Taher Y. El-Sharkawy

Electrophysiologic control of motility in the human colon

Characteristics of electrical activities, and the relationship between electrical and motor activities, were studied in circular and longitudinal (taenia) muscle of the human colon that was obtained from 21 individuals. Recordings were obtained with suction electrodes, the sucrose-gap method, and microelectrodes. The circular muscle electrical activity consisted of oscillatory activity of relatively low amplitude, with a frequency range from 4.5 to 60 cycle/min. Spiking activity was present on most oscillations. Contractile activity was associated with individual oscillations at frequencies below 12 cycle/min. Contractions related to periods of oscillations at frequencies above 12 cycle/min showed summation resulting in prolonged contractions. In these periods, oscillations were either of relatively high amplitude, or had superimposed spiking activity. Longitudinal muscle activity consisted of slow electrical oscillations at frequencies between 24 and 36 cycle/min with spiking activity superimposed on most oscillations. Contractions were related to bursts of such activity. These findings provide the electrophysiologic basis for short and prolonged phasic contractions and for sustained contractions of the human colon muscle layers. Activities in both muscle layers were myogenic in nature, were very sensitive to stretch, and could be initiated or modulated by nervous activity.

On a Population of Labile Synthesized Relaxation Oscillators

A labile synthesized relaxation oscillator (SRO), exhibiting rhythmic activity when excited by an appropriate stimulus, is proposed. Such an oscillator can be used to represent a stimulus-dependent (or labile) biological rhythm. A population of coupled labile SROs is investigated and its generic equation is presented. The relationship between an input stimulus and an output rhythmic activity of an SRO is described in a computer-simulated example. Also, a tubular structure of nine coupled labile SROs exhibiting apparently propagating bursts of rhythmic activity is simulated.

Interaction of coupled nonlinear oscillators having different intrinsic resting levels

The interaction among coupled oscillators is governed by oscillator properties (intrinsic frequency and amplitude) and coupling mechanisms. This study considers another oscillator property, the intrinsic resting level, and evaluates its role in governing oscillator interactions. The results of computer experiments on a chain of either three or five bidirectionally coupled nonlinear oscillators, suggest that an intrinsic resting level gradient, if present, is one of the factors governing the interaction between coupled oscillators. If there is no intrinsic frequency gradient, then an intrinsic resting level gradient is sufficient to produce many features of interaction among coupled oscillators. If both intrinsic frequency and intrinsic resting level gradients are present, then both of them determine the manner in which the coupled oscillators interact with each other.