Eric A. Appel scite author profile

Mouldable hydrogels that flow upon applied stress and rapidly self-heal are increasingly utilised as they afford minimally invasive delivery and conformal application. Here we report a new paradigm for the fabrication of self-assembled hydrogels with shear-thinning and self-healing properties employing rationally engineered polymer-nanoparticle interactions. Biopolymer derivatives are linked together by selective adsorption to nanoparticles. The transient and reversible interactions between biopolymers and nanoparticles enable flow under applied shear stress, followed by rapid self-healing when the stress is relaxed. We develop a physical description of polymer-nanoparticle gel formation that is utilised to design biocompatible gels for minimally-invasive drug delivery. Owing to the hierarchical structure of the gel, both hydrophilic and hydrophobic drugs can be entrapped and delivered with differential release profiles, both in vitro and in vivo. The work introduces a facile and generalizable class of mouldable hydrogels amenable to a range of biomedical and industrial applications.

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Injectable Self‐Healing Glucose‐Responsive Hydrogels with pH‐Regulated Mechanical Properties

Yesilyurt

et al. 2015

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Dynamically restructuring pH‐responsive hydrogels are synthesized, employing dynamic covalent chemistry between phenylboronic acid and cis‐diol modified poly(ethylene glycol) macromonomers. These gels display shear‐thinning behavior, followed by a rapid structural recovery (self‐healing). Size‐dependent in vitro controlled and glucose‐responsive release of proteins from the hydrogel network, as well as the biocompatibility of the gels, are evaluated both in vitro and in vivo.

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Ultrahigh-Water-Content Supramolecular Hydrogels Exhibiting Multistimuli Responsiveness

et al. 2012

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Hydrogels are three-dimensional networked materials that are similar to soft biological tissues and have highly variable mechanical properties, making them increasingly important in a variety of biomedical and industrial applications. Herein we report the preparation of extremely high water content hydrogels (up to 99.7% water by weight) driven by strong host-guest complexation with cucurbit[8]uril (CB[8]). Cellulosic derivatives and commodity polymers such as poly(vinyl alcohol) were modified with strongly binding guests for CB[8] ternary complex formation (K(eq) = 10(12) M(-2)). When these polymers were mixed in the presence of CB[8], whereby the overall solid content was 90% cellulosic, a lightly colored, transparent hydrogel was formed instantaneously. The supramolecular nature of these hydrogels affords them with highly tunable mechanical properties, and the dynamics of the CB[8] ternary complex cross-links allows for rapid self-healing of the materials after damage caused by deformation. Moreover, these hydrogels display responsivity to a multitude of external stimuli, including temperature, chemical potential, and competing guests. These materials are easily processed, and the simplicity of their preparation, their availability from inexpensive renewable resources, and the tunability of their properties are distinguishing features for many important water-based applications.

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Healable, Stable and Stiff Hydrogels: Combining Conflicting Properties Using Dynamic and Selective Three‐Component Recognition with Reinforcing Cellulose Nanorods

McKee

Appel

Seitsonen

et al. 2014

Adv Funct Materials

239

196

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Nanocomposite hydrogels are prepared combining polymer brush‐modified ‘hard’ cellulose nanocrystals (CNC) and ‘soft’ polymeric domains, and bound together by cucurbit[8]uril (CB[8]) supramolecular crosslinks, which allow dynamic host–guest interactions as well as selective and simultaneous binding of two guests, i.e., methyl viologen (the first guest) and naphthyl units (the second guest). CNCs are mechanically strong colloidal rods with nanometer‐scale lateral dimensions, which are functionalized by surface‐initiated atom transfer radical polymerization to yield a dense set of methacrylate polymer brushes bearing naphthyl units. They can then be non‐covalently cross‐linked through simple addition of poly(vinyl alcohol) polymers containing pendant viologen units as well as CB[8]s in aqueous media. The resulting supramolecular nanocomposite hydrogels combine three important criteria: high storage modulus (G′ > 10 kPa), rapid sol–gel transition (<6 s), and rapid self‐healing even upon aging for several months, as driven by balanced colloidal reinforcement as well as the selectivity and dynamics of the CB[8] three‐component supramolecular interactions. Such a new combination of properties for stiff and self‐healing hydrogel materials suggests new approaches for advanced dynamic materials from renewable sources.

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Activation Energies Control the Macroscopic Properties of Physically Cross‐Linked Materials

et al. 2014

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Here we show the preparation of a series of water-based physically cross-linked polymeric materials utilizing cucurbit[8]uril (CB[8]) ternary complexes displaying a range of binding, and therefore cross-linking, dynamics. We determined that the mechanical strength of these materials is correlated directly with a high energetic barrier for the dissociation of the CB[8] ternary complex cross-links, whereas facile and rapid self-healing requires a low energetic barrier to ternary complex association. The versatile CB[8] ternary complex has, therefore, proven to be a powerful asset for improving our understanding of challenging property-structure relationships in supramolecular systems and their associated influence on the bulk behavior of dynamically cross-linked materials.

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Eric A. Appel

Self-assembled hydrogels utilizing polymer–nanoparticle interactions

Injectable Self‐Healing Glucose‐Responsive Hydrogels with pH‐Regulated Mechanical Properties

Ultrahigh-Water-Content Supramolecular Hydrogels Exhibiting Multistimuli Responsiveness

Healable, Stable and Stiff Hydrogels: Combining Conflicting Properties Using Dynamic and Selective Three‐Component Recognition with Reinforcing Cellulose Nanorods

Activation Energies Control the Macroscopic Properties of Physically Cross‐Linked Materials

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