Gastrointestinal System

doi:10.1017/9781107415782.012

12 - Gastrointestinal System

from Systemic Psychophysiology

Published online by Cambridge University Press: 27 January 2017

Kenneth L. Koch and

Edited by

Louis G. Tassinary and

Gary G. Berntson

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John T. Cacioppo: Affiliation:
University of Chicago
Louis G. Tassinary: Affiliation:
Texas A & M University
Gary G. Berntson: Affiliation:
Ohio State University

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Type: Chapter
Information: Handbook of Psychophysiology , pp. 258 - 283

DOI: https://doi.org/10.1017/9781107415782.012 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2016

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References

Abell, T. L. & Malagelada, J. R. (1985). Glucagon-evoked gastridysrhythmias in humans shown by an improved electrogastrographic technique. Gastroenterology, 88: 1932–1940.Google Scholar

Abell, T. L., Malagelada, J. R., Lucas, A. R., Brown, M. L., Camilleri, M., Go, V. L., … & Zinsmeister, A. R. (1987). Gastric electromechanical and neurohormonal function in anorexia nervosa. Gastroenterology, 93: 958–965.Google Scholar

Abell, T. L., Tucker, R., & Malagelada, J. R. (1985). Simultaneous gastric electromanometry in man. In Stern, R. M. & Koch, K. L. (eds.), Electrogastrography (pp. 78–88). New York: Praeger.Google Scholar

Alvarez, W. C. (1922). The electrogastrogram and what it shows. Journal of the American Medical Association, 78, 1116–1119.Google Scholar

Alvarez, W. C. (1943). Nervousness, Indigestion, and Pain. New York: Hoeber.Google Scholar

Baldaro, B., Mazzetti, M., Codispoti, M., Tuozzi, G., Bolzani, R., & Trombini, G. (2001). Autonomic reactivity during viewing of an unpleasant film. Perceptual and Motor Skills, 93: 797–805.Google Scholar

Beaumont, W. (1959 [1833]). Experiments and Observations on the Gastric Juice and the Physiology of Indigestion. New York: Dover.Google Scholar

Benson, P. W., Hooker, J. B., Koch, K. L., & Weinberg, R. B. (2012). Bitter taster status predicts susceptibility to vection-induced motion sickness and nausea. Neurogastroenterology and Motility, 24: 134–140.Google Scholar

Berntson, G. G., Cacioppo, J. T., Binkley, P. F., Uchino, B. N., Quigley, K. S., & Fieldstone, A. (1994). Autonomic cardiac control: III. Psychological stress and cardiac response in autonomic space as revealed by pharmacological blockades. Psychophysiology, 31: 599–608.Google Scholar

Berntson, G. G., Quigley, K. S., & Lozano, D. (2007). Cardiovascular psychophysiology. In Caccioppo, J. T., Tassinary, L. G., & Berntson, G. G. (eds.), Handbook of Psychophysiology, 3rd edn. (pp. 182–210). Cambridge University Press.Google Scholar

Bortolotti, M., Sarti, P., Barara, L., & Brunelli, F. (1990). Gastric myoelectrical activity in patients with chronic idiopathic gastroparesis. Journal of Gastrointestinal Motility, 2: 104–108.Google Scholar

Brehmer, A. (2006). Structure of enteric neurons. Advances in Anatomy, Embryology, and Cell Biology, 186: 1–91.Google Scholar

Brown, B. H., Smallwood, R. H., Duthie, H. L., & Stoddard, C. J. (1975). Intestinal smooth muscle electrical potentials recorded from surfaces electrodes. Medical Biological Engineering, 13: 97–103.Google Scholar

Bruley des Varannes, S., Mizrahi, M., & Dubois, A. (1991). Relation between postprandial gastric emptying and cutaneous electrogastrogram in primates. American Journal of Physiology, 261: G248–G255.Google Scholar

Bruno, C., Lopetuso, L. R., Ianiro, G., Laterza, L., Gerardi, V., Petito, V., … & Scaldaferri, F., (2013). ¹³C-octanoic acid breath test to study gastric emptying time. European Review for Medical and Pharmacological Sciences, 17: 59–64.Google Scholar

Brzana, R. J., Koch, K. L., & Bingaman, S. (1998). Gastric myoelectrical activity in patients with gastric outlet obstruction and idiopathic gastroparesis. American Journal of Gastroenterology, 93: 1803–1809.Google Scholar

Camilleri, M., Malagelada, J. R., Brown, M. L., Becker, G., & Zinsmeister, A. R. (1985). Relation between antral motility and gastric emptying of solids and liquids in humans. American Journal of Physiology, 249: G580–G585.Google Scholar

Cannon, W. B. (1936). Digestion and Health. New York: Norton.Google Scholar

Cannon, W. B. & Washburn, A. L. (1912). An explanation of hunger. American Journal of Physiology, 29: 441–454.Google Scholar

