Increased dynorphin immunoreactivity in spinal cord after traumatic injury

Opiate antagonists, at high doses, have been shown to improve physiological variables and outcome after experimental spinal injury. Dynorphin appears to be unique amongst opioids in producing hindlimb paralysis after intrathecal injection. Taken together, these findings suggest a possible pathophysiological role for endogenous opioids, particularly dynorphin, in spinal injury. In the present studies we examined the relationship between changes in dynorphin immunoreactivity (Dyn-ir) in rat spinal cord after traumatic injury and the subsequent motor dysfunction. Trauma was associated with significantly increased Dyn-ir at the injury site, but not distant from the lesion. Dyn-ir was found elevated as early as 2 h and as late as 2 weeks after trauma, and was significantly correlated with the degree of injury. These data are consistent with the hypothesis that dynorphin systems may be involved in the secondary injury that follows spinal trauma.     

Stereospecific reversal of nitrous oxide analgesia by naloxone

The opiate antagonist naloxone was found to block nitrous oxide analgesia in a stereospecific fashion. Using a modified hotplate test in mice, the (-)-enantiomer of naloxone (which has a KD of approximately 1 nM for opiate receptors) antagonized the analgesic actions of nitrous oxide in a dose-dependent (2.5-20 mg/kg) fashion. In contrast, the (+)-enantiomer (KD approximately 10,000 nM) had no effect on nitrous oxide analgesia at the highest dose tested (40 mg/kg). These data strongly suggest that nitrous oxide analgesia is mediated via opiate receptors and is consistent with the hypotheses that this effect occurs either through the release of endogenous opioids or by physical perturbation of the opiate receptors.     

Modulation of motilin-induced somatostatin release in dogs by naloxone

Somatostatin release in dogs is modulated by exogenous and endogenous opioids. Since postprandial somatostatin secretion is in part due to the stimulatory effect of postprandially activated gastrointestinal hormones as well as endogenous opioids, it was of interest to determine the interaction between motilin, a known stimulus of somatostatin release, and endogenous opioids with regard to activation of D-cell function. In a group of eight conscious dogs the infusion of synthetic porcine motilin at doses of 0.05, 0.25 and 0.5 micrograms/kg X hr elicited a significant increase of peripheral vein plasma somatostatin-like immunoreactivity (SLI), confirming previously reported data. The additional infusion of the opiate receptor antagonist naloxone attenuated this SLI response, suggesting that endogenous opioids participate in motilin-induced SLI release. Since previous studies have shown that the interaction between endogenous opioids and postprandial somatostatin secretion is modified by elevated plasma glucose levels, the experiments were repeated during an IV glucose (0.2 g/min) background infusion increasing circulating glucose levels by 20-30 mg/dl. During IV glucose, the SLI response to motilin was almost abolished. In this group the addition of naloxone restored the SLI response, indicating that the inhibitory effect of elevated glucose on D-cell function is, at least in part, mediated by endogenous opioids. These data suggest that motilin has to be considered as one regulatory factor which participates in the previously observed interaction between glucose and endogenous opioids during postprandial SLI release.     

Effect of the opiate antagonist naloxone on the electrical activity of identified neurons in the edible snail

The opiate antagonist naloxone modifies the electric activity of some identified neurons of the Helix lucorum which have not been preliminary exposed to the effect of exogenous opioids. Some neurons are excited while others are inhibited by naloxone, and in both cases the reaction may have both a short and long latent period. The reactions depend on naloxone dose and become less expressed or are blocked when naloxone is administered together with the agonists of opiate receptor (morphine, D-Ala2, D-Leu5-enkephalin, bremazocine and beta-endorphin). Opioids alone do not produce any effect on neurons. The effect of naloxone on neurons is assumed to be a result of the elimination by the opiate antagonist of the tonic effect of endogenous opioids by their replacing on opiate receptors which are constantly stimulated by endogenous ligands.     

Naloxone and TRH affect regional blood flows in the anesthetized rabbit

The cardiovascular effects of IV naloxone and a subsequent administration of TRH IV were studied in the rabbit. Naloxone caused a vasodilation in the myocardium and adrenal glands. Naloxone elicited an increment in cerebral blood flow in several regions which attenuated the cerebrovasodilating effect of TRH in a few regions. The blockade of endogenous opioids with naloxone did not modify the peripheral vasoconstricting effect of TRH or affect the vascular effects of TRH mediated by the peripheral sympathetic nerves. The results indicate that naloxone has a vasodilating effect in the myocardium and CNS in anesthetized rabbits. The major part of the cardiovascular effect of TRH is not dependent on mechanisms sensitive to naloxone.     

