Neural Control of Feeding and Swallowing

Physical Medicine and Rehabilitation Clinics of North America

Volumn 19, Issue 4, 2008, Pages 709-728

  Mistry, Satish ^a   Hamdy, Shaheen ^a  

^a UNIVERSITY OF MANCHESTER   (United Kingdom)

Author keywords

[No Author keywords available]

Indexed keywords

BRAIN CORTEX; BRAIN FUNCTION; BRAIN STEM; BREATHING; CONTROL SYSTEM; DRINKING; EATING; ELECTROMYOGRAM; EVOKED SOMATOSENSORY RESPONSE; FACIAL NERVE; FEEDBACK SYSTEM; FEEDING; FUNCTIONAL MAGNETIC RESONANCE IMAGING; GLOSSOPHARYNGEAL NERVE; GUSTATORY SYSTEM; HUMAN; HYPOGLOSSAL NERVE; MAGNETOENCEPHALOGRAPHY; MASTICATION; MUSCLE INNERVATION; NEUROIMAGING; NEUROPHYSIOLOGY; NONHUMAN; POSITRON EMISSION TOMOGRAPHY; PRIORITY JOURNAL; REVIEW; SENSATION; SENSORY NERVE; SEX DIFFERENCE; SMELLING; STROKE; SWALLOWING; TASTE; TRANSCRANIAL MAGNETIC STIMULATION; TRIGEMINAL NERVE; VAGUS NERVE;

CEREBRAL CORTEX; DEGLUTITION; HUMANS; MASTICATION; OLFACTORY PERCEPTION; UPPER GASTROINTESTINAL TRACT;

EID: 54049089334     PISSN: 10479651     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.pmr.2008.05.002     Document Type: Review

References (94)

