Thomas Garrick

CRF microinjected into the dorsal vagal complex inhibits TRH analog- and kainic acid-stimulated gastric contractility in rats

The effect of CRF microinjected into the dorsal vagal complex (DVC) on centrally-stimulated gastric contractility was investigated in fasted, urethane-anesthetized rats. Miniature strain gauge force transducers were acutely implanted on the corpus of the stomach and contractility was analyzed by computer. Microinjection of the stable thyrotropin-releasing hormone (TRH) analog, RX 77368, (26 pmol) into the DVC induced a 12.2-fold stimulation of gastric contractility within 30 min. Corticotropin-releasing factor (CRF) (63-210 pmol) microinjected into the DVC concomitantly with RX 77368 (26 pmol) induced a dose-related inhibition of stimulated gastric contractility. Neither CRF alone (210 pmol) nor vehicle modified basal gastric contractility. Microinjection of kainic acid (141 pmol) into the raphe pallidus nucleus induced a 3.6-fold stimulation of gastric contractility after 45 min. This stimulation was suppressed by bilateral microinjection of CRF (105 pmol/site) into the DVC. These results demonstrate that CRF acts in the DVC to inhibit centrally-stimulated gastric contractility and suggest that TRH and CRF may interact in the DVC to regulate gastric motor function.

Raphe pallidus stimulation increases gastric contractility via TRH projections to the dorsal vagal complex in rats

The role of thyrotropin releasing hormone (TRH) in the dorsal vagal complex (DVC) in mediating the enhanced gastric contractility induced by glutamate (100 pmol) microinjected into the raphe pallidus (Rpa) was investigated in urethane-anesthetized rats acutely implanted with miniature strain gauge force transducers on the corpus of the stomach. Glutamate-induced stimulation of gastric contractility was dose-dependently inhibited by bilateral microinjection into the DVC of TRH antibody (0.17, 0.85 or 1.7 micrograms/100 nl/site) but not by vehicle. TRH antibody microinjected into the dorsal medullary reticular field had no effect. These data indicate that activation of Rpa neurons by glutamate increases gastric motor function through TRH release in the DVC.

Intracerebroventricular Pressure Inhibits Gastric Antral and Duodenal Contractility but Not Acid Secretion in Conscious Rabbits

Acute nausea characteristically accompanies head injury or increased intracranial pressure, or both. The etiology of this symptom is unclear. We studied the effect of increased intracranial pressure on gastric antral and duodenal contractility and gastric acid secretion in conscious rabbits. Intracerebroventricular pressure was maintained at 3, 8, or 13 cmH2O using normal saline perfused into the lateral cerebral ventricle and gastric antral and duodenal contractility was monitored using chronically implanted strain gauge force transducers. Gastric acid secretion was measured in a separate group of rabbits with chronically implanted gastric cannulas. Increased intracerebroventricular pressure (13 cmH2O) resulted in an immediate suppression of the amplitude of gastric and duodenal contractions by greater than 80% and greater than 60%, respectively. After normalization of intracerebroventricular pressure, the contractile pattern returned to basal levels. Intravenous bolus injection of bethanechol reversed the suppression of gastric antral contractility induced by increased intracranial pressure. Increased pressure for 2 h did not modify gastric acid output as compared with normal pressure controls, whereas atropine significantly inhibited and histamine stimulated gastric acid secretion in the same animals maintained at normal pressure. These results demonstrate that acutely increased intracranial pressure rapidly and reversibly inhibits gastric and duodenal motor function in conscious rabbits.

