Evidence for CGRP accumulation and activity in experimental neuromas.

Calcitonin gene-related peptide (CGRP) is a potent vasodilator and widely distributed neuropeptide that may participate in the injury response of peripheral nerve. We examined evidence for the presence of CGRP immunoreactivity (IR) and its activity in experimental neuromas of Sprague-Dawley rats created by sectioning the midsciatic nerve with resection of 2-3 cm of its distal portion and branches. CGRP activity was evaluated by measuring local blood flow in neuromas using hydrogen polarography and laser-Doppler flowmetry. At all time points studied after nerve section (24 h, 48 h, 7 days, 14 days) there was a rise in local blood flow in the neuroma stumps. At 48 h the hyperemia was maximum but was reversed by topical application of human CGRP(8--37), a specific CGRP-receptor antagonist. CGRP presence was evaluated by immunohistochemistry and radioimmunoassay (RIA). At 24 and 48 h, CGRP IR was intense and distributed in a globular and diffuse pattern apparently not confined to discrete axonlike profiles. At 7 and 14 days, CGRP IR remained prominent and was associated with disorganized axonlike profiles, sometimes directed in a circumferential pattern around the outside of the neuroma. RIA confirmed rises in CGRP content at 24 and 48 h that accompanied the changes in local blood flow and altered distribution of CGRP IR. CGRP accumulates in a time-related fashion within experimental neuromas, where it induces among other possible actions prominent local vasodilatation. CGRP may be important in the regenerative milieu of injured nerves.

Dorsal root ganglia microenvironment of female BB Wistar diabetic rats with mild neuropathy.

Abnormalities in the microenvironment of dorsal root ganglia (DRG) might play a role in the pathogenesis of sensory abnormalities in human diabetic neuropathy. We examined aspects of DRG microenvironment by measuring local blood flow and oxygen tension in the L4 dorsal root ganglia of female BB Wistar (BBW) diabetic rats with mild neuropathy. The findings were compared with concurrent measurements of local sciatic endoneurial blood flow and oxygen tension. Diabetic rats were treated with insulin and underwent electrophysiological, blood flow and oxygen tension measurements at either 7-11 or 17-23 weeks after the development of glycosuria. Nondiabetic female BB Wistar rats from the same colony served as controls. At both ages, BBW diabetic rats had significant abnormalities in sensory, but not motor conduction compared to nondiabetic controls. Sciatic endoneurial blood flow in the diabetic rats of both ages was similar to control values, but the older (17-23 week diabetic) BBW diabetic rats had a selective reduction in DRG blood flow. Sciatic endoneurial oxygen tensions were not significantly altered in the diabetic rats. DRG oxygen tension appeared lowered in younger (7-11 week diabetic) but not older (17-23 week diabetic) BBW rats. Our findings indicate that there are important changes in the DRG microenvironment of diabetic rats with selective sensory neuropathy.