Doppler ultrasonography of the lower extremity arteries: anatomy and scanning guidelines
Article information
Abstract
Doppler ultrasonography of the lower extremity arteries is a valuable technique, although it is less frequently indicated for peripheral arterial disease than for deep vein thrombosis or varicose veins. Ultrasonography can diagnose stenosis through the direct visualization of plaques and through the analysis of the Doppler waveforms in stenotic and poststenotic arteries. To perform Doppler ultrasonography of the lower extremity arteries, the operator should be familiar with the arterial anatomy of the lower extremities, basic scanning techniques, and the parameters used in color and pulsed-wave Doppler ultrasonography.
Introduction
Imaging modalities for evaluating peripheral arterial disease in the lower extremities include computed tomography (CT) angiography, conventional angiography, and Doppler ultrasonography (US). Three-dimensional CT angiography provides information about atherosclerotic calcifications and the extent of stenosis or occlusion of the arteries. CT angiography has some advantages, such as a shorter examination time, the ability to evaluate the iliac artery, and the fact that it is less affected by the operator’s experience. Conventional angiography is used for vascular interventions such as angioplasty or stent application, as well as in the diagnosis of peripheral arterial disease. Doppler US is the only noninvasive technique that does not require contrast enhancement, preparation of the patient before the study, or radiation exposure [1,2]. Doppler US is a good method for screening and follow-up, as well as for the definitive diagnosis of peripheral arterial disease [3-7]. Color Doppler US can easily identify arteries by finding round objects with regular pulsation and can be used to detect stenotic or occluded segments [4,8]. Pulsed-wave Doppler US can show the exact flow velocity of each arterial segment and determine the degree of severity of the stenosis based on an analysis of the pulsed-wave Doppler spectral waveform [9].
Knowledge of the ultrasonographic anatomy of the lower extremity arteries and the corresponding anatomical landmarks is essential for performing Doppler US. In this article, we review the basic scanning techniques of color and pulsed-wave Doppler US for the lower extremity arteries and the spectral analysis of normal and stenotic arteries on pulsed-wave Doppler US.
Anatomy of the Lower Extremity Arteries on CT Angiography
Each lower extremity artery is visible with an accompanying vein, extending from the iliac artery to the popliteal artery. The anterior tibial artery, the posterior tibial artery, and the peroneal artery are seen with two homonymous veins. The overall anatomy of the arteries in the lower extremities is shown on CT angiography in Fig. 1.
The common iliac artery splits into the internal iliac artery and the external iliac artery in the pelvic cavity. The external iliac artery is continuous with the common femoral artery (Fig. 1A). The inguinal ligament is a landmark for the junction of the external iliac artery and common femoral artery. The inguinal ligament is located more proximally than the inguinal crease. The common femoral artery is a short segment, generally about 4 cm long, and bifurcates into the superficial femoral artery medially and the deep femoral artery laterally [10]. The superficial femoral artery descends without prominent branching between the quadratrus and adductor muscle groups in the anteromedial thigh. In the distal thigh, the superficial femoral artery enters the adductor canal. On leaving the adductor hiatus, the name of the artery becomes the popliteal artery in the popliteal fossa and ends by bifurcating into the anterior tibial artery and the tibioperoneal trunk in the posterior aspect of the proximal calf [11].
Below the knee, the anterior tibial artery passes from the posterior to the anterior, and then descends along the interosseous membrane behind the anterior tibialis muscle and the extensor muscles in the anterolateral leg. The tibioperoneal trunk divides into the posterior tibial artery medially and the peroneal artery laterally (Fig. 1B). The posterior tibial artery runs along the intermuscular space between the posterior tibialis muscle and the soleus muscles. The peroneal artery extends down between the posterior tibialis muscle and the flexor hallucis longus muscle.
In the ankle and foot region, the anterior tibial artery continues into the dorsalis pedis artery distal to the extensor retinaculum [11]. The dorsalis pedis artery forms the arcuate artery at the metatarsal base and gives rise to the dorsal metatarsal artery. The posterior tibial artery passes behind the medial malleolus of the tibia and bifurcates, forming the medial and lateral plantar arteries. The deep plantar arch from the medial and lateral plantar arteries gives rise to the plantar metatarsal and digital arteries of the foot [11].
US Anatomy of the Lower Extremity Arteries
Arteries can be differentiated from veins on US by several characteristics. First, arteries are round in transverse images, while veins are somewhat oval. Second, arteries are smaller than veins. Third, arteries have visible walls and sometimes have calcified plaques on the walls. Fourth, when the vessels are compressed by the transducer, arteries are partially compressed, while veins are completely collapsed [12].
