Role of vagal afferents and spinal pathways modulating inhibition of bradykinin-induced plasma extravasation by intrathecal nicotine

From neuroimunomodulation to bioelectronic treatment of rheumatoid arthritis

Neuronal stimulation is an emerging field in modern medicine to control organ function and reestablish physiological homeostasis during illness. The nervous system innervates most of the peripheral organs and provides a fine tune to control the immune system. Most of these studies have focused on vagus nerve stimulation and the physiological, cellular and molecular mechanisms regulating the immune system. Here, we review the new results revealing afferent vagal signaling pathways, immunomodulatory brain structures, spinal cord-dependent circuits, neural and non-neural cholinergic/catecholaminergic signals and their respective receptors contributing to neuromodulation of inflammation in rheumatoid arthritis. These new neuromodulatory networks and structures will allow the design of innovative bioelectronic or pharmacological approaches for safer and low-cost treatment of arthritis and related inflammatory disorders.

Analgesic and anti-edematogenic effects of oral trypsin were abolished after subdiaphragmatic vagotomy and spinal monoaminergic inhibition in rats

AIMS

Rheumatoid arthritis brings great burdens to the patients. In addition to the highly expensive treatment, they are commonly associated with severe side effects. In such context, the research for safe and affordable treatments is needed.

MAIN METHODS

Arthritis was induced by CFA (0.5mg/mL) in female wistar rats. Trypsin was given p.o. (2.95mg/kg; 2mL) 24h after the intra-articular CFA injection. Articular incapacitation was measured daily by counting the paw elevation time (PET; s) during 1-min periods of stimulated walk, throughout the 7-days after intra-articular CFA injection. Articular diameter (AD) was accessed just after each PET measurement, taken the difference between naïve and diseased knee-joint diameter (cm).

KEY FINDINGS

The present study showed that orally administered trypsin was able to reduce nociception and edema, effects that could be observed throughout the evaluation period. These effect, however, were not observed in animals underwent subdiaphragmatic vagotomy, suggesting a vagal mediation for trypsin effects. Likewise, these effects were blocked in rats which received intrathecal injection of the neurotoxins 5,7-dihydroxytryptamine or 6-hydroxydopamine, suggesting the involvement of spinal amines from axon terminals.

SIGNIFICANCE

The present study proposes that oral trypsin may cause vagal activation, followed by the activation of descending inhibitory pathways and such mechanism may lead to a novel approach for the treatment of arthritis.

Acute inflammation in the joint: its control by the sympathetic nervous system and by neuroendocrine systems

Inflammation of tissues is under neural control involving neuroendocrine, sympathetic and central nervous systems. Here we used the acute experimental inflammatory model of bradykinin-induced plasma extravasation (BK-induced PE) of the rat knee joint to investigate the neural and neuroendocrine components controlling this inflammation. 1. BK-induced PE is largely dependent on the sympathetic innervation of the synovium, but not on activity in these neurons and not on release of norepinephrine. 2. BK-induced PE is under the control of the hypothalamo-pituitary-adrenal (HPA) system and the sympatho-adrenal (SA) system, activation of both leading to depression of BK-induced PE. The inhibitory effect of the HPA system is mediated by corticosterone and dependent on the sympathetic innervation of the synovium. The inhibitory effect of the SA system is mediated by epinephrine and β2-adrenoceptors. 3. BK-induced PE is inhibited during noxious stimulation of somatic or visceral tissues and is mediated by the neuroendocrine systems. The nociceptive-neuroendocrine reflex circuits are (for the SA system) spinal and spino-bulbo-spinal. 4. The nociceptive-neuroendocrine reflex circuits controlling BK-induced PE are under powerful inhibitory control of vagal afferent neurons innervating the defense line (connected to the gut-associated lymphoid tissue) of the gastrointestinal tract. This inhibitory link between the visceral defense line and the central mechanisms controlling inflammatory mechanisms in body tissues serves to co-ordinate protective defensive mechanisms of the body. 5. The circuits of the nociceptive-neuroendocrine reflexes are under control of the forebrain. In this way, the defensive mechanisms of inflammation in the body are co-ordinated, optimized, terminated as appropriate, and adapted to the behavior of the organism.

