Jason D. Ehrick scite author profile

Certain proteins undergo a substantial conformational change in response to a given stimulus. This conformational change can manifest in different manners and result in an actuation, that is, catalytic or signalling event, movement, interaction with other proteins, and so on. In all cases, the sensing-actuation process of proteins is initiated by a recognition event that translates into a mechanical action. Thus, proteins are ideal components for designing new nanomaterials that are intelligent and can perform desired mechanical actions in response to target stimuli. A number of approaches have been undertaken to mimic nature's sensing-actuating process. We now report a new hybrid material that integrates genetically engineered proteins within hydrogels capable of producing a stimulus-responsive action mechanism. The mechanical effect is a result of an induced conformational change and binding affinities of the protein in response to a stimulus. The stimuli-responsive hydrogel exhibits three specific swelling stages in response to various ligands offering additional fine-tuned control over a conventional two-stage swelling hydrogel. The newly prepared material was used in the sensing, and subsequent gating and transport of biomolecules across a polymer network, demonstrating its potential application in microfluidics and miniaturized drug-delivery systems.

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Glucose Responsive Hydrogel Networks Based on Protein Recognition

Ehrick

Luckett

Khatwani

et al. 2009

Macromolecular Bioscience

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Stimuli-responsive materials capable of manifesting physical changes in response to environmental signals are valuable tools for use in a variety of biomedical applications. Herein we describe one such smart glucose-responsive hydrogel material prepared by immobilizing the glucose/galactose binding protein within an acrylamide hydrogel network. This hydrogel demonstrates a quantitative "accordion"-like dynamic response in the presence of glucose. We further show the feasibility of employing this responsive smart material as a gating agent for controlled drug delivery, thus, demonstrating that these hydrogels may eventually lead to the development of implantable drug delivery systems for diabetes management applications.

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Chemically Tunable Lensing of Stimuli‐Responsive Hydrogel Microdomes

et al. 2007

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Macromol. Biosci. 9/2009

Ehrick

Luckett

Khatwani

et al. 2009

Macromolecular Bioscience

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Considerations for the Development of Nasal Dosage Forms

Ehrick¹,

Shah²,

Shaw³

et al. 2013

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The anatomy and physiology of the nasal cavity provide unique advantages for accessing targets for local, systemic, and potentially central nervous system drug delivery. This chapter discusses these advantages and the challenges that must be overcome to reach these targets. The chapter then comprehensively reviews nasal dosage forms, analytical testing, and regulatory requirements in the context of existing nasal spray products. Since nasal sprays are moving towards being preservativefree, the chapter covers specialized methods of achieving a sterile product, namely, formulation strategies, manufacturing strategies, and the device landscape that support this upcoming platform. Finally, the chapter reviews various pathways for regulatory approval around the world, for brand and generic, with particular emphasis on the growing acceptance of in vitro data for locally acting nasal spray products.

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Jason D. Ehrick

Genetically engineered protein in hydrogels tailors stimuli-responsive characteristics

Glucose Responsive Hydrogel Networks Based on Protein Recognition

Chemically Tunable Lensing of Stimuli‐Responsive Hydrogel Microdomes

Macromol. Biosci. 9/2009

Considerations for the Development of Nasal Dosage Forms

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