Spontaneous incomplete recovery of peroneal palsy after a sealbite

Incomplete recovery of peroneal palsy, after a sealbite during swimming has not been reported. A 58-year-old woman was bitten into the right knee by a seal during swimming, resulting in incomplete division of the right profound branch of the peroneal nerve and complete division of the superficial branch of the peroneal nerve. Initial drop-foot, absent foot eversion, and hypaesthesia of the lateral lower leg were followed by almost complete clinical recovery of motor functions within four month by spontaneous re-innervation from the proximal nerve stump, despite severely abnormal electrophysiological findings. Re-evaluation 6 years after the accident revealed only discrete weakness for foot and toe extension, slight distal hypaesthesia, but still increased distal latency, reduced compound muscle action potential, slowed nerve conduction velocity of the right peroneal nerve, and neurogenic electromyography of the right anterior tibial and long peroneal muscles. Nerve conduction studies were hampered by co-innervation of the extensor digitorum brevis muscles by the tibial nerves. This case shows that peroneal palsy from a sealbite may recover spontaneously almost completely, but may go along with residual, subclinical, electrophysiological abnormalities. The later may be enhanced by innervation variants.     

Behavioural and anatomical analysis of selective tibial nerve branch transfer to the deep peroneal nerve in the rat

Nerve transfer procedures involving the repair of a distal denervated nerve element with that of a foreign proximal nerve have become increasingly popular for clinical nerve repair as a surgical alternative to autologous nerve grafting. However, the functional outcomes and the central plasticity for these procedures remain poorly defined, particularly for a clinically relevant rodent model of hindlimb nerve transfer. We therefore evaluated the effect of selective tibial branch nerve transfer on behavioural recovery in animals following acute transection of the deep peroneal nerve. The results indicate that not only can hindlimb nerve transfers be successfully accomplished in a rat model but that these animals display a return of skilled locomotor function on a par with animals that underwent direct deep peroneal nerve repair (the current gold standard). At 2 months, ground reaction force analysis demonstrated that partial restoration of braking forces occurred in the nerve transfer group, whereas the direct repair group had fully restored these forces to similar to baseline levels. Ankle kinematic analysis revealed that only animals in the direct repair group significantly recovered flexion during the step cycle, indicating a recovery of surgically induced foot drop. Terminal electrophysiological and myological assessments demonstrated similar levels of reinnervation, whereas retrograde labelling studies confirmed that the peroneal nerve‐innervated muscles were innervated by neurons from the tibial nerve pool in the nerve transfer group. Our results demonstrate a task‐dependent recovery process, where skilled locomotor recovery is similar between nerve transfer and direct repair animals, whereas flat surface locomotion is significantly better in direct repair animals.     

坐骨神经及其分支损害的临床电生理分析

目的回顾性分析坐骨神经及其分支损害的病因及电生理表现。方法结合70例患者病因,分析腓神经和胫神经传导速度及健、患侧胫骨前肌、腓肠肌针电极肌电图表现。结果外伤导致的有36例(51%),其次是肌肉注射,占20例(29%),外科手术并发5例(7%),不明原因9例(13%)。单纯腓神经损害25例,单纯胫神经损害13例,坐骨神经损害32例。结论外伤是本组坐骨神经及其分支损伤的主要原因,电生理检测对确定受损神经、损害性质、损害程度及评价预后有重要价值。     

Clinical and electrophysiological recovery from peroneal palsy

Clinical examination, electromyography and conduction studies in motor and sensory fibres were performed in 14 patients with peroneal palsy of compressive or spontaneous origin. After a period of from 5 months - 3 years, the clinical and electrophysiological examinations were repeated. The rate of recovery was not uniformly good, as only 6 of 14 patients had a complete clinical recovery. Most patients had an incomplete electrophysiological recovery which only partly corresponded to the clinical findings. Electromyography and conduction studies in sensory and motor fibres were found to be of value in predicting the outcome of the peroneal palsy.     

