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"Faces" of the day:

Katharina Jandl

Nina Höller

Nariae Baik-Schneditz

Ellen Heitzer

Marianne Brodmann

Ewald Kolesnik

Bernhard Schwaberger

Maximilian Seles

Gabor Toth-Gayor

Lukas Peter Mileder

Niels Hammer

Christian Josef Hill

Christian Viertler

Philipp Klaritsch

Daniel Scherr

Harald Köfeler

Gerhard Pichler

Roland Malli

Michael Fuchsjäger

Gernot Plank

Peter Fickert

Richard Zigeuner

Peter Holzer

Selected Publication:

SHR Neuro Cancer Cardio Lipid Metab Microb

Schneditz, D; Sauseng, N.
Diffusive solute transport in hollow fiber dialyzers is not affected by variable feed viscosity
BIOCYBERN BIOMED ENG. 2022; 42(4): 1112-1122. Doi: 10.1016/j.bbe.2022.09.0030168-8227
Web of Science FullText FullText_MUG

 

Leading authors Med Uni Graz

Schneditz Daniel

Co-authors Med Uni Graz

Sauseng Notburga

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Abstract:

Dialyzer clearance (K) for hemodialysis is usually predicted from the mass transfer area product (K0A) provided in manufacturer data sheets without accounting for elevated feed-viscosity when treating blood. The boundary layer model for mass transport across hollow fiber membranes, however, predicts an increase in mass transfer resistance (1/K0) and a decrease in K with increasing feed-viscosity.The effect of increased feed-side viscosity relative to baseline crystalloid viscosity on small solute K and 1/K0 was therefore examined in commercial high- (HF) and low-flux (LF) dialyzers in lab-bench studies using standard dialysis equipment in the normal operating range. Homogeneous colloid solutions and bovine plasma were used to simulate the range of relative viscosities (grel) and oncotic pressures expected under in-vivo conditions. Internal filtration (IF) was quantified by a mathematical model to obtain diffusive transport characteristics (K', 1/K00).An up to 5-fold increase in grel caused a small increase in K and a small decrease in 1/K0 in HF, but not in LF dialyzers. After correction for a small convective contribution by IF, K' and 1/K00 remained constant in both LF and HF dialyzers.Diffusive transport characteristics of commercial HF and LF dialyzers are independent of variable feed-side viscosity. This suggests an insignificant contribution of the feed-side boundary layer resistance in dialyzers optimized for operation in hemodialysis. Increasing the feed-side viscosity, however, increases the convective component of dialyzer solute transport because of IF. Diffusive dialyzer clearance predicted from the dialyzer K0A is independent of elevated feed-viscosity. (c) 2022 The Author(s). Published by Elsevier B.V. on behalf of Nalecz Institute of Biocybernetics and Biomedical Engineering of the Polish Academy of Sciences. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

Find related publications in this database (Keywords)

Hemodialysis

Transport

Clearance

Viscosity

Diffusivity

Dialyzer

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