利用含酞菁亚铁的纤维素消除水中的致突变污染物。

IF 2.7 4区 医学 Q2 GENETICS & HEREDITY
Kayoko Sano, Yuka Soga, Kaori Ohta, Yuki Kitamura, Sakae Arimoto-Kobayashi
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引用次数: 0

摘要

背景:我们曾研究过利用含共价结合三异硫铜酞菁的纤维素(蓝棉和蓝人造丝)从水溶液中分离致突变污染物的方法。结构中含有三个或三个以上融合芳香环的致突变污染物被吸附在蓝色棉花和蓝色人造丝上。由于铜酞菁被认为是一种不适合吸收水氯化副产物的配体,如 3-氯-4-(二氯甲基)-5-羟基-2(5H)-呋喃酮(致突变物 X 或 MX),因此我们研究开发了一种新材料,用于消除水溶剂中的 MX:我们选择了含有酞菁亚铁(FePh)的绿色纤维素粉末(以下简称绿色纤维素或 GP)作为候选材料。GP 由阳离子化纤维素(白色纤维素,WP)和四羧酸亚铁组成。经 GP 处理后,溶解在缓冲液或二甲基亚砜(DMSO)溶液中的 MX 的诱变性明显降低。在对同一 GP 重复吸附 70 个循环后,GP 对 MX 从溶剂中去除的作用已接近于耗尽,根据对所得结果的推断,GP 去除 MX 的能力估计在重复吸附 120 个循环后耗尽;因此,GP 上的相互作用配体可能在完全吸附 MX 后达到饱和。溶解在水缓冲液中的 MX 在 pH 值为 7.4 时的诱变性明显降低,而在 pH 值为 4.0 时则没有。由于 MX 在 pH 值为 6 或更高时离解为阴离子形式,因此在 pH 值为 7.4 的缓冲液中,MX 的负电荷可能会与 GP 中亚铁离子的正电荷相互作用,在 MX 和 GP 之间形成连接。GP 吸附 MX 后,诱变性经水或乙腈萃取,并在洗脱液中回收。因此,MX 与 FePh 之间的可逆相互作用可能导致了 MX 在 GP 上的吸附:结论:GP 可用作氯化饮用水中 MX 的新型去除剂和回收剂。开发用于去除和回收检测水中与诱变污染物有关的氯化剂的新材料有利于环境健康。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Elimination of mutagenic contaminants from water using cellulose bearing ferrous-phthalocyanine.

Background: We previously investigated methods for separating mutagenic contaminants from aqueous solutions using cellulose-bearing covalently bound trisulfo-Cu-phthalocyanine (blue cotton and blue rayon). Mutagenic contaminants with three or more fused aromatic rings in their structures were adsorbed onto blue cotton and rayon. Since Cu-phthalocyanine is considered an unsuitable absorption ligand for byproducts of water chlorination, such as 3-chloro-4-(dichloromethyl)-5-hydroxy-2(5H)-furanone (Mutagen X or MX), we investigated the development of a new material for the elimination of MX from aqueous solvents.

Results: We selected green cellulose powder bearing ferrous phthalocyanine (FePh), hereafter referred to as green cellulose or GP, as the candidate material. GP is composed of cationized cellulose (white cellulose, WP) and FePh tetracarboxylic acid. The mutagenicity of MX dissolved in buffer or dimethyl sulfoxide (DMSO) solution significantly decreased after treatment with GP. The effects of GP on the elimination of MX from the solvent were very close to being expired after 70 cycles of repeated adsorption of the same GP, and the capacity of GP for MX removal was estimated to be exhausted after 120 cycles of repeated adsorption based on the extrapolation of the obtained result; thus, the interacting ligands on GP may be saturated after complete MX adsorption. The mutagenicity of MX dissolved in aqueous buffer significantly decreased after treatment at pH7.4 but not at pH 4.0. Since MX is dissociated to be the anionic form at pH 6 or higher, the negative charge of MX in the buffer at pH 7.4 may interact with the positive charge of ferrous ions in GP to create a linkage between MX and GP. After GP adsorbed MX, mutagenicity was extracted with water or acetonitrile and recovered in the eluent. Thus, the reversible interaction between MX and FePh may have caused adsorption of MX onto GP.

Conclusion: GP could be used as a new eliminator and recovery agent for MX in chlorinated drinking water. Developing new materials for the removal and recovery of agents for the detection of mutagenic contaminant-related chlorination in water is beneficial for environmental health.

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来源期刊
Genes and Environment
Genes and Environment Biochemistry, Genetics and Molecular Biology-Genetics
CiteScore
4.00
自引率
0.00%
发文量
24
审稿时长
27 weeks
期刊介绍: Genes and Environment is an open access, peer-reviewed journal that aims to accelerate communications among global scientists working in the field of genes and environment. The journal publishes articles across a broad range of topics including environmental mutagenesis and carcinogenesis, environmental genomics and epigenetics, molecular epidemiology, genetic toxicology and regulatory sciences. Topics published in the journal include, but are not limited to, mutagenesis and anti-mutagenesis in bacteria; genotoxicity in mammalian somatic cells; genotoxicity in germ cells; replication and repair; DNA damage; metabolic activation and inactivation; water and air pollution; ROS, NO and photoactivation; pharmaceuticals and anticancer agents; radiation; endocrine disrupters; indirect mutagenesis; threshold; new techniques for environmental mutagenesis studies; DNA methylation (enzymatic); structure activity relationship; chemoprevention of cancer; regulatory science. Genetic toxicology including risk evaluation for human health, validation studies on testing methods and subjects of guidelines for regulation of chemicals are also within its scope.
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