Distal sensory nerve conduction of the superficial peroneal nerve: new method and its clinical application

The superficial peroneal nerve subserves sensation on the entire surface of the dorsum of the foot, except in small areas. All previously reported techniques for evaluating nerve conduction along this nerve tested a proximal portion of the nerve. We report a new method for evaluating sensory nerve conduction of the four branches of the distal superficial peroneal nerve. Two branches to the second and third toes of the medial dorsal cutaneous nerve and two branches to the fourth and fifth toes of the intermediate dorsal cutaneous nerve were studied orthodromically and antidromically in 37 feet of 21 normal volunteers using surface stimulating and recording electrodes and with a distance of 10 cm between the stimulating and recording electrodes. Maximum nerve conduction velocities (NCV) ranged from 41.8 to 46.9 m/s, and mean response amplitude ranged from 6.5 to 7.6 microV with the orthodromic technique. Values for NCV were almost identical when elicited by antidromic and orthodromic techniques, but response amplitudes were higher with the antidromic technique. Mean amplitudes of the distal superficial peroneal nerve were about 50% of the proximal superficial peroneal, and the conduction velocity in the distal superficial peroneal was slower than that in the proximal superficial peroneal nerve, by 8-14 m/s. In seven cases, distal superficial peroneal neuropathy was confirmed with this technique: two with proper digital neuropathy, two with medial dorsal cutaneous neuropathy, and three with intermediate dorsal cutaneous neuropathy.     

Soleus nerve transfer to deep peroneal nerve for treatment of foot drop

Different mechanisms including knee dislocation, replacement surgery, nerve tumor, lumbar disc herniation, sharp injury, and gunshot wound lead to foot drop. Several surgical techniques have been used for treatment of foot drop, however, they have had sub-optimal outcomes. Soleus branch of tibial nerve is a good donor for nerve transfer for treatment of foot drop. In this is retrospective study, we reviewed medical records of 6 consecutive patients with sustained foot drop following injury to lumbar root or peroneal nerve, who underwent transfer of the soleus branch of tibial nerve to deep peroneal nerve during 2014–2016. The mean age of the patients was 44.8 years and duration of injury to surgery and follow-up was 8.3 and 14.6 months, respectively. At the end of the follow-up, ankle dorsiflexion force was M4 in two patients (with traumatic peroneal nerve injury with M3 toe extension) and was M2 in one patient. There were three patients with lumbar degenerative disease. Of these patients, two showed M0 and one patient experienced M1 ankle dorsiflexion. We recommend that transfer of soleus nerve to deep peroneal nerve is used as an alternative technique for treatment of foot drop.     

Evaluation of atrophy of foot muscles in diabetic neuropathy -- a comparative study of nerve conduction studies and ultrasonography.

OBJECTIVE: To evaluate the relation between the findings at nerve conduction studies and the size of small foot muscles determined by ultrasonography. METHODS: In 26 diabetic patients the size of the extensor digitorum brevis muscle (EDB) and of the muscles between the first and second metatarsal bone (MIL) was determined. Motor nerve conduction studies of the peroneal and tibial nerves were performed with determination of the amplitudes of the CMAPs and of the nerve conduction velocities (NCV). Further, a standardised clinical examination was performed providing a neurological impairment score. RESULTS: Seventeen patients fulfilled the criteria for diabetic neuropathy. The cross-sectional area of the EDB muscle and the thickness of the MIL muscle were 116 +/- 65 mm2 and 29.6 +/- 8.2 mm, respectively. Close relations were established between muscle size and the amplitude of the CMAP of the peroneal (r=0.77, p<0.001) and of the tibial nerve (r=0.70, p<0.01). Further there were close relations between the muscle size and the NCV of the peroneal (r=0.62, p<0.01) and of the tibial nerve (r=0.71, p<0.001). CONCLUSIONS: The amplitude of the CMAP of the peroneal and of the tibial nerves is closely related to the size of the small foot muscles as determined by ultrasonography. SIGNIFICANCE: In diabetic patients motor nerve conduction studies can reliably determine the size of small foot muscles.     

Biphasic recovery in n-hexane polyneuropathy A clinical and electrophysiological study

We studied the course of recovery in n-hexane polyneuropathy in 4 patients by quantitatively assessing clinical and electrophysiological features. The electrophysiological study included measures of motor conduction of the median, ulnar, tibial and peroneal nerves and sensory conduction of the median, ulnar and sural nerves. After cessation of exposure, there was an initial worsening in muscle strength, sensory deficit and nerve conduction for up to 2-5 months. This deterioration was more severe and prolonged in the lower limbs than in the upper limbs. The period of deterioration was followed by a slow recovery studied for 1 year.     

