Local regulatory mechanism to coordinate colorectal motility in rats

The presence of a fecal pellet in the colorectum causes ascending contraction and descending relaxation, propelling the pellet aborally. However, random occurrence of the reflexes at multiple sites would disturb sequential excretion of the pellets, resulting in inefficient defecation. Hence, we post...

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Bibliographic Details
Published in:Physiological reports 2018-05, Vol.6 (10), p.e13710-n/a
Main Authors: Sawada, Rika, Nakamori, Hiroyuki, Naitou, Kiyotada, Horii, Kazuhiro, Horii, Yuuki, Shimaoka, Hiroki, Shiina, Takahiko, Shimizu, Yasutake
Format: Article
Language:English
Subjects:
Animals
Anus
Autonomic Nervous System
Balloons
Blood pressure
Colitis
Colitis - physiopathology
Colon
Colon - physiology
colorectal motility
Contraction
Defecation
Enteric nervous system
Enteric Nervous System - physiology
Experiments
Feces
Gastrointestinal Motility
Ghrelin
Immunology
Inflammatory bowel disease
Laboratory animals
lumbosacral defecation center
Male
Motility
Nervous system
Original Research
Parasympathetic Nervous System - physiology
Physiology
Polyethylene
Pressure transducers
Rats, Sprague-Dawley
Rectum - physiology
Reflexes
Regulation
Spinal cord
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Summary:The presence of a fecal pellet in the colorectum causes ascending contraction and descending relaxation, propelling the pellet aborally. However, random occurrence of the reflexes at multiple sites would disturb sequential excretion of the pellets, resulting in inefficient defecation. Hence, we postulated that a regulatory mechanism to coordinate peristaltic motility initiated at adjacent portions of the colorectum may exist. Colorectal motility was recorded with balloons located at 2 cm, 5 cm and 7 cm from the anus in vivo in anesthetized rats. The presence of a balloon in the colorectum inhibited motility of the oral side and enhanced motility of the anal side. Both the ascending inhibitory and descending facilitatory actions were unaffected by cutting the pelvic nerves, suggesting little contribution of the lumbosacral defecation center. In contrast, disrupting the continuity of the enteric nervous system abolished the local reflex mechanism. The ascending inhibitory pathway operated in a condition in which facilitatory input from the lumbosacral defecation center was fully activated by intrathecal injection of ghrelin. We also found that functional impairment of the local reflex pathways was evident in rats that recovered from 2,4,6‐trinitrobenzensulfonic acid‐induced colitis. These results demonstrate that an intrinsic regulatory mechanism to coordinate peristaltic motility initiated at adjacent portions exists in the rat colorectum. The regulation may be beneficial to propel multiple pellets efficiently. In addition, impairment of the local regulatory mechanism might be involved in postinflammatory dysmotility in the colorectum. An intrinsic regulatory mechanism to coordinate peristaltic motility initiated at adjacent portions exists in the rat colorectum. The regulation may be beneficial to propel multiple pellets efficiently. In addition, impairment of the local regulatory mechanism might be involved in postinflammatory dysmotility in the colorectum.
ISSN:2051-817X
DOI:10.14814/phy2.13710