# Metallogels as Hybrid Metal-Organic Soft Materials: Classification, Fabrication Pathways and Functional Applications

**Authors:** Maciej Grabowski, Tomasz Grygier, Anna Trusek

PMC · DOI: 10.3390/gels12020124 · Gels · 2026-02-01

## TL;DR

Metallogels are hybrid materials combining metals and organic components, offering unique properties for advanced applications like sensing and drug delivery.

## Contribution

This review systematically classifies metallogels and highlights their synthesis and functional applications in next-generation technologies.

## Key findings

- Metallogels exhibit tunable mechanical and functional properties due to metal-ligand coordination.
- They enable applications in catalysis, conductivity, and biomedical fields like wound healing and drug delivery.
- Structure-function relationships are key to developing advanced soft technologies.

## Abstract

Metallogels constitute a rapidly expanding class of hybrid soft materials in which metal ions, metal complexes, or metal-containing nanoparticles play a decisive structural and functional role within a three-dimensional gel network. Their unique combination of supramolecular assembly, metal-ligand coordination, and dynamic network behaviour provides tunable mechanical, optical, electrical, redox, and catalytic properties that are not accessible in conventional hydrogels or organogels. This review systematically summarises current knowledge on metallogels, beginning with a classification based on matrix type, dominant metal interaction and functional output, spanning metallohydrogels, metal-organic gels, metal-phenolic gels, nanoparticle-based gels, polymer-based metallogels and low-molecular-weight metallogels. Key synthesis pathways are discussed, including coordination-chemistry-driven formation, metal-ligand self-assembly, in situ reduction, diffusion-mediated strategies, sol-gel-like polymerisation, enzyme-assisted routes, and bio-derived fabrication. Particular emphasis is placed on structure-function relationships that enable the development of catalytic, conductive, luminescent, antimicrobial, and biomedical metallogels. The examples compiled here highlight the versatility and transformative potential of metallogels in next-generation soft technologies, including sensing, energy conversion, wound healing, drug delivery, and emerging applications such as soft electronics and on-skin catalytic or bioactive patches. By mapping current progress and emerging design principles, this review aims to support the rational engineering of metallogels for advanced technological and biomedical applications

## Full-text entities

- **Genes:** TNF (tumor necrosis factor) [NCBI Gene 7124] {aka DIF, IMD127, TNF-alpha, TNFA, TNFSF2, TNLG1F}, MGs [NCBI Gene 100126595], MOG (myelin oligodendrocyte glycoprotein) [NCBI Gene 4340] {aka BTN6, BTNL11, MOGIG2, NRCLP7}, IL6 (interleukin 6) [NCBI Gene 3569] {aka BSF-2, BSF2, CDF, HGF, HSF, IFN-beta-2}
- **Diseases:** mitochondrial dysfunction (MESH:D028361), inflammation (MESH:D007249), injury to (MESH:D014947), cancer (MESH:D009369), Cytotoxicity (MESH:D064420), infected (MESH:D007239), glioblastoma (MESH:D005909), infectious (MESH:D003141)
- **Chemicals:** chitosan (MESH:D048271), phosphate (MESH:D010710), lithium carbonate (MESH:D016651), aromatic amino acids (MESH:D024322), Zn (MESH:D015032), sulphates (MESH:D013431), oxygen (MESH:D010100), carrageenan (MESH:D002351), alginate (MESH:D000464), Phytic acid (MESH:D010833), succinic acid (MESH:D019802), CaCO3 (MESH:D002119), pyrene (MESH:C030984), picric acid (MESH:C005858), Metal (MESH:D008670), Pt (MESH:D010984), Au (MESH:D006046), nitronyl nitroxide (MESH:C000714367), L-(+)-tartaric acid (MESH:C029768), Polymer (MESH:D011108), carbons (MESH:D002244), Ni (MESH:D009532), ammonium (MESH:D064751), ferrocene (MESH:C004998), pectin (MESH:D010368), polysaccharide (MESH:D011134), MOFs (MESH:C040750), uric acid (MESH:D014527), La(III) (MESH:D003975), Fe (MESH:D007501), tetraphenylethylene (MESH:C000617116), catechol (MESH:C034221), Li+ (MESH:D008094), Tb (MESH:D013725), water (MESH:D014867), Schiff-base (MESH:D012545), zinc oxide (MESH:D015034), azelaic acid (MESH:C010038), hydrazone (MESH:D006835), copper chloride (MESH:C029892), malic acid (MESH:C030298), cholesterol (MESH:D002784), methicillin (MESH:D008712), hyaluronic acid (MESH:D006820), Ce (MESH:D002563), UiO-66 (MESH:C000711576), Ag (MESH:D012834), thiourea (MESH:D013890), Copper (MESH:D003300), Fc (MESH:C095424), MOF (MESH:C037042), Eu (MESH:D005063), Al (MESH:D000535), 5-aminonaphthalene-1,8-bis(dicarboxylate) (-), H2O2 (MESH:D006861), indium tin oxide (MESH:C109984), oxalic acid (MESH:D019815), Zr (MESH:D015040), phenanthroline (MESH:D010618), trimesic acid (MESH:C069849)
- **Species:** Escherichia coli (E. coli, species) [taxon 562], Danio rerio (leopard danio, species) [taxon 7955], Homo sapiens (human, species) [taxon 9606], Staphylococcus epidermidis (species) [taxon 1282], Staphylococcus aureus (species) [taxon 1280]

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12940883/full.md

## References

111 references — full list in the complete paper: https://tomesphere.com/paper/PMC12940883/full.md

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Source: https://tomesphere.com/paper/PMC12940883