Carabotti, M., Scirocco, A., Maselli, M. A., & Severi, C. (2015). The gut–brain axis: interactions between enteric microbiota, central, and enteric nervous systems. Annals of Gastroenterology, 28: 203–209.Google Scholar

Carlson, A. J. (1916). The Control of Hunger in Health and Disease. University of Chicago Press.Google Scholar

Chen, J. D. Z., Davenport, K., & McCallum, R. W. (1993a). Effects of fat preload on gastric myoelectrical activity in normal humans. Journal of Gastrointestinal Motility, 5: 281–287.Google Scholar

Chen, J. D. Z., Lin, Z. Y., Parolisi, S., & McCallum, R. W. (1995). Inhibitory effects of cholecystokinin on postprandial gastric myoelectric activity. Digestive Diseases and Sciences, 40: 2614–2622.Google Scholar

Chen, J. D. Z. & McCallum, R. W. (1991). Electrogastrogram: measurement, analysis and prospective applications. Medical and Biological Engineering and Computing, 29: 339–350.Google Scholar

Chen, J. D. Z., Pan, J., & Orr, W. C. (1996). Role of sham feeding in postprandial changes of gastric myoelectrical activity. Digestive Diseases and Sciences, 41: 1706–1712.Google Scholar

Chen, J. D. Z., Richards, R., & McCallum, R. W. (1993b). Frequency components of the electrogastrogram and their correlations with gastrointestinal motility. Medical and Biological Engineering and Computing, 31: 60–67.Google Scholar

Chen, J. D. Z., Stewart, W. R., & McCallum, R. W. (1993c). Adaptive spectral analysis of episodic rhythmic variations in gastric myoelectric potentials. IEEE Transactions on Biomedical Engineering, 40: 128–135.Google Scholar

Chen, J. D. Z., Vandewalle, J., Sansen, W., Vantrappen, G., & Janssens, J. (1990). Adaptive spectral analysis of cutaneous electrical signals using autoregressive moving average modeling. Medical and Biological Engineering and Computing, 28: 531–536.Google Scholar

Chen, J. D. Z., Zou, X., Lin, X., Ouyang, S., & Liang, J. (1999). Detection of slow wave propagation from the cutaneous electrogastrogram. American Journal of Physiology, 277: G424–G430.Google Scholar

Cheng, L. K., Du, P., & O’Grady, G. (2013). Mapping and modeling gastrointestinal bioelectricity: from engineering bench to bedside. Physiology, 28: 310–317.Google Scholar

Chiloiro, M., Riezzo, G., Guerra, V., Reddy, S. N., & Girgio, I. (1994). The cutaneous electrogastrogram reflects postprandial gastric emptying in humans. In Chen, J. D. Z. & McCallum, R. W. (eds.), Electrogastrography: Principles and Applications (pp. 293–306). New York: Raven Press.Google Scholar

Code, C. F. & Marlett, J. A. (1975). The interdigestive myo-electric complex of the stomach and small bowel of dogs. Journal of Physiology, 246: 289–309.Google Scholar

Coelho-Aguiar, J. M., Bon-Frauches, A. C., Gomes, A. L. T., Verissimo, C. P., Aguiar, D. P., Matias, D., … & Moura-Neta, V. (2015). The enteric glia: identity and functions. Glia, 63: 921–935.Google Scholar

Couturier, D., Roze, C., Paologgi, J., & Debray, C. (1972). Electrical activity of the normal human stomach: a comparative study of recordings obtained from serosal and mucosal sites. Digestive Diseases and Sciences, 17: 969–976.Google Scholar

Davis, R. C., Garafolo, L., & Gault, F. P. (1957). An exploration of abdominal potentials. Journal of Comparative and Physiological Psychology, 50: 519–523.Google Scholar

Davis, R. C., Garafolo, L., & Kveim, K. (1959). Conditions associated with gastrointestinal activity. Journal of Comparative and Physiological Psychology, 52: 466–475.Google Scholar

Diamanti, A., Bracci, F., Gambarara, M., Ciofetta, G. C., Sabbi, T., Ponticelli, A., … & Castro, M. (2003). Gastric electric activity assessed by electrogastrography and gas emptying scintigraphy in adolescents with eating disorders. Journal of Pediatric Gastroenterology and Nutrition, 37: 35–41.Google Scholar

Dickman, R., Zilper, T., Steinmetz, A., Pakanaev, L., Ron, Y., Bernstine, H., … & Shirin, H. (2013). Comparison of continuous breath test and gastric scintigraphy for the measurement of gastric emptying rate in healthy and dyspeptic individuals. European Journal of Gastroenterology and Hepatology, 25: 291–295.Google Scholar

Dubois, M. & Mizrahi, M. (1994). Electrogastrography, gastric emptying, and gastric motility. In Chen, J. D. Z. & McCallum, R. W. (eds.). Electrogastrography: Principles and Applications (pp. 247–256). New York: Raven Press.Google Scholar

Enck, P., Hefner, J, Herbert, B. M., Mazurak, N., Weimer, K., Muth, E. R., … & Martens, U. (2013). Sensitivity and specificity of hypnosis effects on gastric myoelectrical activity. PLoS One, 8: e83486.Google Scholar