1. Hiiemae K.M., and Palmer J.B. Food transport and bolus formation during complete feeding sequences on foods of different initial consistency. Dysphagia 14 (1999) 31-42
2. Palmer J.B., Hiiemae K.M., Matsuo K., et al. Volitional control of food transport and bolus formation during feeding. Physiol Behav 91 (2007) 66-70
3. Onozuka M., Fujita M., Watanabe K., et al. Mapping brain region activity during chewing: a functional magnetic resonance imaging study. J Dent Res 81 (2002) 743-746
4. Lund J.P. Mastication and its control by the brain stem. Crit Rev Oral Biol Med 2 (1991) 33-64
5. Lund J.P., and Kolta A. Generation of the central masticatory pattern and its modification by sensory feedback. Dysphagia 21 (2006) 167-174
6. Turker K.S. Reflex control of human jaw muscles. Crit Rev Oral Biol Med 13 (2002) 85-104
7. Bakke M., Moller E., Thomsen C.E., et al. Chewing in patients with severe neurological impairment. Arch Oral Biol 52 (2007) 399-403
8. Hughes T. Neurology of swallowing and oral feeding disorders: assessment and management. J Neurol Neurosurg Psychiatr 74 Suppl 3 (2003) iii48-iii52
9. Hiiemae K., Heath M.R., Heath G., et al. Natural bites, food consistency and feeding behaviour in man. Arch Oral Biol 41 (1996) 175-189
10. Peyron A., Lassauzay C., and Woda A. Effects of increased hardness on jaw movement and muscle activity during chewing of visco-elastic model foods. Exp Brain Res 142 (2002) 41-51
11. Peyron M.A., Blanc O., Lund J.P., et al. Influence of age on adaptability of human mastication. J Neurophysiol 92 (2004) 773-779
12. Cerf-Ducastel B., and Murphy C. FMRI brain activation in response to odors is reduced in primary olfactory areas of elderly subjects. Brain Res 986 (2003) 39-53
13. Poellinger A., Thomas R., Lio P., et al. Activation and habituation in olfaction-an fMRI study. Neuroimage 13 (2001) 547-560
14. Rolls E.T. Taste, olfactory, and food texture processing in the brain, and the control of food intake. Physiol Behav 85 (2005) 45-56
15. Sobel N., Prabhakaran V., Zhao Z., et al. Time course of odorant-induced activation in the human primary olfactory cortex. J Neurophysiol 83 (2000) 537-551
16. Zald D.H., and Pardo J.V. Emotion, olfaction, and the human amygdala: amygdala activation during aversive olfactory stimulation. Proc Natl Acad Sci U S A 94 (1997) 4119-4124
17. Shepherd G.M. Smell images and the flavour system in the human brain. Nature 444 (2006) 316-321
18. Breslin P.A., and Huang L. Human taste: peripheral anatomy, taste transduction, and coding. Adv Otorhinolaryngol 63 (2006) 152-190
19. Lindemann B. Receptors and transduction in taste. Nature 413 (2001) 219-225
20. Rolls E.T. Smell, taste, texture, and temperature multimodal representations in the brain, and their relevance to the control of appetite. Nutr Rev 62 (2004) S193-S204 discussion S224-41
21. Bromley S.M., and RL D. Taste. In: Ashbury A.K., McKhann G.M., Ian McDonald W., et al. (Eds). Diseases of the nervous system-clinical neuroscience and therapeutic principles. 3rd edition (2002), Cambridge University Press, Cambridge (England) vol. 1. p. 610-20
22. Kinnamon S.C., and Cummings T.A. Chemosensory transduction mechanisms in taste. Annu Rev Physiol 54 (1992) 715-731
23. Schiffman S.S., and Gatlin C.A. Clinical physiology of taste and smell. Annu Rev Nutr 13 (1993) 405-436
24. Rolls E.T. Sensory processing in the brain related to the control of food intake. Proc Nutr Soc 66 (2007) 96-112
25. Saper C.B., Chou T.C., and Elmquist J.K. The need to feed: homeostatic and hedonic control of eating. Neuron 36 (2002) 199-211
26. O'Doherty J., Rolls E.T., Francis S., et al. Representation of pleasant and aversive taste in the human brain. J Neurophysiol 85 (2001) 1315-1321
27. Small D.M., Zald D.H., Jones-Gotman M., et al. Human cortical gustatory areas: a review of functional neuroimaging data. Neuroreport 10 (1999) 7-14
28. Smits M., Peeters R.R., van Hecke P., et al. A 3 T event-related functional magnetic resonance imaging (fMRI) study of primary and secondary gustatory cortex localization using natural tastants. Neuroradiology (2006)
29. Zald D.H., Hagen M.C., and Pardo J.V. Neural correlates of tasting concentrated quinine and sugar solutions. J Neurophysiol 87 (2002) 1068-1075
30. Hooker D. Early human fetal behavior, with a preliminary note on double simultaneous fetal stimulation. Res Publ Assoc Res Nerv Ment Dis 33 (1954) 98-113
31. Martin R.E., and Sessle B.J. The role of the cerebral cortex in swallowing. Dysphagia 8 (1993) 195-202
32. Diamant N.E. Firing up the swallowing mechanism. Nat Med 2 (1996) 1190-1191
33. Anderson D., Hannam A.G., and Matthews B. Sensory mechanisms in mammalian teeth and their supporting structures. Physiol Rev 50 (1970) 171-195
34. Luschei E.S., and Goodwin G.M. Patterns of mandibular movement and jaw muscle activity during mastication in the monkey. J Neurophysiol 37 (1974) 954-966
