Literature DB >> 309042

Hodgkin-Huxley type electronic modelling of gastrointestinal electrical activity.

R J Patton, D A Linkens.   

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Year:  1978        PMID: 309042     DOI: 10.1007/bf02451921

Source DB:  PubMed          Journal:  Med Biol Eng Comput        ISSN: 0140-0118            Impact factor:   2.602


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  14 in total

1.  A linked oscillator model of electrical activity of human small intestine.

Authors:  B H Brown; H L Duthie; A R Horn; R H Smallwood
Journal:  Am J Physiol       Date:  1975-08

2.  A quantitative description of membrane current and its application to conduction and excitation in nerve.

Authors:  A L HODGKIN; A F HUXLEY
Journal:  J Physiol       Date:  1952-08       Impact factor: 5.182

3.  Mathematical modeling of the colorectal myoelectrical activity in humans.

Authors:  D A Linkens; I Taylor; H L Duthie
Journal:  IEEE Trans Biomed Eng       Date:  1976-03       Impact factor: 4.538

4.  Frequency entrainment of coupled Hodgkin-Huxley-type oscillators for modeling gastro-intestinal electrical activity.

Authors:  D A Linkens; S Datardina
Journal:  IEEE Trans Biomed Eng       Date:  1977-07       Impact factor: 4.538

Review 5.  Electrical activity of gastrointestinal smooth muscle.

Authors:  H L Duthie
Journal:  Gut       Date:  1974-08       Impact factor: 23.059

6.  A mathematical model of the slow-wave electrical activity of the human small intestine.

Authors:  B Robertson-Dunn; D A Linkens
Journal:  Med Biol Eng       Date:  1974-11

7.  Simulation of the electric-control activity of the stomach by an array of relaxation oscillators.

Authors:  S K Sarna; E E Daniel; Y J Kingma
Journal:  Am J Dig Dis       Date:  1972-04

8.  An electronic model of neuroelectric point processes.

Authors:  E R Lewis
Journal:  Kybernetik       Date:  1968-07

Review 9.  Applications of Hodgkin-Huxley equations to excitable tissues.

Authors:  D Noble
Journal:  Physiol Rev       Date:  1966-01       Impact factor: 37.312

10.  The stability of entrainment conditions for RLC coupled Van der Pol oscillators used as a model for intestinal electrical rhythms.

Authors:  D A Linkens
Journal:  Bull Math Biol       Date:  1977       Impact factor: 1.758
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  6 in total

1.  Conoidal dipole model of electrical field produced by the human stomach.

Authors:  M P Mintchev; K L Bowes
Journal:  Med Biol Eng Comput       Date:  1995-03       Impact factor: 2.602

2.  Effects of gap junction inhibition on contraction waves in the murine small intestine in relation to coupled oscillator theory.

Authors:  Sean P Parsons; Jan D Huizinga
Journal:  Am J Physiol Gastrointest Liver Physiol       Date:  2014-12-11       Impact factor: 4.052

3.  Development of electrical coupling and action potential synchrony between paired aggregates of embryonic heart cells.

Authors:  D L Ypey; D E Clapham; R L DeHaan
Journal:  J Membr Biol       Date:  1979-12-12       Impact factor: 1.843

4.  Multioscillator simulator for gastrointestinal electrical activity modelling.

Authors:  D A Linkens; M Khelfa; G Nicklin
Journal:  Med Biol Eng Comput       Date:  1983-09       Impact factor: 2.602

5.  Simple electronic analogue for teaching on the nerve cell.

Authors:  G Roy; M Lavoie
Journal:  Med Biol Eng Comput       Date:  1981-11       Impact factor: 2.602

6.  Polygonally Meshed Dipole Model Simulation of the Electrical Field Produced by the Stomach and Intestines.

Authors:  Masaki Kawano; Takahiro Emoto
Journal:  Comput Math Methods Med       Date:  2020-10-21       Impact factor: 2.238
  6 in total

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