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Literature DB >> 29161461

Ruthenium-Crosslinked Hydrogels with Rapid, Visible-Light Degradation.

Teresa L Rapp¹, Christopher B Highley², Brian C Manor¹, Jason A Burdick², Ivan J Dmochowski¹.

Abstract

Incorporation of photoresponsive molecules within soft materials can provide spatiotemporal control over bulk properties and address challenges in targeted delivery and mechanical variability. However, the kinetics of in situ photochemical reactions are often slow and typically employ ultraviolet wavelengths. Here, we present a novel photoactive crosslinker Ru(bipyridine)2 (3-pyridinaldehyde)2 (RuAldehyde), which was reacted with hydrazide-functionalized hyaluronic acid to form hydrogels capable of encapsulating protein cargo. Visible light irradiation (400-500 nm) initiated rapid ligand exchange on the ruthenium center, which degraded the hydrogel within seconds to minutes, depending on gel thickness. An exemplar enzyme cargo, TEM1 β-lactamase, was loaded into and photoreleased from the Ru-hydrogel. To expand their applications, Ru-hydrogels were also processed into microgels using a microfluidic platform.

Entities: Chemical Disease Gene Species

Keywords: hydrogels; microfluidics; protein delivery; ruthenium; stimulus-responsive

Year: 2018 PMID： 29161461 PMCID： PMC5915374 DOI： 10.1002/chem.201704580

Source DB: PubMed Journal: Chemistry ISSN： 0947-6539 Impact factor: 5.236

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