The role of high-resolution ultrasound and MRI in the evaluation of peripheral nerves in the lower extremity

US provides a distinct advantage over MRN in the setting of image-guided percutaneous injections of peripheral nerves. Given that US provides real-time visualization of a nerve, it has been widely adopted for use of nerve blocks in the anesthesiologic setting and has proved beneficial in improving accuracy of injections and decreasing complications as compared to land-mark based blind injections⁽⁸⁾. Short-axis visualization of the target nerve with the needle in-plane with the transducer is the best technique for performing perineural injections. This is due to the ability of this imaging plane to make it possible to see the margins of the nerve at all times as well as easily visualize the tip of the needle, which has been shown to decrease the risk of intraneural injection⁽⁹⁾.

Radiofrequency ablation (RFA) and cryoablation (CA) techniques have been recently employed to treat chronic pain in osteoarthritis or prolonged pain following surgery. Particularly in the lower extremity RFA has been used to treat chronic pain by ablating the articular branches supplying the joints. These include the articular sensory branches of the femoral and obturator nerves in the hip⁽¹⁰⁾ and the genicular nerves in the knee⁽¹¹⁾. RFA of the lateral femoral cutaneous nerve has also been used to great effect in the setting of meralgia paresthetica⁽¹²⁾. While RFA procedures are often performed with fluoroscopic guidance, US is also widely used for more accurate targeting of the nerves⁽¹³⁾. CA of peripheral nerves, also known as cryoneurolysis (CN), has also been used in the pelvis and lower extremity to treat conditions such as pudendal neuralgia, as well as the obturator nerve to relieve hip spasticity in a patient with multiple sclerosis⁽¹⁴⁾. One feature distinguishing CN from RFA is the potential for nerve regeneration, which can result in the need for serial ablations to maintain pain relief⁽¹⁵⁾.

The sciatic nerve (SN) is the largest nerve in the human body. It originates from the ventral rami of the L2–S3 nerve roots which converge to form a single nerve. It consists of a larger and more medial tibial trunk (TT) that is comprised of fibers from the L4–S3 nerve roots, and a smaller, more lateral common peroneal trunk (CPT), which is comprised of fibers from the L4–S2 nerve roots. The two trunks are encased in a common nerve sheath. The nerve exits the pelvis passing below the piriformis muscle through the greater sciatic notch and continues in the posterior compartment of the thigh. As it approaches the popliteal fossa, it bifurcates into the tibial nerve (TN) and the common peroneal nerve (CPN). The TT gives motor innervation to the long and short heads of biceps femoris, semimembranosus, and semitendinosus muscles. The CPT gives motor innervation to the short head of the biceps femoris muscle. The undivided SN has no direct sensory function. A commonly encountered anatomic variant is high division of the SN particularly at the level of the piriformis muscle. Beaton and Anson were the first to describe 6 morphological types of this variant anatomy⁽¹⁶⁾. In a literature meta-analysis by Poutoglidou et al.⁽¹⁷⁾, the pooled prevalence for variants other than the typical anatomy was 13%, and type B anatomy, in which the CPN exits the pelvis through the piriformis muscle, was the most common variant at 8% pooled prevalence (Fig. 4).

Fig. 4.

Sciatic neuropathy commonly presents as sharp pain, weakness, and numbness within the lower back, buttock, hip, posterior thigh, and lower leg. Direct nerve injury in the setting of trauma and pelvic fractures is the most common cause. Other etiologies include direct nerve compression due to mass effect from a herniated disc or piriformis syndrome as well as iatrogenic causes, such traction injury during total hip arthroplasty⁽¹⁸⁾.

MRN is the modality of choice for evaluation of the SN as it is easily evaluated given its large size, with findings of thickening and increased signal intensity of the nerve indicating neuropathy (Fig. 5). US can also be used to assess the SN, which can be seen proximally at the level of the ischial tuberosity deep to the gluteus maximus and piriformis muscles in the transverse orientation and traced distally (Fig. 6). Within the mid-thigh, the SN can be surprisingly difficult to distinguish from the surrounding posterior compartment skeletal muscles since it is often similar in echogenicity. In these cases, it is helpful to identify the nerve proximally as it exits the sciatic notch and courses close to the ischial tuberosity or distally in the popliteal fossa and track it proximally to the thigh. Normally, the individual nerve fascicles of the sciatic nerve are of similar thickness as compared to other peripheral nerves, which may have more variable thickness. Direct US findings of neuropathy include hypoechogenicity and enlargement of the nerve as well as loss of the normal fascicular architecture. Fatty atrophy of the affected muscles of the hamstrings and adductor magnus can also be seen on both modalities, but are more easily seen on MRN. Both US and MRN can reliably detect space-occupying mass lesions that may be causing mass effect on the nerve.

