@article{ab15d4906f584082a6cf3057e845ec33,
title = "Fouling during hemodialysis – Influence of module design and membrane surface chemistry",
abstract = "Hemodialysis acts as an artificial kidney that selectively removes specific toxins, bio-compounds, or fluid from the main blood stream in a patient with kidney failure. The current process uses ultrafiltration-based membrane technology, where a semi-permeable material selectively extracts chemicals, such as uremic retention products, or remove excess water from blood by retaining certain compounds based on their size. As sugars, fats, proteins, biomolecules, cells, and platelets move into and across the tubular membrane in the hemodialysis process, the surface of the membrane begins to foul, which leads to major operational challenges that include sharp pressure drops with increasing operation times. The design of membranes with enhanced biocompatibility and anti-fouling properties is one avenue to increase the lifespan of the membrane used while facilitating the device operation and limiting the stress and discomfort of patients. This review presents interfacial interactions between blood components and membrane materials used in hemodialysis. The discussion analyzes the impacts of the hemodialyzer module design, membrane material morphology and surface chemistry on the long-term operation and performance of the hemodialyzers. Avenues for the development of next-generation-membrane-materials as well as new strategies to enhance the selective removal of toxic compounds from blood are also discussed.",
keywords = "Bio-separation, Biocompatibility, Biofouling, Hemodialysis, Membrane materials",
author = "Bacal, \{Christine Jurene O.\} and Munro, \{Catherine J.\} and Blaise Tardy and Maina, \{James W.\} and Sharp, \{Julie A.\} and Razal, \{Joselito M.\} and Greene, \{George W.\} and Nandurkar, \{Harshal H.\} and Dwyer, \{Karen M.\} and Dum{\'e}e, \{Ludovic F.\}",
note = "Funding Information: Aside from f- MWCNTs, functionalized graphene oxide (GO), such as carboxylated-GO and heparin-immobilized GO, were also explored to improve membrane antifouling performance (Table 4, entries 12 and 14) [132,133,145]. Carboxylated-GO was immobilized on the surface of poly(lactic acid) (PLA) membranes (Table 4, entry 12) [134]. The dopamine-grafted carboxylated-GO (DA-g-GO-COOH) was attached to the PLA membrane surface supporting lower contact angle from 77.4\textbackslash{}u00B0 to 36.2\textbackslash{}u00B0. The surface charge also decreased from \textbackslash{}u221226.6 to \textbackslash{}u221247.7 \textbackslash{}u200BmV, which was attributed to an increased presence of negatively-charged \textbackslash{}u2013COOH groups on DA-g-GO-COOH. Negatively charged platelets and other proteins will therefore be electrostatically repelled by the negative charges coming from DA-g-GO-COOH resulting in less protein adsorption. Heparin-immobilized GO was also incorporated onto poly(etherimide) membranes to reduce membrane fouling (Table 4, entry 13) [132,133] and the water contact angle decreased from \textbackslash{}u223C72.5\textbackslash{}u00B0 to 39\textbackslash{}u00B0 supporting mild decreased plasma protein adsorption from \textbackslash{}u223C33 to 61 \textbackslash{}u200B\% in control membranes to \textbackslash{}u223C25\textbackslash{}u201338 \textbackslash{}u200B\%. Publisher Copyright: {\textcopyright} 2024 The Authors",
year = "2024",
month = jan,
doi = "10.1016/j.advmem.2024.100100",
language = "English",
volume = "4",
journal = "Advanced Membranes",
issn = "2772-8234",
publisher = "KeAi Publishing Communications Ltd.",
}