Iron sulfate-reinforced hydrogel reactors with glucose deprivation, serial reactive oxygen species generation, ferroptosis induction, and photothermal ablation for cancer therapy

•Iron sulfate-reinforced injectable hydrogels for cancer therapy were fabricated.•Glucose oxidase in hydrogel may decompose glucose and supply H2O2.•Iron sulfate in hydrogel can provide hydroxyl radical and ferroptosis in cancer cells.•Polydopamine and iron ion-catechol coordination can be used for...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2022-06, Vol.438, p.135584, Article 135584
Main Authors: Jeong, Da In, Kim, Sungyun, Lee, Song Yi, Kim, Han-Jun, Lee, Junmin, Lee, KangJu, Cho, Hyun-Jong
Format: Article
Language:English
Subjects:
Cancer starvation
Chemodynamic therapy
Fenton catalyst
Ferroptosis
Hydrogel
Photothermal therapy
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Summary:•Iron sulfate-reinforced injectable hydrogels for cancer therapy were fabricated.•Glucose oxidase in hydrogel may decompose glucose and supply H2O2.•Iron sulfate in hydrogel can provide hydroxyl radical and ferroptosis in cancer cells.•Polydopamine and iron ion-catechol coordination can be used for photothermal therapy.•Multiple modalities-embodied hydrogel reactor may be used for local cancer therapy. Glucose deprivation, hydroxyl radical generation, photothermal ablation, and ferroptosis induction-installed injectable hydrogel reactor was designed for multiple therapy of localized breast cancer. Iron sulfate (IS) was introduced to hydrogel reactor network for coordination with catechol groups of hyaluronic acid-catechol (HC) conjugate, photothermal conversion by reaction with catechols, Fenton-reaction-related hydroxyl radical production, and ferroptosis induction of cancer cells. Glucose oxidase (GOx) was incorporated in hydrogel reactor for the decomposition of glucose and production of H2O2. Following curing strategies were elaborately organized in the one-pot hydrogel reactor structure: i) starvation of cancer cells and self-supply of H2O2 by GOx, ii) hydroxyl radical generation (from H2O2) and ferroptosis induction by IS, and iii) photothermal therapy by catechol polymerization and iron ion-catechol binding. Exquisite arrangement of therapeutic modalities in HC-based hydrogel network by local injection to breast cancer was applied in this study. Also, the rheological properties of HC hydrogel were tuned by pH adjustment for endowing immediate and uniform gelation features, injection through single syringe, shear-thinning behaviors, and self-healing characteristics. It is expected that fabricated hydrogel reactor system can be used efficiently and safely for curing cancers following its local injection.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2022.135584