Jingxian Yang scite author profile

Glucose oxidase (GOx), which catalyzes the conversion of glucose into gluconic acid and hydrogen peroxide (H 2 O 2) in the presence of oxygen (O 2), has aroused growing interest for cancer therapy. GOx can starve tumor cells to death by depleting glucose, which is very important for their energy supply, and the generated H 2 O 2 is can be used for oxidation therapy. In addition, GOx-catalyzed glucose oxidation exerts a variety of effects on the tumor environment, such as enhancing hypoxia and increasing acidity. The full use of these characteristics can effectively reduce side effects and enhance the therapeutic efficiency of GOx-related cancer therapies. As is generally acknowledged, it is difficult to completely eliminate tumors with a single treatment, whereas combining two or more therapies may yield super-additive results because when properly designed, different treatments can compensate for the shortcomings of the other treatments and bring out the best in each other. In view of these facts, enhanced therapies and combination therapies related to glucose oxidation have been widely studied, and this review provides a systematic overview of recent research on GOx-related cancer therapies (especially starvation therapy) from the perspective of glucose oxidation (including the reaction itself, oxygen, enzymes, gluconic acid, and H 2 O 2) and other combination therapies.

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Pyroelectric Catalysis-Based “Nano-Lymphatic” Reduces Tumor Interstitial Pressure for Enhanced Penetration and Hydrodynamic Therapy

Cong

et al. 2021

ACS Nano

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Owing to de ciency of lymphatic re ux in the tumor, the retention of tumor interstitial uid causes the aggravation of tumor interstitial pressure (TIP), which leads to unsatisfactory tumor penetration of nanomedicine. It is the main inducement of tumor recurrence and metastasis. Herein, we design a pyroelectric catalysis-based "Nano-lymphatic" to decrease the TIP for enhanced tumor penetration and treatments. It realizes photothermal therapy and decomposition of tumor interstitial uid under NIR-II laser irradiation after reaching the tumor, which reduces the TIP for enhanced tumor penetration.Simultaneously, reactive oxygen species generated during the pyroelectric catalysis can further damage deep tumor stem cells. The results indicate that the "Nano-lymphatic" relieves 52% of TIP, leading to enhanced tumor penetration, which effectively inhibits the tumor proliferation (93.75%) and recurrence.Our nding presents a novel strategy to reduce TIP by pyroelectric catalysis for enhanced tumor penetration and improved treatments, which is of great signi cance for drug delivery.

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Global existence and steady states of a two competing species Keller--Segel chemotaxis model

Wang¹,

Zhang²,

Yang³

et al. 2015

KRM

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A facile preparation method for new two-component supramolecular hydrogels and their performances in adsorption, catalysis, and stimuli-response

et al. 2019

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Jingxian Yang

Rapid fabrication of wearable carbon nanotube/graphite strain sensor for real-time monitoring of plant growth

Glucose Oxidase‐Related Cancer Therapies

Pyroelectric Catalysis-Based “Nano-Lymphatic” Reduces Tumor Interstitial Pressure for Enhanced Penetration and Hydrodynamic Therapy

Global existence and steady states of a two competing species Keller--Segel chemotaxis model

A facile preparation method for new two-component supramolecular hydrogels and their performances in adsorption, catalysis, and stimuli-response

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