# Detection and Fate of Microplastics and Nanoplastics and Technologies for Their Removal

**Authors:** Qiuping Zhang, Qi Wang, Jifei Xu, Jianguo Liu

PMC · DOI: 10.3390/molecules31040613 · 2026-02-10

## TL;DR

This paper reviews how microplastics and nanoplastics are detected, their environmental impact, and methods to remove them.

## Contribution

The paper provides a comprehensive review of detection techniques, environmental fate, and removal strategies for microplastics and nanoplastics.

## Key findings

- Microplastics and nanoplastics persist in the environment and accumulate in biota.
- Various detection methods like FT-IR microscopy and Raman spectroscopy are used for accurate identification.
- Removal strategies include physical, chemical, and biological methods with specific pros and cons.

## Abstract

As primary degradation products of persistent plastic waste, microplastics (MPs, <5 mm) and nanoplastics (NPs, <1 μm) have emerged as a critical global environmental concern, with their ubiquitous distribution documented across aquatic, terrestrial, and atmospheric ecosystems. With annual plastic production exceeding 460 million metric tons, their widespread presence in environmental matrices and biota—from marine organisms to human tissues—poses significant, yet incompletely understood, threats to ecological integrity and public health. This paper systematically reviews the state-of-the-art detection techniques, environmental fate processes, and remediation strategies for MPs and NPs. In terms of detection, we cover microscopy, mass spectrometry, flow cytometry, chromatography, and spectroscopy, emphasizing hyphenated techniques (e.g., FT-IR microscopy, Raman spectroscopy) for enhancing sensitivity and specificity. Fate studies reveal that MPs/NPs exhibit long environmental persistence, undergo bioaccumulation and trophic transfer, and can act as carriers for organic pollutants and heavy metals. Removal techniques include physical (membrane filtration, adsorption), chemical (coagulation, advanced oxidation), and biological (biochar immobilization, microbial degradation) approaches, each with distinct advantages and limitations. This review synthesizes current knowledge gaps and provides a scientific framework for developing integrated management strategies to mitigate plastic pollution risks.

## Full-text entities

- **Diseases:** lung damage (MESH:D008171), cancer (MESH:D009369), injury to (MESH:D014947), inflammation (MESH:D007249), system (MESH:D015619), toxicity (MESH:D064420), respiratory problems (MESH:D012818)
- **Chemicals:** hydroxyl radicals (MESH:D017665), polyurethane foam (MESH:C028279), PE (MESH:D020959), HCl (MESH:D006851), iron oxide (MESH:C000499), water (MESH:D014867), C (MESH:D002244), polymer (MESH:D011108), MOFs (MESH:C040750), O (MESH:D010100), Nile red (MESH:C044808), chitosan (MESH:D048271), metal (MESH:D008670), MP (MESH:D000080545), heavy metals (MESH:D019216), cellulose (MESH:D002482), H (MESH:D006859), THF (MESH:C018674), PP (MESH:D011126), Biochar (MESH:C540010), carbon dioxide (MESH:D002245), titanium dioxide (MESH:C009495), PS (MESH:D011137), PVC (MESH:D011143), Phthalates (MESH:C032279), PBDEs (MESH:D055768), LCHP (-)
- **Species:** Saccharomyces cerevisiae (baker's yeast, species) [taxon 4932], earthworms (species) [taxon 71170], Eisenia fetida (brandling worm, species) [taxon 6396], PX clade (clade) [taxon 569578], Penaeus vannamei (Pacific white shrimp, species) [taxon 6689], Alternaria alternata (species) [taxon 5599], Homo sapiens (human, species) [taxon 9606], Mesoplodon mirus (True's beaked whale, species) [taxon 52113]

## Figures

2 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12943563/full.md

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Source: https://tomesphere.com/paper/PMC12943563