Dual-Functional Hafnium Oxide Nanoplatform Combining High-Z Radiosensitization With Bcl-2 Gene Silencing for Enhanced Cancer Radiotherapy

Seungyong Shin; Ga Hyun Bae; Jun Hyeok Han; Ha Eun Shin; Joo Dong Park; Seunghyo Ko; Eun Young Koh; Jieun Han; Su Chul Han; Jason Joon Bock Lee; Dong Hyun Kim; Heerim Nam; Wooram Park

doi:10.1002/adhm.202404819

Dual-Functional Hafnium Oxide Nanoplatform Combining High-Z Radiosensitization With Bcl-2 Gene Silencing for Enhanced Cancer Radiotherapy

Seungyong Shin, Ga Hyun Bae, Jun Hyeok Han, Ha Eun Shin, Joo Dong Park, Seunghyo Ko, Eun Young Koh, Jieun Han, Su Chul Han, Jason Joon Bock Lee, Dong Hyun Kim, Heerim Nam, Wooram Park^*

^*Corresponding author for this work

Radiology

Research output: Contribution to journal › Article › peer-review

Abstract

The efficacy of radiotherapy is often limited by insufficient radiosensitization and tumor radioresistance. This study reports a dual-functional hafnium oxide nanoplatform that combines high-Z radiosensitization with Bcl-2 gene silencing for enhanced cancer radiotherapy. The nanoplatform is developed by surface modification of hafnium oxide nanoparticles with polyethyleneimine, enabling efficient siRNA delivery while maintaining inherent high-Z radiosensitizing properties. Comprehensive physicochemical characterization confirmed the successful surface modification and stable siRNA complexation. Upon radiation exposure, the nanoplatform enhanced reactive oxygen species generation and DNA damage while simultaneously delivering Bcl-2 siRNA to suppress radioresistance mechanisms. In vitro studies revealed significant enhancement of radiation-induced cell death through synergistic effects of high-Z radiosensitization and Bcl-2 silencing, evidenced by increased γ-H2AX expression and apoptotic cell population. In a murine colon cancer model, the nanoplatform achieved remarkable tumor growth inhibition (80%) when combined with radiotherapy while exhibiting favorable biocompatibility in major organs. Mechanistic studies confirmed effective Bcl-2 downregulation and enhanced DNA damage in tumor tissues, validating this dual-functional therapeutic approach. This study presents a promising strategy for improving radiotherapy outcomes through the simultaneous enhancement of radiosensitization and suppression of radioresistance, potentially advancing the field of cancer radiotherapy.

Original language	English (US)
Article number	2404819
Journal	Advanced Healthcare Materials
Volume	14
Issue number	15
DOIs	https://doi.org/10.1002/adhm.202404819
State	Published - Jun 10 2025

Funding

S.S. and G.-H.B. contributed equally to this work as co-first authors. Illustrations were created using the BioRender.com software. This work was supported by grants from the Basic Science Research Program through the National Research Foundation of Korea (RS-2024-00350878, RS-2024-00402899, RS-2023-00218648, and RS-2023-00242443). Additional support was provided by the KBSMC-SKKU Future Clinical Convergence Academic Research Program (2023), a collaborative initiative between Kangbuk Samsung Hospital and Sungkyunkwan University. S.S. and G.\u2010H.B. contributed equally to this work as co\u2010first authors. Illustrations were created using the BioRender.com software. This work was supported by grants from the Basic Science Research Program through the National Research Foundation of Korea (RS\u20102024\u201000350878, RS\u20102024\u201000402899, RS\u20102023\u201000218648, and RS\u20102023\u201000242443). Additional support was provided by the KBSMC\u2010SKKU Future Clinical Convergence Academic Research Program (2023), a collaborative initiative between Kangbuk Samsung Hospital and Sungkyunkwan University.

