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. 2025 Feb 7;23(1):90.
doi: 10.1186/s12951-025-03113-7.

A systematic review of nanocarriers used in medicine and beyond - definition and categorization framework

Affiliations

A systematic review of nanocarriers used in medicine and beyond - definition and categorization framework

Sabine Gressler et al. J Nanobiotechnology. .

Abstract

Nanocarriers are transport and encapsulation systems that primarily serve to protect and improve the dispersibility of predominantly hydrophobic active ingredients but also enable their targeted delivery and controlled release at the site of action. Nanocarriers are mainly made of either organic or inorganic materials, but various combinations of materials in complex structures are also under development. Most nanocarriers represent entities that are rationally designed to meet the functional requirements of a specific application. They can therefore be understood as Advanced Materials. Nanocarrier systems are already being used in medicine, cosmetics, agriculture, food, and household products. They are therefore used in a variety of products, ideally designed to be safe and sustainable, and may need to be registered before they can be placed on the market. Inspired by medical research, nanocarriers are also increasingly being used for precision farming (nano-agrochemicals) or products, such as air fresheners or lithium-ion batteries, and could thus be released into the environment in large quantities. To enable the identification of critical nanocarriers in subsequent investigations, a comprehensive literature review of the broad and heterogeneous research field of nanocarriers is provided, as well as an approach for categorization based on the origin and chemical composition of their constituent materials. A definition of nanocarriers based on size (1-1000 nm) and function is also proposed for their risk assessment.

Keywords: Advanced materials; Nanocarrier; Nanocarrier categorization; Nanoencapsulation; Targeted delivery systems.

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Conflict of interest statement

Declarations. Consent to participate: Not applicable. Consent to publish: Not applicable. Competing interests: The authors declare no competing interests. Ethics Declaration: Not applicable.

Figures

Fig. 1
Fig. 1
Types of nanocarriers categorized by their origin and material composition based on Gressler et al. [17]
Fig. 2
Fig. 2
Number of publications considered for each nanocarrier category. A total (Σ) of 115 studies were analyzed in detail for this review
Fig. 3
Fig. 3
Schematic illustration of examples of (A) inorganic, (B) organic, (C) hybrid nanocarriers, and (D) supraparticles. Active ingredients (purple dots) can be covalently bound or electrostatically attached to the particle surface (A or C), encapsulated in vesicles (B) or trapped in the pores of nanostructured materials (D)

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