Neurogenic inflammation and arthritis

Inflammation and inflammatory diseases are sexually dimorphic, but the underlying causes for this observed sexual dimorphism are poorly understood. We discuss neural-immune mechanisms that underlie sexual dimorphism in three critical aspects of the inflammatory process-plasma extravasation, neutrophil function, and inflammatory hyperalgesia. Plasma extravasation and accumulation/activation of leukocytes into tissues are critical components in inflammation and are required for several other aspects of the inflammatory response. Pain (hyperalgesia) also markedly influences the magnitude of other components of the inflammatory response and induces a feedback control of plasma extravasation and neutrophil function. More important, this feedback control itself is powerfully modulated by vagal afferent activity and both the function of the primary afferent nociceptor and the modulation of inflammatory hyperalgesia by vagal afferent activity are highly sexually dimorphic.

Mechanosensitive duodenal afferents contribute to vagal modulation of inflammation in the rat

Noxious stimuli inhibit inflammation by activating neuroendocrine stress axes, an effect that is potently attenuated by ongoing activity in subdiaphragmatic vagal afferents. Because this vagal afferent activity is carried in the coeliac and coeliac accessory branches of the subdiaphragmatic vagus, we tested the hypothesis that the activity arises from vagal afferents that innervate a proximal segment of the gastrointestinal tract. Surgical removal of the duodenum, but not the stomach, produces a marked (six orders of magnitude) leftward shift in the dose-response curve for intraplantar capsaicin-induced inhibition of synovial plasma extravasation induced by the potent inflammatory mediator bradykinin, in the knee joint; this is similar in magnitude to the inhibition produced by subdiaphragmatic or by coeliac plus coeliac accessory branch vagotomy. Fasting, to unload mechanically sensitive polymodal afferents in the proximal gastrointestinal tract, produces a similar leftward shift in the dose-response curve for the inhibitory effect of capsaicin, an effect that is reversed by balloon distension in the duodenum in fasted rats, while balloon distension postvagotomy had no effect. These results suggest that activation of mechanically sensitive vagal afferents in the duodenum contributes vagal afferent activity that modulates neuroendocrine control of the inflammatory response.

Central terminals of nociceptors are targets for nicotine suppression of inflammation

Spinal intrathecal administration of nicotine inhibits bradykinin-induced plasma extravasation, a component of the inflammatory response, in the knee joint of the rat in a dose-related fashion. Nociceptors contain nicotinic receptors and activation of a nociceptor at its peripheral terminal, by capsaicin, also produces inhibition of inflammation. Therefore the aim of this study was to test the hypothesis that the spinal target for this effect of nicotine is the central terminal of the primary afferent nociceptor. Intrathecal administration of the neurokinin-1 receptor antagonist, (3aR,7aR)-7,7-diphenyl-2-(1-imino-2(2-methoxyphenyl)-ethyl) perhydroisoindol-4-1 hydrochloride or the N-methyl-D-aspartate receptor antagonist, DL-2-amino-5-phosphonovaleric acid, both antagonists of the action of primary afferent neurotransmitters, markedly attenuated the inhibition of bradykinin-induced plasma extravasation produced by both intrathecal nicotine and intraplantar capsaicin.Conversely, intrathecal administration of an alpha-adrenoceptor antagonist, phentolamine or an opioid receptor antagonist, naloxone, to block descending antinociceptive controls, which provide inhibitory input to primary afferent nociceptors, enhanced the action of both nicotine and capsaicin. These findings support the hypothesis that the central terminal of the primary afferent nociceptor is a CNS target at which nicotine acts to inhibit inflammation.

Vagal modulation of spinal nicotine-induced inhibition of the inflammatory response mediated by descending antinociceptive controls

Noxious stimuli activate neuroendocrine axes, inhibiting inflammation, an effect that is powerfully attenuated by ongoing activity in subdiaphragmatic vagal afferents. To evaluate whether this inhibitory effect of vagal afferent activity is mediated by descending antinociceptive control, we tested whether antagonizing descending antinociceptive controls: (i) enhances the inhibition of inflammation produced by spinal nicotine (which stimulates central terminals of nociceptors) and (ii) occludes the enhancing effect of subdiaphragmatic vagotomy, in the rat. Spinal intrathecal co-administration of the alpha-adrenergic receptor antagonist phentolamine and the non-selective opioid receptor antagonist naloxone, and acute subdiaphragmatic vagotomy each produced enhancement, with similar magnitude, of nicotine-induced inhibition of plasma extravasation, produced by the potent inflammatory mediator, bradykinin. The combination of subdiaphragmatic vagotomy and intrathecal receptor antagonists, however, produced no further enhancement compared to each treatment alone. These findings support the suggestion that activity in descending antinociceptive controls modulates noxious stimulus-induced inhibition of inflammation and the vagal modulation of noxious stimulus-induced inhibition of inflammation is mediated by descending antinociceptive controls.

