The common fibular nerve, also known as the common peroneal nerve, is a major peripheral nerve of the lower limb that serves as a terminal branch of the sciatic nerve, providing both motor and sensory innervation to the lateral and anterior compartments of the leg, as well as portions of the foot.[1] It originates from the bifurcation of the sciatic nerve at the apex of the popliteal fossa in the posterior thigh, deriving its fibers primarily from spinal roots L4 through S2.[2] This nerve is essential for functions such as foot dorsiflexion and eversion, and it is particularly susceptible to injury due to its superficial course around the fibular neck.[3]The common fibular nerve follows an inferolateral path through the popliteal fossa, traveling deep to the biceps femoris tendon and superficial to the lateral head of the gastrocnemius muscle, before winding laterally around the posterior aspect of the fibular neck.[1] At this point, near the fibular head, it divides into two primary terminal branches: the superficial fibular nerve, which supplies the lateral compartment of the leg, and the deep fibular nerve, which innervates the anterior compartment.[2] Along its course, it gives off smaller branches, including the lateral sural cutaneous nerve for sensory supply to the upper posterolateral leg and knee, and a communicating branch to the sural nerve for the lower posterolateral calf.[3]Motor innervation from the common fibular nerve targets key muscles involved in ankle and foot movement; the deep branch supplies the tibialis anterior, extensor hallucis longus, extensor digitorum longus, and fibularis tertius for dorsiflexion, while the superficial branch innervates the fibularis longus and brevis for eversion.[1] Sensory distribution includes the anterolateral aspect of the leg and the dorsum of the foot via the superficial branch, with the deep branch providing sensation to the first web space between the great and second toes.[2] Clinically, compression or trauma to the nerve—often from fibular fractures, prolonged knee flexion, or tight casts—can lead to peroneal neuropathy, manifesting as foot drop, steppage gait, and sensory loss over the dorsolateral foot, highlighting its vulnerability in the fibular head region.[3]
Anatomy
Origin and course
The common fibular nerve, also known as the common peroneal nerve, originates as the lateral and smaller terminal branch of the sciatic nerve within the popliteal fossa, typically at the level of the superior angle of this region. It derives its fibers primarily from the posterior divisions of the L4, L5, S1, and S2 spinal roots through the lumbosacral plexus.[1][4]From its point of bifurcation, the nerve courses laterally and obliquely along the medial border of the biceps femoris muscle and its tendon in the popliteal fossa, lying deep to the long head of the biceps femoris. It maintains a close relationship with the popliteal vessels as it progresses. Along this initial segment, it gives off a small branch, the lateral sural cutaneous nerve, which supplies sensation to the posterolateral lower leg.[1][5]Continuing its descent, the common fibular nerve winds laterally and posteriorly around the neck of the fibula, where it lies superficially against the bone, adjacent to the attachment of the fibularis longus muscle and in proximity to the fibular head. This vulnerable position at the fibular neck marks the site of its division into the superficial and deep fibular nerves, occurring at the fibular neck, approximately 2.8 cm (median) distal to the fibular head. The nerve has a diameter of roughly 3-4 mm, corresponding to a cross-sectional area of about 8.9 mm² at the fibular head.[1][6][7]
Cutaneous branches
The lateral sural cutaneous nerve arises from the common fibular nerve within the popliteal fossa.[8] It descends posterolaterally between the heads of the gastrocnemius muscle, traveling in the distal third of the posterior leg before becoming superficial around the mid-calf.[8] This nerve supplies sensory innervation to the skin of the lateral aspect of the calf.[8] It typically communicates with the medial sural cutaneous nerve, a branch of the tibial nerve, to form the sural nerve in the distal calf, often alongside the short saphenous vein.[8]The superficial fibular nerve, a major division of the common fibular nerve, provides the primary cutaneous innervation from this trunk after branching at the fibular neck.[9] It courses distally within the lateral compartment of the leg, anterior to the fibula and between the fibularis longus and extensor digitorum longus muscles.[1] The nerve pierces the crural fascia approximately 10 to 12 cm above the lateral malleolus, where it becomes subcutaneous.[9] From this point, it supplies the skin of the anterolateral leg from the mid-lateral aspect distally to the ankle.[9]Distally, the superficial fibular nerve bifurcates into the medial dorsal cutaneous nerve and the intermediate dorsal cutaneous nerve, which provide sensory innervation to the entire dorsum of the foot except the first web space.[9] These dorsal digital nerves extend to the toes 2 through 5, covering the proximal and medial aspects of the second toe, the medial and lateral aspects of the third and fourth toes, and the lateral aspect of the fifth toe.[9] The first web space receives its cutaneous supply from the terminal sensory branch of the deep fibular nerve.[9]The cutaneous branches of the common fibular nerve form anastomoses that contribute to overlapping sensory territories. The lateral sural cutaneous nerve anastomoses with the sural nerve to ensure comprehensive coverage of the posterolateral calf and foot.[8] The superficial fibular nerve's terminal branches connect with the terminal sensory branch of the deep fibular nerve on the dorsum of the foot and with the sural nerve along the lateral margin of the foot.[9] Additionally, variable communications may occur with the saphenous nerve from the femoral nerve, particularly in medial-overlapping regions of the distal leg.[9]