Familoni, B. O., Bowes, K. L., Kingma, Y. J., & Cote, K. R. (1991). Can transcutaneous electrodes diagnose gastric electrical abnormalities? Gut, 32: 141–146.Google Scholar

Friesen, C. A., Lin, Z., Schurman, J. V., Andre, L., & McCallum, R. W. (2007). Autonomic nervous system response to a solid meal and water loading in healthy children: its relation to gastric myoelectrical activity. Neurogastroenterology and Motility, 19: 376–382.Google Scholar

Furness, J. B. & Costa, M. (1980). Types of nerves in the enteric nervous system. Neuroscience, 5: 1–20.Google Scholar

Gabbay, F. H. & Stern, R. M. (2012). A quiet voice: Roland Clark Davis and the emergence of psychophysiology. Psychophysiology, 49: 443–453.Google Scholar

Geldof, H., van der Schee, E. J., & Grashuis, J. L. (1986a). Accuracy and reliability of electrogastrography (EGG). Gastroenterology, 90: 1425.Google Scholar

Geldof, H., van der Schee, E. J., van Blankenstein, M., & Grashuis, J. L. (1986b). Electrogastrographic study of gastric myoelectrical activity in patients with unexplained nausea and vomiting. Gut, 27: 799–808.Google Scholar

Ghoos, Y. F., Maes, B. D., Geypens, B. J., Mys, G., Hiele, M. I., Rutgeerts, P. J., & Vantrappen, G. (1993). Measurement of gastric emptying rate of solids by means of a carbon-labeled octanoic acid breath test. Gastroenterology, 104: 1640–1647.Google Scholar

Gianaros, P. J., Quigley, K. S., Mordkoff, J. T., & Stern, R. M. (2001). Gastric myoelectrical and autonomic cardiac reactivity to laboratory stressors. Psychophysiology, 38: 642–652.Google Scholar

Grover, M., Farrugia, G., Lurken, M. S., Bernard, C. E., Faussone-Pellegrini, M. S., Smyrk, T. C., … & Pasricha, P. J. (2011). Cellular changes in diabetic and idiopathic gastroparesis. Gastroenterology, 140: 1575–1585.Google Scholar

Hamilton, J. W., Bellahsene, B. E., Reichelderfer, M., Webster, J. H., & Bass, P. (1986). Human electrogastrograms: comparison of surface and mucosal recordings. Digestive Diseases and Sciences, 31: 33–39.Google Scholar

Harrison, N. A., Gray, M. A., Gianaros, P. J., & Critchley, H. D. (2010). The embodiment of emotional feelings in the brain. Journal of Neuroscience, 30: 12878–12884.Google Scholar

Hasler, W. L. (2014). The use of SmartPill for gastric monitoring. Expert Review of Gastroenterology and Hepatology, 8: 587–600.Google Scholar

Herbert, B. M., Muth, E. R., Pollatos, O., & Herbert, C. (2012). Interoception across modalities: on the relationship between cardiac awareness and the sensitivity for gastric functions. PLoS One, 7: e36646.Google Scholar

Hinder, R. A. & Kelly, K. A. (1977). Human gastric pacesetter potentials: site of origin and response to gastric transection and proximal vagotomy. American Journal of Physiology, 133: 29–33.Google Scholar

Hölzl, R., Loffler, K., & Muller, G. M. (1985). On conjoint gastrography or what the surface gastrograms show. In Stern, R. M. & Koch, K. L. (eds.), Electrogastrography: Methodology, Validation, and Applications (pp. 89–115). New York: Praeger.Google Scholar

Huisinga, J. D. (2001). Physiology and pathophysiology of the interstitial cells of Cajal: from bench to bedside. II: Gastric motility: lessons from mutant mice on slow waves and innervation. American Journal of Physiology, 281: G1129–G1134.Google Scholar

Jednak, M. A., Shadigian, E. M., Kim, M. S., Woods, M. L., Hooper, F. G., Owyang, , & Hasler, W. L. (1999). Protein meals reduce nausea and gastric slow wave dysrhythmic activity in first trimester pregnancy. American Journal of Physiology, 277: G855–861.Google Scholar

Jokerst, M. D., Gatto, M., Fazio, R., Stern, R. M., & Koch, K. L. (1999). Slow deep breathing prevents the development of tachygastria and symptoms of motion sickness. Aviation, Space, and Environmental Medicine, 70: 1189–1192.Google Scholar

Jones, K. R. & Jones, G. E. (1985). Pre- and postprandial EGG variation. In Stern, R. M. & Koch, K. L. (eds.), Electrogastrography: Methodology, Validation and Applications (pp. 168–181). New York: Praeger.Google Scholar

Keller, J., Andresen, V., Wolter, J., Layer, P., & Camilleri, M. (2009). Influence of clinical parameters on the results of ¹³C-ooctanoic acid breath tests: examination of different mathematical models in a large patient cohort. Neurogastroenterology and Motility, 21: 1039–1047.Google Scholar