Doppler US of the lower extremity begins at the inguinal crease by putting a transducer on the common femoral artery in the transverse plane with the patient in the supine position (Fig. 2). The common femoral artery is seen lateral to the femoral vein, which is drained from the greater saphenous vein anteromedially at the inguinal area (Fig. 3A). Just below the inguinal crease, the superficial femoral artery and the deep femoral artery are present alongside the femoral vein, showing a shape reminiscent of Mickey Mouse’s face on a transverse scan (Fig. 3B). The common femoral artery, the bifurcated superficial femoral artery and deep femoral artery are seen in a fallen-Y configuration in a longitudinal scan (Fig. 2). From the proximal to distal thigh, scanning is performed by moving a transducer distally along the superficial femoral artery deep to the sartorius muscle. The superficial femoral artery goes together with the femoral vein (Fig. 2).
The popliteal artery is evaluated from the knee crease level in the transverse plane and then traced proximally up to the adductor canal at the supracondylar level of the femur (Fig. 2). The popliteal artery is seen in the central portion of popliteal fossa between the medial and lateral heads of the gastrocnemius muscles. The evaluation of the posterior tibial artery can be started from its origins at the tibioperoneal trunk, if scanning distally, or from the ankle behind the medial malleolus, if scanning proximally (Fig. 4). The peroneal artery is scanned along the lateral side of the posterior calf and is visualized alongside the fibular bone (Fig. 4).
The evaluation of the anterior tibial artery can be started from the ankle anterior to the talus neck and continued proximally or started from the proximal anterolateral leg between the tibia and the fibula and continued distally (Fig. 4). The transducer is traced from the anterior ankle to the dorsal foot to evaluate the dorsalis pedis artery, continuing to the first dorsal metatarsal artery between the first and second metatarsal bones (Fig. 4).
US Technique
Transducer and Patient Position
A linear transducer with a variable ultrasound frequency of 9-15 MHz is generally used, but a convex transducer with a lower frequency can be selected for the evaluation of iliac arteries in the pelvic cavity [13]. The transducer is placed over an artery for transverse scanning, and then is rotated 90° for longitudinal scanning. The artery should be scanned on a longitudinal plane as long as possible. The operator should rotate or move the transducer delicately to maintain visualization of the artery. Pulsed-wave Doppler US is performed in the longitudinal plane.
The examination is usually performed with the patient placed in the supine position. The patient’s hip is generally abducted and externally rotated, and the knee is flexed like frog legs in order to easily approach the popliteal artery in the popliteal fossa and the posterior tibial artery in the medial calf (Fig. 2). The left lateral decubitus position or the prone position are the alternatives for evaluating the popliteal artery, the posterior tibial artery, and the peroneal artery (Fig. 4). The anterior tibial artery and dorsalis pedis artery are scanned in the supine position (Fig. 4).
Parameters and Optimization of Doppler US
The operator should be aware of both color and pulsed-wave Doppler parameters and how to adjust these parameters to obtain an optimal Doppler image.
Among these parameters, the color box, color gain, color velocity scale, and inversion are frequently used during color Doppler US scanning. The color box is a square area within the grayscale sonogram in which all color Doppler information is displayed (Fig. 3). The size and location of the box are adjustable, and the image resolution and quality are affected by the box size and depth [14]. The box should be made as small and placed as superficially as possible, thereby maximizing the frame rate. The color box should be tilted using the “steer” button according to the arterial axis during longitudinal scanning (Fig. 5). Color gain refers to the amplification of flow data to improve the depiction of flow [14]. Color gain (the “gain” button on the US machine) should be set as high as possible without displaying background color noise. The color velocity is the range of flow velocities that are depicted in color Doppler US [14]. If the velocity scale (the “scale” button on the US machine) setting is lower than the flow velocity of the artery, aliasing artifacts will be present. An operator can detect the color flow within an arterial lumen by increasing the gain or decreasing the scale. Color flow artifacts outside an artery should be removed by decreasing the gain. A homogeneous color of arterial flow can be obtained by increasing the scale. Flow toward the transducer typically appears red on color Doppler sonograms when a red color appears above the baseline on the color bar. Inversion can electronically invert the direction of flow, which may complicate the interpretation of the flow direction. Therefore, the flow direction should be interpreted based on the setting of the color bar. The wall filter (WF) eliminate the low frequency noise that may arise from vessel wall motion below an operator-defined frequency threshold [9,14]. WF settings are usually preset by manufacturer (Fig. 6).
