Sensory reinnervation of muscle receptor in human

Sensory nerve regeneration and reinnervation in muscle following peripheral nerve injury

Sensory afferent fibers are an important component of motor nerves and compose the majority of axons in many nerves traditionally thought of as "pure" motor nerves. These sensory afferent fibers innervate special sensory end organs in muscle, including muscle spindles that respond to changes in muscle length and Golgi tendons that detect muscle tension. Both play a major role in proprioception, sensorimotor extremity control feedback, and force regulation. After peripheral nerve injury, there is histological and electrophysiological evidence that sensory afferents can reinnervate muscle, including muscle that was not the nerve's original target. Reinnervation can occur after different nerve injury and muscle models, including muscle graft, crush, and transection injuries, and occurs in a nonspecific manner, allowing for cross-innervation to occur. Evidence of cross-innervation includes the following: muscle spindle and Golgi tendon afferent-receptor mismatch, vagal sensory fiber reinnervation of muscle, and cutaneous afferent reinnervation of muscle spindle or Golgi tendons. There are several notable clinical applications of sensory reinnervation and cross-reinnervation of muscle, including restoration of optimal motor control after peripheral nerve repair, flap sensation, sensory protection of denervated muscle, neuroma treatment and prevention, and facilitation of prosthetic sensorimotor control. This review focuses on sensory nerve regeneration and reinnervation in muscle, and the clinical applications of this phenomena. Understanding the physiology and limitations of sensory nerve regeneration and reinnervation in muscle may ultimately facilitate improvement of its clinical applications.

Elbow joint position sense following brachial plexus palsy treated with double free muscle transfer

PURPOSE

Restoration of elbow flexion is the highest priority for brachial plexus reconstruction, and its reconstructive strategy is well established. The purpose of this article is to report elbow joint position sense (JPS) after double free muscle transfer (DFMT) for complete paralysis of brachial plexus.

METHODS

Thirteen patients with complete brachial plexus paralysis who were treated with DFMT underwent evaluation of elbow JPS. JPS was measured as the subject's ability to actively reproduce a previously presented position of the elbow joint (target angle). We calculated the difference between target and reproduced angle and defined this as the absolute error (AE). Ten healthy control subjects participated in this study.

RESULTS

In control subjects, mean AE measured 4 degrees +/- 1 degree at the target angle of 60 degrees and 4 degrees +/- 2 degrees at 80 degrees. After DFMT, patients' mean AE measured 5 degrees +/- 2 degrees at the target angle of 60 degrees and 5 degrees +/- 3 degrees at 80 degrees. There was no statistical difference between the control and DFMT groups at target angles of 60 degrees and 80 degrees.

CONCLUSIONS

Patients with complete paralysis of the brachial plexus had evidence of elbow JPS after successful restoration of elbow flexion after DFMT. Although this study provides us with useful information regarding the perception of elbow JPS, further study is necessary to confirm the exact mechanism of perception of elbow JPS.

TYPE OF STUDY/LEVEL OF EVIDENCE

Therapeutic IV.

Sensory reinnervation of a musculocutaneous flap: an experimental rabbit study

Sensory neurotisation of a muscle (sensory nerve transfer to the motor nerve of a muscle) produces muscle sensibility, but not skin sensibility. How to achieve sensation of a musculocutaneous flap remains a challenge to reconstructive microsurgeons. The purpose of our study was to determine if multiple nerve grafts which were placed vertically between the neuromuscular entrance zone of a muscle and a target area of dermis on the overlying skin could improve sensation. Thirty-six gracilis musculocutaneous flaps (18 rabbits) were raised and divided into three groups: group 1 consisted of 12 sensory neurotised gracilis musculocutaneous flaps with five nerve grafts each; group 2 consisted of another 12 sensory neurotised gracilis flaps with 10 nerve grafts each; and the control group consisted of 12 sensory neurotised gracilis musculocutaneous flaps without any nerve grafts. All nerve grafts spanned the distance between the neuromuscular entrance zone of the gracilis muscle and a specified 3 cm diameter area of the skin island. The saphenous nerve (sensory) was coapted to the obturator nerve (motor nerve of the gracilis) in an effort to achieve improved sensation of the skin island in the musculocutaneous flaps. After 6 months, the flaps were individually evaluated using cortical somatosensory evoked potentials (CSSEP) using normal, painful, cold and hot stimuli. One unoperated rabbit was studied as the baseline CSEEP for comparison. Retrograde horseradish peroxidase (HRP) labelling was then performed to evaluate the possibility of newly established neural pathways. Results of the CSSEP testing revealed that flaps possessing 10 nerve grafts (group 2) demonstrated better sensation when compared to flaps possessing five nerve grafts (group 1) or no nerve grafts (control group). Furthermore, retrograde HRP labelling proved that a new neural pathway had been established from the skin island to the dorsal root ganglia of S1 and S2 via the interposed nerve grafts and the sensory neurotised gracilis muscle in groups 1 and 2 rabbits. The control group did not display any sensory regeneration.