On the specificity of naloxone as an opiate antagonist.

Since the discovery of endogenous opioid peptides in brain (68,69,97,113, 128) and the pituitary gland (26,81,105,125) there has been considerable interest in their possible roles in a variety of physiological and pharmacological processes. Many studies have used antagonism by naloxone as a criterion for implicating endogenous opiates in a process, assuming that naloxene has no pharmacological actions other than those related to blockade of opiate receptors. The doses of naloxene used are often higher than those required to antagonize the analgesic and other effects of morphine. However, multiple forms of opiate receptors are present in nervous tissue and higher concentrations of naloxene are required to antagonize effects mediated by some of these receptors (83). Although the earlier literature supports the assumption that the effects of naloxene are due to the blockade of opiate receptors (87), there are an increasing number of reports which indicate that naloxene may have pharmacological actions unrelated to opiate receptor blockade. The subsequent review serves to emphasize that antagonism by naloxene is a necessary but not sufficient criterion for invoking the mediation of a response by an endogenous opiate (61). Additional lines of evidence which serve to strengthen the conclusion that endogenous opiates mediate a process will be considered.     

Opioids and neuropeptides: mechanisms in circulatory shock

Endogenous opioid systems are activated in stressful situations such as circulatory shock. The opiate antagonist naloxone improves cardiovascular function in several models of shock caused by endotoxemia, hypovolemia, anaphylaxis, and spinal trauma. The ergotropic neuropeptide, thyrotropin-releasing hormone, in supraphysiological doses, also improves cardiovascular function in these shock models, but this effect does not result from action at the opiate receptor. For both these agents a central nervous system (CNS) site of action has been partially characterized. A variety of neuropeptides, including the opioids, seem capable of modulating autonomic function through their CNS actions. In addition, they may play a role in peripheral integration and transmission of autonomic nervous activity by actions at the ganglia and/or at nerve endings. Some neuropeptides also have direct autacoid effects on cells, including those of the microvasculature. This raises new questions concerning possible peripheral functions of neuropeptides during circulatory shock, and the nature of their interactions with other potential shock mediators such as monokines and arachidonic acid derivatives.     

Supraspinal injection of Substance P attenuates allodynia and hyperalgesia in a rat model of inflammatory pain

The neuropeptide Substance P (SP), that has a high affinity for the neurokinin 1 (NK1) receptor, is involved in modulation of pain transmission. Although SP is thought to have excitatory actions and promote nociception in the spinal cord, the peptide induces analgesia at the supraspinal level. The aim of this study was to evaluate the role of supraspinal SP and the NK1 receptor in inflammatory pain induced by injection of carrageenan in the hind paw of the rat. There are two nociceptive behavioral responses associated with this pain state: mechanical allodynia and heat hyperalgesia. Because the NK1 receptor colocalizes with the MOP receptor in supraspinal sites involved in pain modulation, we also decided to study the possible involvement of the opioid system on SP-induced analgesia. We found that treatment with SP, at doses of 3.5, 5 and 7 μg/5 μl/rat i.c.v., clearly showed inhibition of allodynia and hyperalgesia. Pretreatment with the selective NK1 antagonist L-733,060 (10mg/kg i.p.) blocked the SP-induced analgesia, suggesting the involvement of the NK1 receptor. This SP-induced analgesia was significantly reduced by administration of the opioid antagonist naloxone (3mg/kg s.c.). This reduction occurred when SP was administered either before or after the carrageenan injection. These results suggest a significant antinociceptive role for SP and the NK1 receptor in inflammatory pain at the supraspinal level, possibly through the release of endogenous opioids.     