Vagal modulation of bradykinin-induced mechanical hyperalgesia in the female rat

In male rats, activity in subdiaphragmatic vagal afferents modulates nociception via an adrenal medulla-dependent mechanism. Because both the vagus and adrenal medullae are sexually dimorphic, we evaluated vagotomy-induced changes in mechanical nociceptive threshold and inflammatory hyperalgesia in female rats and compared them to those previously reported in male rats. We have found that (1) mechanical nociceptive threshold is lower in female rats than in male rats, perhaps because of tonic release of adrenal medullary factors in female rats; (2) mechanical nociceptive threshold in female rats is influenced to a lesser degree by activity in the subdiaphragmatic vagus; (3) vagotomy-induced enhancement of bradykinin hyperalgesia is greater in female rats; (4) in female rats, in contrast to male rats, celiac plus celiac accessory branch vagotomy failed to fully account for the enhancement of bradykinin hyperalgesia in complete subdiaphragmatic vagotomy; and (5) in female rats, in contrast to male rats, adrenal medullectomy plus subdiaphragmatic vagotomy only partially (approximately 30%) reversed the effect of vagotomy on bradykinin hyperalgesia. These findings demonstrate sexual dimorphism in the modulation of both mechanical nociceptive threshold and bradykinin-induced hyperalgesia by activity in subdiaphragmatic vagal afferents as well as the adrenal medulla.

Vagal afferents are necessary for the establishment but not the maintenance of kainic acid-induced hyperalgesia in mice

Systemic administration of a single, sub-convulsive dose (20mg/kg) of kainic acid (KA) produces long-term hyperalgesia. The robustness and reproducibility of this effect makes this a valuable model of chronic pain. However, the mechanism by which KA produces hyperalgesia remains unknown. We evaluated the role of vagal afferents on KA-induced hyperalgesia in mice by assessing the influence of bilateral subdiaphragmatic vagotomy and of direct application of KA to vagal afferents on the development of hyperalgesia. The hot plate and tail flick tests were used to assess pain behavior. Central nervous system (CNS) activity evoked by acute administration of KA or exposure to a nociceptive stimulus was also determined by the immunocytochemical detection of Fos and of phosphorylated extracellular signal-regulated protein kinases 1 and 2 (pErk). Mice exhibited a persistent hyperalgesia after either systemic application of KA or topical treatment with KA on vagal afferents. Vagotomy performed 2 weeks before the application of KA was able to prevent the establishment of hyperalgesia, but vagotomy performed 2 weeks after the application of KA was unable to reverse the already established hyperalgesia. This result establishes that vagal afferents are pivotal to the onset of hyperalgesia. Consistent with this, KA evoked the expression of Fos in vagal related areas of the brainstem, including the nucleus tractus solitarius (NTS) and area postrema (AP), as well as widespread areas of the forebrain. Vagotomy selectively decreased KA-evoked Fos in the NTS while sparing that in other brain areas. In addition to hyperalgesia, weeks after KA treatment, stimulus induced pErk was increased in spinal nociceptive neurons and the medial hypothalamus, a phenomenon that was prevented by prior vagotomy. No signs of cell death were detected using in situ nick end-labeling (TUNEL) assay and Nissl staining at 1, 5, 24, 36 h and 12 days post-KA. These findings suggest that the mechanism underlying KA-induced hyperalgesia is a long-term dysfunction of CNS areas that are activated by vagal afferents and involved in descending control of spinal nociceptive neurons.

Vagal modulation of nociception is mediated by adrenomedullary epinephrine in the rat

Vagal afferent activity modulates mechanical nociceptive threshold and inflammatory mediator-induced hyperalgesia, effects that are mediated by the adrenal medulla. To evaluate the role of epinephrine, the major hormone released from the adrenal medulla, the beta2-adrenergic receptor antagonist ICI 118,551 was chronically administered to vagotomized rats and epinephrine to normal rats. In vagotomized rats, chronic administration of ICI 118,551 markedly attenuated vagotomy-induced enhancement of bradykinin hyperalgesia but had no effect on nociceptive threshold. In normal rats, chronic epinephrine had the opposite effect, enhancing bradykinin hyperalgesia. Like vagotomy-, epinephrine-induced enhancement of hyperalgesia developed slowly, taking 14 days to reach its peak. Vagotomy induced a chronic elevation in plasma concentrations of epinephrine. We suggest that ongoing activity in vagal afferents inhibits the release of epinephrine from the adrenal medulla. Chronically elevated levels of epinephrine, occurring after vagotomy, desensitize peripheral beta2-adrenergic receptors and lead to enhancement of bradykinin hyperalgesia. The ability of prolonged elevated plasma levels of epinephrine to sensitize bradykinin receptors could contribute to chronic generalized pain syndromes.

