# Nanoparticle Applications in Plant Biotechnology: A Comprehensive Review

**Authors:** Viktor Husak, Milos Faltus, Alois Bilavcik, Stanislav Narozhnyi, Olena Bobrova

PMC · DOI: 10.3390/plants15030364 · Plants · 2026-01-24

## TL;DR

This review explores how nanoparticles are used in plant biotechnology to improve genetic engineering, stress resistance, and cryopreservation, while highlighting the need for standardized protocols and safety assessments.

## Contribution

The paper provides a consolidated framework linking nanoparticle properties to biological outcomes and identifies research priorities for safe and reproducible nanotechnology applications in plant biotechnology.

## Key findings

- Nanoparticles can enhance targeted delivery of biomolecules and improve plant resilience under stress.
- Selected nanomaterials act as effective cryoprotective agents by reducing oxidative injury and improving post-thaw viability.
- NP efficacy is highly dependent on factors like dose, size, surface chemistry, and plant genotype.

## Abstract

Nanotechnology is becoming a key tool in plant biotechnology, enabling nanoparticles (NPs) to deliver biomolecules with high precision and to enhance plant and tissue resilience under stress. However, the literature remains fragmented across genetic delivery, in vitro regeneration, stress mitigation, and germplasm cryopreservation, and it still lacks standardized, comparable protocols and robust long-term safety assessments—particularly for NP use in cryogenic workflows. This review critically integrates recent advances in NP-enabled (i) genetic engineering and transformation, (ii) tissue culture and regeneration, (iii) nanofertilization and abiotic stress mitigation, and (iv) cryopreservation of plant germplasm. Across these areas, the most consistent findings indicate that NPs can facilitate targeted transport of DNA, RNA, proteins, and regulatory complexes; modulate oxidative and osmotic stress responses; and improve regeneration performance in recalcitrant species. In cryopreservation, selected nanomaterials act as multifunctional cryoprotective adjuvants by suppressing oxidative injury, stabilizing cellular membranes, and improving post-thaw viability and regrowth of sensitive tissues. At the same time, NP outcomes are highly context-dependent, with efficacy governed by dose, size, and surface chemistry; formulation; plant genotype; and interactions with culture media or vitrification solutions. Evidence of potential phytotoxicity, persistence, and biosafety risks highlights the need for harmonized reporting, mechanistic studies on NP–cell interfaces, and evaluation of environmental fate. Expected outcomes of this review include a consolidated framework linking NP properties to biological endpoints, identification of design principles for application-specific NP selection, and a set of research priorities to accelerate the safe and reproducible translation of nanotechnology into sustainable plant biotechnology and long-term germplasm preservation.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12899883/full.md

## References

189 references — full list in the complete paper: https://tomesphere.com/paper/PMC12899883/full.md

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Source: https://tomesphere.com/paper/PMC12899883