Past progress in environmental nanoanalysis and a future trajectory for atomic mass-spectrometry methods

IF 4.7 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

NanoImpact Pub Date : 2024-07-01 DOI:10.1016/j.impact.2024.100518

M.D. Montaño , A.J. Goodman , J.F. Ranville

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Abstract

The development of engineered nanotechnology has necessitated a commensurate maturation of nanoanalysis capabilities. Building off a legacy established by electron microscopy and light-scattering, environmental nanoanalysis has now benefited from ongoing advancements in instrumentation and data analysis, which enable a deeper understanding of nanomaterial properties, behavior, and impacts. Where once environmental nanoparticles and colloids were grouped into broad ‘dissolved or particulate’ classes that are dependent on a filter size cut-off, now size distributions of submicron particles can be separated and characterized providing a more comprehensive examination of the nanoscale. Inductively coupled plasma-quadrupole mass spectrometry (ICP-QMS), directly coupled to field flow fractionation (FFF-ICP-QMS) or operated in single particle mode (spICP-MS) have spearheaded a revolution in nanoanalysis, enabling research into nanomaterial behavior in environmental and biological systems at expected release concentrations. However, the complexity of the nanoparticle population drives a need to characterize and quantify the multi-element composition of nanoparticles, which has begun to be realized through the application of time-of-flight MS (spICP-TOFMS). Despite its relative infancy, this technique has begun to make significant strides in more fully characterizing particulate systems and expanding our understanding of nanoparticle behavior. Though there is still more work to be done with regards to improving instrumentation and data processing, it is possible we are on the cusp of a new nanoanalysis revolution, capable of broadening our understanding of the size regime between dissolved and bulk particulate compartments of the environment.

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环境纳米分析的过去进展和原子质量谱仪方法的未来轨迹。

随着工程纳米技术的发展，纳米分析能力也必须相应成熟。在电子显微镜和光散射技术的基础上，环境纳米分析现在已经受益于仪器和数据分析的不断进步，从而能够更深入地了解纳米材料的特性、行为和影响。过去，环境纳米粒子和胶体被归类为 "溶解或微粒 "类别，这些类别取决于过滤器的截留尺寸，而现在，亚微米级粒子的尺寸分布可以被分离和表征，从而对纳米尺度进行更全面的检查。电感耦合等离子体-四极杆质谱法（ICP-QMS）、直接耦合场流分馏法（FFF-ICP-QMS）或单颗粒模式（spICP-MS）在纳米分析领域掀起了一场革命，使纳米材料在预期释放浓度下在环境和生物系统中的行为研究成为可能。然而，纳米粒子群的复杂性促使人们需要对纳米粒子的多元素组成进行表征和量化，这一点已开始通过应用飞行时间质谱（spICP-TOFMS）得以实现。尽管这项技术还处于起步阶段，但它已开始在更全面地表征微粒系统和扩展我们对纳米微粒行为的理解方面取得重大进展。尽管在改进仪器和数据处理方面仍有许多工作要做，但我们有可能正处于一场新的纳米分析革命的风口浪尖上，它能够拓宽我们对环境中溶解和散装微粒之间的粒度体系的理解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

NanoImpact Social Sciences-Safety Research

CiteScore

11.00

自引率

6.10%

发文量

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.