Vagus nerve stimulation in awake rats reduces formalin-induced nociceptive behaviour and fos-immunoreactivity in trigeminal nucleus caudalis

Besides its well-established efficacy in epilepsy, vagus nerve stimulation (VNS) may be of potential interest in pain treatment. It has, however, not yet been assessed in animal pain models with the devices and stimulation protocols used in humans. We have therefore studied in awake rats the effects of left cervical VNS on trigeminal nociception using an implantable electrode and stimulator (NCP-Cyberonics). VNS was applied for 24h at 2 mA intensity, 20 Hz frequency, 0.5 ms pulse width and a duty cycle of 20s ON/18s OFF. As a nociceptive stimulus, we injected formalin into the left mystacial vibrissae, assessed behaviour for 45 min and sacrificed the animals 45 min later. Fos-immunoreactive (Fos-Ir) neurons were counted in laminae I-II of trigeminal nucleus caudalis (TNC) on both sides. We used three groups of control animals: VNS without formalin, formalin without VNS and sham VNS (implanted without stimulation or formalin). Whereas sham VNS had no significant effect, VNS alone increased Fos expression in ipsilateral TNC in addition to the expected increase in nucleus tractus solitarius. It also significantly attenuated the increase of Fos-Ir neurons observed in ipsilateral TNC laminae I-II after formalin injection. If the proper VNS effect on Fos-expression was subtracted, the reduction of formalin-induced nociceptor activation was 55%. VNS also reduced nociceptive behaviour on average by 96.1% during the early phase (0-6 min) and by 60.7% during the late phase (6-45 min) after the formalin injection. These results suggest that VNS applied with a device used in human therapy may have in awake rats a significant antinociceptive effect in a model of trigeminal pain.

Sympathetic-independent bradykinin mechanical hyperalgesia induced by subdiaphragmatic vagotomy in the rat

Bradykinin-induced mechanical hyperalgesia is sympathetically dependent and B(2)-type bradykinin receptor-mediated in the rat; however, a sympathetically independent component of bradykinin hyperalgesia is shown after subdiaphragmatic vagotomy. We evaluated the mechanism of this bradykinin-induced sympathetic-independent mechanical hyperalgesia. The dose-response curve for bradykinin mechanical hyperalgesia in sympathectomized plus vagotomized rats was similar in magnitude to that for sympathetically dependent bradykinin hyperalgesia in normal rats. Although bradykinin mechanical hyperalgesia was mediated by the B(2)-type bradykinin receptors after sympathectomy plus vagotomy, it had a much more rapid latency to onset. This hyperalgesia was significantly attenuated by inhibition of protein kinase A but not protein kinase C, similar to the hyperalgesia produced by prostaglandin E(2), an agent that directly sensitizes primary afferent nociceptors. However, unlike prostaglandin E(2)-induced mechanical hyperalgesia in normal rats, after sympathectomy plus vagotomy, bradykinin-induced hyperalgesia was not attenuated by inhibition of nitric oxide synthesis. Peripheral administration of a mu opioid agonist, [D-Ala(2),N-Me-Phe(4),Gly(5)-ol]-enkephalin, significantly attenuated bradykinin mechanical hyperalgesia after sympathectomy plus vagotomy. These data suggest that after sympathectomy plus subdiaphragmatic vagotomy, bradykinin acts directly on primary afferents to produce mechanical hyperalgesia via a novel protein kinase A-dependent signaling mechanism.

Spino-bulbo-spinal pathway mediating vagal modulation of nociceptive-neuroendocrine control of inflammation in the rat