Fig. 5.

Fig. 6.

Piriformis syndrome

Piriformis syndrome (PS) is an uncommon cause of compressive sciatic neuropathy in which the piriformis muscle causes mass effect on the SN^(19–20). It is considered a diagnosis of exclusion. A 6% incidence of PS has been reported in the literature in patients with sciatic neuropathy^(21–22). Some authors have suggested that the previously mentioned SN anatomic variants may increase the risk of nerve compression, however their impact on the incidence of piriformis syndrome has not been definitively studied. In their cadaveric assessment of the sciatic nerve variations, Pokorný et al. concluded that piriformis tenotomy routinely performed in the setting of total hip arthroplasty could result in contracture and shortening of the muscle, which can cause overstretching and compression of the CPN in the type B variant⁽²³⁾. Lacking knowledge of the anatomic variants, especially the high bifurcation of the sciatic nerve, may increase the risk of anesthetizing only the CPN or TN and not the other in the setting of sciatic nerve blockade⁽¹⁵⁾. In addition to the typical findings of neuropathy, other MRN findings include asymmetric hypertrophy of the piriformis muscle. Percutaneous injection of the affected piriformis muscle with local anesthetic and steroid as well as botulinum toxin type A have been widely used to great effect to relieve sciatic nerve compression⁽²⁴⁾. Steroid injection can cause atrophy of the muscle, thereby alleviating compression (Fig. 7).

Fig. 7.

The obturator nerve (ON) is a mixed sensory and motor nerve arising from the anterior divisions of the L2–L4 nerve roots. It courses anteroinferiorly along the medial margin of the psoas major muscle before passing through the obturator canal, which is a small defect within the obturator membrane along the superior aspect of the obturator foramen, where it divides into its anterior and posterior divisions. The anterior division exits the obturator canal and enters the medial thigh, coursing between the adductor brevis and pectineus muscles and gives off motor branches to adductor brevis, adductor longus, and gracilis muscles as well as sensory branches to the hip joint and the medial thigh. The posterior division exits the obturator canal by piercing through the obturator externus muscle and courses between the adductor brevis and adductor magnus muscles, giving off motor branches to supply the obturator externus and the pubic part of the adductor magnus muscles as well as a sensory branch to the knee joint.

Obturator neuropathy most commonly presents with pain, numbness, and paresthesias along the medial thigh, associated with weakness in hip adduction and internal rotation⁽²⁵⁾. The etiologies of neuropathy include trauma, iatrogenic injury from pelvic surgery, mass effect from space occupying lesions such as tumors, obturator hernias, and in rare cases an acetabular paralabral cyst^(26–27). The Howship-Romberg sign is defined as inner-thigh pain with internal rotation of the hip, which clinically indicates obturator neuropathy in the setting of an obturator hernia⁽²⁸⁾.

Given that a large portion of the ON is intra-pelvic in course, MRN is best suited for its evaluation. Increased signal intensity on fluidsensitive sequences and thickening of the nerve can be seen as well as denervation edema and fatty atrophy within the terminal adductor muscles. Both MRN and US can be effectively utilized to evaluate for space occupying lesions causing mass effect on ON. The ON and its branches can be found on US by using the adductor brevis muscle as an anatomic landmark. The anterior division of the ON can be seen coursing along the fascial plane between the adductor brevis and the adductor longus muscles, whereas the posterior division of the ON can be seen between the adductor brevis and the adductor magnus muscles. US has a distinct advantage in percutaneous block of the obturator nerve, which is commonly performed to prevent intraprocedural sudden thigh adduction during transurethral resection of bladder tumor⁽²⁹⁾ (TURBT).

The lateral femoral cutaneous nerve (LFCN) is a pure sensory branch of the lumbar plexus arising from the posterior divisions of the L2 and L3 nerve roots. It emerges from the lateral border of the psoas major muscle and courses along the iliacus muscle obliquely toward the anterior superior iliac spine (ASIS). After crossing the deep circumflex iliac vessel, the nerve exits the pelvis passing underneath the lateral end of the inguinal ligament and then dives vertically to run within the subcutaneous soft tissue along the surface of the sartorius muscle. It then splits into anterior and posterior divisions, which supply sensation to the anterior and lateral thigh respectively.

Meralgia paresthetica

Meralgia paresthetica, also known as LFCN entrapment, is a condition characterized by numbness, paresthesias, and pain in the anterolateral thigh, aggravated by standing, walking, or wearing tight clothing. Entrapment of the LFCN is most commonly caused by extrinsic compression as it crosses the inguinal ligament. Risk factors include obesity, wearing tight clothing, pregnancy, large volume ascites, injury to the hip or thigh, and diabetes⁽³⁰⁾.

