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Role of Peptidergic Sensory Neurons in Gastric Mucosal Blood Flow and Protection (1991)

HOLZER, P. ; LIPPE, I. TH. ; RAYBOULD, H. E. ; [et al.]

Oxford, UK : Blackwell Publishing Ltd

Annals of the New York Academy of Sciences 632 (1991), S. 0

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ISSN: 1749-6632

Source: Blackwell Publishing Journal Backfiles 1879-2005

Topics: Natural Sciences in General

Notes: The present findings have revealed a new aspect of how mechanisms of gastric mucosal resistance to injury are called into effect and are coordinated by the nervous system. Capsaicin-sensitive sensory neurons in the stomach play a physiological role in monitoring acid influx into the superficial mucosa. Once activated, they strengthen gastric mucosal defense against deep injury, with a key process in this respect being an increase in blood flow through the gastric mucosa. This concept opens up completely new perspectives in the physiology and pathophysiology of the gastric mucosa if we consider that the long-term integrity of the gastric mucosa may be under the subtle control of acid-sensitive sensory neurons and that, vice versa, improper functioning of these neural control mechanisms may predispose to gastric ulcer disease.The present observations also indicate that some of the peptides contained in gastric sensory nerve endings might fulfill a transmitter or mediator role in controlling gastric mucosal blood flow and integrity. Whereas substance P and neurokinin A are unlikely to play a role in the regulation of gastric mucosal blood flow, there is severalfold evidence that CGRP is very important in this respect. This peptide, which in the rat gastric mucosa originates exclusively from spinal sensory neurons,2,4,27 is released upon stimulation of sensory nerve endings and is extremely potent in facilitating gastric mucosal blood flow and in protecting the mucosa from injurious factors. Selective ablation of spinal sensory neurons containing CGRP weakens the resistance of the gastric mucosa against acid injury, which is most likely due to inhibition of protective vasodilator reflexes. We now aim at providing direct pharmacological evidence that antagonism of endogenously released CGRP results in similar pathophysiological consequences as ablation of capsaicin-sensitive sensory neurons.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1111/j.1749-6632.1991.tb33115.x

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The role of calcium in the enhanced myocardial contractility of the hyperthyroid rat heart (1990)

Butkow, N. ; Wheatley, A. M. ; Lippe, I. Th. ; [et al.]

Springer

Basic research in cardiology 85 (1990), S. 297-306

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ISSN: 1435-1803

Keywords: hyperthyroidism ; calcium ; myocardialcontractility ; verapamil ; dantrolene

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary The hyperthyroid rat myocardium exhibits enhanced contractility. There is evidence that altered calcium handling by the myocardium may be responsible for this enhanced state. To investigate this, isolated hyperthyroid and cuthyroid hearts were perfused in the working mode and exposed to alterations in external calcium concentration. Heart rate was not significantly different in either group of hearts, nor was it altered by the change in calcium. The concentration of calcium needed to elicit half-maximal contractility (dP/dtmax) was lower in the hyperthyroid (0.81±0.07 mM) than in the cuthyroid hearts (1.12±0.09 mM, p〈0.05). This increase in calcium sensitivity was unlikely to be at the site of the sarcolemma as verapamil exerted equal negative inotropic effects on both groups of hearts. Dantrolene, which blocks calcium release from the sarcoplasmic reticulum, exerted a significantly greater (p〈0.01) depression in dP/dtmax after 12 min in the hyperthyroid (50±7%) than in the cuthyroid heart (15±2%). We conclude from our results that the enhanced contractile state of the hyperthyroid rat heart is likely to involve an altered mechanical response to calcium which is possibly at the level of enhanced calcium release from the sarcoplasmic reticulum.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01907118

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Enhanced myocardial contractility but not tachycardia persists in isolated working hyperthyroid rat hearts (1988)

Wheatley, A. M. ; Butkow, N. ; Marcus, R. H. ; [et al.]

Springer

Basic research in cardiology 83 (1988), S. 634-646

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ISSN: 1435-1803

Keywords: hyperthyroid rat heart ; heart rate ; heartcontractility in hyperthyroidism ; tachycardia in hyperthyroidism

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary It is generally believed that the increased contractility and tachycardia of the hyperthyroid heart are a result of thyroid hormone-induced alterations of the mechanical and electrical properties of the heart, respectively. We compared the contractility (dP/dtmax) and the spontaneous beating rate of hyperthyroid and euthyroid hearts perfused in vitro in either a non-working or a working mode. The dP/dtmax (4196±74 mm Hg s−1) and beating rate (322±8 beats/min) of the non-working hyperthyroid hearts were significantly higher (p〈0.001) than those of the euthyroid hearts (3267±115 mm Hg s−1 and 260±6 beats/min at an external Ca2+ of 2.5 mM). At 2.5 mM Ca2+, the working hyperthyroid hearts again displayed enhanced contractility (5636±179 mm Hg s−1 vs 4508±172 mm Hg s−1; p〈0.001) but the spontaneous beating rate (275±7 beats/min) was not significantly different from euthyroid (261±8 beats/min). When hearts were subjected to periods of alternate non-working and working perfusion, the beating rate of the hyperthyroid hearts was significantly higher than euthyroid during non-working (p〈0.02) but not during working perfusion. Increasing the afterload on the non-working preparations in a stepwise fashion from 75 cm H2O to 120 cm H2O caused significant changes in left ventricular pressure and dP/dtmax in both heart types but the tachycardia in the hyperthyroid hearts persisted (at 120 cm H2O; hyperthyroid, 294±9 beats/min; euthyroid, 224±10 beats/min; p〈0.001). Alteration of the preload (10 to 25 cm H2O) and afterload (75 to 105 cm H2O) on working hyperthyroid and euthyroid hearts caused changes in both left ventricular pressure and dP/dtmax but the beating rates of both heart types were never significantly different. We conclude from our results that (i) the increased contractility of the hyperthyroid rat heart is due to thyroid hormone-induced alteration of the mechanical properties of the heart; (ii) the tachycardia of hyperthyroidism is not due to thyroid hormone-induced changes in the electrical properties of the heart, but probably involves some as yet unidentified chronotropic agent.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01906958

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