Keywords

Bcl-2 silencing
cancer radiotherapy
hafnium oxide nanoplatform
radiosensitization
siRNA delivery

ASJC Scopus subject areas

Biomaterials
Biomedical Engineering
Pharmaceutical Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/adhm.202404819

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Shin, S., Bae, G. H., Han, J. H., Shin, H. E., Park, J. D., Ko, S., Koh, E. Y., Han, J., Han, S. C., Lee, J. J. B., Kim, D. H., Nam, H., & Park, W. (2025). Dual-Functional Hafnium Oxide Nanoplatform Combining High-Z Radiosensitization With Bcl-2 Gene Silencing for Enhanced Cancer Radiotherapy. Advanced Healthcare Materials, 14(15), Article 2404819. https://doi.org/10.1002/adhm.202404819

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abstract = "The efficacy of radiotherapy is often limited by insufficient radiosensitization and tumor radioresistance. This study reports a dual-functional hafnium oxide nanoplatform that combines high-Z radiosensitization with Bcl-2 gene silencing for enhanced cancer radiotherapy. The nanoplatform is developed by surface modification of hafnium oxide nanoparticles with polyethyleneimine, enabling efficient siRNA delivery while maintaining inherent high-Z radiosensitizing properties. Comprehensive physicochemical characterization confirmed the successful surface modification and stable siRNA complexation. Upon radiation exposure, the nanoplatform enhanced reactive oxygen species generation and DNA damage while simultaneously delivering Bcl-2 siRNA to suppress radioresistance mechanisms. In vitro studies revealed significant enhancement of radiation-induced cell death through synergistic effects of high-Z radiosensitization and Bcl-2 silencing, evidenced by increased γ-H2AX expression and apoptotic cell population. In a murine colon cancer model, the nanoplatform achieved remarkable tumor growth inhibition (80\%) when combined with radiotherapy while exhibiting favorable biocompatibility in major organs. Mechanistic studies confirmed effective Bcl-2 downregulation and enhanced DNA damage in tumor tissues, validating this dual-functional therapeutic approach. This study presents a promising strategy for improving radiotherapy outcomes through the simultaneous enhancement of radiosensitization and suppression of radioresistance, potentially advancing the field of cancer radiotherapy.",

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AU - Shin, Seungyong

AU - Bae, Ga Hyun

AU - Han, Jun Hyeok

AU - Shin, Ha Eun

AU - Park, Joo Dong

AU - Ko, Seunghyo

AU - Koh, Eun Young

AU - Han, Jieun

AU - Han, Su Chul

AU - Lee, Jason Joon Bock

AU - Kim, Dong Hyun

AU - Nam, Heerim

AU - Park, Wooram

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AB - The efficacy of radiotherapy is often limited by insufficient radiosensitization and tumor radioresistance. This study reports a dual-functional hafnium oxide nanoplatform that combines high-Z radiosensitization with Bcl-2 gene silencing for enhanced cancer radiotherapy. The nanoplatform is developed by surface modification of hafnium oxide nanoparticles with polyethyleneimine, enabling efficient siRNA delivery while maintaining inherent high-Z radiosensitizing properties. Comprehensive physicochemical characterization confirmed the successful surface modification and stable siRNA complexation. Upon radiation exposure, the nanoplatform enhanced reactive oxygen species generation and DNA damage while simultaneously delivering Bcl-2 siRNA to suppress radioresistance mechanisms. In vitro studies revealed significant enhancement of radiation-induced cell death through synergistic effects of high-Z radiosensitization and Bcl-2 silencing, evidenced by increased γ-H2AX expression and apoptotic cell population. In a murine colon cancer model, the nanoplatform achieved remarkable tumor growth inhibition (80%) when combined with radiotherapy while exhibiting favorable biocompatibility in major organs. Mechanistic studies confirmed effective Bcl-2 downregulation and enhanced DNA damage in tumor tissues, validating this dual-functional therapeutic approach. This study presents a promising strategy for improving radiotherapy outcomes through the simultaneous enhancement of radiosensitization and suppression of radioresistance, potentially advancing the field of cancer radiotherapy.

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Dual-Functional Hafnium Oxide Nanoplatform Combining High-Z Radiosensitization With Bcl-2 Gene Silencing for Enhanced Cancer Radiotherapy

Abstract

Funding

Keywords

ASJC Scopus subject areas

UN SDGs

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