Mathematical model of the changes in heart rate elicited by vagal stimulation.

Dexter, Franklin; Levy, Matthew N.; Rudy, Yoram

doi:10.1161/01.res.65.5.1330

Cited by 40 publications

(23 citation statements)

References 34 publications

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“…We based this study on the assumption that the relationship between cardiac cycle duration and VNS frequency can be approximated to be linearly proportional over a given range of frequencies, based on earlier reports [10,13,27]. In previous cardiac VNS studies, stimulation frequencies were either low (5-10 Hz) [4,13,36] or high [21,23,27].…”

Section: Control Parametersmentioning

confidence: 99%

Closed-loop control of the heart rate by electrical stimulation of the vagus nerve

et al. 2006

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Stimulation of the vagus nerve potentially decreases the risk of sudden cardiac death. An improvement of the technique would be its regulation using the heart rate (HR) as a feedback variable. We address the possibility of closed-loop control of the HR, focusing on the stimulation parameters, nerve fibre populations and the reproducibility of the cardiovascular response. The response to electrical stimulation of the vagus nerve was studied in seven acute experiments on pigs. Feedback regulation of the HR over periods of 5 min was carried out. Three main populations of myelinated fibres were found. The performance of the controller was significantly better at amplitudes higher than those needed for stimulation of the myelinated components only. A 18% change in the duration of the RR interval could be controlled in all experiments. The possibility of closed-loop control of the HR seems to be promising.

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Section: Control Parametersmentioning

confidence: 99%

Closed-loop control of the heart rate by electrical stimulation of the vagus nerve

et al. 2006

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“…[1][2][3][4][5][6][7][8][9][10][11]14 The AA of the PRC for the chronotropic response denotes the overall responsiveness of the automatic cells to vagal stimulation, regardless of the timing of those stimuli within the cardiac cycle. The amplitude of the PRC defines the range of AA intervals over which the automatic cells can be entrained in a 1:1 ratio by free-running, repetitive bursts of vagal stimuli",2; free-running stimuli are those that are not intentionally delivered at preset times in the cardiac cycle.…”

Section: Automatic Cell Entrainmentmentioning

confidence: 99%

“…6,8,9 In the single cell, as the timing of the vagal stimulus is gradually shifted on successive cycles from just after to just before a critical time in its activity cycle, the chronotropic response abruptly changes from its minimum to its maximum value.6'8-11 The critical time precedes the beginning of the upstroke of the pacemaker action potential by an interval equal to the latent period for the released acetylcholine (ACh) to increase the potassium conductance of the cell membrane.6-11 A vagal stimulus delivered just after the critical time will be too late to delay the next expected action potential, and the chronotropic response to that stimulus will be minimal. Conversely, a vagal stimulus delivered just before the critical time will delay the next expected action potential, and the chronotropic response will be maximal.…”

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confidence: 99%

Effects of the spatial dispersion of acetylcholine release on the chronotropic responses to vagal stimulation in dogs.

Yang

Cheng

Levy

1990

Circulation Research

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We determined the effects of changing the spatial dispersion of acetylcholine release on the phase-dependent chronotropic responses to vagal stimulation in anesthetized dogs. We stimulated the vagus nerves with one brief burst of electrical pulses each cardiac cycle, and we changed the timing of the stimulus by a small, constant amount each cardiac cycle to scan the entire cycle. To vary the heterogeneity of acetylcholine release, we changed the voltage of the stimulus pulses over a range of submaximal values. To achieve the maximum homogeneity of acetylcholine release, we used supramaximal voltages, and we varied the level of acetylcholine release from each excited fiber by changing the number of pulses per burst. We used the average cardiac cycle length of the phase-response curve to assess the overall vagal effect, independent of its timing within the cardiac cycle. We found that the amplitude of the phase-response curve varied directly and the minimum-to-maximum phase difference varied inversely with the overall efficacy of vagal activity. However, for any given alteration in the overall efficacy, the specific changes in the characteristics of the phase-response curve did not depend on whether the alteration was achieved by varying the number of pulses per burst or by varying the stimulus voltage. Therefore, we conclude that although the cardiac chronotropic response is very sensitive to changes in the timing of vagal stimulation, it is not influenced appreciably by the spatial dispersion of acetylcholine release from the vagal nerve endings over a wide range of stimulation strengths.

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“…Dexter et al 13,14 modelled SAN pacemaker activity using six ion channels, including an acetylcholine-activated potassium current activated by vagal stimulation. Michaels et al 15,16 extended this model to predict phase response curves from triphasic responses to vagal stimulation of isolated cat and rabbit sinoatrial node tissue preparations.…”

Section: Introductionmentioning

confidence: 99%

Vagal entrainment of heart rate is simulated by an integrator with feedback

Bath

Cloherty

Dokos

et al. 2001

Australas. Phys. & Eng. Sci. Med.

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Paradoxical stable entrainment of heart rate to inhibitory vagal impulses can be simulated with two distinct mathematical models; a complex ionic current model of sinoatrial node pacemaker activity, as well as a simple integrator with non-linear feedback. We show that both models exhibit similar entrainment characteristics to repetitive vagal stimuli. By applying a sharp disturbance to each model whilst entrained, the subsequent path of cycle length recovery can be described by dynamic phase response curves and phase-phase plots, the properties of which dictate whether stable entrainment is possible.

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Mathematical model of the changes in heart rate elicited by vagal stimulation.

Cited by 40 publications

References 34 publications

Closed-loop control of the heart rate by electrical stimulation of the vagus nerve

Closed-loop control of the heart rate by electrical stimulation of the vagus nerve

Effects of the spatial dispersion of acetylcholine release on the chronotropic responses to vagal stimulation in dogs.

Vagal entrainment of heart rate is simulated by an integrator with feedback

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