Kelly, K. A., Code, C. F., & Elveback, L. R. (1969). Patterns of canine gastric electrical activity. American Journal of Physiology, 217: 461–470.Google Scholar

Kim, J., Napadow, V., Kuo, B., & Barbieri, R. (2011). A combined HRV–fMRI approach to assess cortical control of cardiovagal modulation by motion sickness. In Proceedings of the IEEE Engineering in Medicine and Biological Society, 2011, (pp. 2825–2828). Piscataway, NJ: IEEE.Google Scholar

Kim, T. W., Beckett, E. A., Hanna, R., Koh, S. D., Ordög, T., Ward, S. M., & Sanders, K. M. (2002). Regulation of pacemaker frequency in the murine gastric antrum. Journal of Physiology, 538: 145–157.Google Scholar

Kingma, Y. J. (1989). The electrogastrogram and its analysis. Critical Reviews in Biomedical Engineering, 17: 105–124.Google Scholar

Koch, K. L. (2002). Electrogastrography. In Schuster, M. M., Crowell, M. D., & Koch, K. L. (eds.), Schuster Atlas of Gastrointestinal Motility, 2nd edn. (pp. 185–202). Hamilton, ON: Decker.Google Scholar

Koch, K. L. (2014) Gastric dysrhythmias: a potential objective measure of nausea. Experimental Brain Research, 232: 2553–2561.Google Scholar

Koch, K. L., Hong, S. P., & Xu, L. (2000). Reproducibility of gastric myoelectrical activity and the water load test in patients with dysmotility-like dyspepsia symptoms and in control subjects. Journal of Clinical Gastroenterology, 12: 125–129.Google Scholar

Koch, K. L. & Stern, R. M. (1985). The relationship between the cutaneously recorded electrogastrogram and antral contractions in man. In Stern, R. M. & Koch, K. L. (eds.), Electrogastrography: Methodology, Validation, and Applications (pp. 116–131). New York: Praeger.Google Scholar

Koch, K. L, & Stern, R. M. (1993). Electrogastrography. In Kumar, D. & Wingate, D. (eds.), An Illustrated Guide to Gastrointestinal Motility (pp. 290–307). London: Churchill Communications Europe.Google Scholar

Koch, K. L. & Stern, R. M. (2004). Handbook of Electrogastrography. Oxford University Press.Google Scholar

Koch, K. L., Stern, R. M., Bingaman, S., & Eggli, D. (1991). Satiety, stomach volume, and gastric myoelectrical activity during solid-phase gastric emptying: a study of healthy individuals. Journal of Gastrointestinal Motility, 5: 41–47.Google Scholar

Koch, K. L., Stewart, W. R., & Stern, R. M. (1987). Effects of barium meals on gastric electromechanical activity in man: a fluorscopic-electrogastrophic study. Digestive Diseases and Sciences, 32: 1217–1222.Google Scholar

Koch, K. L., Tran, T. N., Stern, R. M., Bingaman, S., & Sperry, N. (1993). Gastric myoelectrical activity in premature and term infants. Neurogastroenterology & Motility, 5: 41–47.Google Scholar

Kokubo, T., Matsui, S., & Ishiguro, M. (2013). Meta-analysis of oro-cecal transit time in fasting subjects. Pharmaceutical Research, 30: 402–411.Google Scholar

Kundu, S. & Koch, K. L. (2011). Effect of balloon distention or botulinum toxin A injection of the pylorus on symptoms and body weight in patients with gastroparesis and normal 3 cycle per minute gastric electrical activity. American Journal of Gastroenterology, 106: S35.Google Scholar

Kwong, N. K., Brown, B. H., Whittaker, G. E., & Duthie, H. L. (1970). Electrical activity of the gastric antrum in man. British Journal of Surgery, 12: 913–916.Google Scholar

Lacy, B. E., Koch, K. L., & Crowell, M. D. (2002). Manometry. In Schuster, M. M., Crowell, M. D., & Koch, K. L. (eds.), Schuster Atlas of Gastrointestinal Motility, 2nd edn. (pp. 135–150). Hamilton, ON: Decker.Google Scholar

Lavigne, M. E., Wiley, Z. D., Meyer, J. H., Martin, P., & MacGregor, I. L. (1978). Gastric emptying rates of solid food in relation to body size. Gastroenterology, 74: 1258–1260.Google Scholar

Lee, K., Chey, W., Tai, H., & Yajima, H. (1978). Radioimmunoassay of motilin: validation and studies on the relationship between plasma motilin and interdigestive myoelectric activity in the duodenum of dog. Digestive Diseases and Sciences, 23: 789–795.Google Scholar

Levine, M. E., DeRusso, D. M., Tehan, J. M., & Shafer, A. L. (2010). The beneficial effects of ginger for the prevention of motion-induced nausea and gastric dysrhythmia. Psychosomatic Medicine, 72: A109.Google Scholar

