Journal
AMERICAN JOURNAL OF PHYSIOLOGY-GASTROINTESTINAL AND LIVER PHYSIOLOGY
Volume 320, Issue 4, Pages G675-G687Publisher
AMER PHYSIOLOGICAL SOC
DOI: 10.1152/ajpgi.00463.2020
Keywords
closed-loop controller; colonic motor complex; enteric nervous system; neurogastroenterology; neuromodulation
Categories
Funding
- National Institute of Diabetes and Digestive and Kidney Diseases Grant [R01DK119795]
- National Health and Medical Research Council [1156416]
- Australian Research Council [DP190103628]
- Department of Biomedical Engineering at Duke University
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Electrical stimulation of the enteric nervous system can modify gastrointestinal transit by influencing colonic motor complexes. This study found that electrical stimulation can entrain myoelectric complexes in the smooth muscle of the colon, with timing parameters playing a crucial role in regulating the rate and duration of these complexes. Additionally, the absolute refractory period identified in the study provides valuable insight for designing neuromodulation strategies to treat colonic dysmotility.
Electrical stimulation of the enteric nervous system (ENS) is an attractive approach to modify gastrointestinal transit. Colonic motor complexes (CMCs) occur with a periodic rhythm, but the ability to elicit a premature CMC depends, at least in part, upon the intrinsic refractory properties of the ENS, which are presently unknown. The objectives of this study were to record myoelectric complexes (MCs, the electrical correlates of CMCs) in the smooth muscle and 1) determine the refractory periods of MCs, 2) inform and evaluate closed-loop stimulation to repetitively evoke MCs, and 3) identify stimulation methods to suppress MC propagation. We dissected the colon from male and female C57BL/6 mice, preserving the integrity of intrinsic circuitry while removing the extrinsic nerves, and measured properties of spontaneous and evoked MCs in vitro. Hexamethonium abolished spontaneous and evoked MCs, confirming the necessary involvement of the ENS for electrically evoked MCs. Electrical stimulation reduced the mean interval between evoked and spontaneous CMCs (24.6 +/- 3.5 vs. 70.6 +/- 15.7 s, P = 0.0002, n = 7). The absolute refractory period was 4.3 s (95% confidence interval (CI) = 2.8-5.7 s, R-2 = 0.7315, n = 8). Electrical stimulation applied during fluid distention-evoked MCs led to an arrest of MC propagation, and following stimulation, MC propagation resumed at an increased velocity (n = 9). The timing parameters of electrical stimulation increased the rate of evoked MCs and the duration of entrainment of MCs, and the refractory period provides insight into timing considerations for designing neuromodulation strategies to treat colonic dysmotility. NEW & NOTEWORTHY Maintained physiological distension of the isolated mouse colon induces rhythmic cyclic myoelectric complexes (MCs). MCs evoked repeatedly by closed-loop electrical stimulation entrain MCs more frequently than spontaneously occurring MCs. Electrical stimulation delivered at the onset of a contraction temporarily suppresses the propagation of MC contractions. Controlled electrical stimulation can either evoke MCs or temporarily delay MCs in the isolated mouse colon, depending on timing relative to ongoing activity.
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