35. Shaker R., Ren J., Zamir Z., et al. Effect of aging, position, and temperature on the threshold volume triggering pharyngeal swallows. Gastroenterology 107 (1994) 396-402
36. Dodds W.J., Man K.M., Cook I.J., et al. Influence of bolus volume on swallow-induced hyoid movement in normal subjects. AJR Am J Roentgenol 150 (1988) 1307-1309
37. Ertekin C., and Aydogdu I. Neurophysiology of swallowing. Clin Neurophysiol 114 (2003) 2226-2244
38. Jean A. Brain stem control of swallowing: neuronal network and cellular mechanisms. Physiol Rev 81 (2001) 929-969
39. Mansson I., and Sandberg N. Effects of surface anaesthesia on deglutition in man. Laryngoscope 84 (1974) 427-437
40. Miller A.J., Vargervik K., and Phillips D. Neuromuscular adaptation of craniofacial muscles to altered oral sensation. Am J Orthod 87 (1985) 303-310
41. Ali G.N., Laundl T.M., Wallace K.L., et al. Influence of mucosal receptors on deglutitive regulation of pharyngeal and upper esophageal sphincter function. Am J Phys 267 (1994) G644-G649
42. Miller A.J. Deglutition. Physiol Rev 62 (1982) 129-184
43. Cichero J.A., and Murdoch B.E. Dysphagia: foundation, theory and practice (2006), John Wiley & Sons, Ltd, Chichester (UK)
44. Zemlin W.R. Speech and hearing science: anatomy and physiology (1997), Allyn & Bacon, Boston
45. Bieger D., and Hockman C.H. Suprabulbar modulation of reflex swallowing. Exp Neurol 52 (1976) 311-324
46. Sumi T. Some properties of cortically-evoked swallowing and chewing in rabbits. Brain Res 15 (1969) 107-120
47. Jean A. Brainstem control of swallowing: localisation and organization of the central pattern generator for swallowing. In: Taylor A. (Ed). Neurophysiology of the jaws and teeth (1990), MacMillan Press, London 294-321
48. Jean A. Brainstem organization of the swallowing network. Brain Behav Evol 25 (1984) 109-116
49. Beyak M.J., Collman P.I., Valdez D.T., et al. Superior laryngeal nerve stimulation in the cat: effect on oropharyngeal swallowing, oesophageal motility and lower oesophageal sphincter activity. Neurogastroenterol Motil 9 (1997) 117-127
50. Jean A., and Car A. Inputs to the swallowing medullary neurons from the peripheral afferent fibers and the swallowing cortical area. Brain Res 178 (1979) 567-572
51. Miller A.J. Characteristics of the swallowing reflex induced by peripheral nerve and brain stem stimulation. Exp Neurol 34 (1972) 210-222
52. Hockman C.H., Bieger D., and Weerasuriya A. Supranuclear pathways of swallowing. Prog Neurobiol 12 (1979) 15-32
53. Bernheimer H., Birkmayer W., Hornykiewicz O., et al. Brain dopamine and the syndromes of Parkinson and Huntington. Clinical, morphological and neurochemical correlations. J Neurol Sci 20 (1973) 415-455
54. Leopold N.A., and Kagel M.C. Pharyngo-oesophageal dysphagia in Parkinsons disease. Dysphagia 12 (1997) 11-18
55. Bastian H.C. A treatise on aphasia and other speech defects (1898), Lewis, London
56. Hamdy S., Xue S., Valdez D., et al. Induction of cortical swallowing activity by transcranial magnetic stimulation in the anaesthetized cat. Neurogastroenterol Motil 13 (2001) 65-72
57. Martin R.E., Kemppainen P., Masuda Y., et al. Features of cortically evoked swallowing in the awake primate (Macaca fascicularis). J Neurophysiol 82 (1999) 1529-1541
58. Robbins J., Levine R.L., Maser A., et al. Swallowing after unilateral stroke of the cerebral cortex. Arch Phys Med Rehabil 74 (1993) 1295-1300
59. Hamdy S., Aziz Q., Rothwell J.C., et al. The cortical topography of human swallowing musculature in health and disease. Nat Med 2 (1996) 1217-1224
60. Hamdy S., Aziz Q., Rothwell J.C., et al. Sensorimotor modulation of human cortical swallowing pathways. J Physiol 506 Pt 3 (1998) 857-866
61. Fraser C., Rothwell J., Power M., et al. Differential changes in human pharyngoesophageal motor excitability induced by swallowing, pharyngeal stimulation, and anesthesia. Am J Physiol Gastrointest Liver Physiol 285 (2003) G137-G144
62. Mistry S., Rothwell J.C., Thompson D.G., et al. Modulation of human cortical swallowing motor pathways after pleasant and aversive taste stimuli. Am J Physiol Gastrointest Liver Physiol 291 (2006) G666-G671
63. Fraser C., Power M., Hamdy S., et al. Driving plasticity in human adult motor cortex is associated with improved motor function after brain injury. Neuron 34 (2002) 831-840
64. Gow D., Rothwell J., Hobson A., et al. Induction of long-term plasticity in human swallowing motor cortex following repetitive cortical stimulation. Clin Neurophysiol 115 (2004) 1044-1051
65. Mistry S., Verin E., Singh S., et al. Unilateral suppression of pharyngeal motor cortex to repetitive transcranial magnetic stimulation reveals functional asymmetry in the hemispheric projections to human swallowing. J Physiol 585 (2007) 525-538
66. Rodel R.M., Olthoff A., Tergau F., et al. Human cortical motor representation of the larynx as assessed by transcranial magnetic stimulation (TMS). Laryngoscope 114 (2004) 918-922