Endocrine actions of opioids

The widespread occurrence of opioid peptides and their receptors in brain and periphery correlates with a variety of actions elicited by opioid agonists and antagonists on hormone secretion. Opioid actions on pituitary and pancreatic peptides are summarized in Table 1. In rats opioids stimulate ACTH and corticosterone secretion while an inhibition of ACTH and cortisol levels was observed in man. In both species, naloxone, an opiate antagonist, stimulates the release of ACTH suggesting a tonic suppression by endogenous opioids. In rats, a different stimulatory pathway must be assumed through which opiates can stimulate secretion of ACTH. Both types of action are probably mediated within the hypothalamus. LH is decreased by opioid agonists in many adult species while opiate antagonists elicit stimulatory effects, both apparently by modulating LHRH release. A tonic, and in females, a cyclic opioid control appears to participate in the regulation of gonadotropin secretion. Exogenous opiates potently stimulate PRL and GH secretion in many species. Opiate antagonists did not affect PRL or GH levels indicating absence of opioid control under basal conditions, while a decrease of both hormones by antagonists was seen after stimulation in particular situations. In rats, opiate antagonists decreased basal and stress-induced secretion of PRL. Data regarding TSH are quite contradictory. Both inhibitory and stimulatory effects have been described. Oxytocin and vasopressin release were inhibited by opioids at the posterior pituitary level. There is good evidence for an opioid inhibition of suckling-induced oxytocin release. Opioids also seem to play a role in the regulation of vasopressin under some conditions of water balance. The pancreatic hormones insulin and glucagon are elevated by opioids apparently by an action at the islet cells. Somatostatin, on the contrary, was inhibited. An effect of naloxone on pancreatic hormone release was observed after meals which contain opiate active substance. Whether opioids play a physiologic role in glucose homeostasis remains to be elucidated.     

家兔中枢内源性阿片样物质在紧张性高血糖反应中的作用

本工作观察家兔内源性阿片样物质在紧张性高血糖反应中的作用。通过向家兔侧脑室内注射阿片受体阻断剂纳洛酮或羧基肽酶 A 的抑制剂 D-苯丙氨酸以分别减弱或加强脑内内源性阿片样物质的作用。结果表明,纳洛酮能使由乙醚或2-脱氧葡萄糖所引起的高血糖反应减弱,而使由胰岛素所引起的低血糖反应加强并延搁其回复过程。D-苯丙氨酸表现为相反的效应。在已对吗啡形成耐受的家兔,2-脱氧葡萄糖所引起的高血糖反应也呈减弱。这些结果提示,脑内内源性阿片样物质与紧张性高血糖反应有关。     

Spinal cord immunoreactive TRH is altered after local traumatic injury

The effect of impaction-induced spinal trauma on the concentration of immunoreactive TRH (TRH-ir) in the spinal cord was studied. Samples were obtained from tissues proximal to, distal to, and at the site of injury at 30 min, 1 hr, 4 hr, and 6 weeks after impaction. After an initial 38% depletion of TRH-ir at the injury site at 30 min, concentrations were progressively elevated over time at all sites. These elevations reached statistical significance in the proximal and distal segments by 4 hr posttrauma. By 6 weeks, a rostral-caudal gradient of TRH-ir concentration was observed, indicating that axoplasmic transport was restricted. The gradient was characterized by a significant TRH-ir elevation proximal to, and a 60% depletion distal to, the injury. The short-term TRH-ir elevation measured indicates that the ability of exogenously administered TRH to reduce the incidence of posttraumatic functional deficit stems from a restoration of endogenous TRH action. The role of the raphe-spinal tract in the development of traumatic paralysis is considered.     

Effect of myelopeptides on physiological and pathological pain

The action of bone marrow low-molecular peptides (myelopeptides) was studied in the models of physiologic and pathologic pain. Myelopeptides were demonstrated to have a pronounced analgetic effect: they increased the latent period of the rats' response in the hot plate test (physiologic pain) and suppressed severe spinal pain syndrome induced by the generator of pathologically enhanced excitation in the dorsal horn of the spinal cord (pathologic pain). In the experiments with naloxone (an opiate receptor blocker) the data on the opiate properties of myelopeptides were further substantiated. The analgetic effect of myelopeptides can be compared to that of morphine and promedol. Myelopeptides even in considerable doses did not have the side effects characteristic of the majority of opiate analgesics. Therefore, they may be recommended for clinical trials.     

Erythropoietin attenuates the sequels of ischaemic spinal cord injury with enhanced recruitment of CD34+ cells in mice

