Hemodialysis raises oxidative stress through carbon-centered radicals despite improved biocompatibility

Leukocyte activation and the resulting oxidative stress induced by bioincompatible materials during hemodialysis impact the prognosis of patients. Despite multiple advances in hemodialysis dialyzers, the prognosis of hemodialysis patients with complications deeply related to oxidative stress, such a...

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Veröffentlicht in:	Journal of Clinical Biochemistry and Nutrition 2021, Vol.69(1), pp.44-51
Hauptverfasser:	Hirayama, Aki, Akazaki, Satomi, Nagano, Yumiko, Ueda, Atsushi, Lee, Masaichi Chang-il, Aoyagi, Kazumasa, Oowada, Shigeru, Sato, Keizo
Format:	Artikel
Sprache:	eng
Schlagworte:	alkyl peroxyl radical Biocompatibility Carbon Cell activation Diabetes Diabetes mellitus Dialysis Dialyzers Electron paramagnetic resonance Electron spin Electron spin resonance Hemodialysis Hydroxyl radicals i-STrap Leukocytes Lipophilic Lipophilicity MULTIS Original Oxidative stress Oxygen Peroxyl radicals Polysulfone Polysulfone resins Prognosis Radicals Reactive oxygen species Scavenging Spin resonance
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creator	Hirayama, Aki Akazaki, Satomi Nagano, Yumiko Ueda, Atsushi Lee, Masaichi Chang-il Aoyagi, Kazumasa Oowada, Shigeru Sato, Keizo
description	Leukocyte activation and the resulting oxidative stress induced by bioincompatible materials during hemodialysis impact the prognosis of patients. Despite multiple advances in hemodialysis dialyzers, the prognosis of hemodialysis patients with complications deeply related to oxidative stress, such as diabetes mellitus, remains poor. Thus, we re-evaluated the effects of hemodialysis on multiple reactive oxygen species using electron spin resonance-based methods for further improvement of biocompatibility in hemodialysis. We enrolled 31 patients in a stable condition undergoing hemodialysis using high-flux polysulfone dialyzers. The effects of hemodialysis on reactive oxygen species were evaluated by two methods: MULTIS, which evaluates serum scavenging activities against multiple hydrophilic reactive oxygen species, and i-STrap, which detects lipophilic carbon-center radicals. Similar to previous studies, we found that serum hydroxyl radical scavenging activity significantly improved after hemodialysis. Unlike previous studies, we discovered that scavenging activity against alkoxyl radical was significantly reduced after hemodialysis. Moreover, patients with diabetes mellitus showed a decrease in serum scavenging activity against alkyl peroxyl radicals and an increase in lipophilic carbon-center radicals after hemodialysis. These results suggest that despite extensive improvements in dialyzer membranes, the forms of reactive oxygen species that can be eliminated during dialysis are limited, and multiple reactive oxygen species still remain at increased levels during hemodialysis.
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Despite multiple advances in hemodialysis dialyzers, the prognosis of hemodialysis patients with complications deeply related to oxidative stress, such as diabetes mellitus, remains poor. Thus, we re-evaluated the effects of hemodialysis on multiple reactive oxygen species using electron spin resonance-based methods for further improvement of biocompatibility in hemodialysis. We enrolled 31 patients in a stable condition undergoing hemodialysis using high-flux polysulfone dialyzers. The effects of hemodialysis on reactive oxygen species were evaluated by two methods: MULTIS, which evaluates serum scavenging activities against multiple hydrophilic reactive oxygen species, and i-STrap, which detects lipophilic carbon-center radicals. Similar to previous studies, we found that serum hydroxyl radical scavenging activity significantly improved after hemodialysis. Unlike previous studies, we discovered that scavenging activity against alkoxyl radical was significantly reduced after hemodialysis. Moreover, patients with diabetes mellitus showed a decrease in serum scavenging activity against alkyl peroxyl radicals and an increase in lipophilic carbon-center radicals after hemodialysis. These results suggest that despite extensive improvements in dialyzer membranes, the forms of reactive oxygen species that can be eliminated during dialysis are limited, and multiple reactive oxygen species still remain at increased levels during hemodialysis.</description><identifier>ISSN: 0912-0009</identifier><identifier>EISSN: 1880-5086</identifier><identifier>DOI: 10.3164/jcbn.20-141</identifier><identifier>PMID: 34376913</identifier><language>eng</language><publisher>Japan: SOCIETY FOR FREE RADICAL RESEARCH JAPAN</publisher><subject>alkyl peroxyl radical ; Biocompatibility ; Carbon ; Cell activation ; Diabetes ; Diabetes mellitus ; Dialysis ; Dialyzers ; Electron paramagnetic resonance ; Electron spin ; Electron spin resonance ; Hemodialysis ; Hydroxyl radicals ; i-STrap ; Leukocytes ; Lipophilic ; Lipophilicity ; MULTIS ; Original ; Oxidative stress ; Oxygen ; Peroxyl radicals ; Polysulfone ; Polysulfone resins ; Prognosis ; Radicals ; Reactive oxygen species ; Scavenging ; Spin resonance</subject><ispartof>Journal of Clinical Biochemistry and Nutrition, 2021, Vol.69(1), pp.44-51</ispartof><rights>2021 JCBN</rights><rights>Copyright © 2021 JCBN.</rights><rights>2021. 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Clin. Biochem. Nutr.</addtitle><description>Leukocyte activation and the resulting oxidative stress induced by bioincompatible materials during hemodialysis impact the prognosis of patients. Despite multiple advances in hemodialysis dialyzers, the prognosis of hemodialysis patients with complications deeply related to oxidative stress, such as diabetes mellitus, remains poor. Thus, we re-evaluated the effects of hemodialysis on multiple reactive oxygen species using electron spin resonance-based methods for further improvement of biocompatibility in hemodialysis. We enrolled 31 patients in a stable condition undergoing hemodialysis using high-flux polysulfone dialyzers. The effects of hemodialysis on reactive oxygen species were evaluated by two methods: MULTIS, which evaluates serum scavenging activities against multiple hydrophilic reactive oxygen species, and i-STrap, which detects lipophilic carbon-center radicals. Similar to previous studies, we found that serum hydroxyl radical scavenging activity significantly improved after hemodialysis. Unlike previous studies, we discovered that scavenging activity against alkoxyl radical was significantly reduced after hemodialysis. Moreover, patients with diabetes mellitus showed a decrease in serum scavenging activity against alkyl peroxyl radicals and an increase in lipophilic carbon-center radicals after hemodialysis. 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subjects	alkyl peroxyl radical Biocompatibility Carbon Cell activation Diabetes Diabetes mellitus Dialysis Dialyzers Electron paramagnetic resonance Electron spin Electron spin resonance Hemodialysis Hydroxyl radicals i-STrap Leukocytes Lipophilic Lipophilicity MULTIS Original Oxidative stress Oxygen Peroxyl radicals Polysulfone Polysulfone resins Prognosis Radicals Reactive oxygen species Scavenging Spin resonance
title	Hemodialysis raises oxidative stress through carbon-centered radicals despite improved biocompatibility
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