# Microenvironment-Engineered Biocatalytic Metal–Organic Framework Nanomotors for Selective and Transformative Water Decontamination

**Authors:** Shu Xu, Jueyi Xue, Linyun Bao, Joel Yong, Ying Cao, Jun Ma, Kang Liang

PMC · DOI: 10.1007/s40820-025-02064-w · 2026-01-26

## TL;DR

Researchers created nanomotors using metal-organic frameworks and enzymes to efficiently and selectively remove pollutants from water.

## Contribution

A novel biocatalytic nanomotor system was developed using MOFs and enzymes, with a tunable microenvironment for enhanced decontamination.

## Key findings

- Nanomotors achieved ~98% bisphenol A removal in 2 minutes through enzymatic transformation.
- Surface engineering with tannic acid improved contaminant preconcentration and catalytic selectivity.
- Etching-induced voids enhanced mass transfer to enzyme active sites, improving efficiency.

## Abstract

Biocatalytic metal–organic framework nanomotors were engineered with tunable microenvironment through a synergistic etching and surface engineering strategy.Enhanced catalytic efficiency and selectivity for dye decontamination were achieved through charge-based enrichment and nanoconfinement effects.Exceptional performance in water remediation of emerging contaminants, e.g., ~ 98% bisphenol A removal, in 2 min was achieved via enzymatic transformation into recoverable products.

Biocatalytic metal–organic framework nanomotors were engineered with tunable microenvironment through a synergistic etching and surface engineering strategy.

Enhanced catalytic efficiency and selectivity for dye decontamination were achieved through charge-based enrichment and nanoconfinement effects.

Exceptional performance in water remediation of emerging contaminants, e.g., ~ 98% bisphenol A removal, in 2 min was achieved via enzymatic transformation into recoverable products.

The online version contains supplementary material available at 10.1007/s40820-025-02064-w.

Catalytically powered micro-/nanomotors have become a compelling alternative to conventional catalysts for active and efficient removal of environmental pollutants in water remediation. We developed a novel biocatalytic nanomotor system by encapsulating catalase and peroxidase enzymes into metal–organic frameworks (MOFs), demonstrating exceptional speed and facilitated motion-induced convection and mass transfer. Leveraging a synergistic structural etching and surface engineering strategy using tannic acid (TA), we create a tailored microenvironment of the MOF’s framework with charge-selective and nanoconfinement properties. Both experimental and simulation results indicate that microenvironment modulation of MOF matrix could act in synergy with the encapsulated enzymes and significantly improve efficiency and selectivity in removing charged pollutants. Surface engineering of TA selectively preconcentrates target contaminants by modulating the MOF shell's surface charge, while etching-induced voids facilitate rapid mass transfer to the enzyme active sites. Finally, we also validated the applicability of these nanomotors in the transformative removal of pollutants from the aqueous phase into polymeric products via an enzyme-mediated polymerization pathway. This biocatalytic nanomotor system provides a promising water remediation paradigm for reducing carbon emissions and recycling chemical energy from emerging contaminants.

The online version contains supplementary material available at 10.1007/s40820-025-02064-w.

## Linked entities

- **Proteins:** Cat (Catalase), peroxidase (peroxidase PPOD1-like)
- **Chemicals:** bisphenol A (PubChem CID 6623), tannic acid (PubChem CID 16129778)

## Full-text entities

- **Genes:** CAT (catalase) [NCBI Gene 847]
- **Chemicals:** TA (-), carbon (MESH:D002244), MOF (MESH:D000073396), Water (MESH:D014867)

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12834862/full.md

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Source: https://tomesphere.com/paper/PMC12834862