The nerve can be identified on US within the fascial plane between the sartorius muscle and the tensor fascia lata approximately 1–2 cm inferior to the ASIS at the level of the inguinal ligament⁽³¹⁾. It can be traced proximally to the point where it courses beneath the inguinal ligament and distally, where the anterior division crosses over the sartorius. Ultrasound findings of neuropathy include abrupt caliber change at the ASIS with indistinct perineurium and abnormal intra-neural vascularity⁽³²⁾. MRN findings of neuropathy include thickening of the LFCN, compression of the nerve at the level of the inguinal ligament, and abnormal bright signal similar to that of regional veins on fluid-sensitive FS MRI sequences (Fig. 8)⁽³³⁾.

Fig. 8.

Femoral nerve

The femoral nerve (FN) arises from the dorsal divisions of the L2–L4 nerve roots of the lumbar plexus. It courses through the psoas major muscle and extends anterior to the iliopsoas muscle running under the inguinal ligament into the anterior thigh. It gives off the nerve to the pectineus muscle at the level of the inguinal ligament before splitting into anterior and posterior divisions within the upper thigh as it courses through the femoral triangle. The femoral triangle is an anatomical space in the anterior upper thigh bounded laterally by the medial border of sartorius, medially by the medial border of the adductor longus, and superiorly by the inguinal ligament. From lateral to medial, it contains the FN, femoral artery, and femoral vein. The anterior division gives rise to the intermediate femoral cutaneous nerve, medial femoral cutaneous nerve, and the nerve to the sartorius. The posterior division gives rise to the saphenous nerve (SaN) and motor branches to the quadriceps femoris muscles. The FN provides motor supply to the quadriceps femoris muscles, pectineus, and sartorius and sensory supply to the anteromedial aspect of the thigh and medial aspect of the knee extending to the foot via the SN.

Femoral neuropathy presents with groin pain, weakness with hip flexion and knee extension, and numbness along the anteromedial thigh and medial lower leg. The most common cause is iatrogenic compression in the setting of the pelvic and hip surgeries as well as during femoral vascular access⁽³⁴⁾. Other less common etiologies include direct injury in the setting of trauma, mass effect from tumors, infection, and diabetes.

Both US and MRN can be utilized for the evaluation of femoral neuropathy. However, MRN has distinct advantages in that it is operator-independent and can more easily evaluate its deep intra-pelvic course, which is frequently limited on US evaluation due to overlying bowel gas⁽⁵⁾. Apart from the typical appearance of neuropathy, both MRN and US can be used to evaluate for space occupying lesions that may be causing mass effect on the FN. Fatty atrophy of the quadriceps muscles can also indicate neuropathy and is easily seen on both modalities, although denervation edema of the muscles is better evaluated on MRN (Fig. 9).

Fig. 9.

Saphenous nerve (SaN)

The SaN is the largest cutaneous branch of the FN. It is a continuation of the posterior division of the FN and is the longest nerve in the body. It branches from the FN at the level of the upper thigh and travels through the adductor (Hunter’s) canal alongside the femoral artery and vein (Fig. 10), and supplies a branch to the vastus medialis muscle.

Fig. 10.

The adductor canal is bordered anteromedially by the sartorius muscle, laterally by the vastus medialis muscle, and posteriorly by the adductor longus and magnus muscles. In the knee, the SaN travels inferiorly alongside the saphenous vein to the foot. The SaN is a purely sensory nerve supplying the medial thigh and lower leg extending to the foot.

Saphenous neuropathy presents with pain and paresthesia in its distribution. This is a well-known complication after total knee arthroplasty, anterior cruciate ligament reconstruction, knee arthroscopy, and knee trauma (Fig. 11)⁽³⁵⁾. Although the nerve is visible on both MRN and US, its small caliber results in decreased signal on fluidsensitive FS MRI sequences and may make the normal nerve inconspicuous on MRN. As a result, US may be the best initial imaging modality to assess the SaN. The SaN can be consistently found on US just distal to the adductor canal between the femoral artery and the sartorius muscle. These anatomic landmarks can also be used for US-guided saphenous nerve blocks. This was well-demonstrated by Saranteas et al., who observed complete sensory block in the SaN distribution without motor deficits in 22 of 23 healthy volunteers injected with 1.5% lidocaine into the compartment bounded by the femoral artery and sartorius muscle⁽³⁶⁾. Apart from the typical findings of neuropathy, MRN and US can be useful for visualizing space occupying lesions that may cause extrinsic compression on the SaN. Since it is purely sensory, no muscle fatty atrophy will be seen.

Fig. 11.