Analysis of activity of motor units in the biceps brachii muscle after intercostal-musculocutaneous nerve transfer

We examined respiratory activity of motor units (MUs) in the internal intercostal nerves (IICNs)-transferred biceps brachii muscle (IC-biceps) in cats. MUs of IC-biceps showed respiratory discharges in inspiratory and expiratory phases, and these were enhanced by CO2 inhalation. Narrowing the airway also enhanced inspiratory and expiratory MUs activity. A mechanical load to the thorax immediately enhanced inspiratory MUs activity and weakened expiratory MUs activity. We analyzed the cross-correlation of MUs activity in interchondral muscle and IC-biceps to characterize the respiratory spinal descending inputs to motoneurons. We confirmed the short-term synchronization from interchondral muscles indicating divergence of a single respiratory presynaptic axon to thoracic motoneurons, but could not find synchronization from IC-biceps. The motor axonal conduction velocity (axonal CV) of IC-biceps MUs was lower than that of interchondral muscles. There was no correlation between the respiratory recruitment order of IC-biceps MUs and their axonal CV. These results indicate that IC-biceps shows the respiratory activities and afferent inputs from intercostal muscle spindles in the neighboring segments remain influential on activity of IC-biceps. In addition, the short-term synchronization from IC-biceps could not be found, suggesting that the intercostal nerve transfer alters the respiratory spinal descending inputs to thoracic motoneurons.

Sensory restoration of the skin graft on a free muscle flap: experimental rabbit study

Transplantation of a muscle flap with free skin graft for wound coverage is a common procedure in reconstructive microsurgery. However, the grafted skin has little or no sensation. Restoration of the sensibility of the grafted skin on the transferred muscle is critically important, especially in palmar hand, plantar foot, heel, and oral cavity reconstruction. The purpose of this study was to investigate the possibility of sensory restoration of the grafted skin on a trimmed muscle surface that has been sensory neurotized after sensory nerve-to-motor nerve transfer, using the rabbit gracilis muscle as an animal model. The ipsilateral saphenous nerve (sensory) was transferred to the motor nerve of the gracilis muscle for sensory neurotization. A 4 x 4-cm2 area of skin island over the midportion of the gracilis muscle was harvested as a full-thickness skin graft. The upper half of the gracilis muscle was then excised, becoming a rough surface. The harvested skin was reapplied on the trimmed rough surface of the muscle. After 6 months, retrograde and antegrade horseradish peroxidase labeling studies were performed through skin and muscle injection. The group with a free skin graft was compared with the group with an intact surface of the gracilis muscle. This study clearly shows that sensory nerves can regenerate and penetrate into the trimmed muscle surface and grow into the overlying grafted skin. However, if the muscle surface is intact as with the compared group, sensory reinnervation of the grafted skin is not possible.

