Influences of peripheral nerve components on axonal growth

A new millenium for spinal cord regeneration: growth-associated genes

INTRODUCTION

Neurons surviving spinal cord injury undergo extensive reorganization that may result in the formation of functional synaptic contacts. Many neurons, however, fail to activate the necessary mechanisms for successful regeneration. In this review, we discuss the implications of growth cone genes that we have correlated with successful spinal cord axonal regeneration.

METHOD

Factors that inhibit regeneration, and activation of genes that promote it are discussed.

RESULTS/DISCUSSION

The early progress n understanding mechanisms that seem to promote or inhibit regeneration in the central nervous system may have significant clinical utility in the future.

Conduction of impulses by axons regenerated in a Schwann cell graft in the transected adult rat thoracic spinal cord

Central nervous system axons regenerate into a Schwann cell implant placed in the transected thoracic spinal cord of an adult rat. The present study was designed to test whether these regenerated axons are capable of conducting action potentials. Following the transection and removal of a 4- to 5-mm segment of the thoracic spinal cord (T8-T9), a polymer guidance channel filled with a mixture of adult rat Schwann cells and Matrigel was grafted into a 4- to 5-mm-long gap in the transected thoracic spinal cord. The two cut ends of the spinal cord were eased into the guidance channel openings. Transected control animals received a channel containing Matrigel only. Three months after implantation, electrophysiological studies were performed. Tungsten microelectrodes were used for monopolar stimulation of regenerated axons within the Schwann cell graft. Glass microelectrodes were used to record responses in the spinal cord rostral to the stimulation site. Evoked responses to electrical stimulation of the axon cable were found in two out of nine Schwann cell-grafted animals. These responses had approximate latencies in the range of those of myelinated axons. No responses were seen in any of the Matrigel-grafted animals. Histological analysis revealed that the two cases that showed evoked potentials had the largest number of myelinated axons present in the cable. This study demonstrates that axons regenerating through Schwann cell grafts in the complete transected spinal cord can produce measurable evoked responses following electrical stimulation.

Long-term effects of deprivation of cell support in the distal stump on peripheral nerve regeneration

The distal stump of an injured peripheral nerve supports regenerating axons by offering a favourable growth substratum and several cell-produced growth factors. Deprivation of cellular factors alone has been shown not to prevent fairly rapid axonal elongation after nerve injury if the growth substratum was preserved. The present study examined possible long-term untoward effects of cell support deprivation during an early phase of nerve regeneration. Rat sciatic nerve was crushed and a 25 mm long distal nerve segment was made acellular by freezing-thawing, while the integrity of the growth substratum for the regenerating axons was preserved. Toe-spreading reflex and skin sensitivity to pinch in the foot were monitored to follow recovery of motor and sensory function, respectively. The number of myelinated axons was determined in the sciatic nerve proximally to the lesion site, and distally in the predominantly sensory sural nerve as well as in the mixed motor nerve to the soleus muscle. Except for a short delay in the onset of recovery, explainable by the reduced elongation rate of axons growing through the acellular nerve segment, we found no deleterious effect of cell support deprivation on sensory or motor function recovery after nerve crush. Most of regenerating sensory neurons did not critically depend on the distal stump cell support. However, a 15% and 25% loss of myelinated axons both proximally to the lesion and distally in the sensory sural nerve, respectively, indicated that a corresponding minor loss of injured sensory neurons occurred when they were deprived of such cell support even if provided with a favourable growth substratum for successful regeneration.(ABSTRACT TRUNCATED AT 250 WORDS)

Nerve fibers in human myocardial scars

The relationships between ischemic heart disease, myocardial scars, ventricular nerve fibers, and ventricular arrhythmias have not been established despite considerable evidence suggesting important correlations. We recently described the reactions of nerve fibers in necrotic, healing, and healed rat myocardium. Prompted by these studies and by the lack of similar information for humans, we studied the structural relationships between nerve fibers and human myocardial scars. Hearts were obtained from transplant surgery and autopsy. Nerve fibers were labeled with antibody to S-100 protein. Light and electron microscopy of left ventricular scars revealed (1) fiber densities greater than those in adjacent intact myocardium, (2) fiber aggregates concentrated irregularly along the periphery of lesions, (3) fibers few in number or absent in the deeper aspects of scars, and (4) axonal enlargements containing clear and dense storage granules within the fiber aggregates. Like all other elements of the scars, the nerve fibers appeared to be oriented predominantly in the long axis of myocytes located at the edges of the lesions. Based on our experimental findings in rat hearts, these studies suggest that human myocardial nerve fibers regenerate after necrotizing injuries and that at least some of the resulting scar-associated fibers have structural features differing from those in uninjured myocardium. We suspect that these structural differences might be associated with functional alterations that could affect the triggering of ventricular arrhythmias.

Neuropeptides in cutaneous neurofibromas of von Recklinghausen's disease

The occurrence of neuropeptides was studied in neurofibromas of von Recklinghausen's disease by indirect immunofluorescence. All non-plexiform cutaneous neurofibromas contained abundant vasoactive intestinal polypeptide, peptide histidine-isoleucine and calcitonin gene-related peptide immunoreactive nerves. The nerves were small and unmyelinated. Neuropeptides might be responsible for itch that occurs especially in small cutaneous neurofibromas. Neuropeptides are also suggested to act as modulators and/or trophic factors for neurofibroma growth.