Levine, M. E., Holt, L., & Koch, K. L. (2007). Effects of soy, casein, and whey protein-predominant drinks on gastric myoelectrical activity and postprandial symptoms of fullness and satiety. Neurogastroenterology & Motility, 19: 526–527.Google Scholar

Levine, M. E., Muth, E. R., Williamson, M. J., & Stern, R. M. (2004). Protein-predominant meals inhibit the development of gastric tachyarrhythmia, nausea and the symptoms of motion sickness. Alimentary Pharmacology & Therapeutics, 19: 583–590.Google Scholar

Levine, M. E. & Puzino, K. M. (2013). Music helps but shadowing doesn’t: the effects of emotional and cognitive distraction on motion-induced nausea and gastric dysrhythmia. Psychosomatic Medicine, 75: A87.Google Scholar

Levine, M. E. & Stern, R. M. (2015). The use of facial cooling for the management of motion-induced nausea and gastric dysrhythmia. Psychosomatic Medicine, 77: A112.Google Scholar

Levine, M. E., Stern, R. M., & Koch, K. L. (2014). Enhanced perceptions of control and predictability reduce motion-induced nausea and gastric dysrhythmia. Experimental Brain Research, 232: 2675–2684.Google Scholar

Lin, H. C. & Hasler, W. L. (1995). Disorders of gastric emptying. In Yamada, T. (ed.), Textbook of Gastroenterology (pp. 1318–1346). Philadelphia, PA: J. P. Lippincott.Google Scholar

Lin, Z. & Chen, J. D. Z. (1994). Comparison of three running spectral analysis methods. In Chen, J. D. Z. & McCallum, R. W. (eds.), Electrogastrography: Principles and Applications (pp. 75–98). New York: Raven Press.Google Scholar

Lunding, J. A., Nordstrom, L. M., Haukelid, A. O., Gilja, O. H., Berstad, A., & Hausken, T. (2008). Vagal activation by sham feeding improves gastric motility in functional dyspepsia. Neurogastroenterology and Motility, 20: 618–624.Google Scholar

Marie, I., Gourcerol, G., Leroi, A., Menard, J., Levesque, H., & Ducrotte, P. (2012). Delayed gastric emptying determined using the ¹³C-octanoic acid breath test in patients with systemic sclerosis. Arthritis and Rheumatism, 64: 2346–2355.Google Scholar

Mayer, E. A., Tillisch, K., & Gupta, A. (2015). Gut/brain axis and the microbiota. Journal of Clinical Investigation, 125: 926–938.Google Scholar

McCallum, R. W., Snape, W., Brody, F., Wo, J., Parkman, H. P., & Nowak, T. (2010). Gastric electrical stimulation with Enterra therapy improves symptoms from diabetic gastroparesis in a prospective study. Clinical Gastroenterology and Hepatology, 8: 947–954.Google Scholar

McNearney, T., Lin, X., Shrestha, J., Lisse, J., & Chen, J. D. Z. (2002). Characterization of gastric myoelectrical rhythms in patients with systemic sclerosis using multichannel surface electrogastrography. Digestive Diseases & Sciences, 47: 690–698.Google Scholar

Meissner, K. (2009). Effects of placebo interventions on gastric motility and general autonomic activity. Journal of Psychosomatic Research, 66: 391–398.Google Scholar

Meyer, J. H. (1987). Motility of the stomach and gastroduodenal junction. In Johnson, L. R., Christensen, J., Jacobsen, E. D., & Schultz, S. G. (eds.), Physiology of the Gastrointestinal Tract (pp. 613–630). New York: Raven Press.Google Scholar

Meyer, J. H., Gu, Y., Elashoff, J., Reedy, T., Dressman, J., & Amidon, G. (1986). Effect of viscosity and flow rate on gastric emptying of solids. American Journal of Physiology, 250: G161–G164.Google Scholar

Meyer, J. H., MacGregor, I. L., Gueller, R., Martin, P., & Cavalieri, R. (1976). 99Tc-tagged chicken liver as a marker of solid food in the human stomach. American Journal of Digestive Diseases, 21: 296–304.Google Scholar

Meyer, J. H., Ohashi, H., Jehn, D., & Thompson, J. B. (1981). Size of liver particles emptied from the human stomach. Gastroenterology, 80: 1489–1496.Google Scholar

Mintchev, M. P., Otto, S. J., & Bowes, K. L. (1997). Electrogastrography can recognize gastric electrical uncoupling in dogs. Gastroenterology, 112: 2006–2011.Google Scholar

Mirizzi, N. & Scafoglieri, V. (1983). Optimal direction of the electrogastrographic signal in man. Medical and Biological Engineering and Computing, 21: 385–389.Google Scholar

Moraes, E. R., Toncon, L. E., Baffa, O., Oba-Kunyioshi, A. S., Wakai, R., & Leuthold, A. (2003). Adaptive, autoregressive spectral estimation for analysis of electrical signals of gastric origin. Physiological Measurement, 24: 91–106.Google Scholar