The tibial nerve (TN) is a terminal branch of the sciatic nerve in the distal third of the lower leg. It courses through the popliteal fossa posterior to the popliteal vessels, between the heads of the gastrocnemius, and deep to the tibial and fibular heads of the soleus muscle (soleal sling). It continues distally in the posterior lower leg, running with the posterior tibial vessels to the level of the posteromedial ankle, where it passes deep to the flexor retinaculum and through the tarsal tunnel alongside the long medial flexor tendons and the posterior tibial vessels. At the level of the medial malleolus, the TN divides into its 3 terminal branches: the medial calcaneal nerve (MCN), the medial plantar nerve (MPN) and the lateral plantar nerve (LPN) (Fig. 12).

Fig. 12.

The TN provides motor supply to all of the superficial and deep muscles in the posterior compartment of the lower leg. The superficial muscles include the soleus, gastrocnemius, plantaris, and popliteus. The deep muscles include the tibialis posterior, flexor hallucis longus, and flexor digitorum longus. In the lower leg, the TN gives off 2 cutaneous branches: the sural nerve (SuN), which gives sensory supply to the posterolateral lower leg, lateral foot, and fifth toe, and the medial calcaneal nerve (MCN), which gives sensory supply to the medial aspect and sole of the heel.

Tarsal tunnel syndrome

A common area of TN entrapment is the tarsal tunnel in the setting of tarsal tunnel syndrome (TTS), which is analogous to carpal tunnel syndrome in the wrist. The tarsal tunnel is a fibro-osseous tunnel along the posteromedial ankle. The flexor retinaculum makes up the roof of the tarsal tunnel, while the medial surfaces of the tibia, talus, and calcaneus make up the floor. Presenting symptoms of TTS include burning pain and paresthesias within the heel, sole, and toes, exacerbated by weight bearing. Given that the tarsal tunnel is a narrow space, space occupying lesions such as ganglion cysts, varicosities, and tumors such as schwannomas, along with flexor tenosynovitis can cause extrinsic compression of the TN. Congenital abnormalities such as talocalcaneal coalition can also cause TTS. However, the most common cause of TTS is idiopathic, accounting for approximately 50% of cases⁽³⁷⁾.

Both US and MRN can be employed to evaluate for direct nerve abnormalities as well as space occupying lesions causing mass effect within the tarsal tunnel. The TN at the tarsal tunnel is easily found on US by placing the probe in transverse orientation, parallel with the malleolar-calcaneal axis, and it is found superficial to the flexor tendons (Fig. 13 A)⁽³⁸⁾. US of superficial nerves, such as the TN in the tarsal tunnel, has a distinct advantage over MRN in being able to elicit a Tinel’s sign during scanning. These anatomic landmarks are also often utilized for US-guided percutaneous injection of anesthetic and corticosteroids into the tarsal tunnel (Fig. 13 B).

Fig. 13.

Soleal sling syndrome

A less common area of TN entrapment is at the level of the soleal sling in the setting of soleal sling syndrome (SSS), where the TN becomes compressed under the fibrous sling between the tibial and fibular origins of the soleus muscle (Fig. 14). Clinical findings include exquisite tenderness at the site of compression, usually 5–9 cm distal to the knee joint as well as a positive Tinel’s sign.

Fig. 14.

MRN findings include thickening of the fascial soleal sling with compression and flattening of the TN and abnormal hyperintense signal within the nerve on fluid-sensitive sequences, which gradually fades and resolves in the distal calf (Fig. 15). In addition to a thickened soleal fascial sling, space occupying lesions such as extraneural ganglion cysts and tethering vascular leashes can be seen exerting a “sandwich effect” on the nerve⁽³⁹⁾. Denervation edema and fatty atrophy of the muscles of the posterior leg can also be seen. The TN can be easily traced by first identifying the popliteal artery in the popliteal fossa in the transverse orientation and identifying the nerve just superficial to it. Space occupying lesions and denervation fatty atrophy of the muscles can also be seen on US in addition to flattening of the nerve at the soleal sling. In our experience, the imaging findings described in soleal sling syndrome may be infrequently observed in patients with clinical symptoms of this condition.

Fig. 15.

The MPN is one of three terminal branches of the TN which originates at the level of the medial malleolus and courses within the medial plantar tunnel after traversing between the abductor hallucis and quadratus plantae muscles in close proximity to the master knot of Henry, which is the site where the flexor hallucis longus and flexor digitorum longus tendons crossover each other in the plantar midfoot. In the distal midfoot, it passes between the abductor hallucis and flexor digitorum brevis muscles and gives off the medial proper digital nerve to the great toe before branching into three common plantar digital nerves, which course along the first, second, and third intermetatarsal web spaces. The MPN gives motor supply to four intrinsic muscles of the forefoot including the abductor hallucis, flexor hallucis brevis, flexor digitorum brevis, and the first lumbrical. Fatty atrophy of these muscles may be seen on MRI, MRN and/or US in the setting of neuropathy. The MPN gives sensory supply to the medial distal two-thirds of the plantar surface of the foot as well as the adjacent plantar surfaces of the first through fourth toes. MPN compression or entrapment is referred to as “jogger’s foot.”