Articular branches
The common fibular nerve issues two primary articular branches to the knee joint: the superior lateral genicular nerve and the inferior lateral genicular nerve, which together provide sensory innervation to the lateral aspects of the joint capsule.[10] These branches arise in close proximity to the popliteal fossa and contribute to the genicular nerve network surrounding the knee.[11]The superior lateral genicular nerve originates from the common fibular nerve near the popliteal fossa, approximately 8–10 cm proximal to the kneejoint line.[11] It courses superiorly along the lateral femoral condyle, accompanying the superior lateral genicular artery, to supply the superior portion of the lateral kneejoint capsule and the patellofemoral joint. This innervation supports sensory feedback from the anterolateral knee structures.The inferior lateral genicular nerve emerges from the common fibular nerve just proximal to its bifurcation around the fibular neck.[13] It travels distally with the inferior lateral genicular artery, passing deep to the lateral collateral ligament and superior to the popliteus tendon, to innervate the inferior lateral knee joint capsule, including the proximal tibiofibular articulation.[13] This positioning aligns with the nerve's course near the fibular head.Both nerves convey sensory afferents essential for proprioception, transmitting signals for joint position sense and nociception from the knee ligaments, synovium, and surrounding capsule.[10] Their vascular accompaniment facilitates targeted distribution to these joint components.[13]
Motor branches
The common fibular nerve divides into its two major terminal branches at the fibular neck, each providing motor innervation to specific compartments of the leg.[1]The deep fibular nerve, the smaller of the two branches, penetrates the anterior intermuscular septum to enter the anterior compartment of the leg, traveling alongside the anterior tibial artery between the tibialis anterior and extensor digitorum longus muscles.[14] It supplies motor innervation primarily to the tibialis anterior, extensor hallucis longus, extensor digitorum longus, and fibularis tertius muscles in this compartment.[14] In the foot, the deep fibular nerve continues as its lateral terminal branch, which provides motor supply to the extensor digitorum brevis muscle on the dorsum.[14] These contributions derive mainly from spinal nerve roots L4 and L5.[15]The superficial fibular nerve, the larger branch, courses through the lateral compartment of the leg, passing between the fibularis longus and fibularis brevis muscles after emerging from the common trunk.[9] Its motor component innervates the fibularis longus and fibularis brevis muscles, which are responsible for foot eversion.[9] This branch arises predominantly from spinal nerve roots L5 through S1.[16]Collectively, the motor branches of the common fibular nerve facilitate key actions in the lower leg and foot, including dorsiflexion of the ankle (via tibialis anterior and extensors), eversion of the foot (via fibularis muscles), and extension of the toes (via extensor digitorum longus and hallucis longus).[14][9]
Function
Motor functions
The common fibular nerve plays a critical role in lower limb motor control, primarily facilitating movements essential for normal gait and balance. Through its deep peroneal division, it innervates the anterior compartment muscles, including the tibialis anterior, extensor digitorum longus, and extensor hallucis longus, enabling ankle dorsiflexion.[1] This action lifts the foot during the swing phase of walking, preventing toe drag and ensuring efficient forward progression.[17] Similarly, toe extension by the extensor digitorum longus and extensor hallucis longus, also mediated by the deep peroneal nerve, clears the toes from the ground during propulsion and swing, reducing the risk of stumbling.[18]The superficial peroneal division of the common fibular nerve supplies the lateral compartment muscles, such as the fibularis longus and fibularis brevis, which are responsible for foot eversion.[1] This eversion counteracts excessive inversion forces during the stance phase of gait, providing lateral stability and preventing ankle sprains.[19] Peroneal muscle activity increases eccentrically to resist inversion perturbations encountered in uneven terrain or dynamic walking, contributing to overall ankle joint control.[20]These motor functions rely on the fiber type composition of the innervated muscles, which predominantly feature fast-twitch fibers for rapid, powerful contractions. The tibialis anterior and extensor digitorum longus contain a high proportion of fast-twitch fibers (types IIa and IIx), optimized for quick movements like sudden dorsiflexion during gait initiation or obstacle avoidance, though this comes at the cost of relative fatigue susceptibility compared to slow-twitch dominant muscles.[21] The peroneal muscles similarly exhibit fast-twitch characteristics, enabling explosive eversion for stability corrections.[1]