Morgan, K. G., Schmalz, P. F., & Szurszewski, J. H. (1978). The inhibitory effects of vasoactive intestinal polypeptide on the mechanical and electrical activity of canine antral smooth muscle. Journal of Physiology, 282: 437–450.Google Scholar

Muth, E. R., Koch, K. L, & Stern, R. M. (2000). Significance of autonomic nervous system activity in functional dyspepsia. Digestive Diseases and Sciences, 45: 854–863.Google Scholar

Muth, E. R., Koch, K. L., Stern, R. M., & Thayer, J. F. (1999). Effect of autonomic nervous system manipulations on gastric myoelectrical activity and emotional responses in healthy human subjects. Psychosomatic Medicine, 61: 297–303.Google Scholar

Muth, E. R., Stern, R. M., & Koch, K. L. (1996). Effects of vection-induced motion sickness on gastric myoelectric activity and oral-cecal transit time. Digestive Diseases and Sciences, 41: 330–334.Google Scholar

Napadow, V., Sheehan, J., Kim, J., Dassatti, A., Thurler, A. H., Surjanhata, B., … & Kuo, B. (2013a). Brain white matter microstructure is associated with susceptibility to motion-induced nausea. Neurogastroenterology and Motility, 25: 448–450.Google Scholar

Napadow, V., Sheehan, J. D., Kim, J., LaCount, L. T., Park, K., Kaptchuk, T. J., … & Kuo, B. (2013b). The brain circuitry underlying the temporal evolution of nausea in humans. Cerebral Cortex, 23: 806–813.Google Scholar

Nelsen, T. S. & Kohatsu, S. (1968). Clinical electrogastrography and its relationship to gastric surgery. American Journal of Surgery, 116: 215–222.Google Scholar

Neunlist, M., Rolli-Derkinderen, M., Latorre, R., Van Landeghem, L., Coron, E., Derkinderen, P., & DeGiorgio, R. (2014). Enteric glial cells: recent developments and future directions. Gastroenterology, 147: 1230–1237.Google Scholar

Nobrega, A. C. M., Ferreira, B. R. S., Oliveira, G. J., Sales, K. M. O., Santos, A. A., Nobre E Souza, M. A., … & Souza, M. H. L. P. (2012). Dyspeptic symptoms and delayed gastric emptying of solids in patients with inactive Crohn’s disease. BMC Gastroenterology, 12: 175.Google Scholar

Nonaka, T., Inamori, M., Endo, H., Matsuura, M., Uchiyama, S., Yamada, E., … & Maeda, S. (2014). Correlation between gastric transit time measured by video capsule endoscopy and gastric emptying determined by the continuous real-time ¹³C breath test (Breath ID system). Hepatogastroenterology, 61: 2159–2162.Google Scholar

Ogawa, A., Mizuta, I., Fukunaga, T., Takeuchi, N., Honaga, E., Sugita, Y., … & Takeda, M. (2004). Electrogastrography abnormality in eating disorders. Psychiatry and Clinical Neurosciences, 58: 300–310.Google Scholar

O’Grady, G., Angeli, T., Du, P., Lahr, C., Lammers, W. J., Windsor, J. A., … & Cheng, L. K. (2012). Abnormal initiation and conduction of slow wave activity in gastroparesis defined by a high resolution electrical mapping. Gastroenterology, 143: 589–598.Google Scholar

Peyrot des Gachons, C., Beauchamp, G. K., Stern, R. M., Koch, K. L., & Breslin, P. A. (2011). Bitter taste induces nausea. Current Biology, 21: R247–R248.Google Scholar

Qin, S., Miao, L., Xi, N., Wang, Y., & Yang, C. (2010). A real-time weighted-eigenvector MUSIC method for time-frequency analysis of electrogastrogram slow wave. In Proceedings of the IEEE Engineering in Medicine and Biological Society, 2010 (pp. 867–870). Piscataway, NJ: IEEE.Google Scholar

Read, N. W., An-Janabi, M. N., Bates, T. E., Holgate, A. M., Cann, P. A., Kinsman, R. I., … & Brown, C. (1985). Interpretation of the breath hydrogen profile obtained after ingesting a solid meal containing unabsorbable carbohydrate. Gut, 26: 834–842.Google Scholar

Riezzo, G., Castellana, R. M., De Bellis, T., Laforgia, F., Indrio, F., & Chilorio, M. (2003). Gastric electrical activity in normal neonates during the first year of life: effect of feeding with breast milk and formula. Journal of Gastroenterology, 38: 836–843.Google Scholar

Riezzo, G., Porcelli, P., Guerra, V., & Giorgio, I. (1996). Effects of different psychophysiological stressors on the cutaneous electrogastrogram in healthy subjects. Archives of Physiology and Biochemistry, 104: 282–286.Google Scholar

Roman, C. & Gonella, J. (1987). Extrinsic control of digestive tract motility. In Johnson, L. R., Christensen, J., Jacobsen, E. D., & Schultz, S. G. (eds.), Physiology of the Gastrointestinal Tract (pp. 507–553). New York: Raven Press.Google Scholar

