Biology:Slow-wave potential

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Short description: Rhythmic electrophysiological event in the gastrointestinal tract


A slow-wave potential is a rhythmic electrophysiological event in the gastrointestinal tract. The normal conduction of slow waves is one of the key regulators of gastrointestinal motility.[1] Slow waves are generated and propagated by a class of pacemaker cells called the interstitial cells of Cajal, which also act as intermediates between nerves and smooth muscle cells.[2] Slow waves generated in interstitial cells of Cajal spread to the surrounding smooth muscle cells and control motility.

Description

In the human enteric nervous system, the slow-wave threshold is the slow-wave potential which must be reached before a slow wave can be propagated in gut wall smooth muscle. Slow waves themselves seldom cause any smooth muscle contraction (Except for, probably in the stomach). When the amplitude of slow waves in smooth muscle cells reaches the slow-wave threshold — the L-type Ca2+ channels are activated, resulting in calcium influx and initiation of motility.[3] Slow waves are generated at unique intrinsic frequencies by the interstitial cells of Cajal, even within the same organ. Entrainment of these different intrinsic frequencies through electrical coupling allows these unique intrinsic frequencies to occur at a single frequency within the stomach and segments of the small intestine. Electron microscopic and dye coupling studies to date have confirmed gap junctions as the major coupling mechanisms between interstitial cells of Cajal.[4][5]

Coupling between ICC and smooth muscle cells is uncertain. Gap junctions have been demonstrated in rare circumstances as one coupling mechanism between ICC and smooth muscle cells.[6] Another potential coupling mechanism is the "Peg and Socket" theory which demonstrates that the membranes of smooth muscle cells have the ability either form physical narrow "sockets" or "pegs" to lock onto other smooth muscle cells and/or interstitial cells of Cajal.[7]

Types

A depiction of a slow wave, contraction and electrical threshold in relation to smooth muscle tone and resting membrane potential.

Gastric slow waves occur at around 3 cycles-per-minute in humans and exhibit significance variances in both amplitudes and propagation velocities in the stomach[8][9][10] due to the existence of a gradient of resting membrane potential gradient,[11] interstitial cells of Cajal distributions, and gastric wall thickness. Gastric slow waves frequency, propagation velocity, and amplitude demonstrate significant inter-species differences. Extracellular bioelectrical recording studies have demonstrated that gastric slow waves originate from a pacemaker region located on the greater curvature of the stomach.[8][9][10] Human gastric slow waves propagate slower in the corpus than in the pacemaker region and antrum of the stomach.[8] Up to four simultaneous slow wave wavefronts can occur in the human stomach.

Intestinal slow waves occur at around 12 cycles-per-minute in the duodenum, and decreases in frequency towards the colon.[12][13] Entrainment of intestinal slow waves forms "frequency plateaus" in a piece-wise manner along the intestine. Similar to the stomach, intestinal slow waves frequency, propagation velocity, and amplitude also demonstrate significant inter-species differences.

In uterine smooth muscle, slow waves have not been consistently observed. Uterine muscle seems to generate action potentials spontaneously.[14]

In gastrointestinal smooth muscle, the slow-wave threshold can be altered by input from endogenous and exogenous innervation, as well as excitatory (acetylcholine and Substance P) and inhibitory (vasoactive intestinal peptide and nitric oxide) compounds.[15]

