Transform commercial magnetic materials into injectable gel for magnetic hyperthermia therapy in vivo.

Guangchao Xie, Lishi Wang, Bingjie Li, Cai Zhang, Xuejun Zhang

Colloids and surfaces. B, Biointerfaces 2023 Apr

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Magnetic hyperthermia therapy of tumors employing magnetic materials has been greatly developed due to their low invasiveness, high specificity, few side effects and no limitation of tissue penetration depth. However, traditional nanoscale magnetocaloric materials exhibited the disadvantages of low tumor enrichment efficiency, complex preparation process and difficulty in large-scale production. While eddy current loss-based magnetic hyperthermia tumor ablation with metal implants faces shortcomings such as high invasiveness and low selectivity of tumor shape and volume. Herein, we developed injectable magnetic gels by adding commercial magnetic metal or metal oxide powders (CMMPs) into alginate-Ca2+ (ALG-Ca2+) gel through an ultra-simple mixing strategy for magneto-thermal therapy of tumors in vivo. The ALG-Ca2+ gel can not only turn the water-insoluble CMMPs into injectable gel, but also retain the inherent magnetic loss-based heating capacity. Besides, CMMPs in the gels are easily retained at the tumor site after peritumoral injection because of their large size and strong hydrophobicity, which benefits the efficiency and accuracy of the treatment and reduces side effects to the surrounding tissues. The prepared ALG-Ca2+-CMMPs give full play to the inherent magneto-thermal capacity of CMMPs, which possesses super high loading ability (>100 mg magnetic materials/mL), superior large-scale production capability (>1 kg in laboratory synthesis), low cost, satisfactory syringeability and biological safety. Collectively, this study provides a convenient and universal strategy for the construction of magnetocaloric materials for biological applications. Copyright © 2023 Elsevier B.V. All rights reserved.

Citation

Guangchao Xie, Lishi Wang, Bingjie Li, Cai Zhang, Xuejun Zhang. Transform commercial magnetic materials into injectable gel for magnetic hyperthermia therapy in vivo. Colloids and surfaces. B, Biointerfaces. 2023 Apr;224:113185