Chronic relapsing experimental allergic encephalomyelitis was induced in Lewis rats by inoculation with guinea-pig spinal cord and complete Freund's adjuvant followed by treatment with low-dose cyclosporin A. In most animals, tail and limb weakness developed in a relapsing remitting pattern but in some these signs were persistent or progressive from onset. Histological studies during the early stages of clinically active disease (less than 25 days after inoculation) revealed inflammation and primary demyelination in the central nervous system (CNS), particularly the spinal cord, and in the peripheral nervous system (PNS), specifically the ventral and dorsal roots and dorsal root ganglia. Animals studied in the later stages of clinically active disease (greater than 28 days after inoculation) had extensive spinal cord demyelination but minimal PNS demyelination. In these animals, large plaques of demyelination with gliosis and prominent plasma cells occurred particularly in the thoracic spinal cord, and lesions of different ages were present within the spinal cord, CNS and PNS remyelination by oligodendrocytes and Schwann cells, respectively, was present in all animals studied later than 18 days after inoculation (the time of the first remission, if it occurred). In both early and late clinically active disease electron microscopy revealed macrophages invading and destroying CNS myelin sheaths. Active demyelination was sometimes found in regions of CNS remyelination, suggesting that remyelinated fibres were being attached. Axonal degeneration occurred in the spinal cord. During clinical remission there was CNS and PNS remyelination and much less inflammation; however, active demyelination still occurred to a limited degree.
SUMMARYElectrophysiological studies were performed in Lewis rats with chronic relapsing experimental allergic encephalomyelitis (EAE) induced by inoculation with guinea-pig spinal cord and adjuvants and treatment with low dose cyclosporin A. During clinical episodes there was conduction failure in the central nervous system (CNS), namely the spinal cord dorsal columns, and in the afferent fibres in the peripheral nervous system (PNS). The following observations indicated that the conduction failure was mainly due to demyelination-induced conduction block: (1) rate-dependent conduction block in the CNS and PNS; (2) temporal dispersion due to slowing of PNS conduction; (3) restoration of PNS conduction by cooling; (4) restoration of CNS conduction by ouabain; (5) previously demonstrated histological evidence of primary demyelination in the dorsal columns, dorsal root ganglia and dorsal roots; and (6) the temporal association of restoration of conduction with remyelination. However, it is likely that CNS and PNS axonal degeneration, which occurs in this disease, also contributed to the conduction failure. In clinical remissions there was restoration of conduction in the CNS and PNS which can be explained by ensheathment/remyelination by oligodendrocytes and Schwann cells, respectively. In most rats during clinical episodes the cerebral somatosensory evoked potential was reduced in amplitude and prolonged in latency, which can be accounted for by demyelination and axonal degeneration in the CNS and PNS components of the afferent pathway. In 2 rats with episodes of EAE, however, this potential was markedly increased in amplitude, which might have been due to demyelination-induced conduction block of descending pathways that normally inhibit synaptic transmission in the afferent pathway. In well-established remission there was residual conduction failure in the CNS and PNS which can be mainly accounted for by axonal degeneration.
Focal conduction block in the dorsal root ganglion in experimental allergic neuritis
Acute experimental allergic neuritis was induced in Lewis rats by inoculation with bovine intradural root myelin and adjuvants. In terminal experiments, sensory conduction was assessed in rats with hindlimb ataxia and weakness by stimulating the exposed sciatic nerve and recording directly from the exposed L-4 spinal nerve, dorsal root ganglion, dorsal root, and dorsal root entry zone. Focal conduction block was present in a high proportion of large-diameter fibers in the dorsal root ganglion. In contrast, nerve conduction in the peripheral nerve and spinal nerve was essentially normal apart from probable conduction block in some fibers in the proximal spinal nerve in a minority of rats. The afferent volley arriving at the dorsal root entry zone of the spinal cord was greatly reduced, as a consequence of the conduction block in the dorsal root ganglion and probable conduction block in the dorsal root. The M wave recorded from the fourth dorsal interosseus muscle of the hindfoot was normal in amplitude but slightly prolonged in latency and the H reflex was absent. These electrophysiological findings correlated well with the histological findings of inflammation and prominent demyelination in the dorsal root ganglia and dorsal roots with minimal involvement of the proximal spinal nerve and no involvement of the sciatic nerve. It is concluded that the hindlimb ataxia in rats with this form of acute experimental allergic neuritis is due to demyelination-induced nerve conduction block in the dorsal root ganglia and probably in the dorsal roots.Experimental allergic neuritis (EAN) is an autoimmune demyelinating disease of the peripheral nervous system (PNS) induced by inoculation with PNS tissue [1] or P2 protein [2] and adjuvants. In its acute form, it is widely studied as an animal model of the human disorder, the Guillain-Barré syndrome. The distribution of lesions in the PNS differs among different models of acute EAN. In rabbits and mice with acute EAN induced by inoculation with whole PNS tissue, the dorsal root ganglion is the most consistently affected region of the PNS [1,3]. The dorsal root ganglion is also a major site of involvement in rats with PNS myelin-induced or P2-induced acute EAN [4,5]. Electrophysiological studies in animals with acute EAN have demonstrated conduction abnormalities in the PNS [6-14], but have not assessed whether focal conduction block occurs in the dorsal root ganglion. We have previously demonstrated focal conduction block in the dorsal root ganglia of rabbits and, to a lesser extent, in rats with acute experimental allergic encephalomyelitis, an autoimmune demyelinating disease that affects the central nervous system and also results in PNS lesions similar to those of EAN [ 1 5 -1 8 ] . The present study was undertaken to determine whether similar focal conduction block occurs in the dorsal root ganglion in rats with EAN. Materials and Methods Induction of EANFemale Lewis rats (JC strain) bred by the Central Animal Breeding House of the University of Queensland (Brisban...
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