PURPOSE: We examined the electrical and mechanical characteristics of the smooth muscles in the human colon at the muscle cell, the muscle strip, and at the whole tissue levels METHODS: Conventional microelectrode recordings and tension recordings were performed. RESULTS: There was no difference in resting membrane potential, frequency, and amplitude of slow waves between the right and left colon; but there were significant differences in frequency and amplitude of the slow waves between inner circular muscle (CM) and longitudinal muscle (LM), and between inner CM and outer CM, but not between outer CM and LM. On tension recording of CM and LM strip and colonic segment, amplitude, frequency, and area under the curve showed no difference between the right and left colon. In whole colonic segment, high amplitude dominant waves (DW) were found both in CM and LM. Low amplitude non-DWs were detected only in CM, more commonly in right colon and propagated aborally. DWs in the CM were associated with DWs in the LM. In the CM of the left colon, all DWs in the CM propagated aborally ending-up with DW in the LM layer. However, in the right colon, mixed pattern of propagation was detected in adjacent recording sites in 60% of tissues examined. CONCLUSION: Electrophysiologic and mechanical characteristics were similar between the right and left human colon. However, the retrograde propagation of both DWs and non-DWs in the CM was more frequent in the right colon, accounting for mixing function in this region of the human colon.
PURPOSE: We examined the electrical and mechanical characteristics of the smooth muscles in the human colon at the muscle cell, the muscle strip, and at the whole tissue levels METHODS: Conventional microelectrode recordings and tension recordings were performed. RESULTS: There was no difference in resting membrane potential, frequency, and amplitude of slow waves between the right and left colon; but there were significant differences in frequency and amplitude of the slow waves between inner circular muscle (CM) and longitudinal muscle (LM), and between inner CM and outer CM, but not between outer CM and LM. On tension recording of CM and LM strip and colonic segment, amplitude, frequency, and area under the curve showed no difference between the right and left colon. In whole colonic segment, high amplitude dominant waves (DW) were found both in CM and LM. Low amplitude non-DWs were detected only in CM, more commonly in right colon and propagated aborally. DWs in the CM were associated with DWs in the LM. In the CM of the left colon, all DWs in the CM propagated aborally ending-up with DW in the LM layer. However, in the right colon, mixed pattern of propagation was detected in adjacent recording sites in 60% of tissues examined. CONCLUSION: Electrophysiologic and mechanical characteristics were similar between the right and left human colon. However, the retrograde propagation of both DWs and non-DWs in the CM was more frequent in the right colon, accounting for mixing function in this region of the human colon.
Authors: Hyun-Tai Lee; Grant W Hennig; Kyu Joo Park; Peter O Bayguinov; Sean M Ward; Kenton M Sanders; Terence K Smith Journal: Gastroenterology Date: 2009-03-05 Impact factor: 22.682
Authors: S Nakanishi; S Kakita; I Takahashi; K Kawahara; E Tsukuda; T Sano; K Yamada; M Yoshida; H Kase; Y Matsuda Journal: J Biol Chem Date: 1992-02-05 Impact factor: 5.157
Authors: Susanna Every-Palmer; Roger G Lentle; Gordon Reynolds; Corrin Hulls; Paul Chambers; Helen Dunn; Pete M Ellis Journal: Front Pharmacol Date: 2017-04-24 Impact factor: 5.810