Nonlinear Analysis of Renal Autoregulation Under Broadband Forcing Conditions

V Z Marmarelis; K H Chon; Y M Chen; D J Marsh; N H Holstein-Rathlou

Nonlinear Analysis of Renal Autoregulation Under Broadband Forcing Conditions

V Z Marmarelis, K H Chon, Y M Chen, D J Marsh, N H Holstein-Rathlou

Department of Biomedical Sciences

30 Citations (Scopus)

Abstract

Linear analysis of renal blood flow fluctuations, induced experimentally in rats by broad-band (pseudorandom) arterial blood pressure forcing at various power levels, has been unable to explain fully the dynamics of renal autoregulation at low frequencies. This observation has suggested the possibility of nonlinear mechanisms subserving renal autoregulation at frequencies below 0.2 Hz. This paper presents results of 3rd-order Volterra-Wiener analysis that appear to explain adequately the nonlinearities in the pressure-flow relation below 0.2 Hz in rats. The contribution of the 3rd-order kernel in describing the dynamic pressure-flow relation is found to be important. Furthermore, the dependence of 1st-order kernel waveforms on the power level of broadband pressure forcing indicates the presence of nonlinear feedback (of sigmoid type) based on previously reported analysis of a class of nonlinear feedback systems.

Original language	English
Journal	Annals of Biomedical Engineering
Volume	21
Issue number	6
Pages (from-to)	591-603
Number of pages	12
ISSN	0090-6964
Publication status	Published - 1994

Cite this

@article{9d56866074ce11dbbee902004c4f4f50,

title = "Nonlinear Analysis of Renal Autoregulation Under Broadband Forcing Conditions",

abstract = "Linear analysis of renal blood flow fluctuations, induced experimentally in rats by broad-band (pseudorandom) arterial blood pressure forcing at various power levels, has been unable to explain fully the dynamics of renal autoregulation at low frequencies. This observation has suggested the possibility of nonlinear mechanisms subserving renal autoregulation at frequencies below 0.2 Hz. This paper presents results of 3rd-order Volterra-Wiener analysis that appear to explain adequately the nonlinearities in the pressure-flow relation below 0.2 Hz in rats. The contribution of the 3rd-order kernel in describing the dynamic pressure-flow relation is found to be important. Furthermore, the dependence of 1st-order kernel waveforms on the power level of broadband pressure forcing indicates the presence of nonlinear feedback (of sigmoid type) based on previously reported analysis of a class of nonlinear feedback systems.",

author = "Marmarelis, {V Z} and Chon, {K H} and Chen, {Y M} and Marsh, {D J} and Holstein-Rathlou, {N H}",

note = "Keywords: Animals; Blood Pressure; Feedback; Homeostasis; Male; Models, Biological; Nonlinear Dynamics; Rats; Rats, Sprague-Dawley; Renal Circulation",

year = "1994",

language = "English",

volume = "21",

pages = "591--603",

journal = "Annals of Biomedical Engineering",

issn = "0090-6964",

publisher = "Springer",

number = "6",

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TY - JOUR

T1 - Nonlinear Analysis of Renal Autoregulation Under Broadband Forcing Conditions

AU - Marmarelis, V Z

AU - Chon, K H

AU - Chen, Y M

AU - Marsh, D J

AU - Holstein-Rathlou, N H

N1 - Keywords: Animals; Blood Pressure; Feedback; Homeostasis; Male; Models, Biological; Nonlinear Dynamics; Rats; Rats, Sprague-Dawley; Renal Circulation

PY - 1994

Y1 - 1994

N2 - Linear analysis of renal blood flow fluctuations, induced experimentally in rats by broad-band (pseudorandom) arterial blood pressure forcing at various power levels, has been unable to explain fully the dynamics of renal autoregulation at low frequencies. This observation has suggested the possibility of nonlinear mechanisms subserving renal autoregulation at frequencies below 0.2 Hz. This paper presents results of 3rd-order Volterra-Wiener analysis that appear to explain adequately the nonlinearities in the pressure-flow relation below 0.2 Hz in rats. The contribution of the 3rd-order kernel in describing the dynamic pressure-flow relation is found to be important. Furthermore, the dependence of 1st-order kernel waveforms on the power level of broadband pressure forcing indicates the presence of nonlinear feedback (of sigmoid type) based on previously reported analysis of a class of nonlinear feedback systems.

AB - Linear analysis of renal blood flow fluctuations, induced experimentally in rats by broad-band (pseudorandom) arterial blood pressure forcing at various power levels, has been unable to explain fully the dynamics of renal autoregulation at low frequencies. This observation has suggested the possibility of nonlinear mechanisms subserving renal autoregulation at frequencies below 0.2 Hz. This paper presents results of 3rd-order Volterra-Wiener analysis that appear to explain adequately the nonlinearities in the pressure-flow relation below 0.2 Hz in rats. The contribution of the 3rd-order kernel in describing the dynamic pressure-flow relation is found to be important. Furthermore, the dependence of 1st-order kernel waveforms on the power level of broadband pressure forcing indicates the presence of nonlinear feedback (of sigmoid type) based on previously reported analysis of a class of nonlinear feedback systems.

M3 - Journal article

C2 - 8116912

SN - 0090-6964

VL - 21

SP - 591

EP - 603

JO - Annals of Biomedical Engineering

JF - Annals of Biomedical Engineering

IS - 6

ER -

Nonlinear Analysis of Renal Autoregulation Under Broadband Forcing Conditions

Abstract

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