Jogger’s foot

As the name suggests, jogger’s foot is commonly seen in recreational joggers as well as running athletes with a clinical presentation of pain along the heel and medial plantar arch as well as numbness and paresthesias along the medial plantar foot and plantar first and second toes. A positive Tinel’s sign may be elicited in the medial plantar arch immediately posterior to the navicular tuberosity⁽⁴⁰⁾. The etiologies of jogger’s foot include structural abnormalities of the foot, such as hindfoot valgus, running activities in shoes with poor arch support resulting in repetitive microtrauma to the nerve, extrinsic compression of the nerve from space-occupying lesions such as ganglion cysts, flexor tenosynovitis, and iatrogenic causes usually related to foot surgery. The most common site of nerve entrapment is between the master knot of Henry and the navicular tuberosity.

Apart from the typical findings of neuropathy, MRN and US can be used to evaluate space occupying lesions causing extrinsic compression on the nerve (Fig. 16). Both modalities can also evaluate for tenosynovitis of the flexor hallucis longus and flexor digitorum longus tendons at the master knot of Henry, causing entrapment of the nerve between it and the navicular tuberosity (Fig. 17 A). Fatty atrophy of the terminal muscles, especially the abductor hallucis muscle, can also point to the diagnosis (Fig. 17 B and C)⁽⁴¹⁾. The MPN can be identified on US as the most anterior nerve at the tibial tunnel with the probe in transverse orientation along the malleolus-calcaneal axis adjacent to the posterior tibial vessels⁽⁴²⁾.

Fig. 16.

Fig. 17.

Morton’s neuroma

Chronic entrapment of the plantar digital nerves of the foot by the intermetatarsal ligament can result in perineural fibrosis known as Morton’s neuroma. It is more likely to occur in the third rather than the second intermetatarsal web spaces, and rarely in the first and fourth intermetatarsal web spaces. The clinical presentation includes pain and paresthesias in the intermetatarsal region exacerbated by weightbearing or use of high-heeled shoes. However, it should be noted that not all Morton’s neuromas are symptomatic. Bencardino et al. found that 33% of cases can be asymptomatic and clinically “silent”⁽⁴³⁾. Classic ultrasound findings of a Morton’s neuroma include a focal, hypoechoic, noncompressible nodule at the level of the metatarsal heads centered in the intermetatarsal web space and under the intermetatarsal ligament. Dynamic side to side compression of the metatarsal heads causes displacement of the nodule toward the plantar surface with a palpable and sometimes audible click when examined with real-time US, which is called the sonographic Mulder sign (Fig. 18). Morton’s neuroma is best seen on short-axis sequences of the forefoot on MRI with findings including an ovoid mass centered at the plantar aspect of the intermetatarsal web space, which, given its fibrous composition, exhibits intermediate to low signal intensity on T1W and fluid-sensitive FS sequences. Specifically, short-axis and horizontal long-axis T1W NFS sequences without fat suppression may be most useful for detecting Morton’s neuroma (Fig. 19). Fluid-sensitive FS imaging may be less useful since the lesions usually do not have high signal intensity on fluid-sensitive sequences and may be difficult to see particularly when there is fat-suppression. Additionally, Morton’s neuromas often enhance following intravenous gadolinium administration; however, given its fibrotic etiology, more delayed imaging may be helpful to detect enhancement⁽⁴⁴⁾. Torres-Calaramont et al. directly compared MRN versus US for evaluation of Morton’s neuromas and found that MRN had a higher sensitivity of 85.5% as compared to 56.5% for US⁽⁴⁵⁾. Although the authors agree with the works of Shart et al.⁽⁴⁶⁾ and Resch et al.⁽⁴⁷⁾ that recommended against mandating ancillary tests in the workup of patients with Morton’s neuromas, they do suggest it may be prudent to consider non-invasive confirmation with imaging prior to surgical management given the medicolegal implications otherwise. In our experience, imaging can be particularly helpful in distinguishing Morton’s neuromas from plantar plate injuries, which can have some overlapping clinical presentations. Following surgical resection of a Morton’s neuroma, the treated web space can appear normal, may contain intermetatarsal bursal fluid, may have scarring and architectural distortion, or may have Morton’s neuroma-like nodular soft tissue centered in the plantar intermetatarsal space that could represent fibrous material, consistent with recurrent Morton’s neuroma, or it could cause disorganization of neural tissue and represent a stump neuroma. Espinoza et al. reported their results regarding the postoperative appearance of the intermetatarsal space in their series of 90 Morton’s neuromas in 58 patients. Fifty-seven percent of postoperative intermetatarsal spaces had abnormalities, which rose to 86% in symptomatic patients. Thirty-two percent of the patients in their cohort had Morton’s neuroma-like nodular soft tissue, although this increased to 50% in the symptomatic group. Given enough time following surgical resection, most people will develop a stump neuroma; however, only a minority of these will become symptomatic. Stump neuromas may develop in as little as 3–4 months after surgery but can take up to 18 months. The symptoms may reproduce those of the original Morton’s neuroma, or, in some cases, may be more intense.

