# Hydrogel Development, Processing and Applications in Agriculture: A Review

**Authors:** Carmen Mª. Granados-Carrera, Victor M. Perez-Puyana, Mercedes Jiménez-Rosado, Alberto Romero

PMC · DOI: 10.3390/gels12030259 · 2026-03-20

## TL;DR

This review discusses the development of biodegradable hydrogels for agriculture to address water scarcity and soil fertility issues.

## Contribution

The paper provides a critical overview of biopolymer-based hydrogels for sustainable agricultural applications.

## Key findings

- Biodegradable hydrogels from natural polymers like chitosan and cellulose show promise for water retention and nutrient delivery.
- Current challenges include mechanical stability and controlled nutrient release in complex soil environments.
- Natural polymers offer advantages over petroleum-based hydrogels in terms of environmental impact and sustainability.

## Abstract

Hydrogels have emerged as promising functional materials for improving water management and nutrient delivery in agriculture, particularly under conditions of increasing water scarcity and declining soil fertility. However, most commercially available superabsorbent hydrogels are based on petroleum-derived polymers, raising concerns regarding their persistence in soils, potential microplastic formation and long-term environmental impact. In response, significant research efforts are being directed toward the development of biodegradable hydrogels derived from renewable biopolymers. This review provides a critical overview of recent advances in hydrogel systems designed for agricultural applications, with a particular focus on biopolymer-based materials. First, the current landscape of hydrogel technologies used as soil conditioners and controlled-release systems for agrochemicals is contextualized, highlighting the limitations of conventional synthetic hydrogels. Subsequently, the main classes of natural polymers explored for hydrogel fabrication, including polysaccharides (e.g., chitosan, alginate, cellulose and starch) and proteins (e.g., gelatin, keratin and soy protein), are analyzed in terms of raw material sources, gelation mechanisms and structure–property relationships. Their performance in key agricultural functions, such as water retention, controlled nutrient release, soil conditioning and enhancement of plant growth, is also discussed. Finally, the review identifies major challenges that currently hinder large-scale implementation, including mechanical stability, degradation behavior in complex soil environments, nutrient release control and economic scalability. By integrating recent progress and outlining emerging research directions, this work aims to support the rational design of next-generation biodegradable hydrogels capable of contributing to sustainable agriculture and circular bioeconomy strategies.

## Linked entities

- **Proteins:** keratin (keratin, type I cytoskeletal 19)

## Full-text entities

- **Diseases:** injury to (MESH:D014947), drought (MESH:C536747), malnutrition (MESH:D044342), toxicity (MESH:D064420), water (MESH:D000069578), CRFs (MESH:C536209)
- **Chemicals:** Lignin (MESH:D008031), hydrogen (MESH:D006859), manganese (MESH:D008345), Ca (MESH:D002118), methacrylamide (MESH:C045985), citric acid (MESH:D019343), Biological Additives (-), Polymers (MESH:D011108), carbon (MESH:D002244), carboxymethyl cellulose (MESH:D002266), Chitin (MESH:D002686), PVP (MESH:D011205), PVA (MESH:D011142), oxygen (MESH:D010100), acids (MESH:D000143), AM (MESH:D020106), ammonium persulfate (MESH:C031276), polylactic acid (MESH:C033616), methyl acrylate (MESH:C035956), hydroxyapatite (MESH:D017886), charcoal (MESH:D002606), Chitosan (MESH:D048271), zinc oxide (MESH:D015034), monosaccharide (MESH:D009005), acetic acid (MESH:D019342), atrazine (MESH:D001280), lithium chloride (MESH:D018021), amylopectin (MESH:D000687), potassium (MESH:D011188), zinc (MESH:D015032), Zeolite (MESH:D017641), Agar (MESH:D000362), polyacrylic acid (MESH:C006903), NaOH (MESH:D012972), MAA (MESH:C008384), boron (MESH:D001895), Polysaccharides (MESH:D011134), Starch (MESH:D013213), Mg (MESH:D008274), formaldehyde (MESH:D005557), gum arabic (MESH:D006170), PU (MESH:D011140), borax (MESH:C018851), silicate (MESH:D017640), limonene (MESH:D000077222), sodium (MESH:D012964), epichlorohydrin (MESH:D004811), amylose (MESH:D000688), carboxymethyl chitosan (MESH:C514968), phosphate (MESH:D010710), biochar (MESH:C540010), methylcellulose (MESH:D008747), carbonates (MESH:D002254), amino acid (MESH:D000596), PEG (MESH:D011092), ethylene glycol dimethacrylate (MESH:C004919), glutaraldehyde (MESH:D005976), Cellulose (MESH:D002482), Sodium Alginate (MESH:D000464), aluminum silicate (MESH:D000538)
- **Species:** Oryza sativa (Asian cultivated rice, species) [taxon 4530], Solanum tuberosum (potatoes, species) [taxon 4113], Homo sapiens (human, species) [taxon 9606], Cyamopsis tetragonoloba (cluster bean, species) [taxon 3832], Rhodophyta (red algae, phylum) [taxon 2763], PX clade (clade) [taxon 569578], Solanum lycopersicum (tomato, species) [taxon 4081]
- **Cell lines:** RAW — Mus musculus (Mouse), Mouse leukemia, Cancer cell line (CVCL_F681)

## Figures

3 figures with captions in the complete paper: https://tomesphere.com/paper/PMC13025618/full.md

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Source: https://tomesphere.com/paper/PMC13025618