Dual pH/reduction-responsive hybrid polymeric micelles for targeted chemo-photothermal combination therapy

Linhua Zhang; Yu Qin; Zhiming Zhang; Fan Fan; Chenlu Huang; Li Lu; Hai Wang; Xu Jin; Hanxue Zhao; Deling Kong; Chun Wang; Hongfan Sun; Xigang Leng; Dunwan Zhu

doi:10.1016/j.actbio.2018.05.026

Dual pH/reduction-responsive hybrid polymeric micelles for targeted chemo-photothermal combination therapy

Linhua Zhang, Yu Qin, Zhiming Zhang, Fan Fan, Chenlu Huang, Li Lu, Hai Wang, Xu Jin, Hanxue Zhao, Deling Kong, Chun Wang, Hongfan Sun, Xigang Leng, Dunwan Zhu

Biomedical Engineering

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

66 Scopus citations

Abstract

The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed new pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs exhibited nano-sized structure (∼100 nm) with good monodispersity, high encapsulation efficiency of both ICG and DOX, triggered DOX release in response to acid pH and reduction environment, and excellent temperature conversion with laser irradiation. In vitro cellular uptake study indicated FA Co-PMs achieved significant targeting to BEL-7404 cells via folate receptor-mediated endocytosis, and laser-induced hyperthermia further enhanced drug accumulation into cancer cells. In vivo biodistribution study indicated that FA Co-PMs prolonged drug circulation and enhanced drug accumulation into the tumor via EPR effect and FA targeting. Furthermore, the ICG-based photo-triggered hyperthermia combined with DOX-based chemotherapy synergistically induced the BEL-7404 cell death and apoptosis, and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs were promising theranostic nanocarriers for versatile antitumor drug delivery and imaging-guided cancer chemo-photothermal combination therapy. Statement of Significance: The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed novel pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs triggered DOX release in response to acid pH and reduction environment and exhibited excellent temperature conversion with laser irradiation. The results indicated FA Co-PMs achieved significant targeting to BEL-7404 cells in vitro and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs displayed great potential in imaging-guided cancer chemo-photothermal combination therapy as theranostic nanocarriers.

Original language	English (US)
Pages (from-to)	371-385
Number of pages	15
Journal	Acta Biomaterialia
Volume	75
DOIs	https://doi.org/10.1016/j.actbio.2018.05.026
State	Published - Jul 15 2018

Bibliographical note

Funding Information:
This work was supported by National Natural Science Foundation of China (grant numbers 81671806, 81571793, 31670948, 81671694); CAMS Initiative for Innovative Medicine (grant numbers 2017-I2M-4-001, 2017-I2M-3-020); Beijing Municipal Natural Science Foundation (grant number 7172072); Tianjin Municipal Natural Science Foundation (grant numbers 15JCZDJC38300, 15JCQNJC46200) and Science and Technology Support Program of Tianjin (grant number 14RCGFSY00146); Program for Innovative Research Team in Peking Union Medical College, Science Foundation for The Youth Teachers of Peking Union Medical College (grant number 2014zlgc0754), Scientific Research Foundation of the State Human Resource Ministry and the Education Ministry for Returned Chinese Scholars.

Funding Information:
This work was supported by National Natural Science Foundation of China (grant numbers 81671806, 81571793, 31670948, 81671694) ; CAMS Initiative for Innovative Medicine ( grant numbers 2017-I 2 M-4-001, 2017-I2M-3-020); Beijing Municipal Natural Science Foundation ( grant number 7172072); Tianjin Municipal Natural Science Foundation ( grant numbers 15JCZDJC38300, 15JCQNJC46200) and Science and Technology Support Program of Tianjin (grant number 14RCGFSY00146); Program for Innovative Research Team in Peking Union Medical College, Science Foundation for The Youth Teachers of Peking Union Medical College (grant number 2014zlgc0754), Scientific Research Foundation of the State Human Resource Ministry and the Education Ministry for Returned Chinese Scholars.

Publisher Copyright:
© 2018 Acta Materialia Inc.

Keywords

Chemo-photothermal therapy
Doxorubicin
Dual-responsive
Hybrid polymeric micelles
Indocyanine green

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

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title = "Dual pH/reduction-responsive hybrid polymeric micelles for targeted chemo-photothermal combination therapy",

abstract = "The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed new pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs exhibited nano-sized structure (∼100 nm) with good monodispersity, high encapsulation efficiency of both ICG and DOX, triggered DOX release in response to acid pH and reduction environment, and excellent temperature conversion with laser irradiation. In vitro cellular uptake study indicated FA Co-PMs achieved significant targeting to BEL-7404 cells via folate receptor-mediated endocytosis, and laser-induced hyperthermia further enhanced drug accumulation into cancer cells. In vivo biodistribution study indicated that FA Co-PMs prolonged drug circulation and enhanced drug accumulation into the tumor via EPR effect and FA targeting. Furthermore, the ICG-based photo-triggered hyperthermia combined with DOX-based chemotherapy synergistically induced the BEL-7404 cell death and apoptosis, and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs were promising theranostic nanocarriers for versatile antitumor drug delivery and imaging-guided cancer chemo-photothermal combination therapy. Statement of Significance: The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed novel pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs triggered DOX release in response to acid pH and reduction environment and exhibited excellent temperature conversion with laser irradiation. The results indicated FA Co-PMs achieved significant targeting to BEL-7404 cells in vitro and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs displayed great potential in imaging-guided cancer chemo-photothermal combination therapy as theranostic nanocarriers.",

