CaSO4-mediated remote drug loading enables synergistic cancer chemotherapy and ion-interference therapy

Nanomedicine for mediating chemotherapy/ion-interference combination cancer therapy. [Display omitted] As an emerging cancer therapeutic modality, ion-interference therapy (IIT), mediated by the elevated levels of intracellular calcium ions (Ca2+), hasgarneredsignificant research attention in the fi...

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Veröffentlicht in:	International journal of pharmaceutics 2024-12, Vol.667 (Pt A), p.124873, Article 124873
Hauptverfasser:	Zhang, Xiaojuan, Zhang, Shasha, Wang, Yu, Kong, Shuaizhi, Ding, Baoyue, Yang, Xingxia, Li, Dongmei, He, Chuanchuan
Format:	Artikel
Sprache:	eng
Schlagworte:	Breast cancer Chemotherapy Nanomedicine Remote loading
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container_issue	Pt A
container_start_page	124873
container_title	International journal of pharmaceutics
container_volume	667
creator	Zhang, Xiaojuan Zhang, Shasha Wang, Yu Kong, Shuaizhi Ding, Baoyue Yang, Xingxia Li, Dongmei He, Chuanchuan
description	Nanomedicine for mediating chemotherapy/ion-interference combination cancer therapy. [Display omitted] As an emerging cancer therapeutic modality, ion-interference therapy (IIT), mediated by the elevated levels of intracellular calcium ions (Ca2+), hasgarneredsignificant research attention in the field of cancer theranostics. However, most reported IIT strategies have heavily relied on Ca-based inorganic compounds, such as calcium peroxide and calcium carbonate,whose biosafety remains under investigation due to their high density and uncertainbiodegradability.This study describes a novel strategy for efficiently encapsulating doxorubicin (DOX) andCa2+ using the CaSO4 gradient method fordrugremote loading. In breast cancer cell models, we demonstrated a synergistic anticancer effect between Ca2+ and DOX, and elucidated the reactive oxygen species(ROS)-based antitumor mechanisms. This research represents the first instance of nanomedicine inducing combined chemotherapy/ion-interference therapy for cancer treatment without the use of insoluble inorganic compounds, thus offering enhanced biosafety.
doi_str_mv	10.1016/j.ijpharm.2024.124873
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[Display omitted] As an emerging cancer therapeutic modality, ion-interference therapy (IIT), mediated by the elevated levels of intracellular calcium ions (Ca2+), hasgarneredsignificant research attention in the field of cancer theranostics. However, most reported IIT strategies have heavily relied on Ca-based inorganic compounds, such as calcium peroxide and calcium carbonate,whose biosafety remains under investigation due to their high density and uncertainbiodegradability.This study describes a novel strategy for efficiently encapsulating doxorubicin (DOX) andCa2+ using the CaSO4 gradient method fordrugremote loading. In breast cancer cell models, we demonstrated a synergistic anticancer effect between Ca2+ and DOX, and elucidated the reactive oxygen species(ROS)-based antitumor mechanisms. 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[Display omitted] As an emerging cancer therapeutic modality, ion-interference therapy (IIT), mediated by the elevated levels of intracellular calcium ions (Ca2+), hasgarneredsignificant research attention in the field of cancer theranostics. However, most reported IIT strategies have heavily relied on Ca-based inorganic compounds, such as calcium peroxide and calcium carbonate,whose biosafety remains under investigation due to their high density and uncertainbiodegradability.This study describes a novel strategy for efficiently encapsulating doxorubicin (DOX) andCa2+ using the CaSO4 gradient method fordrugremote loading. In breast cancer cell models, we demonstrated a synergistic anticancer effect between Ca2+ and DOX, and elucidated the reactive oxygen species(ROS)-based antitumor mechanisms. 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[Display omitted] As an emerging cancer therapeutic modality, ion-interference therapy (IIT), mediated by the elevated levels of intracellular calcium ions (Ca2+), hasgarneredsignificant research attention in the field of cancer theranostics. However, most reported IIT strategies have heavily relied on Ca-based inorganic compounds, such as calcium peroxide and calcium carbonate,whose biosafety remains under investigation due to their high density and uncertainbiodegradability.This study describes a novel strategy for efficiently encapsulating doxorubicin (DOX) andCa2+ using the CaSO4 gradient method fordrugremote loading. In breast cancer cell models, we demonstrated a synergistic anticancer effect between Ca2+ and DOX, and elucidated the reactive oxygen species(ROS)-based antitumor mechanisms. 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subjects	Breast cancer Chemotherapy Nanomedicine Remote loading
title	CaSO4-mediated remote drug loading enables synergistic cancer chemotherapy and ion-interference therapy
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