Effects of self- and cross-reinnervation on the numbers of motoneurons regenerating to forearm muscles in young and adult rats.

The present study was carried out to compare the ability of motoneurons to regenerate to functionally appropriate and inappropriate muscles, following axotomy at different stages of postnatal development. Five-, 10-, 21-day-old and adult rats of both sexes were used. In one group, the right median and radial nerves were cut and reunited. In a second group, the cut nerves were cross reunited and, in a third group the nerves were merely exposed. Following survival periods of up to one year, the extent of motoneuron regeneration through the repaired nerves was determined by injecting the retrogradely transported tracers horseradish peroxidase (HRP) and Fast Blue into the flexor and extensor muscles of the right forearm. The results were expressed in terms of the difference between the number of labelled motoneurons on the experimental side of the spinal cord and the number on the control side, the latter having been labelled by injection of HRP and Fast Blue into the muscles of the left forearm. Comparisons were then made between the groups with respect to the age at which axotomy occurred, and the target of regeneration. The results showed that when axotomy was performed in 5- and 10-day-old rats, significantly fewer motoneurons were labelled, irrespective of whether or not the target was functionally appropriate, than when axotomy was performed in adulthood. The difference was most likely due to a lower survival rate of motoneurons following axotomy in neonates. No difference was found, however, between the numbers of labelled median and radial nerve motoneurons following self- versus cross-reinnervation in any age group. This suggests that, in both adult and neonatal rats, motoneurons which survive axotomy are able to regenerate equally well to functionally appropriate or inappropriate muscles.

Influence of electrical stimulation on regeneration of the radial nerve in dogs.

The effects of biphasic electric fields on nerve regeneration that follows injury to the left radial nerve were studied in dogs by electromyography (EMG). Left and right radial nerves were crushed with a serrated haemostat. Stimulating electrodes were positioned proximally and distally to the site of the injury. The left nerves received rectangular, biphasic and current pulses (30 microA, 0.5 Hz) through the injury for two months. The right radial nerves were treated as controls and regenerated without electrical stimulation. EMG activities were recorded intramuscularly from the left and right musculus extensor digitalis communis (MEDC). Results obtained at the end of the two-month stimulation period showed a significant difference in EMG activity between the left (stimulated) and the right (non-stimulated) MEDC, suggesting that electrical treatment enhanced nerve regeneration.

Engrailed is expressed in larval development and in the radial nervous system of Patiriella sea stars.

We documented expression of the pan-metazoan neurogenic gene engrailed in larval and juvenile Patiriella sea stars to determine if this gene patterns bilateral and radial echinoderm nervous systems. Engrailed homologues, containing conserved En protein domains, were cloned from the radial nerve cord. During development, engrailed was expressed in ectodermal (nervous system) and mesodermal (coeloms) derivatives. In larvae, engrailed was expressed in cells lining the larval and future adult coeloms. Engrailed was not expressed in the larval nervous system. As adult-specific developmental programs were switched on during metamorphosis, engrailed was expressed in the central nervous system and peripheral nervous system (PNS), paralleling the pattern of neuropeptide immunolocalisation. Engrailed was first seen in the developing nerve ring and appeared to be up-regulated as the nervous system developed. Expression of engrailed in the nerve plexus of the tube feet, the lobes of the hydrocoel along the adult arm axis, is similar to the reiterated pattern of expression seen in other animals. Engrailed expression in developing nervous tissue reflects its conserved role in neurogenesis, but its broad expression in the adult nervous system of Patiriella differs from the localised expression seen in other bilaterians. The role of engrailed in patterning repeated PNS structures indicates that it may be important in patterning the fivefold organisation of the ambulacrae, a defining feature of the Echinodermata.