Fig. 18.

Fig. 19.

The LPN is another of the three terminal divisions of the TN, which originates at the tarsal tunnel. It gives off the inferior calcaneal nerve (ICN) at the level of the medial malleolus before passing through the deep fascia of the abductor hallucis muscle (abductor tunnel). It then courses laterally in the plantar foot between the flexor digitorum and quadratus plantae muscles toward the fifth metatarsal head, where it divides into its superficial and deep components. The LPN provides motor supply to the lateral intrinsic forefoot muscles, including the quadratus plantae, flexor digiti minimi brevis, adductor hallucis, dorsal and plantar interossei, the lateral three lumbricals, and abductor digiti minimi, and provides sensory supply to the plantar distal two-thirds of the lateral sole, fifth toe, and the lateral half of the fourth toe. The clinical presentation of LPN neuropathy often includes numbness and paresthesias along the lateral sole of the foot. Frequent causes include extrinsic compression of the nerve at or distal to the tarsal tunnel, diabetes, and most commonly trauma, which most often occurs at the abductor tunnel⁽⁴⁸⁾. On US, the nerve is best identified in short-axis at the distal tarsal tunnel posterior to the medial plantar nerve and can be traced distally. US findings of neuropathy include enlargement and hypoechogenicity of the nerve with loss of the normal fascicular architecture. MRN findings include thickening and increased signal of the nerve. Both modalities can be used to identify any space occupying lesions that may exert mass effect on the nerve.

The ICN (also known as Baxter nerve) is the first branch of the lateral plantar nerve, which originates at the level of medial malleolus and dives vertically between the abductor hallucis and quadratus plantae before taking a sharp 90 degree turn horizontally to course laterally under the calcaneus to provide motor supply to the abductor digiti quinti/minimi muscle. It also provides sensory supply to the calcaneal periosteum and the long plantar ligament. The ICN can occasionally arise directly from the TN and the MCN.

The MCN is the last of the three terminal branches of the TN and typically originates at the level of the medial malleolus. However, it can vary in origin and number as demonstrated by Zhang et al. who described 6 different branching patterns in which one or two MCNs originated from either the TN or LPN and never from the MPN⁽⁵²⁾. The MCN has an oblique course running inferiorly and posteriorly along the medial surface of the calcaneus and gives sensory supply to the medial heel and sole of the foot. MCN neuropathy can present as pain and paresthesias along this distribution. Common etiologies of isolated MCN neuropathy include direct trauma, diabetes and iatrogenic injury secondary to surgery. The nerve can be found on US in the transverse plane within the tibial tunnel as the third most posterior nerve overlying the calcaneus and can be traced distally⁽⁴²⁾. Potential treatments for MCN neuropathy include percutaneous anesthetic and steroid injection as well as radiofrequency nerve ablation⁽⁵³⁾.

Fig. 20.

The common peroneal nerve (CPN) is one of the two terminal branches of the sciatic nerve, originating proximal to the peroneal fossa. It provides sensory and motor innervation to the lower leg and foot. It initially courses posterolaterally, running just posterior to the long head of the biceps femoris muscle. As the nerve descends, it wraps around the fibular neck, located approximately 2 cm distal to the fibular head, and subsequently passes beneath the lateral compartment of the calf. Near the fibular neck, the nerve divides into its deep and superficial branches⁽⁵⁴⁾.

The CPN is vulnerable to entrapment and traction, which can occur anywhere along its course, especially at the level of the fibular head, where it winds around the fibular neck. Trauma in the form of a direct blow or fracture to the fibular head is the most common cause of CPN neuropathy ⁽⁵⁵⁾. Other etiologies for entrapment include prolonged immobilization, habitual leg crossing, tight-fitting casts or braces, and compression from surrounding structures such as tumors or cysts. Traction or stretch injuries to the CPN can occur during certain activities such as bungee jumping, as well as in the setting of varus knee injuries with rupture of the lateral ligaments⁽⁵⁶⁾. The presence of a thin body habitus or a history of rapid weight loss have been identified as potential risk factors for peroneal neuropathy which has been attributed to the paucity of subcutaneous soft tissue, increasing the likelihood of nerve compression⁽⁵³⁾. The main presentation of CPN entrapment syndrome is a foot drop resulting from weakness of ankle and toe dorsiflexion, and foot eversion. Other symptoms may include numbness, tingling, or pain at the lateral aspect of the leg and top of the foot. In severe cases, muscle atrophy may occur due to denervation⁽⁵⁷⁾.

