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mPEG-b-PES-b-mPEG-based candidate hemodialysis membrane with enhanced performance in sieving, flux, and hemocompatibility

The efficiency of the hemodialysis membrane has been widely improved by blending small molecular additives and modifying the membrane surface for patients with chronic or acute kidney disease. However, a qualified sieving property, flux, and hemocompatibility are intractable to give consideration si...

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Published in:	Journal of membrane science 2022-09, Vol.657, p.120680, Article 120680
Main Authors:	Ren, Jian, Yang, Xin, Yan, Weixing, Feng, Xia, Zhao, Yiping, Chen, Li
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Language:	English
Subjects:	block copolymer Hemodialysis membrane mPEG-b-PES-b-mPEG Post tailoring
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description	The efficiency of the hemodialysis membrane has been widely improved by blending small molecular additives and modifying the membrane surface for patients with chronic or acute kidney disease. However, a qualified sieving property, flux, and hemocompatibility are intractable to give consideration simultaneously, while the elution of small-molecular additives and modifiers easily cause coagulation, complement activation, etc. Fortunately, the BCP methoxy polyethylene glycol-polyethersulfone-block-methoxy polyethylene glycol (mPEG-b-PES-b-mPEG) based membranes exhibiting great potential for sieving in middle molecular toxin and compatibility between mPEG-b-PES-b-mPEG and PES, is nearly unfeasible elution during hemodialysis, by reason of including bounded hydrophilic segments by chemical bonds. Here, the mPEG-b-PES-b-mPEG is synthesized to fabricate the membranes, including blend membranes and BCP membrane. As a result, the blend membranes have shown an increasing flux, hemocompatibility, and sieving of lysozyme with the increasing cooperation of mPEG-b-PES-b-mPEG, the block copolymer (BCP) mPEG-b-PES-b-mPEG membrane has shown better balance than the blend membranes in flux, sieving, and hemocompatibility. Besides, for exploring further possibilities, the typical blend membrane M4 (mPEG-b-PES-b-mPEG: 20%, PES: 5%) and BCP membrane M5 (mPEG-b-PES-b-mPEG: 25%) are post tailored by ethanol at 50 °C for 2 h. This process leading the typical membranes to an efficient flux (M5-P: 442.22 L m−2 h−1) and sieving performances (M5-P: the urea and lysozyme sieving of 96.43% and 74.97%) due to the effect of ethanol at the micro-molecular chain movements and microspheres transfer. Our work presents BCP mPEG-b-PES-b-mPEG a promising future in hemodialysis membranes according to the superior performances of flux and sieving. [Display omitted] •The BCP membrane exhibited excellent balance in permeability and selectivity.•Post-tailoring facilitates the further permeability and lysozyme sieving.•An increasing hemocompatibility following with the increasing cooperation of BCP.•Post-tailoring promotes the transfer of microsphere as a new phenomenon.
doi_str_mv	10.1016/j.memsci.2022.120680
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However, a qualified sieving property, flux, and hemocompatibility are intractable to give consideration simultaneously, while the elution of small-molecular additives and modifiers easily cause coagulation, complement activation, etc. Fortunately, the BCP methoxy polyethylene glycol-polyethersulfone-block-methoxy polyethylene glycol (mPEG-b-PES-b-mPEG) based membranes exhibiting great potential for sieving in middle molecular toxin and compatibility between mPEG-b-PES-b-mPEG and PES, is nearly unfeasible elution during hemodialysis, by reason of including bounded hydrophilic segments by chemical bonds. Here, the mPEG-b-PES-b-mPEG is synthesized to fabricate the membranes, including blend membranes and BCP membrane. As a result, the blend membranes have shown an increasing flux, hemocompatibility, and sieving of lysozyme with the increasing cooperation of mPEG-b-PES-b-mPEG, the block copolymer (BCP) mPEG-b-PES-b-mPEG membrane has shown better balance than the blend membranes in flux, sieving, and hemocompatibility. Besides, for exploring further possibilities, the typical blend membrane M4 (mPEG-b-PES-b-mPEG: 20%, PES: 5%) and BCP membrane M5 (mPEG-b-PES-b-mPEG: 25%) are post tailored by ethanol at 50 °C for 2 h. This process leading the typical membranes to an efficient flux (M5-P: 442.22 L m−2 h−1) and sieving performances (M5-P: the urea and lysozyme sieving of 96.43% and 74.97%) due to the effect of ethanol at the micro-molecular chain movements and microspheres transfer. Our work presents BCP mPEG-b-PES-b-mPEG a promising future in hemodialysis membranes according to the superior performances of flux and sieving. 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However, a qualified sieving property, flux, and hemocompatibility are intractable to give consideration simultaneously, while the elution of small-molecular additives and modifiers easily cause coagulation, complement activation, etc. Fortunately, the BCP methoxy polyethylene glycol-polyethersulfone-block-methoxy polyethylene glycol (mPEG-b-PES-b-mPEG) based membranes exhibiting great potential for sieving in middle molecular toxin and compatibility between mPEG-b-PES-b-mPEG and PES, is nearly unfeasible elution during hemodialysis, by reason of including bounded hydrophilic segments by chemical bonds. Here, the mPEG-b-PES-b-mPEG is synthesized to fabricate the membranes, including blend membranes and BCP membrane. As a result, the blend membranes have shown an increasing flux, hemocompatibility, and sieving of lysozyme with the increasing cooperation of mPEG-b-PES-b-mPEG, the block copolymer (BCP) mPEG-b-PES-b-mPEG membrane has shown better balance than the blend membranes in flux, sieving, and hemocompatibility. Besides, for exploring further possibilities, the typical blend membrane M4 (mPEG-b-PES-b-mPEG: 20%, PES: 5%) and BCP membrane M5 (mPEG-b-PES-b-mPEG: 25%) are post tailored by ethanol at 50 °C for 2 h. This process leading the typical membranes to an efficient flux (M5-P: 442.22 L m−2 h−1) and sieving performances (M5-P: the urea and lysozyme sieving of 96.43% and 74.97%) due to the effect of ethanol at the micro-molecular chain movements and microspheres transfer. Our work presents BCP mPEG-b-PES-b-mPEG a promising future in hemodialysis membranes according to the superior performances of flux and sieving. [Display omitted] •The BCP membrane exhibited excellent balance in permeability and selectivity.•Post-tailoring facilitates the further permeability and lysozyme sieving.•An increasing hemocompatibility following with the increasing cooperation of BCP.•Post-tailoring promotes the transfer of microsphere as a new phenomenon.</abstract><pub>Elsevier B.V</pub><doi>10.1016/j.memsci.2022.120680</doi></addata></record>
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title	mPEG-b-PES-b-mPEG-based candidate hemodialysis membrane with enhanced performance in sieving, flux, and hemocompatibility
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