Articles: peripheral-nerve-injuries.
-
J Hand Surg Eur Vol · Feb 2005
Biography Historical Article Classical Article"Tingling" signs with peripheral nerve injuries. 1915.
-
We have localized cannabinoid receptor 2 protein in rat and mouse somatic sensory nervous system, using an antibody that recognizes mouse cannabinoid receptor 2. Little or no cannabinoid receptor 2 immunoreactivity was found in sections of naive rat or mouse dorsal root ganglia or spinal cord. This was in accord with the lack of detectable cannabinoid receptor 2 mRNA in (dorsal root ganglion) neurons by in situ hybridization experiments described in the literature. ⋯ In the peripheral nerve, accumulation of cannabinoid receptor 2 immunoreactivity was seen in nerve sections proximal, but not distal, to the ligation site, suggesting transport down the nerve from the cell bodies. Although convincing cannabinoid receptor 2 immunoreactivity was seen in neither uninjured nor injured dorsal root ganglion neuron cell bodies in tissue sections, expression was detectable in isolated, cultured neurons that had received a prior axotomy in vivo. This clear demonstration of CB(2) receptors on sensory neurons suggests an additional cellular target for CB(2) agonist induced analgesia, at least in neuropathic models.
-
Intraoperative positioning nerve injuries are regrettable complications of surgery thought to arise from stretch and/or compression of vulnerable peripheral nerves. Generally thought to be preventable, these injuries still occur in patients despite rigorous preventative measures. ⋯ Prevention remains the mainstay of the management of positioning injuries. Diagnosed and managed appropriately, these lesions typically improve completely over time.
-
Pharmacol. Biochem. Behav. · Jan 2005
Comparative StudyComparison of five different rat models of peripheral nerve injury.
Described here is a comparison of five peripheral sciatic nerve injury models in rats which all result in various degrees of neuropathic pain symptoms. They are the chronic constriction injury (CCI), the spinal nerve ligation (SNL), the partial sciatic ligation (PSL), the tibial and sural transection (TST), and the complete sciatic transection (CST) model. ⋯ Overall, all five models of neuropathic pain produced signs of allodynia and hyperalgesia to various stimuli. However, the duration and magnitude of the evoked responses varied considerably between the different models.
-
Partial peripheral nerve injury produces a persistent neuropathic pain which is difficult to relieve. In order to determine whether different degrees of peripheral nerve injury are related with the severity of neuropathic pain, we examined pain-related behaviors, histological changes and NGF in the skin in rats treated with different types of spinal nerve injury: tight ligation of the left L5 spinal nerve, incomplete ligation of the left L4 and L5 spinal nerves and incomplete crush of the left L4 and L5 spinal nerves. In all model rats, the thresholds of paw withdrawal in response to mechanical and heat stimuli began to decrease on the injured side 1 day after the operation, and the decreases in the thresholds persisted for more than 1 month. ⋯ Nerve growth factor (NGF) in the skin of the hindpaw on the injured side was accumulated after incomplete ligation and incomplete crush of the left L4 and L5 spinal nerves, but not tight ligation of the left L5 spinal nerve, on day 15 after the operation, possibly due to impairment of transport via unmyelinated primary afferents. Regeneration of the sciatic nerve alleviated the accumulation of NGF in the injured side hindpaw skin on day 32. The present results suggested that the severity of neuropathic pain was related with the degrees of both degeneration and/or regeneration of myelinated fibers and of functional damage of unmyelinated fibers.