Sensory functions
The common fibular nerve, derived from the L4-S2 spinal roots, provides sensory innervation to the skin of the anterolateral aspect of the leg and the dorsum of the foot, enabling detection of touch, pressure, temperature, and pain through its superficial and deep branches.[1] The superficial fibular nerve supplies the majority of the dorsal foot skin, excluding the first web space, while the deep fibular nerve innervates the skin between the first and second toes, including the first web space.[2] This dermatomal distribution ensures comprehensive coverage for superficial sensations critical to environmental interaction in the lower limb.[1]In addition to cutaneous sensation, the common fibular nerve conveys proprioceptive input from muscle spindles in the anterior and lateral compartments of the leg, such as those in the tibialis anterior and fibularis longus muscles, as well as from joint receptors in the ankle and foot, facilitating awareness of foot positioning and movement.[10] These afferent signals contribute to the coordination of dorsiflexion and eversion, supporting precise control during weight-bearing activities.[1]Deep sensation is mediated primarily via the deep fibular nerve, which extends to the first web space and the sinus tarsi region, providing feedback from deeper tissues that aids in maintaining balance and postural stability.[1] The lateral sural cutaneous nerve, an early branch, adds sensation to the inferolateral knee area, complementing the overall sensory map.[2]Afferent signals from the common fibular nerve ascend via the sciatic nerve and sacral plexus to the spinal cord, ultimately integrating in the primary somatosensory cortex to contribute to spatial awareness and sensory processing during locomotion.[22] This cortical representation allows for the synthesis of lower limb sensory data with motor planning, enhancing gait efficiency and adaptive responses.[23]
Clinical significance
Injury mechanisms
The common fibular nerve, also known as the common peroneal nerve, is particularly vulnerable to injury due to its superficial course around the fibular neck, where it is fixed and exposed to external pressures and mechanical forces.[5]Compression at the fibular neck represents one of the most frequent mechanisms of injury, often resulting from external pressures that entrap the nerve against the underlying bone. Common causes include habitual leg crossing, which applies direct pressure to the nerve's superficial position; tight casts or splints that constrict the area; and prolonged squatting or kneeling, as seen in certain occupational activities or sports.[5][24] Additionally, a fibrous band at the origin of the peroneus longus muscle can contribute to chronic entrapment, exacerbating compression in susceptible individuals.[5]Traumatic injuries to the common fibular nerve typically arise from high-energy impacts or skeletal disruptions near the knee. Knee dislocations are a major cause, occurring in up to 40% of such cases and often involving traction or stretch on the nerve due to its tethering at the fibular head.[5] Direct blows, such as those from football tackles or other contact sports, can contuse or lacerate the nerve, while fractures of the proximal fibula or tibia may sever or compress it during the injury event.[5][25]Iatrogenic injuries occur as complications of surgical procedures near the knee or lower leg, with an incidence ranging from 0.3% to 4% following total knee arthroplasty, particularly in cases with preoperative valgus deformity.[26] These injuries may result from direct surgical trauma, retraction during exposure of the fibular head, or postoperative compression from swelling or bandages.[5] Similar risks arise in peroneal tendon repairs or hip surgeries where positioning stretches the nerve.[5]Systemic factors can predispose the nerve to injury through underlying neuropathies or vascular compromise. Diabetes mellitus is a prominent contributor, leading to chronic neuropathy that weakens the nerve's resilience to compression or minor trauma via microvascular damage and demyelination.[5]Vasculitis, as in conditions like polyarteritis nodosa, induces ischemic injury through inflammation of the vasa nervorum, resulting in focal nerve damage.[27] Individuals with thin body habitus, such as those with anorexia, face heightened risk due to reduced protective adipose tissue around the fibular neck.[5]Regardless of the etiology, the pathophysiology of common fibular nerve injury commonly involves axonal disruption, leading to Wallerian degeneration distal to the lesion site. This process begins within 24-48 hours post-injury, with axonal disintegration and myelin breakdown progressing over 7-10 days, clearing the distal segment to allow potential regeneration.[28][29] In compressive or ischemic cases, initial demyelination may predominate, but severe trauma often triggers complete axonal degeneration.[5]