On US, the CPN can most easily be found by identifying its origin at the bifurcation of the distal sciatic nerve in the posterior knee and tracing it distally as it courses laterally around the fibular neck. It is best evaluated in short-axis which allows for evaluation of the nerve itself (which should be of uniform thickness) as well as characterization of the nerve’s spatial relationships in relation to surrounding anatomic structures⁽⁵⁸⁾. Color Doppler evaluation can also be helpful as any detected internal color flow is considered a pathological finding⁽⁵⁹⁾. Both MRI and US can be used to evaluate for space occupying lesions such as tumors or ganglion cysts. Specifically, a proximal tibiofibular ganglion cyst is rare but well-known entity that can cause extrinsic compression on the CPN resulting in neuropathy (Fig. 21)⁽⁶⁰⁾. Increased signal on fluid-sensitive FS MRI sequences and thickening of the CPN are common MRN findings of neuropathy (Fig. 22). Denervation edema within the terminal muscles is best seen on MRN while fatty atrophy of the muscles may be seen on both US and MRN.

Fig. 21.

Fig. 22.

Intraneural ganglion cysts are an unusual but well-documented cause of peroneal neuropathy that are diagnosed on imaging and can be treated surgically. The majority of described cysts are felt to arise from a capsular defect in the proximal tibiofibular joint that allows synovial fluid to course along the epineurium of the articular branch of the CPN. As the cyst enlarges, it generally tracks superiorly along the CPN toward the sciatic nerve, and in some instances when it becomes long enough, it may course distally along the tibial nerve. In rare instances, the ganglion can arise from the posterior knee joint capsule and involve the CPN more proximally, near the sciatic nerve bifurcation into the CPN and TN. Intraneural ganglia can be well-seen on MRN as a fluid-signal intensity lesion arising from the proximal tibiofibular joint and coursing along the fibular neck that expands the CPN. This is often associated with denervation muscle changes in the anterior and peroneal muscle compartments of the lower leg, including diffuse muscle edema on fluid-sensitive sequences and possibly atrophy on T1W NFS sequences when it becomes chronic. The ganglion is seen as a hypoechoic or anechoic lobulated structure associated with the CPN with posterior acoustical “enhancement”, typical of cyst-like lesions. No internal vascularity should be seen on Doppler imaging. MRN may be preferred to characterize this lesion since it usually shows the curvilinear stalk extending from the proximal tibiofibular joint and coursing along the CPN better, and it can show denervation muscle abnormalities before they become chronic and irreversible.

The superficial peroneal nerve (SPN) arises from the lateral aspect of the common peroneal nerve and travels in the lateral compartment of the leg. It courses in an anteroinferior orientation between the peroneus brevis, peroneus longus, and extensor digitorum longus muscles⁽⁵⁹⁾. As the nerve reaches the lower third of the leg, approximately 5 cm proximal to the ankle joint, it penetrates the crural fascia to emerge from the lateral compartment of the leg to become subcutaneous. The SPN most commonly penetrates the crural fascia as a single branch and then divides into two terminal sensory branches: the intermediate cutaneous nerve (IDCN) and medial dorsal cutaneous nerve⁽⁶¹⁾. Anatomic variations include absence of either of the two terminal sensory branches, a course within the anterior compartment of the leg after piercing the intermuscular septum, or high division of the CPN prior to piercing the crural fascia⁽⁶²⁾.

Trauma, such as plantar flexion and inversion ankle sprain or fracture, is the most common cause of SPN neuropathy. Other causes can include repetitive use injuries, nerve entrapment due to the aforementioned anatomical variations, or compression by tight clothing or footwear. Additionally, certain occupations like dancing may increase the risk of SPN entrapment due to repetitive plantar flexion and inversion⁽⁶³⁾. Occasionally, peripheral nerve entrapment can be associated with myofascial herniations. Tong et al. reported a small case series of 11 patients with peripheral nerve entrapment by muscle herniation. They found that the SPN was the most commonly involved nerve and was associated with peroneal muscle herniation.

SPN neuropathy most commonly presents with numbness and paresthesias in the lateral lower leg and dorsum of the foot, sparing the first web space and the fifth toe without significant peroneal muscle weakness. A notable feature of this condition is that pain increases when the foot is forcefully inverted, which pulls the nerve against its trapped position as it goes through the deep fascia of the lower leg. These symptoms are often exacerbated during walking and exercise⁽⁶⁴⁾.

