Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads

Background: The characterization of the dynamic process of veins walls is essential to understand venous functioning under normal and pathological conditions. However, little work has been done on dynamic venous properties. Aim: To characterize vein compliance (C), viscosity (η), peak-strain (WSt) a...

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Autores principales:	Zócalo, Y., Santana, D.B., Lluberas, S., Armentano, R.L.
Formato:	JOUR
Lenguaje:	English
Materias:	Compliance Damping Energetic Vascular physiology Venous wall Viscosity animal tissue article bioenergy biomechanics blood vessel function cava vein femoral vein jugular vein mechanical stress nonhuman pressure volume curve sheep vein compliance vein diameter vein wall venous circulation viscosity Animals Biomechanics Blood Pressure Blood Volume Femoral Vein Jugular Veins Sheep Vena Cava, Inferior Ovis aries
Acceso en línea:	http://hdl.handle.net/20.500.12110/paper_07169760_v41_n2_p227_Zocalo
Aporte de:	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires

id	todo:paper_07169760_v41_n2_p227_Zocalo
record_format	dspace
spelling	todo:paper_07169760_v41_n2_p227_Zocalo2023-10-03T15:36:19Z Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads Zócalo, Y. Santana, D.B. Lluberas, S. Armentano, R.L. Compliance Damping Energetic Vascular physiology Venous wall Viscosity animal tissue article bioenergy biomechanics blood vessel function cava vein femoral vein jugular vein mechanical stress nonhuman pressure volume curve sheep vein compliance vein diameter vein wall venous circulation viscosity Animals Biomechanics Blood Pressure Blood Volume Compliance Femoral Vein Jugular Veins Sheep Vena Cava, Inferior Viscosity Ovis aries Background: The characterization of the dynamic process of veins walls is essential to understand venous functioning under normal and pathological conditions. However, little work has been done on dynamic venous properties. Aim: To characterize vein compliance (C), viscosity (η), peak-strain (WSt) and dissipated (WD) energy, damping (ξ), and their regional differences in order to evaluate their role in venous functioning during volume-pressure overloads. Methods: In a mock circulation, pressure (P) and diameter (D) of different veins (anterior cava, jugular and femoral; from 7 sheep), were registered during cyclical volume-pressure pulses. From the P-D relationship, C, WSt and ξ (at low and high P-D levels), η and WD were calculated. Results: For each vein there were P-dependent differences in biomechanical, energetics, and damping capability. There were regional-differences in C, η, WSt and WD (p<0.05), but not in ξ. Conclusion: The regional-dependent differences in dynamics and energetics, and regional-similitude in damping could be important to ensure venous functioning during acute overloads. The lower C and higher WSt and WD found in back-limb veins (femoral), commonly submitted to high volume-pressure loads (i.e. during walking), could be considered relevant to ensure adequate venous system functionality and venous wall protection simultaneously. JOUR English info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_07169760_v41_n2_p227_Zocalo
institution	Universidad de Buenos Aires
institution_str	I-28
repository_str	R-134
collection	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
language	English
orig_language_str_mv	English
topic	Compliance Damping Energetic Vascular physiology Venous wall Viscosity animal tissue article bioenergy biomechanics blood vessel function cava vein femoral vein jugular vein mechanical stress nonhuman pressure volume curve sheep vein compliance vein diameter vein wall venous circulation viscosity Animals Biomechanics Blood Pressure Blood Volume Compliance Femoral Vein Jugular Veins Sheep Vena Cava, Inferior Viscosity Ovis aries
spellingShingle	Compliance Damping Energetic Vascular physiology Venous wall Viscosity animal tissue article bioenergy biomechanics blood vessel function cava vein femoral vein jugular vein mechanical stress nonhuman pressure volume curve sheep vein compliance vein diameter vein wall venous circulation viscosity Animals Biomechanics Blood Pressure Blood Volume Compliance Femoral Vein Jugular Veins Sheep Vena Cava, Inferior Viscosity Ovis aries Zócalo, Y. Santana, D.B. Lluberas, S. Armentano, R.L. Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads
topic_facet	Compliance Damping Energetic Vascular physiology Venous wall Viscosity animal tissue article bioenergy biomechanics blood vessel function cava vein femoral vein jugular vein mechanical stress nonhuman pressure volume curve sheep vein compliance vein diameter vein wall venous circulation viscosity Animals Biomechanics Blood Pressure Blood Volume Compliance Femoral Vein Jugular Veins Sheep Vena Cava, Inferior Viscosity Ovis aries
description	Background: The characterization of the dynamic process of veins walls is essential to understand venous functioning under normal and pathological conditions. However, little work has been done on dynamic venous properties. Aim: To characterize vein compliance (C), viscosity (η), peak-strain (WSt) and dissipated (WD) energy, damping (ξ), and their regional differences in order to evaluate their role in venous functioning during volume-pressure overloads. Methods: In a mock circulation, pressure (P) and diameter (D) of different veins (anterior cava, jugular and femoral; from 7 sheep), were registered during cyclical volume-pressure pulses. From the P-D relationship, C, WSt and ξ (at low and high P-D levels), η and WD were calculated. Results: For each vein there were P-dependent differences in biomechanical, energetics, and damping capability. There were regional-differences in C, η, WSt and WD (p<0.05), but not in ξ. Conclusion: The regional-dependent differences in dynamics and energetics, and regional-similitude in damping could be important to ensure venous functioning during acute overloads. The lower C and higher WSt and WD found in back-limb veins (femoral), commonly submitted to high volume-pressure loads (i.e. during walking), could be considered relevant to ensure adequate venous system functionality and venous wall protection simultaneously.
format	JOUR
author	Zócalo, Y. Santana, D.B. Lluberas, S. Armentano, R.L.
author_facet	Zócalo, Y. Santana, D.B. Lluberas, S. Armentano, R.L.
author_sort	Zócalo, Y.
title	Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads
title_short	Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads
title_full	Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads
title_fullStr	Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads
title_full_unstemmed	Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads
title_sort	regional differences in veins wall viscosity, compliance, energetics and damping: analysis of the pressure-diameter relationship during cyclical overloads
url	http://hdl.handle.net/20.500.12110/paper_07169760_v41_n2_p227_Zocalo
work_keys_str_mv	AT zocaloy regionaldifferencesinveinswallviscositycomplianceenergeticsanddampinganalysisofthepressurediameterrelationshipduringcyclicaloverloads AT santanadb regionaldifferencesinveinswallviscositycomplianceenergeticsanddampinganalysisofthepressurediameterrelationshipduringcyclicaloverloads AT lluberass regionaldifferencesinveinswallviscositycomplianceenergeticsanddampinganalysisofthepressurediameterrelationshipduringcyclicaloverloads AT armentanorl regionaldifferencesinveinswallviscositycomplianceenergeticsanddampinganalysisofthepressurediameterrelationshipduringcyclicaloverloads
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Regional differences in veins wall viscosity, compliance, energetics and damping: Analysis of the pressure-diameter relationship during cyclical overloads

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