Erythropoietin has been shown to promote tissue regeneration after ischaemic injury in various organs. Here, we investigated whether Erythropoietin could ameliorate ischaemic spinal cord injury in the mouse and sought an underlying mechanism. Spinal cord ischaemia was developed by cross-clamping the descending thoracic aorta for 7 or 9 min. in mice. Erythropoietin (5000 IU/kg) or saline was administrated 30 min. before aortic cross-clamping. Neurological function was assessed using the paralysis score for 7 days after the operation. Spinal cords were histologically evaluated 2 and 7 days after the operation. Immunohistochemistry was used to detect CD34(+) cells and the expression of brain-derived neurotrophic factor and vascular endothelial growth factor. Each mouse exhibited either mildly impaired function or complete paralysis at day 2. Erythropoietin-treated mice with complete paralysis demonstrated significant improvement of neurological function between day 2 and 7, compared to saline-treated mice with complete paralysis. Motor neurons in erythropoietin-treated mice were more preserved at day 7 than those in saline-treated mice with complete paralysis. CD34(+) cells in the lumbar spinal cord of erythropoietin-treated mice were more abundant at day 2 than those of saline-treated mice. Brain-derived neurotrophic factor and vascular endothelial growth factor were markedly expressed in lumbar spinal cords in erythropoietin-treated mice at day 7. Erythropoietin demonstrated neuroprotective effects in the ischaemic spinal cord, improving neurological function and attenuating motor neuron loss. These effects may have been mediated by recruited CD34(+) cells, and enhanced expression of brain-derived neurotrophic factor and vascular endothelial growth factor.     

Decoy peptides that bind dynorphin noncovalently prevent NMDA receptor-mediated neurotoxicity

Prodynorphin-derived peptides elicit various pathological effects including neurological dysfunction and cell death. These actions are reduced by N-methyl-d-aspartate receptor (NMDAR) but not opioid receptor antagonists suggesting NMDAR-mediation. Here, we show that a conserved epitope (KVNSEEEEEDA) of the NR1 subunit of the NMDAR binds dynorphin peptides (DYNp) noncovalently. Synthetic peptides containing this epitope form stable complexes with DYNp and prevent the potentiation of NMDAR-gated currents produced by DYNp. They attenuate DYNp-evoked cell death in spinal cord and prevent, as well as reverse, DYNp-induced paralysis and allodynia. The data reveal a novel mechanism whereby prodynorphin-derived peptides facilitate NMDAR function and produce neurotoxicity. Furthermore, they suggest that synthetic peptides that bind DYNp, thus preventing their interaction with NMDAR, may be novel therapeutic agents for the treatment of spinal cord injury.     

Antagonism of diazepam-induced feeding in rats by antisera to opioid peptides

Diazepam-induced feeding in rats is antagonized not only by the opiate antagonist naloxone but also intraventricular administration of specific antisera to the endogenous opioid peptides met-enkephalin or beta-endorphin. Pituitary beta-endorphin is probably not implicated in the diazepam effect since blockade with the glucocorticoid dexamethasone of the release of beta-endorphin from the anterior pituitary does not modify the diazepam-induced feeding, which is however prevented by TRH, a suggested physiological antagonist of some of the effects of opioid peptides. The possible central participation of both beta-endorphin and met-enkephalin in the ingestive behavior induced by diazepam gives further support to the postulated physiological role of endogenous opioids in appetite regulation.     

Analog specificity of the thyrotropin-releasing hormone receptor in the central nervous system: possible clinical implications

TRH has rapid-onset (30 sec), slow-offset (1-12 days) clinical benefit in patients with amyotrophic lateral sclerosis and other motor neuron disorders. This benefit is probably receptor-mediated and may have at least 2 components. To obtain a better understanding of the various responses to TRH of the spinal lower motor neurons (LMNs) in patients, and possibly to help guide selection of additional therapeutic agents, we utilized rat CNS (spinal-cord and brain membranes) to analyze the ability of certain molecules to inhibit specific binding of [3H]methyl TRH [( 3H]MeTRH) to the TRH receptor. We found: a) lack of high-affinity binding of the TRH-analog DN-1417 by spinal-cord and brain TRH receptor, despite its known strong TRH-like action physiologically on LMNs; b) lack of high-affinity binding of the TRH-product cyclo(His-Pro) by spinal-cord and brain TRH receptor despite its having some strong TRH-like physiologic actions on the CNS; and c) lack of any identifiable high-affinity receptor for cyclo(His-Pro) in spinal cord and brain. From these data we hypothesize that the acute transmitter-like action of DN-1417, TRH, and possibly other TRH-analogs and products on LMNs is via a non-TRH receptor, such as an amine or amino acid neurotransmitter receptor, e.g. a 5-hydroxytryptamine receptor. We further postulate that the CNS TRH-receptor may modulate a trophic-like influence of TRH on LMNs.     