Stimulation of nociceptors by intradermal capsaicin produces depression of bradykinin (BK)-induced synovial plasma extravasation (PE) that is markedly enhanced by subdiaphragmatic vagotomy. This depression is mediated by the adrenal medullae, a propriospinal pathway between the afferent nociceptive input and preganglionic neurones projecting to the adrenal medullae, and a spino-bulbo-spinal pathway. Here we investigated the role of spinal ascending and descending pathways in the interaction between noxious and vagal afferent inputs, leading to inhibition of BK-induced PE mediated by the adrenal medullae. Nociceptors in the paw were activated by capsaicin and depression of BK-induced PE was measured in rats with intact or cut subdiaphragmatic vagus nerves. After cutting the dorsolateral funiculus (DLF) contralateral to the stimulated hindpaw (segmental level C5/C6 and T8/T9), depression of BK-induced PE was weak or absent both in rats with intact vagus nerves and in vagotomised rats, suggesting that an ascending excitatory pathway was interrupted. After cutting the DLF ipsilateral to the stimulated hindpaw, depression of BK-induced PE was already markedly enhanced, even in the absence of vagotomy. Ipsilateral DLF lesion (L2/L3) below the level of the spinal output to the adrenal medullae produced the same effect, suggesting interruption of a descending inhibitory pathway that relays the effect of vagal activity to the level of the capsaicin-induced nociceptive input. Contralateral and ipsilateral hemisection of the spinal cord (C5/C6) produced the same changes as the corresponding DLF lesions. Ipsi- or contralateral lesion of the dorsal funiculus at the spinal level T8/T9 had no effect on depression of BK-induced PE generated by cutaneous noxious stimulation of the forepaw. We suggest that noxious stimulation activates an ascending pathway of the spino-bulbo-spinal excitatory circuit which projects through the DLF contralateral to the nociceptive input, and that the inhibitory pathway which is activated by vagal afferent activity projects through the DLF ipsilateral to the nociceptive input.

Gender and gonadal hormone effects on vagal modulation of tonic nociception

We studied the influence of gender and gonadal hormones on modulation of tonic nociception exerted by vagal activity. In male rats, subdiaphragmatic vagotomy resulted in significantly reduced nociceptive behavior during phase 2 of the formalin test. Whereas gonadectomy alone had no effect, it completely eliminated the suppressive effect of subdiaphragmatic vagotomy; however, sex hormone replacement with either testosterone or dihydrotestosterone did not restore the ability of subdiaphragmatic vagotomy to suppress nociceptive behavior. These results suggest that, in males, a gonad-dependent but androgenic gonadal hormone-independent mechanism contributes to pronociceptive effects of vagal afferent activity. Although neither gonadectomy nor subdiaphragmatic vagotomy alone affected the response to formalin in females, gonadectomy plus vagotomy resulted in significantly reduced nociceptive behavior during phase 2. Reconstitution with 17 beta-estradiol implants in gonadectomized females not only prevented suppression of nociceptive behavior seen with gonadectomy plus vagotomy, but also led to increased nociceptive behavior in the interphase between phases 1 and 2. However, placement of 17 beta-estradiol implants in gonad-intact females had no effect on formalin-induced nociceptive behavior. The finding that estrogen produced an increase in nociceptive behavior in gonadectomized female rats after vagotomy but not in normal female rats (with intact gonads and subdiaphragmatic vagus) suggests that the interaction between estrogen and nociceptive afferent activity is suppressed by vagal function. In conclusion, a nonandrogenic action of testicular function in male rats and estrogen in females seems to influence the effect of vagal activity on formalin-induced nociceptive behavior.

Functional and chemical anatomy of the afferent vagal system

The results of neural tracing studies suggest that vagal afferent fibers in cervical and thoracic branches innervate the esophagus, lower airways, heart, aorta, and possibly the thymus, and via abdominal branches the entire gastrointestinal tract, liver, portal vein, billiary system, pancreas, but not the spleen. In addition, vagal afferents innervate numerous thoracic and abdominal paraganglia associated with the vagus nerves. Specific terminal structures such as flower basket terminals, intraganglionic laminar endings and intramuscular arrays have been identified in the various organs and organ compartments, suggesting functional specializations. Electrophysiological recording studies have identified mechano- and chemo-receptors, as well as temperature- and osmo-sensors. In the rat and several other species, mostly polymodal units, while in the cat more specialized units have been reported. Few details of the peripheral transduction cascades and the transmitters for signal propagation in the CNS are known. Glutamate and its various receptors are likely to play an important role at the level of primary afferent signaling to the solitary nucleus. The vagal afferent system is thus in an excellent position to detect immune-related events in the periphery and generate appropriate autonomic, endocrine, and behavioral responses via central reflex pathways. There is also good evidence for a role of vagal afferents in nociception, as manifested by affective-emotional responses such as increased blood pressure and tachycardia, typically associated with the perception of pain, and mediated via central reflex pathways involving the amygdala and other parts of the limbic system. The massive central projections are likely to be responsible for the antiepileptic properties of afferent vagal stimulation in humans. Furthermore, these functions are in line with a general defensive character ascribed to the vagal afferent, paraventricular system in lower vertebrates.

