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Orthogonal Optimization, Characterization, and In Vitro Anticancer Activity Evaluation of a Hydrogen Peroxide-Responsive and Oxygen-Reserving Nanoemulsion for Hypoxic Tumor Photodynamic Therapy

SIMPLE SUMMARY: Tumor hypoxia can significantly reduce the effectiveness of photodynamic therapy (PDT). One approach to addressing this issue is in situ oxygen generation, which involves using catalysts such as catalase to decompose the excess H(2)O(2) produced by tumors. While this strategy can be...

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Detalles Bibliográficos
Autores principales: Hong, Liang, Wang, Jianman, Zhou, Yi, Shang, Guofu, Guo, Tao, Tang, Hailong, Li, Jiangmin, Luo, Yali, Zeng, Xiangyu, Zeng, Zhu, Hu, Zuquan
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10000418/
https://www.ncbi.nlm.nih.gov/pubmed/36900370
http://dx.doi.org/10.3390/cancers15051576
Descripción
Sumario:SIMPLE SUMMARY: Tumor hypoxia can significantly reduce the effectiveness of photodynamic therapy (PDT). One approach to addressing this issue is in situ oxygen generation, which involves using catalysts such as catalase to decompose the excess H(2)O(2) produced by tumors. While this strategy can be specific to tumors, its effectiveness is limited by the usually low tumor H(2)O(2) levels. Another approach, oxygen delivery, involves using substances with high oxygen solubility, such as perfluorocarbon, to transport oxygen for use in PDT. While this method can be effective, it lacks specificity for tumors. To combine the benefits of both approaches, we developed a nanoemulsion system CCIPN. The perfluoropolyether in CCIPN could store oxygen generated by catalase within the same nanoplatform for use in PDT. CCIPN was created using an optimized sonication-phase inversion composition–sonication method, and its properties and anticancer activity were studied in vitro. This research contributes to the design and production of oxygen-supplementing PDT nanomaterials. ABSTRACT: Tumor hypoxia can seriously impede the effectiveness of photodynamic therapy (PDT). To address this issue, two approaches, termed in situ oxygen generation and oxygen delivery, were developed. The in situ oxygen generation method uses catalysts such as catalase to decompose excess H(2)O(2) produced by tumors. It offers specificity for tumors, but its effectiveness is limited by the low H(2)O(2) concentration often present in tumors. The oxygen delivery strategy relies on the high oxygen solubility of perfluorocarbon, etc., to transport oxygen. It is effective, but lacks tumor specificity. In an effort to integrate the merits of the two approaches, we designed a multifunctional nanoemulsion system named CCIPN and prepared it using a sonication-phase inversion composition–sonication method with orthogonal optimization. CCIPN included catalase, the methyl ester of 2-cyano-3,12-dioxooleana-1,9(11)-dien-28-oic acid (CDDO-Me), photosensitizer IR780, and perfluoropolyether. Perfluoropolyether may reserve the oxygen generated by catalase within the same nanoformulation for PDT. CCIPN contained spherical droplets below 100 nm and showed reasonable cytocompatibility. It presented a stronger ability to generate cytotoxic reactive oxygen species and consequently destroy tumor cells upon light irradiation, in comparison with its counterpart without catalase or perfluoropolyether. This study contributes to the design and preparation of oxygen-supplementing PDT nanomaterials.