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      Multiple Neural Oscillators and Muscle Feedback Are Required for the Intestinal Fed State Motor Program

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          Abstract

          After a meal, the gastrointestinal tract exhibits a set of behaviours known as the fed state. A major feature of the fed state is a little understood motor pattern known as segmentation, which is essential for digestion and nutrient absorption. Segmentation manifests as rhythmic local constrictions that do not propagate along the intestine. In guinea-pig jejunum in vitro segmentation constrictions occur in short bursts together with other motor patterns in episodes of activity lasting 40–60 s and separated by quiescent episodes lasting 40–200 s. This activity is induced by luminal nutrients and abolished by blocking activity in the enteric nervous system (ENS). We investigated the enteric circuits that regulate segmentation focusing on a central feature of the ENS: a recurrent excitatory network of intrinsic sensory neurons (ISNs) which are characterized by prolonged after-hyperpolarizing potentials (AHPs) following their action potentials. We first examined the effects of depressing AHPs with blockers of the underlying channels (TRAM-34 and clotrimazole) on motor patterns induced in guinea-pig jejunum, in vitro, by luminal decanoic acid. Contractile episode durations increased markedly, but the frequency and number of constrictions within segmenting bursts and quiescent period durations were unaffected. We used these observations to develop a computational model of activity in ISNs, excitatory and inhibitory motor neurons and the muscle. The model predicted that: i) feedback to ISNs from contractions in the circular muscle is required to produce alternating activity and quiescence with the right durations; ii) transmission from ISNs to excitatory motor neurons is via fast excitatory synaptic potentials (EPSPs) and to inhibitory motor neurons via slow EPSPs. We conclude that two rhythm generators regulate segmentation: one drives contractions within segmentation bursts, the other the occurrence of bursts. The latter depends on AHPs in ISNs and feedback to these neurons from contraction of the circular muscle.

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          Most cited references60

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          Gut peristalsis is governed by a multitude of cooperating mechanisms.

          Peristaltic motor activity of the gut is an essential activity to sustain life. In each gut organ, a multitude of overlapping mechanisms has developed to acquire the ability of coordinated contractile activity under a variety of circumstances and in response to a variety of stimuli. The presence of several simultaneously operating control systems is a challenge for investigators who focus on the role of one particular control activity since it is often not possible to decipher which control systems are operating or dominant in a particular situation. A crucial advantage of multiple control systems is that gut motility control can withstand injury to one or more of its components. Our efforts to increase understanding of control mechanism are not helped by recent attempts to eliminate proven control systems such as interstitial cells of Cajal (ICC) as pacemaker cells, or intrinsic sensory neurons, nor does it help to view peristalsis as a simple reflex. This review focuses on the role of ICC as slow-wave pacemaker cells and places ICC into the context of other control mechanisms, including control systems intrinsic to smooth muscle cells. It also addresses some areas of controversy related to the origin and propagation of pacemaker activity. The urge to simplify may have its roots in the wish to see the gut as a consequence of a single perfect design experiment whereas in reality the control mechanisms of the gut are the messy result of adaptive changes over millions of years that have created complementary and overlapping control systems. All these systems together reliably perform the task of moving and mixing gut content to provide us with essential nutrients.
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            Intrinsic primary afferent neurons and nerve circuits within the intestine.

            Intrinsic primary afferent neurons (IPANs) of the enteric nervous system are quite different from all other peripheral neurons. The IPANs are transducers of physiological stimuli, including movement of the villi or distortion of the mucosa, contraction of intestinal muscle and changes in the chemistry of the contents of the gut lumen. They are the first neurons in intrinsic reflexes that influence the patterns of motility, secretion of fluid across the mucosal epithelium and local blood flow in the small and large intestines. In the guinea pig small intestine, where they have been characterized in detail, IPANs have Dogiel type II morphology, that is they are large round or oval neurons with multiple processes, some of which end close to the luminal surface of the intestine, and some of which form synapses with enteric interneurons, motor neurons and with other IPANs. The IPANs have well-defined ionic currents through which their excitability, and their functions in enteric nerve circuits, is determined. These include voltage-gated Na(+) and Ca(2+) currents, a long lasting calcium-activated K(+) current, and a hyperpolarization-activated cationic current. The IPANs exhibit long-term changes in their states of excitation that can be induced by extended periods of low frequency activity in synaptic inputs and by inflammatory mediators, either applied directly or released during an inflammatory challenge. The IPANs may be involved in pathological changes in enteric function following inflammation.
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              Release of 5-hydroxytryptamine from the mucosa is not required for the generation or propagation of colonic migrating motor complexes.

              The pacemaker mechanism that underlies the cyclic generation of colonic migrating motor complexes (CMMCs) is unknown, although studies have suggested that release of 5-hydroxytryptamine (5-HT) from enterochromaffin cells in the mucosa is essential. However, no recordings of 5-HT release from the colon have been made to support these suggestions. We used real-time amperometry to record 5-HT release directly from the mucosa in mouse isolated colon to determine whether 5-HT release from enterochromaffin cells was required for CMMC generation. We found that 5-HT was released from mucosal enterochromaffin cells during many, but not all, CMMC contractions. However, spontaneous CMMCs still were recorded even after removal of the mucosa, and submucosa and submucosal plexus when all release of 5-HT had been abolished. CMMC pacemaker frequency was slower in the absence of the mucosa, an effect reversed by focal application of exogenous 5-HT onto the myenteric plexus. Despite the absence of the mucosa and all detectable release of 5-HT, ondansetron significantly reduced CMMC frequency, suggesting that 5-HT(3) receptor blockade slows the CMMC pacemaker via a mechanism independent of 5-HT release from enterochromaffin cells. Our results show that 5-HT can be released dynamically during CMMCs. However, the intrinsic pacemaker and pattern generator underlying CMMC generation lies within the myenteric plexus and/or muscularis externa and does not require any release of 5-HT from enterochromaffin cells. Endogenous release of 5-HT from enterochromaffin cells plays a modulatory role, not an essential role, in CMMC generation.
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                Author and article information

                Contributors
                Role: Editor
                Journal
                PLoS One
                plos
                plosone
                PLoS ONE
                Public Library of Science (San Francisco, USA )
                1932-6203
                2011
                5 May 2011
                : 6
                : 5
                : e19597
                Affiliations
                [1 ]Department of Physiology, The University of Melbourne, Parkville, Australia
                [2 ]Florey Neuroscience Institutes, Parkville, Australia
                [3 ]Centre for Neuroscience, The University of Melbourne, Parkville, Australia
                Mount Sinai School of Medicine, United States of America
                Author notes

                Conceived and designed the experiments: JDC JCB EAT. Performed the experiments: JDC EAT. Analyzed the data: JDC EAT. Contributed reagents/materials/analysis tools: JCB EAT. Wrote the paper: JDC JCB EAT.

                Article
                PONE-D-10-04613
                10.1371/journal.pone.0019597
                3088688
                21573176
                18e0237e-e7bd-4676-b500-100123e44482
                Chambers et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
                History
                : 27 October 2010
                : 12 April 2011
                Page count
                Pages: 17
                Categories
                Research Article
                Computer Science
                Computer Modeling
                Medicine
                Anatomy and Physiology
                Digestive System
                Digestive Physiology
                Digestive Regulation
                Neurological System
                Nervous System Physiology
                Neural Pathways
                Peripheral Nervous System
                Sensory Systems
                Gastroenterology and Hepatology
                Gastrointestinal Motility Disorders
                Small Intestine
                Neurology
                Autonomic Nervous System
                Neuropharmacology

                Uncategorized
                Uncategorized

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