In this study, we have analyzed the ability of axons to regenerate into chronically denervated peripheral nerve. As an experimental rat model, the proximal end of a newly transected rat tibial nerve was sutured into chronically denervated (3 months up to 16 months) common peroneal nerve. Samples for morphological studies were collected 3 and 6 weeks after anastomosis of the tibial and common peroneal nerves. Our results showing a distinct organization of the endoneurial matrix in the chronically denervated distal stumps conformed with those from previous studies. Long cytoplasmic processes of endoneurial fibroblasts in close contact with collagen fibrils (with a diameter of 50-60 nm) surrounded areas of thin collagen fibrils (with a diameter of 25-30 nm). Remnants of Schwann cell columns (i.e., bands of Büngner) were situated in areas of thin collagen fibrils. After 12 months of denervation the majority of the Schwann cells columns were replaced by thin collagen fibrils. Successful axonal regeneration was noted in distal stumps that had been denervated for 14 and even 16 months. However, axonal regeneration diminished with prolonged denervation. The regenerating axons grew through the areas of thin collagen fibrils. The maturation and thickening of the regenerated axonal sprouts resulted in a decrease in areas of thin collagen fibrils. These results suggest that a chronically denervated nerve stump has the capacity to meet regenerating axons even after 16 months of denervation, although the progressive atrophy of Schwann cell columns impairs the likelihood of good axonal regeneration. The areas of thin collagen fibrils may act as a 'plastic' bed for successful axonal regeneration, and a study of these fibrils may provide further insight into the role of the extracellular matrix during peripheral nerve regeneration.
The expression of B1 laminin and type IV collagen was followed in the microsurgically isolated endoneurium of transected rat sciatic nerves from 3 days until 8 weeks. Northern hybridizations revealed that after nerve transection the proximal stumps of denervated, as well as freely regenerating, nerves showed a markedly increased expression of laminin and type IV collagen which lasted from 3 days up to 8 weeks. In the distal stumps, close to the site of transection (2–7 mm), the expression of laminin, and to a certain extent that of type IV collagen, seemed to be enhanced if free axonal reinnervation was allowed. Further distally (10–15 mm), the patterns of B1 laminin and typeIV collagen expression were similar in both experimental groups, so that an increased expression was noticed during the first 2 weeks. The present results suggest that laminin and type IV collagen gene expression is markedly different in different parts of transected rat sciatic nerve. During peripheral nerve regeneration, there is a long‐lasting basement membrane gene expression in the proximal stump. In the distal part of the transected nerve, the axonal reinnervation possibly up‐regulates, but is not essential for, the expression of B1 laminin and type IV collagen.
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