Tunable biohybrid hydrogels from coacervation of hyaluronic acid and PEO‐based block copolymers

Mabesoone, Mathijs F. J.; Gopez, Jeffrey D.; Paulus, Ilka E.; Klinger, Daniel

doi:10.1002/pol.20200081

Cited by 6 publications

(3 citation statements)

References 40 publications

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“…Figure 1 provides a summary of the hydrogel classification details. Hydrogels can be based on biomedical hydrogels, which are utilized in medical applications, including controlled medication release, tissue engineering, and wound dressings [47][48][49]. Sensors, packaging, and other industrial applications are among the uses of hydrogels [50,51].…”

Section: Hydrogel Classificationmentioning

confidence: 99%

An Overview of Polymeric Hydrogel Applications for Sustainable Agriculture

Vedovello,

Sanches,

da Silva Teodoro

et al. 2024

Agriculture

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Agriculture, a vital element of human survival, confronts challenges of meeting rising demand due to population growth and product availability in developing nations. Reliance on pesticides and fertilizers strains natural resources, leading to soil degradation and water scarcity. Addressing these issues necessitates enhancing water efficiency in agriculture. Polymeric hydrogels, with their unique water retention and nutrient-release capabilities, offer promising solutions. These superabsorbent materials form three-dimensional networks retaining substantial amounts of water. Their physicochemical properties suit various applications, including agriculture. Production involves methods like bulk, solution, and suspension polymerization, with cross-linking, essential for hydrogels, achieved through physical or chemical means, each with different advantages. Grafting techniques incorporate functional groups into matrices, while radiation synthesis offers purity and reduced toxicity. Hydrogels provide versatile solutions to tackle water scarcity and soil degradation in agriculture. Recent research explores hydrogel formulations for optimal agricultural performance, enhancing soil water retention and plant growth. This review aims to offer a comprehensive overview of hydrogel technologies as adaptable solutions addressing water scarcity and soil degradation challenges in agriculture, with ongoing research refining hydrogel formulations for optimal agricultural use.

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Section: Hydrogel Classificationmentioning

confidence: 99%

An Overview of Polymeric Hydrogel Applications for Sustainable Agriculture

Vedovello,

Sanches,

da Silva Teodoro

et al. 2024

Agriculture

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show abstract

“…[187][188][189] Of special interest to such applications is the tunable strength of the bonds which is inherently defined by the pKa and pKb of the employed groups. [190][191][192][193] Also, external factors such as pH and ionic strength will influence the interaction, which can limit the stability and trigger the release of the electrostatically bound molecules, for example, for drug delivery.…”

Section: Acid-base Interactionsmentioning

confidence: 99%

Amphiphilic micro‐ and nanogels: Combining properties from internal hydrogel networks, solid particles, and micellar aggregates

Biglione

Neumann-Tran

Kanwal

et al. 2021

Journal of Polymer Science

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Polymeric micro-and nanogels are defined by their water-swollen hydrophilic networks that can often impart outstanding biocompatibility and highcolloidal stability. Unfortunately, this highly hydrophilic nature limits their potential in areas where hydrophobic or amphiphilic interactions are required, for example, the delivery of hydrophobic cargoes or tailored interactions with amphipathic (bio-)surfaces. To overcome this limitation, amphiphilic microÀ/nanogels are emerging as new colloidal materials that combine properties from hydrogel networks with hydrophobic segments, known from solid hydrophobic polymer particles or micellar cores. The ability to accurately adjust the balance of hydrophobic and hydrophilic components in such amphiphilic colloidal systems enables new tailored properties. This opens up new applications ranging from the

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“…Self-assembled hydrogels encompass a broad diversity of materials in which polymers are linked together into three-dimensional (3D) networks via noncovalent (and typically reversible) interactions, such as electrostatic interactions, hydrophobic interactions, van der Waals forces, π–π stacking, hydrogen bonding, metal coordination, and host–guest interactions. , The reversible interactions supporting the physical networks enable excellent self-healing and recovery behavior − as well as responsiveness to stimuli in such hydrogels. ,− These features make them highly desirable in biomedical and consumer product applications. , …”

Section: Introductionmentioning

confidence: 99%

Advances, Applications, and Emerging Opportunities in Electrostatic Hydrogels

Senebandith,

Li,

Srivastava

2023

Langmuir

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Polyelectrolyte complex (PEC) hydrogels, which selfassemble via complexation of oppositely charged block polymers, have recently risen to prominence owing to their unique characteristics such as hierarchical microstructure, tunable bulk properties, and the ability to precisely assimilate charged cargos (i.e., proteins and nucleic acids). Significant foundational research has delineated the structure−property relationship of PEC hydrogels for use in a wide range of applications. In this Perspective, we summarize key findings on the microstructure and bulk properties of PEC hydrogels and discuss how intrinsic and extrinsic factors can be tuned to create specifically tailored PEC hydrogels with desired properties. We highlight successful applications of PEC hydrogels while offering insight into strategies to overcome their shortcomings and elaborate on emerging opportunities in the field of electrostatic self-assemblies.

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Tunable biohybrid hydrogels from coacervation of hyaluronic acid and PEO‐based block copolymers

Cited by 6 publications

References 40 publications

An Overview of Polymeric Hydrogel Applications for Sustainable Agriculture

An Overview of Polymeric Hydrogel Applications for Sustainable Agriculture

Amphiphilic micro‐ and nanogels: Combining properties from internal hydrogel networks, solid particles, and micellar aggregates

Advances, Applications, and Emerging Opportunities in Electrostatic Hydrogels

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