References

  1. Huizinga, J. D.; Lammers, W. J. E. P. (2008). "Gut peristalsis is governed by a multitude of cooperating mechanisms". AJP: Gastrointestinal and Liver Physiology 296 (1): G1–8. doi:10.1152/ajpgi.90380.2008. PMID 18988693. 
  2. Hanani, Menachem; Farrugia, Gianrico; Komuro, Terumasa (2004). Intercellular Coupling of Interstitial Cells of Cajal in the Digestive Tract. International Review of Cytology. 242. pp. 249–82. doi:10.1016/S0074-7696(04)42006-3. ISBN 978-0-12-364646-0. 
  3. Thorneloe, Kevin S.; Nelson, Mark T. (2005). "Ion channels in smooth muscle: Regulators of intracellular calcium and contractility". Canadian Journal of Physiology and Pharmacology 83 (3): 215–42. doi:10.1139/y05-016. PMID 15870837. 
  4. Horiguchi, K; Komuro, T (1998). "Ultrastructural characterization of interstitial cells of Cajal in the rat small intestine using control and Ws/Ws mutant rats". Cell and Tissue Research 293 (2): 277–84. doi:10.1007/s004410051119. PMID 9662650. 
  5. Zamir, O.; Hanani, M. (1990). "Intercellular dye-coupling in intestinal smooth muscle. Are gap junctions required for intercellular coupling?". Experientia 46 (10): 1002–5. doi:10.1007/BF01940654. PMID 2226711. 
  6. Ishikawa, Koichi; Komuro, Terumasa (1996). "Characterization of the interstitial cells associated with the submuscular plexus of the guinea-pig colon". Anatomy and Embryology 194 (1): 49–55. doi:10.1007/BF00196314. PMID 8800422. 
  7. Thuneberg, Lars; Peters, Susan (2001). "Toward a concept of stretch-coupling in smooth muscle. I. Anatomy of intestinal segmentation and sleeve contractions". The Anatomical Record 262 (1): 110–24. doi:10.1002/1097-0185(20010101)262:1<110::AID-AR1016>3.0.CO;2-0. PMID 11146434. 
  8. 8.0 8.1 8.2 O'Grady, G.; Du, P.; Cheng, L. K.; Egbuji, J. U.; Lammers, W. J. E. P.; Windsor, J. A.; Pullan, A. J. (2010). "Origin and propagation of human gastric slow-wave activity defined by high-resolution mapping". AJP: Gastrointestinal and Liver Physiology 299 (3): G585–92. doi:10.1152/ajpgi.00125.2010. PMID 20595620. 
  9. 9.0 9.1 Egbuji, J. U.; o’Grady, G.; Du, P.; Cheng, L. K.; Lammers, W. J. E. P.; Windsor, J. A.; Pullan, A. J. (2010). "Origin, propagation and regional characteristics of porcine gastric slow wave activity determined by high-resolution mapping". Neurogastroenterology & Motility 22 (10): e292–300. doi:10.1111/j.1365-2982.2010.01538.x. PMID 20618830. 
  10. 10.0 10.1 Lammers, W. J. E. P.; Ver Donck, L.; Stephen, B.; Smets, D.; Schuurkes, J. A. J. (2009). "Origin and propagation of the slow wave in the canine stomach: The outlines of a gastric conduction system". AJP: Gastrointestinal and Liver Physiology 296 (6): G1200–10. doi:10.1152/ajpgi.90581.2008. PMID 19359425. 
  11. Farrugia, G.; Lei, S.; Lin, X.; Miller, S. M.; Nath, K. A.; Ferris, C. D.; Levitt, M.; Szurszewski, J. H. (2003). "A major role for carbon monoxide as an endogenous hyperpolarizing factor in the gastrointestinal tract". Proceedings of the National Academy of Sciences 100 (14): 8567–70. doi:10.1073/pnas.1431233100. PMID 12832617. Bibcode2003PNAS..100.8567F. 
  12. Angeli, Timothy R; O'Grady, Gregory; Paskaranandavadivel, Niranchan; Erickson, Jonathan C; Du, Peng; Pullan, Andrew J; Bissett, Ian P; Cheng, Leo K (2013). "Experimental and Automated Analysis Techniques for High-resolution Electrical Mapping of Small Intestine Slow Wave Activity". Journal of Neurogastroenterology and Motility 19 (2): 179–91. doi:10.5056/jnm.2013.19.2.179. PMID 23667749. 
  13. Lammers, W. J. E. P.; Stephen, B. (2007). "Origin and propagation of individual slow waves along the intact feline small intestine". Experimental Physiology 93 (3): 334–46. doi:10.1113/expphysiol.2007.039180. PMID 18156170. 
  14. Aguilar, H. N.; Mitchell, B. F. (2010). "Physiological pathways and molecular mechanisms regulating uterine contractility". Human Reproduction Update 16 (6): 725–44. doi:10.1093/humupd/dmq016. PMID 20551073. 
  15. Pathophysiology. Porth. 7th Ed. pg.875–878

Textbook of Medical Physiology - Gyton and Hall (12th edition)[page needed]



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