Body Temperature and Wheel Running Predict Survival Times in Rats Exposed to Activity-Stress

The relationship between restricted feeding, core body temperature (Tb), wheel running, survival, and gastric erosion formation was examined in female rats exposed to activity-stress. Core body temperature and gross motor activity were telemetrically monitored in four groups of rats that had free access to running wheels and in one group that was not allowed to run on the wheels. Twenty-four hours prior to the onset of hypothermia and predicted mortality, different groups were left undisturbed, warmed with a heat lamp, denied access to running wheels, or euthanized. Length of survival in wheel-running rats varied from 2 to 12 days. During the first day of food deprivation, premorbid changes in the variability of Tb during the diurnal period and the mean number of wheel revolutions during the nocturnal period were strongly predictive of length of survival. Warming rats with a heat lamp or preventing rats from ever running on the wheel increased the length of survival and attenuated gastric erosion formation. Only rats that were warmed had a greater likelihood of survival. Gastric pathology was also reduced in rats that were euthanized prior to becoming moribund. Rats that were left undisturbed or locked from the running wheel over the last 24 h of testing became moribund and had extensive gastric mucosal damage. These results indicate that thermoregulatory disturbances induced by restricted feeding and not wheel running alone are critical in determining survival and the degree of gastric mucosal injury in rats exposed to activity-stress. Results further suggest that predisposing factors may put some rats at risk for the development of activity-stress-induced mortality.

Physical Symptoms and Self-Image in a Group of Normal Adolescents

The relationship of physical symptoms and self concept were evaluated in a group of 122 adolescents using a brief Adolescent Symptom Checklist and the Offer Self-Image Questionnaire. Adolescents with “normal” self concepts were notably free of complaints of physical symptoms. Adolescent girls with many physical complaints displayed specific disturbances in their psychologic functioning. Adolescent boys with many physical complaints displayed a global disturbance in all aspects of their self concept. The authors conclude that adolescents who have multiple physical complaints are at a high risk for having significant psychologic disturbance.

Central nervous system action of TRH to stimulate gastric function and ulceration

Intracisternal or intracerebroventricular injection of TRH (0.1-10 micrograms) in rats stimulated the secretion of gastric acid and pepsin secretion, increased gastric mucosal blood flow and gastric contractility and emptying, induced gastric hemorrhagic lesions and aggravated experimental ulcers elicited by aspirin, serotonin or indomethacin. TRH action was dose-dependent, rapid in onset and central nervous system-mediated by activation of the parasympathetic outflow to the stomach and cholinergic receptors. The stable TRH analog, RX 77368, was more potent and longer lasting than TRH. TRH and its stable analog appear as new chemical probes to produce centrally-mediated vagal-dependent stimulation of gastric function and experimental ulcers. The physiologic role of endogenous TRH in the central regulation of gastric function and ulceration remains to be established.

Effects of intermittent tail shock or water avoidance on proximal colonic motor contractility in rats.

Changes in proximal colonic mechanical activity and defecation during exposure to three different types of experimental stressors were examined in rats chronically implanted with 2 force transducers on the proximal colon. To validate the integrity of the recording system, meal-induced changes in proximal colonic contractility were initially measured in all rats 1-2 days prior to stress induction. Different groups of ad lib fed rats were then exposed to tail shock, re-exposure to the shock chamber or water avoidance for 1 h over the next 1-2 days. Two types of phasic colonic contractions, long (0-3/min) and short (6-8/min) duration, were analyzed separately using a computer. Long duration contractions were significantly elevated 21-71% over fasting basal values from 61-120 min following a meal. No other consistent changes during the prandial or postprandial period were observed. Tail shock significantly suppressed proximal colonic contractility from pre-shock values and increased fecal output and fluid content when compared to ad lib fed rats that were not shocked. Fecal output increased but proximal colonic contractility did not change when previously shocked rats were re-exposed to the tail shock chamber but not shocked. In rats exposed to water avoidance, proximal colonic contractility was minimally suppressed but defecation was significantly greater than home cage control animals. These results indicate that proximal colonic contractile activity is differentially altered by exposure to different environmental stressors and may be a contributing factor in stress-induced bowel dysfunction.

Predictable and unpredictable shock stimulates gastric contractility and causes mucosal injury in rats.