Toward more rational nerve conduction interpretations: the effect of height

One hundred four normal subjects ranging in age from 17 to 77 years and in height from 115 to 203 cm underwent nerve conduction studies of sural, peroneal, tibial, and median nerves. Foot temperature was measured in each patient. A strong inverse correlation was found between height and sural (r = -0.7104), peroneal (r = -0.6842), and tibial (r = -0.5044) conduction velocities. These correlations were significant at the P less than 0.001 level. Median conduction velocity was not correlated with height. Height was correlated with the distal latencies of all nerves studied (sural r = 0.6518, peroneal r = 0.4583, tibial r = 0.7217, median r = 0.5440). These correlations were significant at the P less than 0.001 level. Age was inversely correlated with both tibial (r = -0.4071) and median (r = -0.3464) nerve conduction velocities but not with sural and peroneal conductions. There were no correlations between distal latencies and age. If the variation in conduction velocity accounted for by the linear relationship with height was removed, then age would be inversely correlated to all conduction velocity measurements with the exception of the sural. Temperature is inversely correlated with the sural (r = -0.2233), peroneal (r = -0.2102), and tibial (r = -0.2710) distal latencies. In all instances, the effects of age and temperature were minor determinants when compared with the effects of height. Diagnostic conclusions made from nerve conduction data without correcting for height may be invalid in patients taller and shorter than normal.(ABSTRACT TRUNCATED AT 250 WORDS)     

The influence of the reference electrode on CMAP configuration: Leg nerve observations and an alternative reference site

Peroneal and tibial compound motor action potentials (CMAP) recorded using the standard belly-tendon montage have different configurations. The peroneal CMAP is a smooth dome shape, while the tibial CMAP has a slow-rising initial component followed by a higher amplitude negative peak. To evaluate possible causes of these differences, we investigated the individual activity recordable at the belly and tendon electrodes by using a referential montage with the opposite foot as the reference. This type recording shows that the peroneal belly site produces most of the nerve CMAP, whereas the tendon site generates most of the high tibial CMAP. Some features and technical problems of referential CMAP recording using an opposite limb reference are shown. An alternative method using an ipsilateral distal leg reference site is described. A montage which separately records the activity at the belly or tendon electrodes may provide new insight into mechanisms of commonly observed nerve conduction phenomena. © 1996 John Wiley & Sons, Inc.     

Medial dorsal superficial peroneal nerve studies in patients with polyneuropathy and normal sural responses

We studied medial dorsal superficial peroneal (MDSP) nerves in 52 patients with clinical evidence of mild chronic sensorimotor polyneuropathy and normal sural nerve responses, in order to assess the diagnostic sensitivity and usefulness of MDSP nerve testing in electrodiagnostic practice. To determine the effect of age on MDSP nerve parameters, 98 normal subjects were also examined. Electrodiagnostic evaluation involved studies of motor nerve conduction in tibial, peroneal, and median nerves; sensory nerve conduction in sural, MDSP, median, and radial nerves; tibial and peroneal nerve F waves; H reflexes from the soleus muscles; and needle electromyography of gastrocnemius and abductor hallucis muscles. Among the patients, 49% had low-amplitude sensory responses in MDSP nerves and 57% had either slowing of sensory conduction velocity or no sensory responses on proximal stimulation. MDSP nerve amplitude, tibial nerve motor velocity, and H reflexes were the most sensitive for detection of mild chronic symmetrical axonal sensorimotor polyneuropathy. MDSP nerve testing should be included in the routine electrodiagnostic evaluation of patients with suspected polyneuropathy and normal sural nerve responses.     

Hereditary neuropathy with liability to pressure palsy: the electrophysiology fits the name

BACKGROUND: Studies of patients with hereditary neuropathy with liability to pressure palsies (HNPP) have shown accentuated distal slowing along with nonuniform conduction abnormalities at segments liable to compression, suggesting a distal myelinopathy as an underlying pathophysiological mechanism. METHODS: We evaluated 12 patients with HNPP by standard nerve conduction studies and by conduction to more proximal muscles in the arm and leg. Three CMT1A patients and six healthy subjects also were evaluated as controls. RESULTS: Median and peroneal motor nerves in all HNPP patients showed prolonged distal motor latencies (DML) (mean +/- SE, 5.9 +/- 0.41 and 8.63 +/- 0.58 milliseconds), but the ulnar and tibial DML were minimally prolonged or normal (mean +/- SE, 3.87 +/- 0.16 and 5.66 +/- 0.24 milliseconds). DML to forearm flexor (median and ulnar nerves) or anterior tibial muscles (peroneal nerve) were also normal. CONCLUSION: Accentuated distal slowing is found primarily in median and peroneal nerve segments liable to pressure palsies or repetitive trauma. However, the ulnar and tibial nerves, which are less liable to compression, have minimal changes. In addition, distal latencies to more proximal muscles in the arm and leg do not have distal slowing. These findings do not support a distal myelinopathy as a determinant of the conduction abnormalities in HNPP.     

