Luke D. He scite author profile

Bioorthogonal catalysis offers a unique strategy to modulate biological processes through the in situ generation of therapeutic agents. However, the direct application of bioorthogonal transition metal catalysts (TMCs) in complex media poses numerous challenges due to issues of limited biocompatibility, poor water solubility, and catalyst deactivation in biological environments. We report here the creation of catalytic "polyzymes", comprised of self-assembled polymer nanoparticles engineered to encapsulate lipophilic TMCs. The incorporation of catalysts into these nanoparticle scaffolds creates water-soluble constructs that provide a protective environment for the catalyst. The potential therapeutic utility of these nanozymes was demonstrated through antimicrobial studies in which a cationic nanozyme was able to penetrate into biofilms and eradicate embedded bacteria through the bioorthogonal activation of a proantibiotic.

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Thermally Gated Bio-orthogonal Nanozymes with Supramolecularly Confined Porphyrin Catalysts for Antimicrobial Uses

Cao‐Milán

Gopalakrishnan

et al. 2020

Chem

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This paper describes the fabrication of thermoresponsive bio-orthogonal catalytic systems though the integration of transition metal catalysts into gold nanoparticles. The confined assemblies of the catalysts provide a temperatureregulated system able to controllably activate antibiotics within biofilms. This work presents a blueprint for synthesizing a family of reversible thermoresponsive nanozymes with tailored activation temperatures and preserved bio-orthogonal activity in complex biological environments.

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Modulating the catalytic activity of enzyme-like nanoparticles through their surface functionalization

Cao‐Milán

Shorkey

et al. 2017

Mol. Syst. Des. Eng.

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The inclusion of transition metal catalysts into nanoparticle scaffolds permits the creation of catalytic nanosystems (nanozymes) able to imitate the behaviour of natural enzymes. Here we report the fabrication of a family of nanozymes comprised of bioorthogonal ruthenium catalysts inserted in the protective monolayer of gold nanoparticles. By introducing simple modifications to the functional groups at the surface of the nanozymes, we have demonstrated control over the kinetic mechanism of our system. Cationic nanozymes with hydrophobic surface functionalities tend to replicate the classical Michaelis Menten model, while those with polar groups display substrate inhibition behaviour, a key mechanism present in 20 % of natural enzymes. The structural parameters described herein can be used for creating artificial nanosystems that mimic the complexity observed in cell machinery.

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Trends in dermatology telehealth uptake in Medicare beneficiaries from 2010 to 2020: A retrospective cross-sectional analysis

Xiang

Nambudiri

et al. 2023

Journal of the American Academy of Dermatology

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Trends in Orthopedic Management of Distal Radius Fractures Among Medicare Beneficiaries From 2019 to 2020: A Claims Analysis

He¹,

Duggan²,

Lans³

et al. 2023

Journal of Hand Surgery Global Online

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Luke D. He

Polymer-Based Bioorthogonal Nanocatalysts for the Treatment of Bacterial Biofilms

Thermally Gated Bio-orthogonal Nanozymes with Supramolecularly Confined Porphyrin Catalysts for Antimicrobial Uses

Modulating the catalytic activity of enzyme-like nanoparticles through their surface functionalization

Trends in dermatology telehealth uptake in Medicare beneficiaries from 2010 to 2020: A retrospective cross-sectional analysis

Trends in Orthopedic Management of Distal Radius Fractures Among Medicare Beneficiaries From 2019 to 2020: A Claims Analysis

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