It is important to understand the meaning of the parameters of pulsed-wave Doppler US and how to adjust them. The sample volume cursor is composed of parallel lines on both sides of the arterial axis line. The sample volume should be placed within an arterial lumen, and the range of the sample volume size is generally from one-third to one-half of the luminal diameter [15]. The Doppler angle is formed by the Doppler line and the axis of arterial flow and should be between 45° and 60° for optimal accuracy [9]. On Doppler US, the line in the center of the artery indicates of the axis of arterial flow. The nearly vertical line is the Doppler line of sight (Fig. 5). The Doppler spectrum is a graph showing the mixture of frequencies over a short period of time [9]. The Doppler frequency is defined as the difference between the received and transmitted frequencies when blood cells are moving. The key elements of the Doppler spectrum are the time and velocity scales [9]. On the Doppler spectrum, time (seconds) is represented on the x-axis, and the velocity scale (cm/sec) is shown on the y-axis (Fig. 5). Flow direction relative to the transducer is shown in relation to the spectrum baseline. Flow toward the transducer is represented by positive velocity above the baseline (Fig. 5). The “high-Q” or peak velocity envelope is the blue outline surrounding the Doppler spectrum. Based on this envelope, peak systolic velocity (PSV), minimum diastolic velocity (MDV), end-diastolic velocity (EDV), and the resistivity index (RI) can be obtained numerically (Figs. 5, 6). PSV is the highest systolic velocity, MDV is the lowest diastolic velocity, and EDV is the highest end-diastolic velocity. The RI is one of popular measurements of the pulsatility representing peripheral flow resistance [9]. If an aliasing artifact is present in the Doppler spectrum, the baseline can be reduced or the scale increased in order to optimize the velocity range (Fig. 6). It can be automatically optimized by pressing the “i-scan” button.
Doppler Spectrum of Normal Lower Extremity Arteries
The Doppler waveform of the lower extremity arteries at rest is classified as a high pulsatility waveform and is characterized by a triphasic flow pattern [9]. Over the course of each heartbeat, a tall, narrow, and sharp systolic peak in the first phase is followed by early diastolic flow reversal in the second phase, and then by late diastolic forward flow in the third phase (Fig. 5). Diastolic flow reversal results from the high peripheral resistance of normal extremity arteries [9]. In normal extremity arteries, flow acceleration in systole is rapid, which means that the peak velocity is reached within a few hundredths of a second after ventricular contraction begins. Blood in the center of the artery moves faster than blood at the periphery, which is described as laminar flow [9]. When the flow is laminar, the blood cells are moving at a similar speed. These features of normal arteries produce a clear space, known as the spectral window, under the Doppler spectrum.
Abnormal US Findings
Doppler US of the lower extremities can be performed by obtaining grayscale images before the color Doppler study; however, grayscale evaluations are sometimes optional and can be considered as a second step when a color Doppler study yields findings suspicious for stenosis or occlusion. On a grayscale image, the presence and the size of a plaque should be described, as well as whether the plaque is calcified or not. Plaque size can be measured in terms of height and length obtained using transverse and longitudinal scans, respectively [16]. Three-dimensional US has been recently used for measuring plaque volume, with good intraobserver and interobserver reproducibility [17].
On color Doppler US, if an occlusion is present in the artery, color flow is absent within the lumen (Fig. 7).
The Doppler spectrum at severely stenotic arterial segments and poststenotic or post-obstructive distal arterial segments is briefly reviewed below. The peak systolic velocity at stenotic segments increases until the diameter is reduced by 70%, which corresponds to a 90% reduction in area [18]. The area of flow disturbance showing spectral broadening occurs within 2 cm beyond the area of stenosis due to loss of the laminar flow pattern (Fig. 6). Spectral broadening is prominent, with a diameter reduction of 20%-50%. The lower extremity artery waveform may convert to a low-resistance form with low pulsatility after exercise or as a result of the occlusion of more proximal arteries [18]. If the waveform is monophasic, that means that the entire waveform is either above or below the Doppler spectrum baseline, depending on the orientation of the US transducer [9]. It is characterized by a “damped” pattern, which means that systolic flow acceleration is slowed, peak systolic velocity is reduced, and diastolic flow is increased [19]. This monophasic waveform is seen at the stenotic site and in the distal artery in cases of severe stenosis with a diameter reduction of more than 50%.
Conclusion
Doppler US has been found to distinguish between stenosis with a diameter reduction greater than or less than 50% (corresponding to an area reduction of 70%) with a sensitivity of 77%-82% and a specificity of 92%-98% [18,20-24]. Complete scanning of both lower extremities may require up to 2 hours depending on the operator’s experience [18]. However, if the operator is familiar with the US anatomy of the lower extremity arteries and understands the parameters and Doppler waveforms of Doppler US, accurate diagnostic results can be produced with less scanning time.
Notes
No potential conflict of interest relevant to this article was reported.