Neurilemmoma of Deep Peroneal Nerve Sensory Branch : Thermographic Findings with Compression Test

We report a case of neurilemmoma of deep peroneal nerve sensory branch that triggered sensory change with compression test on lower extremity. After resection of tumor, there are evoked thermal changes on pre- and post-operative infrared (IR) thermographic images. A 52-year-old female presented with low back pain, sciatica, and sensory change on the dorsal side of the right foot and big toe that has lasted for 9 months. She also presented with right tibial mass sized 1.2 cm by 1.4 cm. Ultrasonographic imaging revealed a peripheral nerve sheath tumor arising from the peroneal nerve. IR thermographic image showed hyperthermia when the neurilemoma induced sensory change with compression test on the fibular area, dorsum of foot, and big toe. After surgery, the symptoms and thermographic changes were relieved and disappeared. The clinical, surgical, radiographic, and thermographic perspectives regarding this case are discussed.     

MR neurography of sciatic nerve injection injury

We report on magnetic resonance neurography (MRN) as a supplementary diagnostic tool in sciatic nerve injection injury. The object of the study was to test if T2-weighted (w) contrast within the sciatic nerve serves as an objective criterion for sciatic injection injury. Three patients presented with acute sensory and/or motor complaints in the distribution of the sciatic nerve after dorsogluteal injection and underwent MRN covering gluteal, thigh and knee levels. Native and contrast-enhanced T1-w images were employed to identify the tibial and peroneal division of the sciatic nerve while T2-w images with fat suppression allowed visualization of the site and extent of the nerve lesion. MRN in the two patients with clinically severe sensory and motor impairment correctly depicted sciatic injury: continuity of the T2-w lesion within the nerve at the lesion site and distal to it corresponded well to severe injury confirmed by NCS/EMG as axonotmetic or neurotmetic. Topography of the T2-w lesion on cross-section corresponded to predominant peroneal involvement; moreover, associated denervation patterns of distal target muscles were revealed. One of these patients completely recovered with concomitant complete regression of MRN abnormalities on follow-up. The third patient experienced transient sensory and mild motor impairment with complete recovery after 2 weeks. In this patient, T2-w signal within the nerve and distal target muscles remained normal indicating only mild, non-axonal nerve affliction. Our case series shows that MRN can be very useful in precisely determining the site of sciatic injection injury and may provide diagnostic criteria for the assessment of lesion severity and recovery.     

Clinical Characteristics of Peroneal Nerve Palsy by Posture

Objective

Posture induced common peroneal nerve (CPN) palsy is usually produced during the prolonged squatting or habitual leg crossing while seated, especially in Asian culture and is manifested by the onset of foot drop. Because of its similarity to discogenic foot drop, patients may be diagnosed with a lumbar disc disorder, and in some patients, surgeons may perform unnecessary examinations and even spine surgery. The purpose of our study is to establish the clinical characteristics and diagnostic assessment of posture induced CPN palsy.

Methods

From June 2008 to June 2012, a retrospective study was performed on 26 patients diagnosed with peroneal nerve palsy in neurophysiologic study among patients experiencing foot drop after maintaining a certain posture for a long time.

Results

The inducing postures were squatting (14 patients), sitting cross-legged (6 patients), lying down (4 patients), walking and driving. The mean prolonged neural injury time was 124.2 minutes. The most common clinical presentation was foot drop and the most affected sensory area was dorsum of the foot with tingling sensation (14 patients), numbness (8 patients), and burning sensation (4 patients). The clinical improvement began after a mean 6 weeks, which is not related to neural injury times. Electrophysiology evaluation was performed after 2 weeks later and showed delayed CPN nerve conduction study (NCS) in 24 patients and deep peroneal nerve in 2 patients.

Conclusion

We suggest that an awareness of these clinical characteristics and diagnostic assessment methods may help clinicians make a diagnosis of posture induced CPN palsy and preclude unnecessary studies or inappropriate treatment in foot drop patients.     