Nociceptive neuroendocrine negative feedback control of neurogenic inflammation activated by capsaicin in the rat paw: role of the adrenal medulla

Recently we have found that inhibition of bradykinin-induced synovial plasma extravasation by transcutaneous electrical stimulation at strengths which excite unmyelinated afferent axons is mediated by the hypothalamo-pituitary-adrenal axis. Here we tested whether stimulation of nociceptors in the rat paw by intradermally injected capsaicin inhibits bradykinin-induced synovial plasma extravasation and whether this inhibition is mediated by the hypothalamo-pituitary-adrenal or sympatho-adrenal axis. Furthermore, we tested whether inhibition of bradykinin-induced plasma extravasation generated by intraperitoneally injected capsaicin, which preferentially excites visceral afferents, is mediated by the hypothalamo-pituitary-adrenal or sympatho-adrenal axis. We used normal rats, subdiaphragmatically vagotomized rats, rats with denervated adrenal medullae and rats with acutely transected spinal cords at the segmental levels T1/T2 or T12/L1. Injection of capsaicin into the plantar or palmar surface of the paws produced a depression of bradykinin-induced plasma extravasation. The inhibition elicited from the forepaw was larger than that from the hindpaw. The inhibition of bradykinin-induced plasma extravasation elicited from both paws was potentiated by subdiaphragmatic vagotomy. Denervation of the adrenal medullae abolished the inhibitory effect of intradermal capsaicin in vagus-intact and in vagotomized animals. After spinalization at the segmental level T1/T2, capsaicin injected into the forepaw did not depress bradykinin-induced plasma extravasation either in vagus-intact or in vagotomized animals. Capsaicin injected into the hindpaw in these spinalized animals produced a small depression. After spinalization at the segmental level T12/L1 no depression was produced by capsaicin injected into the hindpaw. Depression of bradykinin-induced plasma extravasation generated by intraperitoneal injection of capsaicin in vagus-intact and in vagotomized animals was also abolished or attenuated after denervation of the adrenal medullae. This shows that this depression was also largely dependent on the activation of the sympatho-adrenal system. We conclude that depression of bradykinin-induced plasma extravasation during stimulation of nociceptors by capsaicin is mediated predominantly by the sympathoadrenal pathway. This finding differs from the inhibitory mechanism of depression of bradykinin-induced plasma extravasation generated by cutaneous electrical stimulation, which is mediated by the hypothalamo-pituitary-adrenal axis.

Vagotomy-induced enhancement of mechanical hyperalgesia in the rat is sympathoadrenal-mediated

We have recently shown that subdiaphragmatic vagotomy enhances bradykinin-induced hyperalgesic behavior and decreases baseline paw withdrawal threshold to mechanical stimulation of the hindpaw skin in rats by a peripheral mechanism. To elucidate the underlying mechanism, we studied whether lesions of efferent neuroendocrine pathways could prevent or reverse the potentiating effect of vagotomy. In groups of sham-vagotomized or vagotomized rats, we surgically removed or denervated the adrenal medulla. Bradykinin was injected intradermally into the skin of the dorsal surface of the rat hindpaw. Threshold of paw withdrawal to mechanical stimulation of the skin was measured. Vagotomy induced a decrease in mechanical baseline paw withdrawal threshold and enhancement of bradykinin-induced mechanical hyperalgesic behavior, both of which were maintained over the 5 week testing period. Adrenal enucleation or denervation of the adrenal gland by suprarenal ganglionectomy prevented vagotomy-induced decrease in baseline paw withdrawal threshold and enhancement of bradykinin-induced hyperalgesia. In animals that had a demonstrated decrease in baseline paw withdrawal threshold and enhancement of bradykinin-induced hyperalgesia 2 weeks after vagotomy, additional denervation of the adrenal medulla significantly reversed these effects over a 3 week period. These results imply that both the decrease in baseline paw withdrawal threshold and enhancement of bradykinin-induced hyperalgesic behavior after vagotomy are dependent on a hormonal signal released from the adrenal medulla and suggest a novel mechanism of sensitization of cutaneous nociceptors.

