# The First Review on Nano‐Agricultural Applications of MXene and MBene‐Based Materials for Plant‐Immunoengineering, Controlled Protection, and Inducing Biostimulation Mechanisms

**Authors:** Alireza Rafieerad, Ahmad Amiri, Maik Böhmer, Soofia Khanahmadi

PMC · DOI: 10.1002/adma.202510350 · Advanced Materials (Deerfield Beach, Fla.) · 2025-10-16

## TL;DR

This paper reviews how MXene and MBene nanomaterials can improve plant growth and immunity while reducing agrochemical use.

## Contribution

The paper provides the first comprehensive review of MXene and MBene-based materials in nano-agriculture, focusing on plant immunoengineering and biostimulation.

## Key findings

- MXene and MBene materials enhance plant growth and stress resistance through targeted delivery and sustained release.
- These nanomaterials can act as sustainable carriers for agrochemicals, reducing their environmental impact.
- They show biocompatibility and can modulate plant immunity and phytohormone regulation.

## Abstract

Producing quality food crops with a focus on climate and environmental improvement policies has become central to modern farming and sustainability strategies. However, the rising world population and food demand have region‐dependently pushed these boundaries to the overuse of agrochemical inputs. These include plant antimicrobials, pesticides, and soil fertilizers, applied to boost crop yields, reaching a critical juncture. The reliance on agrochemicals has been proven effective in priming, plant growth, and enhancing defense/resistance to biotic stressors, such as phytopathogens and invasive organisms, as well as abiotic pressures, including heat, drought, salinity, and light stress, by increasing nutrient absorption and innate immunity or adaptive stress resistance. However, increasing concerns about the safety, cost, and environmental impact of agrochemicals have intensified the necessity for applying sustainable precision technologies. Nano‐agriculture has introduced emerging possibilities for utilizing low‐dimensional biomaterials for plant protection/stimulation applications, once these technologies are proven safe. Among them, carbon‐based MXenes and derivatives (MBenes) show potential due to their high surface‐to‐volume area, biocompatibility at controlled doses, and tunable physicochemical/biological properties. These unique specifications support targeted delivery and sustained release, while also enhancing plant growth and stress tolerance. This comprehensive review covers their effect on seed germination, seedling maturation, plant‐immunoengineering, priming, eliciting, stomatal closure, antimicrobial actions, and gene or phytohormone regulation. It also discusses their role as sustainable carriers for the delivery and release of agrochemicals and plant protection by nano‐design, aiming to reduce agrochemical consumption. Lastly, we discuss the current environmental regulations for nanomaterials and recommend rational outlooks for future work.

MXene and MBene nanomaterials show significant potential in addressing critical challenges in biomedicine, applied biology, agriculture, and the environment. From a nano‐agricultural perspective, this relatively young field has witnessed emerging advances towards applications for plant‐immunoengineering, biostimulation, and controlled delivery/sustained release of agrochemicals. These strategies encompass the design, fabrication, surface modification, and post‐functionalization of MXene/MBene‐based biomaterials, enabling the enhancement of plant defense mechanisms against biotic/abiotic stresses, as well as the promotion of growth for high‐yield production to reduce the reliance on agrochemical inputs and alleviate their risks to human health and the environment. This innovative review presents comprehensive discussions on the proposed mechanisms, modes of action, biocompatibility, and future outlooks.

## Full-text entities

- **Chemicals:** carbon (MESH:D002244), MXene (MESH:C000723374), MBene (-)

## Full text

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## Figures

28 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12822536/full.md

## References

131 references — full list in the complete paper: https://tomesphere.com/paper/PMC12822536/full.md

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Source: https://tomesphere.com/paper/PMC12822536