Aged Microplastics and Antibiotic Resistance Genes: A Review of Aging Effects on Their Interactions.

IF 4.3 2区 医学 Q1 INFECTIOUS DISEASES Antibiotics-Basel Pub Date : 2024-10-06 DOI:10.3390/antibiotics13100941
Kuok Ho Daniel Tang, Ronghua Li
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Abstract

Background: Microplastic aging affects the dynamics of antibiotic resistance genes (ARGs) on microplastics, yet no review presents the effects of microplastic aging on the associated ARGs. Objectives: This review, therefore, aims to discuss the effects of different types of microplastic aging, as well as the other pollutants on or around microplastics and the chemicals leached from microplastics, on the associated ARGs. Results: It highlights that microplastic photoaging generally results in higher sorption of antibiotics and ARGs due to increased microplastic surface area and functional group changes. Photoaging produces reactive oxygen species, facilitating ARG transfer by increasing bacterial cell membrane permeability. Reactive oxygen species can interact with biofilms, suggesting combined effects of microplastic aging on ARGs. The effects of mechanical aging were deduced from studies showing larger microplastics anchoring more ARGs due to rough surfaces. Smaller microplastics from aging penetrate deeper and smaller places and transport ARGs to these places. High temperatures are likely to reduce biofilm mass and ARGs, but the variation of ARGs on microplastics subjected to thermal aging remains unknown due to limited studies. Biotic aging results in biofilm formation on microplastics, and biofilms, often with unique microbial structures, invariably enrich ARGs. Higher oxidative stress promotes ARG transfer in the biofilms due to higher cell membrane permeability. Other environmental pollutants, particularly heavy metals, antibacterial, chlorination by-products, and other functional genes, could increase microplastic-associated ARGs, as do microplastic additives like phthalates and bisphenols. Conclusions: This review provides insights into the environmental fate of co-existing microplastics and ARGs under the influences of aging. Further studies could examine the effects of mechanical and thermal MP aging on their interactions with ARGs.

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老化微塑料与抗生素抗性基因:老化对其相互作用的影响综述。
背景:微塑料老化会影响微塑料上抗生素耐药基因(ARGs)的动态变化,但目前还没有综述介绍微塑料老化对相关 ARGs 的影响。综述的目的:因此,本综述旨在讨论不同类型的微塑料老化、微塑料上或周围的其他污染物以及从微塑料中析出的化学物质对相关 ARGs 的影响。结果:研究结果表明,由于微塑料表面积增大和官能团发生变化,微塑料光老化通常会导致抗生素和 ARGs 的吸附量增加。光老化会产生活性氧,通过增加细菌细胞膜的通透性促进 ARG 的转移。活性氧可与生物膜相互作用,这表明微塑料老化对 ARGs 产生了综合影响。研究表明,较大的微塑料由于表面粗糙,会锚定更多的 ARG,由此推断出机械老化的影响。因老化而变小的微塑料可渗透到更深、更小的地方,并将 ARGs 运送到这些地方。高温可能会减少生物膜质量和 ARGs,但由于研究有限,受热老化的微塑料上 ARGs 的变化情况仍不得而知。生物老化会在微塑料上形成生物膜,而生物膜通常具有独特的微生物结构,必然会富集 ARGs。由于细胞膜渗透性较高,较高的氧化应激会促进 ARG 在生物膜中的转移。其他环境污染物,特别是重金属、抗菌剂、氯化副产物和其他功能基因,以及邻苯二甲酸盐和双酚等微塑料添加剂,都可能增加微塑料相关的 ARGs。结论:本综述有助于深入了解在老化影响下共存的微塑料和 ARGs 的环境归宿。进一步的研究可以探讨机械和热 MP 老化对其与 ARGs 相互作用的影响。
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来源期刊
Antibiotics-Basel
Antibiotics-Basel Pharmacology, Toxicology and Pharmaceutics-General Pharmacology, Toxicology and Pharmaceutics
CiteScore
7.30
自引率
14.60%
发文量
1547
审稿时长
11 weeks
期刊介绍: Antibiotics (ISSN 2079-6382) is an open access, peer reviewed journal on all aspects of antibiotics. Antibiotics is a multi-disciplinary journal encompassing the general fields of biochemistry, chemistry, genetics, microbiology and pharmacology. Our aim is to encourage scientists to publish their experimental and theoretical results in as much detail as possible. Therefore, there is no restriction on the length of papers.
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