Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling

Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling

The major aim of this work was to understand and estimate the evolution of the membrane selectivity of neutral solutes after the filtration of protein or amino acid solutions. Classical methodologies led to the estimation of the mean pore radius, different for each filtrated neutral solute. The use...

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Main Authors: Simona M. Miron, Patrick Dutournié, Arnaud Ponche
Format: Article
Language:English
Published: MDPI AG 2019-10-01
Series:Water
Subjects:
protein adsorption
neutral solute
ultrafiltration
selectivity modelling
pore size distribution
Online Access:https://www.mdpi.com/2073-4441/11/10/2173
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spelling doaj-079f27cfd6c34df8b155f23321b5ef702020-11-25T00:04:25ZengMDPI AGWater2073-44412019-10-011110217310.3390/w11102173w11102173Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption ModellingSimona M. Miron0Patrick Dutournié1Arnaud Ponche2Institut de Science des Matériaux de Mulhouse IS2M (UMR CNRS 7228), Université de Haute Alsace, 68100 Mulhouse, FranceInstitut de Science des Matériaux de Mulhouse IS2M (UMR CNRS 7228), Université de Haute Alsace, 68100 Mulhouse, FranceInstitut de Science des Matériaux de Mulhouse IS2M (UMR CNRS 7228), Université de Haute Alsace, 68100 Mulhouse, FranceThe major aim of this work was to understand and estimate the evolution of the membrane selectivity of neutral solutes after the filtration of protein or amino acid solutions. Classical methodologies led to the estimation of the mean pore radius, different for each filtrated neutral solute. The use of pore size distribution from nitrogen adsorption/desorption experiments enabled a good description of hydraulic and selectivity performances. The modification of the membrane hydraulic properties after the successive filtration of protein solutions revealed that the decrease is quasi linear, the same for all the studied membranes and independent of prior tests. According to the experimental observations, an adsorption model was developed, considering a layer by layer adsorption in the larger pores of the membrane. The predictive obtained results are in good agreement with the experimental rejection rates, validating the assumptions.https://www.mdpi.com/2073-4441/11/10/2173protein adsorptionneutral soluteultrafiltrationselectivity modellingpore size distribution
collection DOAJ
language English
format Article
sources DOAJ
author Simona M. Miron
Patrick Dutournié
Arnaud Ponche
spellingShingle Simona M. Miron
Patrick Dutournié
Arnaud Ponche
Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling
Water
protein adsorption
neutral solute
ultrafiltration
selectivity modelling
pore size distribution
author_facet Simona M. Miron
Patrick Dutournié
Arnaud Ponche
author_sort Simona M. Miron
title Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling
title_short Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling
title_full Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling
title_fullStr Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling
title_full_unstemmed Filtration of Uncharged Solutes: An Assessment of Steric Effect by Transport and Adsorption Modelling
title_sort filtration of uncharged solutes: an assessment of steric effect by transport and adsorption modelling
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2019-10-01
description The major aim of this work was to understand and estimate the evolution of the membrane selectivity of neutral solutes after the filtration of protein or amino acid solutions. Classical methodologies led to the estimation of the mean pore radius, different for each filtrated neutral solute. The use of pore size distribution from nitrogen adsorption/desorption experiments enabled a good description of hydraulic and selectivity performances. The modification of the membrane hydraulic properties after the successive filtration of protein solutions revealed that the decrease is quasi linear, the same for all the studied membranes and independent of prior tests. According to the experimental observations, an adsorption model was developed, considering a layer by layer adsorption in the larger pores of the membrane. The predictive obtained results are in good agreement with the experimental rejection rates, validating the assumptions.
topic protein adsorption
neutral solute
ultrafiltration
selectivity modelling
pore size distribution
url https://www.mdpi.com/2073-4441/11/10/2173
work_keys_str_mv AT simonammiron filtrationofunchargedsolutesanassessmentofstericeffectbytransportandadsorptionmodelling
AT patrickdutournie filtrationofunchargedsolutesanassessmentofstericeffectbytransportandadsorptionmodelling
AT arnaudponche filtrationofunchargedsolutesanassessmentofstericeffectbytransportandadsorptionmodelling
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