Everything falls apart: How solids degrade and release nanomaterials, composite fragments, and microplastics

IF 4.7 3区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES NanoImpact Pub Date : 2024-04-01 DOI:10.1016/j.impact.2024.100510
Wendel Wohlleben , Nathan Bossa , Denise M. Mitrano , Keana Scott
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引用次数: 0

Abstract

To ensure the safe use of materials, one must assess the identity and quantity of exposure. Solid materials, such as plastics, metals, coatings and cements, degrade to some extent during their life cycle, and releases can occur during manufacturing, use and end-of-life. Releases (e.g., what is released, how does release happen, and how much material is released) depend on the composition and internal (nano)structures of the material as well as the applied stresses during the lifecycle. We consider, in some depth, releases from mechanical, weathering and thermal stresses and specifically address the use cases of fused-filament 3D printing, dermal contact, food contact and textile washing. Solid materials can release embedded nanomaterials, composite fragments, or micro- and nanoplastics, as well as volatile organics, ions and dissolved organics. The identity of the release is often a heterogenous mixture and requires adapted strategies for sampling and analysis, with suitable quality control measures. Control materials enhance robustness by enabling comparative testing, but reference materials are not always available as yet. The quantity of releases is typically described by time-dependent rates that are modulated by the nature and intensity of the applied stress, the chemical identity of the polymer or other solid matrix, and the chemical identity and compatibility of embedded engineered nanomaterials (ENMs) or other additives. Standardization of methods and the documentation of metadata, including all the above descriptors of the tested material, applied stresses, sampling and analytics, are identified as important needs to advance the field and to generate robust, comparable assessments. In this regard, there are strong methodological synergies between the study of all solid materials, including the study of micro- and nanoplastics. From an outlook perspective, we review the hazard of the released entities, and show how this informs risk assessment. We also address the transfer of methods to related issues such as tyre wear, advanced materials and advanced manufacturing, biodegradable polymers, and non-solid matrices. As the consideration of released entities will become more routine in industry via lifecycle assessment in Safe-and-Sustainable-by-Design practices, release assessments will require careful design of the study with quality controls, the use of agreed-on test materials and standardized methods where these exist and the adoption of clearly defined data reporting practices that enable data reuse, meta-analyses, and comparative studies.

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一切都分崩离析:固体如何降解并释放纳米材料、复合碎片和微塑料。
为确保安全使用材料,我们必须评估接触材料的特性和数量。塑料、金属、涂层和水泥等固体材料在其生命周期中会发生一定程度的降解,在制造、使用和报废过程中可能会发生释放。释放(如释放什么、如何释放以及释放多少材料)取决于材料的成分和内部(纳米)结构以及生命周期中的应用应力。我们深入探讨了机械应力、风化应力和热应力引起的释放,并特别讨论了熔丝三维打印、皮肤接触、食品接触和纺织品洗涤等应用案例。固体材料会释放出嵌入式纳米材料、复合碎片、微塑料和纳米塑料,以及挥发性有机物、离子和溶解性有机物。释放物的特性通常是一种异质混合物,因此需要调整采样和分析策略,并采取适当的质量控制措施。对照材料可以通过比较测试来增强稳健性,但目前还不一定有参考材料。释放量通常由随时间变化的速率来描述,这些速率受施加应力的性质和强度、聚合物或其他固体基质的化学特性以及嵌入的工程纳米材料 (ENM) 或其他添加剂的化学特性和兼容性的影响。方法的标准化和元数据的记录,包括测试材料、施加应力、取样和分析的所有上述描述,被认为是推动该领域发展和产生可靠、可比较评估的重要需求。在这方面,所有固体材料的研究,包括微塑料和纳米塑料的研究,在方法上都有很强的协同作用。从展望的角度来看,我们回顾了释放实体的危害,并说明了这如何为风险评估提供信息。我们还探讨了如何将这些方法应用到轮胎磨损、先进材料和先进制造、生物可降解聚合物和非固体基质等相关问题上。在工业中,通过 "安全与可持续设计 "实践中的生命周期评估,对释放实体的考虑将变得更加常规化,因此释放评估将需要精心设计具有质量控制的研究,使用商定的测试材料和标准化方法(如果有的话),并采用明确定义的数据报告实践,以实现数据重用、荟萃分析和比较研究。
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来源期刊
NanoImpact
NanoImpact Social Sciences-Safety Research
CiteScore
11.00
自引率
6.10%
发文量
69
审稿时长
23 days
期刊介绍: NanoImpact is a multidisciplinary journal that focuses on nanosafety research and areas related to the impacts of manufactured nanomaterials on human and environmental systems and the behavior of nanomaterials in these systems.
期刊最新文献
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