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Complexity-based analysis of microvascular blood flow in human skin

Complexity-based analysis of microvascular blood flow in human skin
Complexity-based analysis of microvascular blood flow in human skin

The maintenance of an adequate microvascular perfusion sufficient to meet the metabolic demands of the tissue is dependent on neural, humoral and local vaso-mechanisms that determine vascular tone and blood flow patterns within a microvascular network. It has been argued that attenuation of these flow patterns may be a major contributor to disease risk. Thus, quantitative information on the in vivo spatio-temporal behaviour of microvascular perfusion is important if we are to understand network functionality and flexibility in cardiovascular disease. Time and frequency-domain analysis has been extensively used to describe the dynamic characteristics of Laser Doppler flowmetry (LDF) signals obtained from superficial microvascular networks such as that of the skin. However, neither approach has provided definitive and consistent information on the relative contribution of the oscillatory components of flowmotion (endothelial, neurogenic, myogenic, respiratory and cardiac) to a sustained and adequate microvascular perfusion; nor advance our understanding of how such processes are collectively modified in disease. More recently, non-linear complexity-based approaches have begun to yield evidence of a declining adaptability of microvascular flow patterns as disease severity increases. In this chapter we review the utility and application of these approaches for the quantitative, mechanistic exploration of microvascular (dys)function.

1860-0832
291-310
Springer Cham
Thanaj, Marjola
fb9baacc-4255-483d-8efa-e4fa983a9b2f
Chipperfield, Andrew J.
524269cd-5f30-4356-92d4-891c14c09340
Clough, Geraldine F.
9f19639e-a929-4976-ac35-259f9011c494
Stefanovska, Aneta
McClintock, Peter V.E.
Thanaj, Marjola
fb9baacc-4255-483d-8efa-e4fa983a9b2f
Chipperfield, Andrew J.
524269cd-5f30-4356-92d4-891c14c09340
Clough, Geraldine F.
9f19639e-a929-4976-ac35-259f9011c494
Stefanovska, Aneta
McClintock, Peter V.E.

Thanaj, Marjola, Chipperfield, Andrew J. and Clough, Geraldine F. (2021) Complexity-based analysis of microvascular blood flow in human skin. In, Stefanovska, Aneta and McClintock, Peter V.E. (eds.) Understanding Complex Systems. (Understanding Complex Systems) Springer Cham, pp. 291-310. (doi:10.1007/978-3-030-59805-1_19).

Record type: Book Section

Abstract

The maintenance of an adequate microvascular perfusion sufficient to meet the metabolic demands of the tissue is dependent on neural, humoral and local vaso-mechanisms that determine vascular tone and blood flow patterns within a microvascular network. It has been argued that attenuation of these flow patterns may be a major contributor to disease risk. Thus, quantitative information on the in vivo spatio-temporal behaviour of microvascular perfusion is important if we are to understand network functionality and flexibility in cardiovascular disease. Time and frequency-domain analysis has been extensively used to describe the dynamic characteristics of Laser Doppler flowmetry (LDF) signals obtained from superficial microvascular networks such as that of the skin. However, neither approach has provided definitive and consistent information on the relative contribution of the oscillatory components of flowmotion (endothelial, neurogenic, myogenic, respiratory and cardiac) to a sustained and adequate microvascular perfusion; nor advance our understanding of how such processes are collectively modified in disease. More recently, non-linear complexity-based approaches have begun to yield evidence of a declining adaptability of microvascular flow patterns as disease severity increases. In this chapter we review the utility and application of these approaches for the quantitative, mechanistic exploration of microvascular (dys)function.

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Published date: 6 May 2021
Additional Information: Publisher Copyright: © 2021, Springer Nature Switzerland AG.

Identifiers

Local EPrints ID: 468331
URI: http://eprints.soton.ac.uk/id/eprint/468331
DOI: doi:10.1007/978-3-030-59805-1_19
ISSN: 1860-0832
PURE UUID: 6c65b7de-e92c-4437-ad44-a2de92d20e73
ORCID for Marjola Thanaj: ORCID iD orcid.org/0000-0002-1789-7112
ORCID for Andrew J. Chipperfield: ORCID iD orcid.org/0000-0002-3026-9890
ORCID for Geraldine F. Clough: ORCID iD orcid.org/0000-0002-6226-8964

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Date deposited: 10 Aug 2022 18:10
Last modified: 17 Mar 2024 02:56

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Contributors

Author: Marjola Thanaj ORCID iD
Author: Andrew J. Chipperfield ORCID iD
Author: Geraldine F. Clough ORCID iD
Editor: Aneta Stefanovska
Editor: Peter V.E. McClintock

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