The effects of tailshock on gastric contractility and lesions were investigated in rats exposed to 100 1-mA tailshocks while confined inside plastic tubes. A light preceded each shock in one group and was randomly presented with respect to shock in the other. Following the session, animals were given 3 hr of rest before being sacrificed. Contractility of the corpus of the stomach was measured by means of chronically implanted extraluminal force transducers. Contractility was measured in 10-min blocks and analyzed by computer. Lesions were quantified by inspection; quantitative histology was performed on corpus and antrum sections. Signaled (n = 13) and unsignaled (n = 17) shock stimulated high-amplitude gastric contractions in fasted rats, which continued for 2 hr after the shock session. Cumulative contractile activity (1.5-hr shock plus 2-hr rest) in shocked animals was twice that in restrained and unrestrained control animals (n = 19, p less than .05), and contractile activity had a 30%-40% greater average amplitude than after a meal. Compared with unrestrained controls, shocked rats had visibly more mucosal injury (2.2 +/- 0.5 mm2 vs. 0.1 +/- 0 mm2). Larger cumulative contractile activity was associated with a larger area of erosions (r = .36, p less than .05). Frequency and duration of contractions did not distinguish between shocked and unshocked groups. We conclude that in rats, signaled and unsignaled tailshock stimulates persistent, high-amplitude gastric contractions and is associated with injury of the mucosa of the stomach.

BOMBESIN MICROINJECTED INTO THE DORSAL VAGAL COMPLEX INHIBITS TRH-STIMULATED GASTRIC CONTRACTILITY IN RATS

The effects of centrally injected bombesin on central and peripheral stimulated gastric contractility were investigated in fasted urethane-anesthetized rats. Miniature strain gauge force transducers were acutely implanted on the corpus of the stomach and gastric contractility was analyzed by computer. Intracisternal injection of the stable thyrotropin-releasing hormone (TRH)-analog RX 77368 (77 pmol) induced a stimulation of gastric contractility for 40 min. Intracisternal injection of bombesin (62-620 pmol) followed 30 min later by that of RX 77368 resulted in a dose-related inhibition of the TRH-analog-induced gastric contractility. Intracisternal injection of bombesin (620 pmol) did not modify gastric contractility stimulated by intravenous carbachol. Stimulation of gastric contractility induced by TRH-analog microinjected into the dorsal vagal complex (DVC) was dose-related suppressed by concomitant injections of bombesin (6.2-620 pmol). Neither bombesin alone (6.2 pmol) nor vehicle modified basal gastric contractility. These results demonstrate that bombesin acts within the brain to inhibit vagally stimulated gastric contractility and that the DVC is a sensitive site for bombesin inhibitory action. These findings suggest a possible interaction between TRH and bombesin in the central vagal regulation of gastric contractility.

Microinjection of thyrotropin-releasing hormone in the paraventricular nucleus of the hypothalamus stimulates gastric contractility

Changes in gastric contractility following microinjection of thyrotropin-releasing hormone (TRH) into the paraventricular nucleus of the hypothalamus (PVN) were examined in fasted, urethane-anesthetized rats. Gastric contractility was measured with extraluminal force transducers and analysed by computer. Unilateral and bilateral PVN microinjections of TRH (0.5 and 1.0 microgram) significantly increased the force index of gastric contractions from 0 to 60 min postinjection, when compared with animals microinjected with 0.1 microgram TRH, 0.1% BSA or TRH (0.5 and 1.0 microgram TRH) in sites adjacent to the PVN. The gastric force index was also significantly elevated from 61 to 120 min postinjection in rats receiving bilateral PVN microinjections of TRH (0.5 and 1.0 microgram). Peak gastric responses occurred within 10-20 min postinjection and represented an approximately eight-fold increase over basal values. In the remaining groups, the force index was not significantly altered from preinjection values. The excitatory action of TRH (1.0 microgram) on gastric contractility was completely abolished by subdiaphragmatic vagotomy. These results suggest that TRH acts within the PVN to stimulate gastric contractility via vagal-dependent pathways.