The SPN can be easily observed throughout its path using US due to its shallow location, which may offer a more comprehensive characterization of its fascicular structure compared to MRN. Moreover, US has the added advantage of being able to elicit a Tinel’s sign and utilize dynamic maneuvers to evaluate for myofascial hernias⁽⁶⁵⁾. Subtle caliber change and decreased echogenicity can be more easily detected by comparing it to the nerve in the contralateral leg (Fig. 23). On MRN, the extensor digitorum longus muscle serves as a landmark for the identification of the nerve. As per other neuropathies, abnormal caliber, thickening, and increased intensity of the nerve are usually detected on fluid-sensitive FS MRN (Fig. 24). Additionally, MRN has a better ability to detect surrounding soft tissue and muscle denervation than US⁽⁶⁶⁾.

Fig. 23.

Fig. 24.

The deep peroneal nerve (DPN) arises from the medial aspect of the common peroneal nerve traveling in an oblique orientation distally and anteriorly, passing from the lateral compartment into the anterior compartment of the leg by piercing the anterior intermuscular septum⁽⁶⁷⁾. As it continues coursing distally, it is accompanied by the anterior tibial artery, and is located anterior to the interosseous membrane, deep to the extensor digitorum longus muscle, and between the extensor digitorum longus and the tibialis anterior muscles. At the ankle, the nerve runs in the anterior tarsal tunnel, a fibro-osseous tunnel created by the inferior extensor retinaculum, medial malleolus, lateral malleolus, and the talonavicular joint capsule. Then, approximately 1 cm distal to the ankle mortise, the DPN typically divides into the medial terminal and lateral terminal branches⁽⁶⁸⁾. The DPN provides motor supply to tibialis anterior, extensor digitorum, extensor hallucis longus, and peroneus tertius muscles in the lower leg, as well as extensor digitorum brevis, and extensor hallucis brevis muscles in the ankle via the lateral terminal branch. It provides sensory supply to the first intermetatarsal web space.

Newer, high frequency US transducers can usually depict the proximal segment of the DPN just distal to the knee and the distal segment in the distal lower leg and ankle. In the mid lower leg, when the nerve dives deeply, it may be difficult to assess, particularly if there is muscle fatty infiltration. In these cases, color or power Doppler imaging may help to identify the nerve by locating the adjacent anterior tibial artery (Fig. 25).

Fig. 25.

The sural nerve (SuN) is usually formed by the union of the medial sural cutaneous nerve (a branch of the TN) and the lateral sural cutaneous nerve (a branch of the CPN). However, other patterns describing SuN formation are described in the literature⁽⁷²⁾. This is a pure sensory nerve supplying sensation to the posterolateral aspect of the distal third of the leg and the lateral aspect of the foot⁽⁷³⁾. The SuN descends along the posterior aspect of the leg between the gastrocnemius and soleus muscles. It continues its course more distally, along the lateral aspect of the leg, running parallel to the small saphenous vein and is closely associated with the Achilles tendon. The SuN is always found in the lateral retromalleolar region at the ankle, and it is separated from the lateral malleolus by the peroneal tendons⁽⁷⁴⁾. It then gives rise to the lateral calcaneal branch and continues to travel alongside the peroneal tendons until it divides into two terminal branches, the lateral dorsal cutaneous nerve, and the medial dorsal cutaneous nerve, at the level of the fifth metatarsal⁽⁷⁵⁾.

Sural neuropathy typically presents with pain in the distribution of the SuN, involving the posterolateral aspect of the distal third of the leg, the lateral foot, and the fifth toe. In most cases, the etiology of sural neuropathy is traumatic, including direct trauma, injuries involving nearby structures like the Achilles’ tendon or peroneal tendons, fracture of the distal fibula, talus, calcaneus, or base of the fifth metatarsal, and severe lateral ankle sprain⁽⁷⁶⁾. Additional causes include compression by a space-occupying lesion and iatrogenic injury to the nerve resulting from surgery to the nearby structures.

Evaluating the SuN using ultrasound can be difficult due to its small diameter and multiple anatomical variations in the proximal leg⁽⁷⁷⁾. However, the nerve’s fixed location in the distal leg, close to the small saphenous vein and in the lateral retromalleolar region makes it easier to locate SuN at this level and track it proximally into the proximal leg⁽⁷²⁾. US can show signs of neuropathy such as hypoechogenicity, thickening, increased vascularity on Doppler, and interruption of nerve continuity in cases of nerve transection. Occasionally, neuromas-in-continuity can also be seen in cases of trauma or iatrogenic injury to the nerve (Fig. 26). Although US imaging may provide superior spatial resolution, MRN has higher sensitivity for subtle changes in nerve signal intensity.

Fig. 26.