The experiments described in the present study approached nerve injury from both a biochemical and anatomical perspective by monitoring changes in expression of preprotachykinin (PPT) mRNA encoding the prototypic tachykinin substance P and related peptide species in neurons of the rat dorsal root ganglia (DRG) following unilateral chronic constriction injury of the sciatic nerve. In situ hybridization histochemistry (ISHH) analyses in conjunction with computer-assisted image processing were employed to quantify levels of PPT mRNA distributed in DRG neurons. Injury-induced changes in PPT mRNA expression by affected DRG neurons included: (1) at early postoperative times, generally increased levels of PPT mRNA associated with small and intermediate-size B cells exhibiting normal morphology, (2) at late postoperative times, markedly decreased levels of PPT mRNA associated with degenerating B cells, and (3) induction of PPT gene expression by large A cells which is highly correlated with degenerative morphological changes. The significant aspects of these changes are discussed with special emphasis on the contribution of altered transmitter expression by DRG neurons to the pathophysiology of causalgia. In particular, the induction of PPT gene expression by many of the large neurons undergoing degenerative changes may represent an important biochemical parameter which is associated with the development and persistence of experimental allodynia.
The undecapeptide substance P and the alkaloid morphine sulfate are two agents previously thought to have opposite roles in the mediation of spinal nociceptive processes. The present report, however, demonstrates that low doses of substance P when coadministered with marginally effective doses of morphine sulfate into the rat subarachnoid space produce a markedly enhanced analgesic response, as monitored by the tail-flick test. This pharmacological effect is blocked by prior treatment with the opioid antagonist naloxone, indicating that the potentiated analgesic response is mediated by opioid-responsive neurons. In addition, the putative immediate precursor form of substance P (i.e., substance P-glycine) may substitute for the mature compound in the potentiated pharmacological effect. Moreover, the described synergism is unaffected by transection of the spinal cord, demonstrating the lack of supraspinal modulation of the observed phenomenon. Based on these observations, we are now able to dissociate opioid-potentiating and analgesic properties of substance P from traditional hyperalgesic effects realized at significantly higher concentrations. Consistent with previous biochemical data, a likely mechanism underlying the peptide-mediated enhancement of opioid analgesia may center on the ability of substance P to release endogenous opioid peptides within the local spinal cord environment. Finally, the pharmacological relationship of coadministered substance P and morphine sulfate established here supports the hypothesis that spinal tachykinin and opioid systems have a direct functional interaction in the modulation of local nociceptive responses.
Recent animal models of experimental nerve injury have proven useful in evaluating potential sympathetic involvement in neuropathic pain syndromes. We have employed a widely adopted unilateral L5/L6 spinal nerve ligation model to compare the development of mechanical allodynia with neurochemical changes both at the site of peripheral nerve injury and in the dorsal root ganglia (DRG). We have focused on the expression of neuropeptide Y (NPY), a well-studied regulatory peptide and phenotypic marker of sympathetic neurons, and functionally related Y-receptor binding sites following nerve injury. In sympathetic neurons, NPY is colocalized and coreleased with norepinephrine (NE) at peripheral sites of action. Furthermore, NPY gene expression is induced within the population of medium- and large-diameter DRG neurons of the A beta-fiber class after experimental nerve injury. We therefore hypothesized that concurrent alterations in NPY and NE expression by sympathetic and sensory neurons may be a contributing factor to sympathetically-maintained neuropathic conditions. Animals with unilateral L5/L6 spinal nerve ligation developed mechanical allodynia of the hind paw ipsilateral to the site of injury that persisted until sacrifice at postoperative day 10. A significant induction of preproneuropeptide Y-encoding (PPNPY) mRNA, as detected by in situ hybridization histochemistry (ISHH), occurred in populations of medium- and large-diameter DRG neurons ipsilateral to the site of injury. Immunohistochemical analysis indicated a marked decline in the number of labeled sympathetic axons positive for tyrosine hydroxylase-like and NPY-like immunoreactivities (TH-LI and NPY-LI, respectively) proximal to the site of nerve injury and almost complete elimination of immunopositive fibers distal to the site of ligation. Whereas, the extent of colocalization of NPY-LI to TH-LI-positive sympathetic axons in unaffected L4 or L5 nerve segments exceeded 80%, this figure declined to approximately 50% in regenerating axons of ligated spinal nerve L5. The portion of NPY-LI that was not colocalized to sympathetic TH-LI-positive fibers was most likely contributed by regenerating sensory axons, consistent with marked de novo synthesis of NPY by DRG neurons. In end bulb axon terminals, i.e. morphological profiles characteristic of neuromas, NPY-LI-positive elements that were not colocalized to TH-LI-positive sympathetic elements appeared to be spatially segregated from those of sympathetic origin with colocalized TH-LI and NPY-LI. Receptor autoradiography indicated that small- and medium-diameter DRG somata of the C-fiber class normally express both Y1 and Y2 receptor subtypes. The pattern of the distribution of Y-receptor binding sites appeared to be relatively unaffected by spinal nerve ligation. In contrast, there was a marked increase in the density of Y2 receptor binding sites in the proximal segment of ligated spinal nerve L5, consistent with previously published data indicating differential transport of the Y2 autoregulatory receptor subtype...
Although the retroperitoneal aortic approach (RP) is advocated to reduce myocardial ischemia and cardiac-related death, inadequate physiologic data exist to support this contention. As the aorta is exposed via the transabdominal approach (TA) we noted some patients have manifested reduced systemic vascular resistance (SVR) associated with tachycardia, reduced blood pressure, and facial flushing. To determine whether RP offered physiologic advantages over TA we compared cardiac dynamics and blood levels of 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha), the stable metabolite of prostacyclin, during exposure of the aorta in 52 patients (33 with TA and 19 with RP), comparable in age, cardiac history, medications, and body surface area. Serial measurements of mean arterial pressure, heart rate, wedge pressure, pulmonary artery pressure, cardiac index, and 6-keto-PGF1 alpha were obtained. Results revealed decreased mean arterial pressure and systemic vascular resistance, increased cardiac index and heart rate, and facial flush occurring 10 minutes after the bowel was explored in TA. This was not observed in RP. These hemodynamic alterations correlated in time and magnitude with a fourteen fold increase in 6-keto-PGF1 alpha. These changes in cardiac indexes can produce increased myocardial oxygen consumption with the risk for myocardial ischemia, particularly in patients with coronary artery disease. The absence of this response to bowel exploration in RP may account for some of the observed advantages in "high-risk" aortic reconstruction.
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