Sarna, S. K. (2002). Myoelectrical and contractile activities of the gastrointestinal tract. In Schuster, M. M., Crowell, M. D., & Koch, K. L. (eds.), Schuster Atlas of Gastrointestinal Motility, 2nd edn. (pp. 1–18). Hamilton, ON: Decker.Google Scholar

Schlegel, J. F. & Code, C. F. (1975). The gastric peristalsis of the interdigestive housekeeper. In Vantrappen, G. (ed.), Proceedings from the Fifth International Symposium on Gastrointestinal Motility (p. 321). Herentals, Belgium: Typoff Press.Google Scholar

Sciarretta, G., Furno, A., Mazzoni, M., Garagnani, B., & Malagut, P. (1994). Lactulose hydrogen breath test in orocecal transit assessment: critical evaluation by means of scintigraphic method. Digestive Diseases and Sciences, 39: 1505–1510.Google Scholar

Sclocco, R., Kim, J., Garcia, R. G., Sheehan, J. D., Beissner, F., Bianchi, A. M., … & Napadow, V. (2016). Brain circuitry supporting multi-organ autonomic outflow in response to nausea. Cerebral Cortex, 26: 485–497.Google Scholar

Scott, B. K., Koch, K. L., & Westcott, C. J. (2014). Pyloroplasty for patients with medically-refractory functional obstructive gastroparesis. Gastroenterology, 146: S615.Google Scholar

Smallwood, R. H. (1978). Analysis of gastric electrical signals from surface electrodes using phase-lock techniques. Part 2: System performance with gastric signals. Medical and Biological Engineering and Computing, 16: 513–518.Google Scholar

Smallwood, R. H. & Brown, B. H. (1983). Non-invasive assessment of gastric activity. In Rolfe, P. (ed.), Non-Invasive Physiological Measurements, Volume 2. London: Academic Press.Google Scholar

Smout, A. J. P. M. (1980). Myoelectric activity of the stomach: gastroelectromyography and electrogastrography. Unpublished thesis, Erasmus University, Rotterdam.Google Scholar

Smout, A. J. P. M., Jebbink, H. J. A., & Samsom, M. (1994). Acquisition and analysis of electrogastrographic data: the Dutch experience. In Chen, J. D. Z. & McCallum, R. W. (eds.), Electrogastrography: Principles and Applications (pp. 3–30). New York: Raven Press.Google Scholar

Smout, A. J. P. M., van der Schee, E. J., & Grashuis, J. L. (1980a). Postprandial and interdigestive gastric electrical activity in the dog recorded by means of cutaneous electrodes. In Christensen, J. (ed.), Gastrointestinal Motility (pp. 187–194). New York: Raven Press.Google Scholar

Smout, A. J. P. M., van der Schee, E. J., & Grashuis, J. L. (1980b). What is measured in electrogastrography? Digestive Diseases and Sciences, 25: 179–187.Google Scholar

Stemper, T. J. & Cooke, A. R. (1975). Gastric emptying and its relationship to antral contractile activity. Gastroenterology, 69: 649–653.Google Scholar

Stern, R. M., Crawford, H. E., Stewart, W. R., Vasey, M. W., & Koch, K. L. (1989). Sham feeding: cephalic-vagal influences on gastric myoelectric activity. Digestive Diseases and Sciences, 34: 521–527.Google Scholar

Stern, R. M., Jokerst, M. D., Levine, M. E., & Koch, K. L. (2001). The stomach’s response to unappetizing food: cephalic-vagal effects on gastric myoelectric activity. Neurogastroenterology and Motility, 13: 151–154.Google Scholar

Stern, R. M. & Koch, K. L. (1994). Using the electrogastrogram to study motion sickness. In Chen, J. D. Z. & McCallum, R. W. (eds.), Electrogastrography: Principles and Applications. (pp. 199–218). New York: Raven Press.Google Scholar

Stern, R. M. & Koch, K. L. (1996). Motion sickness and differential susceptibility. Current Directions in Psychological Science, 5: 115–120.Google Scholar

Stern, R. M., Koch, K. L., & Andrews, P. L. R. (2011). Nausea: Mechanisms and Management. Oxford University Press.Google Scholar

Stern, R. M., Koch, K. L., Leibowitz, H. W., Lindblad, I., Shupert, C., & Stewart, W. R. (1985). Tachygastria and motion sickness. Aviation Space and Environmental Medicine, 56: 1074–1077.Google Scholar

Stern, R. M., Koch, K. L., & Muth, E. R. (2000). Gastrointestinal system. In Cacioppo, J. T., Tassinary, L. G., & Berntson, G. G. (eds.), Handbook of Psychophysiology, 2nd edn. (pp. 294–314). Cambridge University Press.Google Scholar

Stern, R. M., Koch, K. L., Stewart, W. R., & Lindblad, I. M. (1987). Spectral analysis of tachygastria recorded during motion sickness. Gastroenterology, 92: 92–97.Google Scholar

