An analytical model for solute transport from blood to tissue

to related objects

Abstract: For narrow tubes, red blood cells concentrate in the core region, leaving an annular zone called cell-free layer. This has an impact on both the tube hematocrit level (Fåhraeus effect) and the apparent blood viscosity (Fåhraeus–Lindqvist effect). Blood flow, mass transfer across the microvessel membrane, and diffusion in the tissue affect the solute concentration profiles. The Krogh tissue cylinder concept, limiting mass transfer to a cylinder around each microvessel, and the marginal zone concept (introduced by Haynes to analyze blood flow dynamics in narrow tubes) are both used to develop a model for solute transfer from blood in microvessels to the surrounding tissues, based on fundamentals. The analysis accounts for advection and diffusion in each zone of the microvessel, solute transport in the microvessel membranes, and diffusion and reaction in the tissues. The present investigation provides an analytical solution. The approach can be extended to treat other kinetic models, while accounting for Fåhraeus and Fåhraeus–Lindqvist effects in blood microvessels. The model is validated against published results for glucose transport from blood to tissue.

Location
Deutsche Nationalbibliothek Frankfurt am Main
Extent
Online-Ressource
Language
Englisch

Bibliographic citation
An analytical model for solute transport from blood to tissue ; volume:20 ; number:1 ; year:2022 ; pages:249-258 ; extent:10
Open physics ; 20, Heft 1 (2022), 249-258 (gesamt 10)

Creator
Chebbi, Rachid

DOI
10.1515/phys-2022-0026
URN
urn:nbn:de:101:1-2022071515590779381391
Rights
Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
Last update
15.08.2025, 7:33 AM CEST

Data provider

This object is provided by:
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Show original at data provider

Associated

  • Chebbi, Rachid

Other Objects (12)

On the reliability of analytical models to predict solute transport in a fracture network

On the reliability of analytical models to predict solute transport in a fracture network

Oxygen transport in blood and tissue

Oxygen transport in blood and tissue

Process-Dependent Solute Transport in Porous Media

Process-Dependent Solute Transport in Porous Media

Applying fluvial depositional concepts in solute transport modelling

Applying fluvial depositional concepts in solute transport modelling

Scale and structure dependent solute diffusivity within microporous tissue engineering scaffolds

Scale and structure dependent solute diffusivity within microporous tissue engineering scaffolds

Water flow and solute transport in degraded peat soils

Hochschulschrift

Water flow and solute transport in degraded peat soils

Stereoselectivity in Drug Membrane Transport by Solute Carriers (SLCs)

Stereoselectivity in Drug Membrane Transport by Solute Carriers (SLCs)

Feedback-controlled solute transport through chemo-responsive polymer membranes

Feedback-controlled solute transport through chemo-responsive polymer membranes

Effluent Osteopontin levels reflect the peritoneal solute transport rate

Effluent Osteopontin levels reflect the peritoneal solute transport rate

BRD.- Regensburg.- Internationales Symposium "Solute-Solute-Silvent Interactions" (Thermodynamik)

Schriftgut

BRD.- Regensburg.- Internationales Symposium "Solute-Solute-Silvent Interactions" (Thermodynamik)

Solute transport along a single fracture in a porous rock: a simple analytical solution and its extension for modeling velocity dispersion

Solute transport along a single fracture in a porous rock: a simple analytical solution and its extension for modeling velocity dispersion

Structure property relations in polymeric membranes for controlled solute transport

Hochschulschrift

Structure property relations in polymeric membranes for controlled solute transport

Related objects