A ganglionic intestinointestinal reflex activated by acute noxious challenge.

To investigate noxious stimulation-responsive neural circuits that could influence the gut, we recorded from intestinally directed (efferent) nerve filaments dissected from mesenteric nerves close to the small intestine in anesthetized rats. These exhibited baseline multiunit activity that was almost unaffected by vagotomy (VagX) and reduced only slightly by cutting the splanchnic nerves. The activity was halved by hexamethonium (Hex) treatment. When an adjacent gut segment received an intraluminal stimulus 2,4,6-trinitrobenzenesulfonate (TNBS) in 30% ethanol, mesenteric efferent nerve activity increased for more than 1 h. The increased activity was almost unaffected by bilateral vagotomy or splanchnic nerve section, indicating a lack of central nervous involvement, but it was 60% reduced by hexamethonium. Spike sorting discriminated efferent single and predominantly single-unit spike trains that responded to TNBS, were unaffected by splachnectomy but were silenced by hexamethonium. After noxious stimulation of one segment, the adjacent segment showed no evidence of suppression of gut motility or vasoconstriction. We conclude that luminal application of a noxious stimulus to the small intestine activates an entirely peripheral, intestinointestinal reflex pathway. This pathway involves enteric intestinofugal neurons that excite postganglionic sympathetic neurons via a nicotinic synapse. We suggest that the final sympathetic efferent neurons that respond to a tissue damaging stimulus are distinct from vasoconstrictor, secretomotor, and motility inhibiting neurons.NEW & NOTEWORTHY An intraluminal noxious chemical stimulus applied to one segment of small intestine increased mesenteric efferent nerve activity to an adjacent segment. This was identified as a peripheral ganglionic reflex that did not require vagal or spinal connections. Hexamethonium blocked most, but not all, ongoing and reflex mesenteric efferent activity. The prevertebral sympathetic efferent neurons that are activated likely affect inflammatory and immune functions of other gut segments.

Calibration of thresholds for functional engagement of vagal A, B and C fiber groups in vivo.

Vagal nerve stimulation is widely used therapeutically but the fiber groups activated are often unknown. AIM: To establish a simple protocol to define stimulus thresholds for vagal A, B and C fibers. METHODS: The intact left or right cervical vagus was stimulated with 0.1 ms pulses in spontaneously breathing anesthetized rats. Heart and respiratory rate responses to vagal stimulation were recorded. The vagus was subsequently cut distally, and mass action potentials to the same stimuli were recorded. RESULTS: Stimulating at either 50 Hz for 2 s or 2 Hz for 10 s at experimentally determined strengths revealed A, B and C fiber thresholds that were related to respiratory and heart rate changes. CONCLUSION: Our simple protocol discriminates vagal A, B and C fiber thresholds in vivo.

Reflex control of rat tail sympathetic nerve activity by abdominal temperature.

The thermoregulatory reflex effects of warming and cooling in the abdomen were investigated in 4 urethane-anesthetized Sprague-Dawley rats. Animals were shaved and surrounded by a water-perfused silastic jacket. Skin temperature under the jacket was recorded by thermocouples at 3 sites and brain temperature was monitored by a thermocouple inserted lateral to the hypothalamus. A heat exchanger made from an array of silicon tubes in parallel loops was placed through a ventral incision into the abdomen; it rested against the intestinal serosa and the temperature of this interface was monitored by a thermocouple. Few- or multi-unit postganglionic activity was recorded from sympathetic nerves supplying tail vessels (tail SNA). Intra-abdominal temperature was briefly lowered or raised between 35-41 °C by perfusing the heat exchanger with cold or warm water. Warming the abdomen inhibited tail SNA while cooling it excited tail SNA in all 4 animals. We also confirmed that cooling the trunk skin activated tail SNA. Multivariate analysis of tail SNA with respect to abdominal, brain and trunk skin temperatures revealed that all had highly significant independent inhibitory actions on tail SNA, but in these experiments abdominal temperature had the weakest and brain temperature the strongest effect. We conclude that abdominal temperature has a significant thermoregulatory action in the rat, but its influence on cutaneous vasomotor control appears to be weaker than that of skin or brain temperatures.

Location of cat brain stem neurons that drive sweating.

The brain stem premotor pathways controlling most noncardiovascular sympathetic outflows are unknown. Here, we mapped the brain stem neurons that drive sweating, by microinjecting excitant amino acid (L-glutamate or D,L-homocysteate: 0.4-3 nmol) into 420 sites over the pons and medulla of eight chloralose-anesthetized cats (70 mg/kg iv). Sweating was recorded by the electrodermal potential at the ipsilateral forepaw pad. Responses were classified as immediate (<5 s latency) or delayed (>10 s latency). Immediate responses were obtained from 16 sites (1-3 per animal) and were accompanied by no change in blood pressure. Those sites were clustered between the facial nucleus and the pyramidal tract in the rostral ventromedial medulla (RVMM). Microinjections into 33 surrounding sites caused delayed electrodermal responses of lesser amplitude, while the remaining 371 sites evoked none. To retrogradely label bulbospinal neurons that may mediate electrodermal responses, fluorescent latex microspheres were injected into the region of the intermediolateral cell column in the fourth thoracic segment in an earlier preparatory procedure on six of the animals. A cluster of retrogradely labeled neurons was identified between the facial nucleus and the pyramidal tract. Neurons in this discrete region of the RVMM, thus, drive sweating in the cat's paw and may do so via direct spinal projections.