Modulation of bradykinin-induced mechanical hyperalgesia in the rat by activity in abdominal vagal afferents

Bradykinin-induced plasma extravasation and mechanical hyperalgesia are sympathetic-dependent components of inflammation. Noxious stimulation has been found to inhibit bradykinin-induced plasma extravasation by activating the hypothalamo-pituitary-adrenal axis. The sensitivity of this nociceptive-neuroendocrine feedback control of inflammation is modulated by activity in subdiaphragmatic vagal afferents. In the present study, we tested the hypothesis that activity in the subdiaphragmatic vagus also modifies bradykinin-induced mechanical hyperalgesia in the rat, using the Randall-Selitto method. Following subdiaphragmatic vagotomy, the baseline paw-withdrawal threshold to mechanical stimulation decreased and bradykinin-induced mechanical hyperalgesia was enhanced. Mechanical hyperalgesia produced by prostaglandin E2, a direct-acting hyperalgesic agent, was not significantly affected by vagotomy. The effect of subdiaphragmatic vagotomy on bradykinin-induced hyperalgesia, but not on baseline paw-withdrawal threshold, was mimicked by coeliac branch vagotomy. Indomethacin blocked the hyperalgesia in normal rats, but not in vagotomized rats, suggesting that bradykinin-induced hyperalgesia in normal rats is mediated by prostaglandins, whose role was unexpectedly diminished after vagotomy. Bradykinin-induced hyperalgesia in normal rats was abolished by lumbar sympathectomy but not by sympathetic decentralization (cutting the preganglionic axons). In rats that were both vagotomized and sympathectomized, hyperalgesia induced by low-dose bradykinin was no longer present. These results demonstrate that vagotomy induces a decrease in baseline mechanical paw-withdrawal threshold and an enhancement of bradykinin-induced mechanical hyperalgesia and suggest that these phenomena are generated by actions in peripheral tissues.

Inhibition of bradykinin-induced plasma extravasation produced by noxious cutaneous and visceral stimuli and its modulation by vagal activity

Intrathecally applied nicotine reduces bradykinin-induced plasma extravasation (BK-induced PE) in the rat knee joint. This depression is mediated by the hypothalamo-pituitary-adrenal (HPA) axis and is enhanced by interruption of impulse traffic in afferents of the abdominal vagus nerve. Like intrathecal nicotine, electrical stimulation of unmyelinated cutaneous fibers also depresses BK-induced PE, which is also dependent on an intact HPA axis. In this study, we investigated whether the inhibitory effect of intrathecal nicotine can be mimicked by noxious stimulation of skin and of viscera. Furthermore we determined whether this depression is potentiated after subdiaphragmatic vagotomy. Stimulation of visceral afferents in the peritoneum, by intraperitoneal capsaicin injection, dose-dependently decreased BK-induced PE. The capsaicin dose-response function was shifted by 1.5-2 orders of magnitude to the left after vagotomy. Stimulation of visceral afferents in the urinary bladder by capsaicin also dose-dependently reduced BK-induced PE, which similarly was potentiated after vagotomy. Transcutaneous stimulation of unmyelinated nociceptive afferents from the plantar skin of the paw depressed BK-induced PE. This depression had a threshold of approximately 0.25 Hz and was maximal at a stimulation frequency of approximately 1 Hz. After subdiaphragmatic vagotomy, the stimulus response function shifted to the left and the inhibition was significantly larger than in control, in the range of 0.125-1 Hz stimulation. These results show that noxious stimulation of skin and viscera depressed BK-induced PE and that such depression was potentiated after subdiaphragmatic vagotomy in a manner similar to that of intrathecally applied nicotine. Based on these observations, we hypothesize that intrathecal nicotine depresses BK-induced PE by exciting spinal nociceptive neurons or the central projections of nociceptive primary afferent neurons.

Vagal branches involved in inhibition of bradykinin-induced synovial plasma extravasation by intrathecal nicotine and noxious stimulation in the rat

1. Stimulation of cutaneous and spinal visceral nociceptive afferents and intrathecal nicotine reduces bradykinin-induced plasma extravasation (BK-induced PE) in the knee joint of the rat. This depression is mediated by the hypothalamo-pituitary-adrenal (HPA) axis and is potentiated by subdiaphragmatic vagotomy. It is believed that activity in vagal afferents tonically inhibits ascending impulse transmission in the neuraxis projecting to the hypothalamus. Vagotomy, by removing such inhibition, allows greater depression of BK-induced PE. In this study we determined whether the vagal afferents which negatively regulate activities of the HPA axis are present in all branches of the abdominal vagus nerves or only in specific branches. 2. We measured the depression of BK-induced PE elicited by graded stimulation of spinal visceral afferents with intraperitoneal capsaicin and by intrathecal nicotine in vagus-intact rats and in rats in which specific vagal branches were selectively interrupted. (i) Interruption of the coeliac branches mimicked the effect of total subdiaphragmatic vagotomy in potentiating the depression of BK-induced PE generated by intrathecal nicotine and by stimulation of spinal visceral afferents. (ii) Interruption of the gastric and hepatic branches of the abdominal vagus nerves together or individually did not affect the depression of BK-induced PE generated by the two stimuli. 3. These results indicate that afferent activity in coeliac and accessory coeliac vagal branches is involved in the regulation of the nociceptive system-initiated depression of BK-induced PE. The afferent fibres in these vagal branches involved probably monitor physiological events in abdominal visceral organs.