67. Humbert I.A., and Robbins J. Normal swallowing and functional magnetic resonance imaging: a systematic review. Dysphagia 22 (2007) 266-275
68. Loose R., Hamdy S., and Enck P. Magnetoencephalographic response characteristics associated with tongue movement. Dysphagia 16 (2001) 183-185
69. Gerloff C., Uenishi N., Nagamine T., et al. Cortical activation during fast repetitive finger movements in humans: steady-state movement-related magnetic fields and their cortical generators. Electroencephalogr Clin Neurophysiol 109 (1998) 444-453
70. Nagamine T., Kajola M., Salmelin R., et al. Movement-related slow cortical magnetic fields and changes of spontaneous MEG- and EEG-brain rhythms. Electroencephalogr Clin Neurophysiol 99 (1996) 274-286
71. Furlong P.L., Hobson A.R., Aziz Q., et al. Dissociating the spatio-temporal characteristics of cortical neuronal activity associated with human volitional swallowing in the healthy adult brain. Neuroimage 22 (2004) 1447-1455
72. Gow D., Hobson A.R., Furlong P., et al. Characterising the central mechanisms of sensory modulation in human swallowing motor cortex. Clin Neurophysiol 115 (2004) 2382-2390
73. Hamdy S., Mikulis D.J., Crawley A., et al. Cortical activation during human volitional swallowing: an event-related fMRI study. Am J Physiol 277 (1999) G219-G225
74. Hamdy S., Rothwell J.C., Brooks D.J., et al. Identification of the cerebral loci processing human swallowing with H2(15)O PET activation. J Neurophysiol 81 (1999) 1917-1926
75. Harris M.L., Julyan P., Kulkarni B., et al. Mapping metabolic brain activation during human volitional swallowing: a positron emission tomography study using [18F]fluorodeoxyglucose. J Cereb Blood Flow Metab 25 (2005) 520-526
76. Hartnick C.J., Rudolph C., Willging J.P., et al. Functional magnetic resonance imaging of the pediatric swallow: imaging the cortex and the brainstem. Laryngoscope 111 (2001) 1183-1191
77. Kern M., Birn R., Jaradeh S., et al. Swallow-related cerebral cortical activity maps are not specific to deglutition. Am J Physiol Gastrointest Liver Physiol 280 (2001) G531-G538
78. Kern M.K., Jaradeh S., Arndorfer R.C., et al. Cerebral cortical representation of reflexive and volitional swallowing in humans. Am J Physiol Gastrointest Liver Physiol 280 (2001) G354-G360
79. Martin R., Barr A., Macintosh B., et al. Cerebral cortical processing of swallowing in older adults. Exp Brain Res 176 (2007) 12-22
80. Mosier K., and Bereznaya I. Parallel cortical networks for volitional control of swallowing in humans. Exp Brain Res 140 (2001) 280-289
81. Mosier K., Patel R., Liu W.C., et al. Cortical representation of swallowing in normal adults: functional implications. Laryngoscope 109 (1999) 1417-1423
82. Suzuki M., Asada Y., Ito J., et al. Activation of cerebellum and basal ganglia on volitional swallowing detected by functional magnetic resonance imaging. Dysphagia 18 (2003) 71-77
83. Teismann I.K., Dziewas R., Steinstraeter O., et al. Time-dependent hemispheric shift of the cortical control of volitional swallowing. Hum Brain Mapp (2007)
84. Teismann I.K., Steinstraeter O., Stoeckigt K., et al. Functional oropharyngeal sensory disruption interferes with the cortical control of swallowing. BMC Neurosci 8 (2007) 62
85. Toogood J.A., Barr A.M., Stevens T.K., et al. Discrete functional contributions of cerebral cortical foci in voluntary swallowing: a functional magnetic resonance imaging (fMRI) "Go, No-Go" study. Exp Brain Res 161 (2005) 81-90
86. Watanabe Y., Abe S., Ishikawa T., et al. Cortical regulation during the early stage of initiation of voluntary swallowing in humans. Dysphagia 19 (2004) 100-108
87. Zald D.H., and Pardo J.V. The functional neuroanatomy of voluntary swallowing. Ann Neurol 46 (1999) 281-286
88. de Araujo I.E., Kringelbach M.L., Rolls E.T., et al. Representation of umami taste in the human brain. J Neurophysiol 90 (2003) 313-319
89. Ogawa H., Wakita M., Hasegawa K., et al. Functional MRI detection of activation in the primary gustatory cortices in humans. Chem Senses 30 7 (2005) 583-592
90. Martin R.E., Goodyear B.G., Gati J.S., et al. Cerebral cortical representation of automatic and volitional swallowing in humans. J Neurophysiol 85 2 (2001) 938-950
91. Abe S., Wantanabe Y., Shintani M., et al. Magnetoencephalographic study of the starting point of voluntary swallowing. Cranio 21 (2003) 46-49
92. Dziewas R., Soros P., Ishii R., et al. Neuroimaging evidence for cortical involvement in the preparation and in the act of swallowing. Neuroimage 20 (2003) 135-144
93. Chee C., Arshad S., Singh S., et al. The influence of chemical gustatory stimuli and oral anaesthesia on healthy human pharyngeal swallowing. Chem Senses 30 (2005) 393-400
94. Butler J.E. Drive to the human respiratory muscles. Respir Physiolo Neurobiol 159 (2007) 115-126