Symptoms and diagnosis
Injury to the common fibular nerve often presents with foot drop due to weakness in ankle dorsiflexion, leading to a characteristic steppage gait where the patient excessively flexes the hip and knee to clear the foot during the swing phase of walking, and a slapping foot sound upon heel strike.[5] Weakness also affects foot eversion mediated by the peroneal muscles and toe extension, while a positive Tinel's sign—elicited by percussion at the fibular head—may produce tingling radiating into the nerve's distribution.[30][5]Sensory deficits typically include numbness, paresthesia, or dysesthesia along the anterolateral aspect of the leg and dorsum of the foot, with the first web space potentially spared in partial injuries involving only the superficial branch.[31][5] These symptoms arise from dysfunction in the nerve's sensory territories and can vary in severity depending on the extent of axonal involvement or demyelination.[32]Diagnosis begins with a thorough clinical examination assessing motor strength, sensory modalities, and gait abnormalities, often confirmed through electrodiagnostic studies such as nerve conduction studies (NCS) and electromyography (EMG).[33] NCS may reveal reduced compound muscle action potential amplitudes or focal slowing across the fibular head in demyelinating lesions, while EMG demonstrates denervation patterns in muscles like the tibialis anterior and peroneus longus, with normal paraspinal findings.[33]Magnetic resonance imaging (MRI) aids in visualizing entrapment or structural causes, showing nerve edema, thickening, or high T2 signal at the fibular neck.[5]Differential diagnosis includes lumbosacral radiculopathy, particularly L5 root involvement, which presents with similar distal weakness but additionally affects hip abductors and ankle invertors, often accompanied by back pain and abnormal paraspinal EMG findings, unlike isolated common fibular neuropathy.[33] Sciatic neuropathy or central causes may also mimic symptoms but are distinguished by broader involvement on electrodiagnostics.[5]
Treatment approaches
Treatment of common fibular nerve injuries begins with conservative management, which is the initial approach for most cases, particularly those involving neuropraxia or mild axonotmesis. Ankle-foot orthoses (AFOs), such as dynamic carbon fiber models, are commonly prescribed to support foot drop by facilitating toe dorsiflexion and ankle stability, improving gait and preventing contractures.[5]Physical therapy, including nerve gliding exercises, strengthening of peroneal muscles, and neuromuscular re-education, is recommended for 3 to 6 months to promote recovery and maintain muscle function.[24] Nonsteroidal anti-inflammatory drugs (NSAIDs) like ibuprofen are used to manage associated pain and swelling, while a trial of bracing or taping may provide immediate symptomatic relief.[5]Pharmacological interventions target inflammation or neuropathic pain when conservative measures are insufficient. Corticosteroids, administered orally or via injection at compression sites like the fibular head, can reduce edema in entrapment neuropathies, with short courses (e.g., prednisone taper) showing efficacy in inflammatory cases.[34] For neuropathic pain, anticonvulsants such as gabapentin or pregabalin are first-line, titrated to 900-3600 mg/day in divided doses to alleviate burning or tingling sensations, often combined with tricyclic antidepressants like amitriptyline for better symptom control.[34]Surgical options are indicated for persistent deficits after 3 months of conservative therapy, open injuries, or progressive deterioration. Neurolysis and decompression at the fibular head address entrapment, with outcomes showing 70-90% improvement in motor function when performed within 6 months of onset.[5] For complete transections, primary end-to-end neurorrhaphy yields good recovery (up to 84% at 24 months) if tension-free, while nerve grafting is preferred for gaps under 6 cm, achieving approximately 75% functional return.[5] In chronic or irreversible cases, tendon transfers—such as posterior tibialis to anterior tibialis—restore dorsiflexion, with success rates exceeding 80% in ambulation improvement.[35]Prognosis depends on injury severity and timeliness of intervention; neuropraxic lesions recover in 70-80% of cases with conservative care alone within 3-6 months, while axonotmesis may yield partial recovery (50-70%) over 12-18 months.[5]Neurotmesis without repair often results in permanent deficits, though surgical reconstruction improves outcomes to 60-80% useful function if addressed early.[36]Recent advances include neuromodulation techniques, such as transcutaneous electrical nerve stimulation (TENS) applied daily to enhance recovery in fibular tunnel syndrome, demonstrating accelerated nerve regeneration in preclinical models.[37] Experimental regenerative therapies, like adipose-derived stem cell transplantation combined with nerve conduits, have shown promise in animal studies for bridging gaps and improving muscle reinnervation, though human trials remain limited as of 2025.[38]