In vivo release of CCK-8 from the dorsal horn of the rat: Inhibition by DAGOL

There is evidence that CCK-8 may interact with opioids and that both systems are probably implicated in pain modulation. In order to elucidate this relationship we sought to examine factors governing the movement of CCK-8 from the spinal cord into the extracellular space. We report that CCK-8 like immunoreactivity, as measured by RIA, is released from the spinal cord of the rat in vivo, following potassium stimulation and by direct activation of high threshold peripheral afferents by stimulation of the sciatic nerve. Also, we show that CCK-8 release is inhibited by the μ-selective opioid receptor agonist DAGOL. Naloxone totally reversed the effect produced by DAGOL, implying an opiate mediated mechanism.     

Contrast Enhanced Ultrasound Imaging for Assessment of Spinal Cord Blood Flow in Experimental Spinal Cord Injury

Reduced spinal cord blood flow (SCBF) (i.e., ischemia) plays a key role in traumatic spinal cord injury (SCI) pathophysiology and is accordingly an important target for neuroprotective therapies. Although several techniques have been described to assess SCBF, they all have significant limitations. To overcome the latter, we propose the use of real-time contrast enhanced ultrasound imaging (CEU). Here we describe the application of this technique in a rat contusion model of SCI. A jugular catheter is first implanted for the repeated injection of contrast agent, a sodium chloride solution of sulphur hexafluoride encapsulated microbubbles. The spine is then stabilized with a custom-made 3D-frame and the spinal cord dura mater is exposed by a laminectomy at ThIX-ThXII. The ultrasound probe is then positioned at the posterior aspect of the dura mater (coated with ultrasound gel). To assess baseline SCBF, a single intravenous injection (400 µl) of contrast agent is applied to record its passage through the intact spinal cord microvasculature. A weight-drop device is subsequently used to generate a reproducible experimental contusion model of SCI. Contrast agent is re-injected 15 min following the injury to assess post-SCI SCBF changes. CEU allows for real time and in-vivo assessment of SCBF changes following SCI. In the uninjured animal, ultrasound imaging showed uneven blood flow along the intact spinal cord. Furthermore, 15 min post-SCI, there was critical ischemia at the level of the epicenter while SCBF remained preserved in the more remote intact areas. In the regions adjacent to the epicenter (both rostral and caudal), SCBF was significantly reduced. This corresponds to the previously described “ischemic penumbra zone”. This tool is of major interest for assessing the effects of therapies aimed at limiting ischemia and the resulting tissue necrosis subsequent to SCI.     

Narcotic antagonists attenuate drinking induced by water deprivation in a primate

Pure narcotic antagonists such as naloxone and naltrexone have consistently been shown to attenuate drinking in the rat after periods of water deprivation. One objective of this study was to extend observations to a primate species, the squirrel monkey. Whereas naloxone and naltrexone have a greater relative affinity for opiate receptors preferentially binding morphine and other opiate alkaloids than for those with high affinity for the endogenous opioid peptides, diprenorphine, another pure opiate antagonist, binds with equally high affinity to both receptor subtypes. Therefore, a second objective was to determine the actions of diprenorphine on drinking in water-deprived rats and squirrel monkeys and to compare the effects of this drug to those of naloxone and naltrexone. All three narcotic antagonists suppressed water consumption of monkeys and rats deprived of water for 18 and 24 hr, respectively. Diprenorphine was the most potent compound tested in both species, producing significant reductions in water consumption of monkeys and rats at systemic doses as low as 0.01 and 0.1 mg/kg respectively. Moreover, diprenorphine was the longest acting of the three drugs in the monkey. These results demonstrate that the narcotic antagonists attenuate drinking in primates as well as in rodents and support the hypothesis that these drugs reduce water intake by interrupting the activity of endogenous opioid pathways mediating drinking behavior.     

Nalorphine: actions at an opiate receptor on frog skeletal muscle fibers

Intracellular microelectrode studies were conducted to investigate the actions of the partial agonist-antagonist nalorphine at an opiate receptor on functional frog skeletal muscle fiber membranes. In high bath concentrations (greater than or equal to 10(-4) M), nalorphine alone produces agonist actions similar to the "full" opiate agonists. These actions were (i) to depress both the sodium and potassium (gNa and gK) conductance increases due to electrical stimulation by a nonspecific local anestheticlike mechanism and (ii) to depress gNa by a specific opiate receptor mediated mechanism. In a much lower bath concentration (1 X 10(-8) M) nalorphine acts to antagonize the specific opiate receptor mediated depression of gNa produced by the "full" agonist meperidine. Thus in this preparation nalorphine, "the partial antagonist," has the same actions as naloxone, which is often considered to be a full antagonist. The quantitative differences observed in the effects of these two opiate antagonists are discussed.