrated review. 4th ed. [place unknown]: Davies publishing; 2011. p. 442. <a href=\"#return-footnote-294-15\" class=\"return-footnote\" aria-label=\"Return to footnote 15\">&crarr;<\/a><\/li><li id=\"footnote-294-16\">Green L, Jorgensen T, Schroedter B, Bendick P. Carotid Duplex and Color Flow Imaging [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2012 Feb 20\u201322. <a href=\"#return-footnote-294-16\" class=\"return-footnote\" aria-label=\"Return to footnote 16\">&crarr;<\/a><\/li><li id=\"footnote-294-17\">Bandyk D, Armstrong PA, Neumyer MJ. Vascular Ultrasound Interpretation [DVD]. St Petersburg (FL): Gulfcoast Ultrasound Institute; 2012 August 9\u201310. <a href=\"#return-footnote-294-17\" class=\"return-footnote\" aria-label=\"Return to footnote 17\">&crarr;<\/a><\/li><li id=\"footnote-294-18\">Grant EG, Benson CB, Moneta GL, Alexandrov AV, Baker JD, Bluth EI, Carroll BA, Eliasziw M, Gocke J, Hertzberg BS, Katanick S, Needleman L, Pellerito J, Polak JF, Rholl KS, Wooster DL, Zierler RE. Carotid artery stenosis: Gray-scale and Doppler US diagnosis\u2014Society of Radiologists in Ultrasound Consensus Conference. Radiology. 2003 Nov;229(2):340\u20136. doi: 10.1148\/radiol.2292030516. Epub 2003 Sep 18. PMID: 14500855. <a href=\"#return-footnote-294-18\" class=\"return-footnote\" aria-label=\"Return to footnote 18\">&crarr;<\/a><\/li><li id=\"footnote-294-19\">North American Symptomatic Carotid Endarterectomy Trial. Methods, patient characteristics, and progress. Stroke. 1991 Jun;22(6):711\u201320. doi: 10.1161\/01.str.22.6.711. PMID: 2057968. <a href=\"#return-footnote-294-19\" class=\"return-footnote\" aria-label=\"Return to footnote 19\">&crarr;<\/a><\/li><li id=\"footnote-294-20\">Chaikof EL, Dalman RL, Eskandari MK, Jackson BM, Lee WA, Mansour MA, Mastracci TM, Mell M, Murad MH, Nguyen LL, Oderich GS, Patel MS, Schermerhorn ML, Starnes BW. The Society for Vascular Surgery practice guidelines on the care of patients with an abdominal aortic aneurysm. J Vasc Surg. 2018 Jan;67(1):2\u201377.e2. doi: 10.1016\/j.jvs.2017.10.044. PMID: 29268916. <a href=\"#return-footnote-294-20\" class=\"return-footnote\" aria-label=\"Return to footnote 20\">&crarr;<\/a><\/li><li id=\"footnote-294-21\">Meissner MH, Moneta G, Burnand K, Gloviczki P, Lohr JM, Lurie F, Mattos MA, McLafferty RB, Mozes G, Rutherford RB, Padberg F, Sumner DS. The hemodynamics and diagnosis of venous disease. J Vasc Surg. 2007 Dec;46 Suppl S:4S\u201324S. doi: 10.1016\/j.jvs.2007.09.043. PMID: 18068561. <a href=\"#return-footnote-294-21\" class=\"return-footnote\" aria-label=\"Return to footnote 21\">&crarr;<\/a><\/li><li id=\"footnote-294-22\">Hodgkiss-Harlow KD, Bandyk DF. Interpretation of arterial duplex testing of lower-extremity arteries and interventions. Semin Vasc Surg. 2013 Jun\u2013Sep;26(2\u20133):95\u2013104. doi: 10.1053\/j.semvascsurg.2013.11.002. Epub 2013 Nov 14. PMID: 24636606. <a href=\"#return-footnote-294-22\" class=\"return-footnote\" aria-label=\"Return to footnote 22\">&crarr;<\/a><\/li><\/ol><\/div>","protected":false},"author":13,"menu_order":10,"template":"","meta":{"pb_show_title":"on","pb_short_title":"","pb_subtitle":"","pb_authors":[],"pb_section_license":""},"chapter-type":[],"contributor":[],"license":[],"part":3,"_links":{"self":[{"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/chapters\/294"}],"collection":[{"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/chapters"}],"about":[{"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/wp\/v2\/types\/chapter"}],"author":[{"embeddable":true,"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/wp\/v2\/users\/13"}],"version-history":[{"count":64,"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/chapters\/294\/revisions"}],"predecessor-version":[{"id":802,"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/chapters\/294\/revisions\/802"}],"part":[{"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/parts\/3"}],"metadata":[{"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/chapters\/294\/metadata\/"}],"wp:attachment":[{"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/wp\/v2\/media?parent=294"}],"wp:term":[{"taxonomy":"chapter-type","embeddable":true,"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/pressbooks\/v2\/chapter-type?post=294"},{"taxonomy":"contributor","embeddable":true,"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/wp\/v2\/contributor?post=294"},{"taxonomy":"license","embeddable":true,"href":"https:\/\/pressbooks.palni.org\/ultrasoundphysicsanditsapplicationinmedicine\/wp-json\/wp\/v2\/license?post=294"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}