Contribution of adrenal hormones to nicotine-induced inhibition of synovial plasma extravasation in the rat

1. In this study, we examined the mechanism(s) by which s.c. nicotine inhibits synovial plasma extravasation. We found that nicotine dose-dependently inhibited bradykinin (BK)- and platelet activating factor (PAF)-induced plasma extravasation. 2. The effect of nicotine on both BK- and PAF-induced plasma extravasation was attenuated by adrenal medullectomy. ICI-118,551 (a selective beta 2-adrenoceptor blocker) (30 micrograms ml-1, intra-articularly) significantly attenuated the inhibitory action of high-dose (1 mg kg-1) nicotine on BK-induced plasma extravasation without affecting the inhibition by low- (0.01 microgram kg-1) dose nicotine or that on PAF-induced plasma extravasation by nicotine at any dose. This suggested that beta 2-adrenoceptors mediate the inhibitory actions of high-dose, but not low-dose, nicotine. We also found that systemic naloxone (an opioid receptor antagonist) (two hourly injections of 1 mg kg-1, i.p.) attenuated the inhibitory action produced by all doses of nicotine on BK- or PAF-induced plasma extravasation, suggesting the contribution of endogenous opioids. 3. RU-38,486 (a glucocorticoid receptor antagonist) (30 mg kg-1, s.c.), and metyrapone (a glucocorticoid synthesis inhibitor) (two hourly injections of 100 mg kg-1, i.p.) both attenuated the action of high-dose nicotine without affecting that of low-dose nicotine. 4. Spinal mecamylamine (a nicotinic receptor antagonist) (0.025 mg kg-1, intrathecally, i.t.) attenuated the action of high-dose, but not low-dose, nicotine, suggesting that part of the action of high-dose nicotine is mediated by spinal nicotinic receptors. 5. Combined treatment with ICI-118,551, naloxone and RU-38,486 attenuated the action of low-dose nicotine by an amount similar to that produced by naloxone alone but produced significantly greater attenuation of the effect of high-dose nicotine when compared to the action of any of the three antagonists alone.

Sympathetic-dependence in bradykinin-induced synovial plasma extravasation is dose-related

While previous studies have implicated a role for sympathetic postganglionic neuron-terminals in bradykinin-induced plasma extravasation, a recent report by Cambridge and Brain [Br. J. Pharmacol., 115 (1995) 641-647] has suggested that it is sympathetic-independent. However, the doses of bradykinin used in these two groups of studies were considerably different. Therefore, in the present study, we characterized the sympathetic-dependence of plasma extravasation at varying doses of bradykinin. By measuring the concentration of Evans blue dye extravasation into the joint perfusate following its intravenous injection, bradykinin-induced plasma extravasation in the knee joint cavity was determined spectrophotometrically. To examine the role of sympathetic postganglionic neuron terminals in mediating bradykinin-induced plasma extravasation, we used surgical ablation of the lumbar sympathetic chain. Intra-articular perfusion of BK dose-dependently increased synovial plasma extravasation. After surgical sympathectomy, the dose-response curve for bradykinin-induced plasma extravasation was significantly shifted to the right. We conclude that at concentrations observed in inflamed tissues (between 10(-8) and 10(-7) M), bradykinin-induced plasma extravasation is largely mediated by sympathetic postganglionic neuron terminals.

Variation in the anatomy of the lumbar sympathetic chain in the rat

The rat is often used when the sympathetic nervous system contribution to various physiological and pathological processes is studied. These experiments require a detailed knowledge of the lumbar sympathetic chain anatomy since the macroscopic anatomy of the L2 and L3 levels of the sympathetic chain, which innervate a major portion of the hindleg, is highly variable. We have performed a detailed study of the anatomy of the lumbar sympathetic chain in 245 Sprague-Dawley rats. Through anatomical characterization of the L2 and L3 sympathetic ganglia white and gray ramus communicants, our study provides an anatomical guide for studies of the function of the lumbar sympathetic chain in the rat.