Topical application of betahistine improves eustachian tube function in an animal model.

CONCLUSION: Betahistine dihydrochloride, a drug used widely in the systemic treatment of balance disorders such as Ménière's disease, was found to improve eustachian tube function when applied topically in the nasopharynx of rats. OBJECTIVES: The study tested the effect of betahistine, a histamine receptor agonist, on eustachian tube function and tested the involvement of H1 and H3 histamine receptors. METHODS: Eustachian tube function was measured in anaesthetized rats while middle ear pressure was increased and then monitored during induced swallowing. Betahistine and other drugs were applied topically in the nasopharynx, bulla and epipharynx, and administered intraperitoneally. RESULTS: Systemic application of betahistine hardly changed eustachian tube function, but topical application significantly improved it. The action of topical betahistine was unaffected by the HI receptor antagonist mepyramine and was mimicked by the H3 agonist, ciproxifan.

Stimulated smooth muscle neosphincter in male intrinsic sphincter deficiency: Proof of principle studies in a rabbit model.

AIMS: Intrinsic sphincter deficiency (ISD) causes significant disability and impairment of quality of life despite a range of treatment options. We investigated a novel method to improve sphincter function that does not appear to have been previously attempted, that is, transplantation to create a smooth muscle cuff, that subsequently becomes innervated, around the urethra. METHODS: Bladder pressure and passage of urine were measured in conscious, sedated rabbits of three groups: 6 control (unoperated) rabbits, 8 rabbits rendered incontinent by incision of their urethral wall, and 12 lesioned rabbits treated by transplantation of a circumferential strip of autologous dartos muscle whose innervation was later stimulated electrically. Effects of stimulation were tested up to 6 months after surgery. RESULTS: Lesions of the proximal urethra caused the bladder to leak at filling volumes that previously caused no leak. The volume added to cause first leak was less than half the volume added to cause a voiding reflex in unoperated rabbits. Transplantation of dartos to the lesioned bladder neck did not affect urodynamic parameters. However, electrical stimulation of the innervation of the transplant increased the bladder volume necessary to cause voiding and restored voiding pressures and filling volumes towards normal. These effects were maintained for 6 months and were not related to spontaneous healing. CONCLUSIONS: Free transplants of smooth muscle that become innervated offer promise as a treatment for ISD that is unlikely to cause urethral erosion and will not require a pump to restore continence.

Evidence that stimulation of ghrelin receptors in the spinal cord initiates propulsive activity in the colon of the rat.

Previous studies have failed to reveal an effect of the gastrointestinal peptide hormone ghrelin on colonic motility. In the present work, ghrelin was applied into the lumbo-sacral spinal cord in the region of defecation control centres, and a synthetic ghrelin receptor agonist, CP464709, which crosses the blood-brain barrier, was applied intravenously or into the lumbo-sacral cord. Both ghrelin and CP464709 elicited propulsive contractions and emptying of the colon in anaesthetized rats. In conscious rats, subcutaneous CP464709 caused fecal expulsion. The sites of action and nerve pathways involved in the stimulation of the colon by ghrelin receptor activation were investigated in anaesthetized rats. Intrathecal application of CP464709 at L6-S1, but not application at ponto-medullary levels or to the thoracic spinal cord, elicited propulsive contractions. The stimulation evoked by intravenous CP464709 was prevented if the pelvic nerve outflows were severed, but not if the spinal cord was cut rostral to the defecation centre at L6-S3. The response was also blocked by hexamethonium. When ghrelin, applied intrathecally, was used to desensitize its receptors, the effect of intravenous CP464709 was blocked. CP464709 did not affect small intestine motility or the amplitudes of visceromotor reflexes caused by colorectal distension. It is concluded that activation of ghrelin receptors in the lumbo-sacral spinal cord triggers co-ordinated propulsive contractions that empty the colo-rectum. The pathways through which these responses are generated pass out of the spinal cord via the pelvic nerves and cause propulsive contractions through activation of enteric neurons.

The visceromotor responses to colorectal distension and skin pinch are inhibited by simultaneous jejunal distension.

Noxious stimuli that are applied to different somatic sites interact; often one stimulus diminishes the sensation elicited from another site. By contrast, inhibitory interactions between visceral stimuli are not well documented. We investigated the interaction between the effects of noxious distension of the colorectum and noxious stimuli applied to the jejunum, in the rat. Colorectal distension elicited a visceromotor reflex, which was quantified using electromyographic (EMG) recordings from the external oblique muscle of the upper abdomen. The same motor units were activated when a strong pinch was applied to the flank skin. Distension of the jejunum did not provoke an EMG response at this site, but when it was applied during colorectal distension it blocked the EMG response. Jejunal distension also inhibited the response to noxious skin pinch. The inhibition of the visceromotor response to colorectal distension was prevented by local application of tetrodotoxin to the jejunum, and was markedly reduced when nicardipine was infused into the local jejunal circulation. Chronic sub-diaphragmatic vagotomy had no effect on the colorectal distension-induced EMG activity or its inhibition by jejunal distension. The nicotinic antagonist hexamethonium suppressed phasic contractile activity in the jejunum, had only a small effect on the inhibition of visceromotor response by jejunal distension. It is concluded that signals that arise from skin pinch and colorectal distension converge in the central nervous system with pathways that are activated by jejunal spinal afferents; the jejunal signals strongly inhibit the abdominal motor activity evoked by noxious stimuli.