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Tumour-microenvironment-responsive Na 2 S 2 O 8 nanocrystals encapsulated in hollow organosilica-metal-phenolic networks for cycling persistent tumour-dynamic therapy.

Yang LiJinyan LinYueyang HeKaiyuan WangCailin HuangRuifeng ZhangXiao-Long Liu
Published in: Exploration (Beijing, China) (2023)
Traditional tumour-dynamic therapy still inevitably faces the critical challenge of limited reactive oxygen species (ROS)-generating efficiency due to tumour hypoxia, extreme pH condition for Fenton reaction, and unsustainable mono-catalytic reaction. To fight against these issues, we skilfully develop a tumour-microenvironment-driven yolk-shell nanoreactor to realize the high-efficiency persistent dynamic therapy via cascade-responsive dual cycling amplification of •SO 4 - /•OH radicals. The nanoreactor with an ultrahigh payload of free radical initiator is designed by encapsulating the Na 2 S 2 O 8 nanocrystals into hollow tetra-sulphide-introduced mesoporous silica (HTSMS) and afterward enclosed by epigallocatechin gallate (EG)-Fe(II) cross-linking. Within the tumour microenvironment, the intracellular glutathione (GSH) can trigger the tetra-sulphide cleavage of nanoreactors to explosively release Na + /S 2 O 8 2 - /Fe 2+ and EG. Then a sequence of cascade reactions will be activated to efficiently generate •SO 4 - (Fe 2+ -catalyzed S 2 O 8 2 - oxidation), proton (•SO 4 - -catalyzed H 2 O decomposition), and •OH (proton-intensified Fenton oxidation). Synchronously, the oxidation-generated Fe 3+ will be in turn recovered into Fe 2+ by excessive EG to circularly amplify •SO 4 - /•OH radicals. The nanoreactors can also disrupt the intracellular osmolarity homeostasis by Na + overload and weaken the ROS-scavenging systems by GSH exhaustion to further amplify oxidative stress. Our yolk-shell nanoreactors can efficiently eradicate tumours via multiple oxidative stress amplification, which will provide a perspective to explore dynamic therapy.
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