Slimmer's paralysis: electrophysiological evidence of compressive lesion

A 14-year-old girl developed right peroneal nerve palsy following diet for weight reduction. Peroneal neuropathy started after sitting and leg-crossing. The main electrophysiologic findings showed a severe slowing of conduction velocity in the above-to-below capitulum fibulae segment and a striking reduction in the size of the compound motor action potential when the nerve was stimulated above the knee. These features are consistent with focal demyelination and conduction block of the nerve fibres. The left peroneal nerve showed the same results but less severe. There were no electrophysiological signs of subclinical polyneuropathy. Examination after 3 months was normal. The clinical and electrophysiological features in this case support the compressive origin of the peroneal neuropathy in slimmer's paralysis.     

Transient forearm conduction block in the median nerve

We present two cases referred for electrophysiological confirmation of carpal tunnel syndrome (CTS). Initial nerve conduction studies were normal. Approximately 20 min into the examination, both patients developed sensory symptoms and weakness in the distal median nerve territory while the elbow was extended and forearm supinated. Further studies demonstrated complete conduction block across the forearm in the median motor and sensory nerve fibers. When measurable, conduction velocities remained normal or were modestly slow. Complete clinical and electrophysiological recovery occurred within 2 min following forearm pronation, suggesting that dysfunction was probably due to focal transient ischemia. Patients describing increased sensory symptoms during routine electrophysiological assessments for CTS should be investigated to rule out the possibility of a more proximal abnormality.     

Proximal and segmental motor nerve conduction in the sciatic nerve produced by percutaneous high voltage electrical stimulation

Percutaneous high voltage electrical stimulation was applied to the proximal sciatic nerve at the hip in 18 normal subjects to evaluate motor conduction in the proximal sciatic nerve, and short-segment stimulation of the sciatic and posterior tibial nerves was given in 6 normal subjects. Compound muscle action potentials (CMAPs) were recorded from the abductor hallucis (AH) and extensor digitorum brevis (EDB) muscles. Supramaximal stimulation was easily obtained at the proximal sciatic nerve and all the sites in the short-segment stimulation. The motor nerve conduction velocity of the sciatic nerve between the hip and the popliteal fossa was 49.2 ± 4.24 m/sec in the tibial division and 54.1 ± 6.48 m/sec in the peroneal division. The respective peak-to-peak amplitude and negative-peak areas of the CMAPs at the hip were reduced to 86.8 ± 5.65% and 97.3 ± 5.36% for the tibial division, and 93.4 ± 7.06% and 96.8 ± 5.09% for the peroneal division as compared to the values for the popliteal fossa. The negative-peak duration of the CMAPs at the hip point were increased to 109.2 ± 7.2% for the tibial nerve and 107.1 ± 5.68% for the peroneal nerve as compared with the duration at the popliteal fossa. This method is non-invasive and useful for evaluating motor nerve conduction in the lower limb.     

Medial plantar nerve testing facilitates identification of polyneuropathy

Many studies have used sural nerve action potential (NAP) as an electrophysiological marker for distal symmetrical polyneuropathy (DSP). We examined the role of medial plantar nerve testing for identifying DSP by comparing amplitudes from sural, superficial peroneal, and medial plantar nerves in 85 participants with symptoms and clinical signs of DSP and 204 participants without DSP. Receiver‐operating characteristic curves were used to determine the sensitivity of all three sensory conduction studies for the diagnosis of DSP. All three nerves could be used to discriminate between subjects with and without DSP with an area under the curve of more than 85% of cases. Sural and superficial peroneal nerve testing sensitivities were about 55%, whereas medial plantar nerve testing sensitivity was more than 90%. These findings suggest that testing the medial plantar nerve may increase the diagnostic yield of nerve conduction studies for DSP. Muscle Nerve 38: 1595–1598, 2008     

Cold-induced peripheral nerve damage: involvement of touch receptors of the foot

A 31-year-old male developed paresthesia and numbness of mainly the right foot following exposure to nonfreezing temperatures under moist conditions over a period of 1 week. The symptoms gradually improved over several months. When seen for electrophysiological studies 6 months after the injury, there was no sensory loss on clinical examination, although he continued to complain of distal numbness of the right foot. The right extensor digitorum brevis muscle was atrophic, and the distal motor latency in the peroneal nerve was prolonged. Conduction studies of the right sural nerve showed a predominantly distal diminution of the SAP evoked by electrical stimulation at the dorsum pedis. Action potentials evoked by tactile stimulation of Pacinian corpuscles showed a prolonged latency on the symptomatic side, suggesting that the most pronounced pathological changes in immersion injury may be localized to the very distal portion of the nerve at the nerve fiber-receptor junction.