Stern, R. M. & Stacher, G. (1982). Recording the electrogastrogram from parts of the body surface distant from the stomach. Psychophysiology, 19: 350.Google Scholar

Stern, R. M., Vasey, M. W., Hu, S., & Koch, K. L. (1991). Effects of cold stress on gastric myoelectric activity. Journal of Gastrointestinal Motility, 3: 225–228.Google Scholar

Stern, R. M., Vitellaro, K., Thomas, M., Higgins, S. C., & Koch, K. L. (2004). Electrogastrographic biofeedback: a technique for enhancing normal gastric activity. Neurogastroenterology and Motility, 16: 753–757.Google Scholar

Stoddard, C. J., Smallwood, R. H., & Duthie, H. L. (1981). Electrical arrhythmias in the human stomach. Gut, 22: 705–712.Google Scholar

Thompson, D. G., Richelson, E., & Malagelada, J. R. (1982). Perturbation of gastric emptying and duodenal motility through the central nervous system. Gastroenterology, 83: 1200–1206.Google Scholar

Thunberg, L. (1989). Interstitial cells of Cajal. In Wood, J. D. (ed..), Handbook of Physiology: The Gastrointestinal System (pp. 349–386). Bethesda, MD: American Physiological Society.Google Scholar

Uijtdehaage, S. H. J., Stern, R. M., & Koch, K. L. (1992) Effects of eating on vection-induced motion sickness, cardiac vagal tone and gastric myoelectric activity. Psychophysiology, 29: 193–201.Google Scholar

Van der Schee, E. J., Smout, A. J. P. M., & Grashuis, J. L. (1982). Applications of running spectrum analysis to electrogastrographic signals recorded from dog and man. In Wienbeck, M. (ed.), Motility of the Digestive Tract (pp. 241–250). New York: Raven Press.Google Scholar

Vantrappen, G., Hostein, J., Janssens, J., Vanderweerd, M., & De Wever, I. (1983). Do slow waves induce mechanical activity?Gastroenterology, 84: 1341.Google Scholar

Vantrappen, G., Janssens, J., Peeters, T. L., Bloom, S., R., Christofides, N. D., & Hellemans, J. (1979). Motility and the interdigestive migrating motor complex in man. Digestive Diseases and Sciences, 24: 497–500.Google Scholar

Verbeke, K. (2009). Will the ¹³C-octanoic acid breath test ever replace scintigraphy as the gold standard to assess gastric emptying? Neurogastroenterology and Motility, 21: 1013–1016.Google Scholar

ver Hagen, M. A. M. T., Luijk, H. D., Samsom, M., & Smout, A. J. P. M. (1998). Effect of meal temperature on the frequency of gastric myoelectrical activity. Neurogastroenterolog and Motility, 10: 175–181.Google Scholar

Vianna, E. P. M., Naqvi, N., Bechara, A., & Tranel, D. (2009). Does vivid emotional imagery depend on body signals? International Journal of Psychophysiology, 72: 46–50.Google Scholar

Vianna, E. P. M. & Tranel, D. (2006). Gastric myoelectrical activity as an index of emotional arousal. International Journal of Psychophysiology, 61: 70–76.Google Scholar

Vianna, E. P. M., Weinstock, J., Elliott, D., Summers, R., & Tranel, D. (2006). Increased feelings with increased body signals. Social, Cognitive, and Affective Neuroscience, 1: 37–48.Google Scholar

Wolf, S. (1943). Relation of gastric function to nausea in man. Journal of Clinical Investigations, 22: 877–882.Google Scholar

Wolf, S. & Wolff, H. G. (1943). Human Gastric Function. Oxford University Press.Google Scholar

Wood, J. D. (2002). Neural and humoral regulation of gastrointestinal motility. In Schuster, M. M., Crowell, M. D., & Koch, K. L. (eds.), Atlas of Gastrointestinal Motility, 2nd edn. (pp. 19–42). Hamilton, ON: Decker.Google Scholar

Xu, L., Koch, K. L., Gianaros, P. J., Schreibman, I. R., Ku, M., & Rolls, B. J. (2002). The effects of soup, casserole, and water ingestion on gastric myoelectrical activity and perception of hunger and fullness. Gastroenterology, 122: A326.Google Scholar

Xu, X., Chen, D. D., Yin, J., & Chen, J. D. Z. (2014). Altered postprandial responses in gastric myoelectrical activity and cardiac autonomic functions in healthy obese subjects. Obesity Surgery, 24: 554–560.Google Scholar

Yin, J. & Chen, J. D. Z. (2013). Electrogastrography: methodology, validation, and applications. Journal of Neurogastroenterology and Motility, 19: 5–17.Google Scholar

You, C. H. & Chey, W. Y. (1984). Study of electromechanical activity of the stomach in humans and in dogs with particular attention to tachygastria. Gastroenterology, 86: 1460–1468.Google Scholar

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