Assessment of muscle flap sensibility by evoked potentials in the rat

This study investigated whether the sensory-to-motor reinervation of the muscle flap provides a better sensory recovery of an overlying skin graft. Fifty-four animals were studied in three groups of 18 rats each: group I (control): 1 cm of the gastrocnemius muscle motor nerve was excised and no repair was performed; group II (motor-to-motor repair): the motor nerve of the gastrocnemius flap was transected and repaired; group III (sensory-to-motor repair): the motor nerve of the gastrocnemius muscle and sural nerve were transected and their distal and proximal ends, respectively, were repaired. At follow-up periods of 6, 12, and 24 weeks, evaluation of hair growth, muscle atrophy, and sensory evoked potentials was performed. Somatosensory evoked potentials (SSEP) at 6 weeks in the sensory-to-motor repair (group III) revealed a significant (P < 0. 05) increase (104.4% +/- 22.9) in the relative response of peak-to-peak potentials when compared with group I (46.6% +/- 19) and group II (51.8% +/- 14.0). Muscle flap stimulation was most prominent at 6 weeks in sensory-to-motor reinvervated flaps (group III 133.1% +/- 25.4; group I 84.9% +/- 20.2). In this study, sensory-to-motor nerve repair significantly improved the sensibility of skin flaps at 6 weeks. Denervated flaps presented with 3 months of sensory recovery delay.

Restoration of elbow flexion in brachial plexus avulsion injury: comparing spinal accessory nerve transfer with intercostal nerve transfer

This study was performed to compare the clinical outcome of 2 types of commonly used nerve transfers, the spinal accessory nerve transfer and the intercostal nerve transfer. This study was a prospective randomized parallel trial involving 205 patients presenting between 1989 and 1994. All patients were males ranging in age from 16 to 43 years. All patients underwent surgery within 6 months of injury. Spinal accessory nerve transfer was performed in 130 patients; better results were obtained in terms of less operative time, fewer blood transfusions, fewer immediate complications, and better motor function (very good and good power in 83% of patients). Intercostal nerve transfer was performed in 75 patients; better results were observed in terms of earlier electromyographic evidence of motor reinnervation, improvement in protective sensation, and reduction of pain. However, very good and good motor recovery was observed in only 64% of patients. There was no significant difference with regard to tidal volume, vital capacity, and the FEV1 to FEV ratio before and after surgery in either group. Smoking adversely affected the rate of recovery. Spinal accessory nerve transfer should be used when motor function of the elbow flexors is the major concern. Intercostal nerve transfer should be performed in patients who need both motor and sensory reconstruction and in those who have chronic pain syndrome after brachial plexus injury.

Reconstruction of tonic vibration reflex in the biceps brachii reinnervated by transferred intercostal nerves in patients with brachial plexus injury

The transfer of intercostal nerves to musculocutaneous nerves has been performed to reconstruct elbow flexion in patients with brachial plexus injury. In nine of 15 such patients, 2-3 Hz tapping of the distal tendon of the biceps muscle reinnervated by the transferred intercostal nerves (IC-biceps) induced a mode in the correlogram between tap and EMG pulse of IC-biceps. In five of the mode-positive patients, tapping of various frequencies induced gradual augmentation of integrated EMG of IC-biceps. This reflex was consistent with the tonic vibration reflex (TVR) in normal controls. Conduction velocity and frequency property of the reflex were compatible with the speculation that rapid-conducting muscle afferents (group Ia or II or both) reinnervate mechanoreceptors, such as muscle spindles. The clinical significance of muscle sensory reinnervation is not clear; however, the reconstruction of TVR following this operation is worthy in that it confirms the specific sensory reinnervation of denervated muscle in humans.

Number and morphology of mechanoreceptors in the myotendinous junction of paralysed human muscle

The mechanoreceptor system of the myotendinous junction (MTJ) of human palmaris longus muscle obtained at autopsy was studied histologically from six patients with flaccid paralysis (complete acute tetraplegia 4-6 weeks before the autopsy, due to a spinal cord injury), eight patients with spastic paralysis (chronic hemiplegia due to cerebral stroke) and ten neurologically normal controls. Four types of nerve endings, Ruffini and Pacini corpuscles, Golgi tendon organs, and free nerve endings, could be identified in the MTJs of the controls. In the MTJs of the patients with flaccid and spastic paralysis, the free nerve endings were not present and the mechanoreceptors that were found were few in number, degenerated, fibrotic, and atrophic. These mechanoreceptors had lost their connection with the muscle fibres and tendon bundles and were frequently located within pathological accumulations of fatty tissue in the myotendinous region. The number and distribution of mechanoreceptors in the MTJ were almost identical in patients with flaccid and spastic paralysis.