keywords = "Chemo-photothermal therapy, Doxorubicin, Dual-responsive, Hybrid polymeric micelles, Indocyanine green",

author = "Linhua Zhang and Yu Qin and Zhiming Zhang and Fan Fan and Chenlu Huang and Li Lu and Hai Wang and Xu Jin and Hanxue Zhao and Deling Kong and Chun Wang and Hongfan Sun and Xigang Leng and Dunwan Zhu",

note = "Funding Information: This work was supported by National Natural Science Foundation of China (grant numbers 81671806, 81571793, 31670948, 81671694); CAMS Initiative for Innovative Medicine (grant numbers 2017-I2M-4-001, 2017-I2M-3-020); Beijing Municipal Natural Science Foundation (grant number 7172072); Tianjin Municipal Natural Science Foundation (grant numbers 15JCZDJC38300, 15JCQNJC46200) and Science and Technology Support Program of Tianjin (grant number 14RCGFSY00146); Program for Innovative Research Team in Peking Union Medical College, Science Foundation for The Youth Teachers of Peking Union Medical College (grant number 2014zlgc0754), Scientific Research Foundation of the State Human Resource Ministry and the Education Ministry for Returned Chinese Scholars. Funding Information: This work was supported by National Natural Science Foundation of China (grant numbers 81671806, 81571793, 31670948, 81671694) ; CAMS Initiative for Innovative Medicine ( grant numbers 2017-I 2 M-4-001, 2017-I2M-3-020); Beijing Municipal Natural Science Foundation ( grant number 7172072); Tianjin Municipal Natural Science Foundation ( grant numbers 15JCZDJC38300, 15JCQNJC46200) and Science and Technology Support Program of Tianjin (grant number 14RCGFSY00146); Program for Innovative Research Team in Peking Union Medical College, Science Foundation for The Youth Teachers of Peking Union Medical College (grant number 2014zlgc0754), Scientific Research Foundation of the State Human Resource Ministry and the Education Ministry for Returned Chinese Scholars. Publisher Copyright: {\textcopyright} 2018 Acta Materialia Inc.",

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AU - Zhang, Linhua

AU - Qin, Yu

AU - Zhang, Zhiming

AU - Fan, Fan

AU - Huang, Chenlu

AU - Lu, Li

AU - Wang, Hai

AU - Jin, Xu

AU - Zhao, Hanxue

AU - Kong, Deling

AU - Wang, Chun

AU - Sun, Hongfan

AU - Leng, Xigang

AU - Zhu, Dunwan

N1 - Funding Information: This work was supported by National Natural Science Foundation of China (grant numbers 81671806, 81571793, 31670948, 81671694); CAMS Initiative for Innovative Medicine (grant numbers 2017-I2M-4-001, 2017-I2M-3-020); Beijing Municipal Natural Science Foundation (grant number 7172072); Tianjin Municipal Natural Science Foundation (grant numbers 15JCZDJC38300, 15JCQNJC46200) and Science and Technology Support Program of Tianjin (grant number 14RCGFSY00146); Program for Innovative Research Team in Peking Union Medical College, Science Foundation for The Youth Teachers of Peking Union Medical College (grant number 2014zlgc0754), Scientific Research Foundation of the State Human Resource Ministry and the Education Ministry for Returned Chinese Scholars. Funding Information: This work was supported by National Natural Science Foundation of China (grant numbers 81671806, 81571793, 31670948, 81671694) ; CAMS Initiative for Innovative Medicine ( grant numbers 2017-I 2 M-4-001, 2017-I2M-3-020); Beijing Municipal Natural Science Foundation ( grant number 7172072); Tianjin Municipal Natural Science Foundation ( grant numbers 15JCZDJC38300, 15JCQNJC46200) and Science and Technology Support Program of Tianjin (grant number 14RCGFSY00146); Program for Innovative Research Team in Peking Union Medical College, Science Foundation for The Youth Teachers of Peking Union Medical College (grant number 2014zlgc0754), Scientific Research Foundation of the State Human Resource Ministry and the Education Ministry for Returned Chinese Scholars. Publisher Copyright: © 2018 Acta Materialia Inc.

PY - 2018/7/15

Y1 - 2018/7/15

N2 - The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed new pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs exhibited nano-sized structure (∼100 nm) with good monodispersity, high encapsulation efficiency of both ICG and DOX, triggered DOX release in response to acid pH and reduction environment, and excellent temperature conversion with laser irradiation. In vitro cellular uptake study indicated FA Co-PMs achieved significant targeting to BEL-7404 cells via folate receptor-mediated endocytosis, and laser-induced hyperthermia further enhanced drug accumulation into cancer cells. In vivo biodistribution study indicated that FA Co-PMs prolonged drug circulation and enhanced drug accumulation into the tumor via EPR effect and FA targeting. Furthermore, the ICG-based photo-triggered hyperthermia combined with DOX-based chemotherapy synergistically induced the BEL-7404 cell death and apoptosis, and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs were promising theranostic nanocarriers for versatile antitumor drug delivery and imaging-guided cancer chemo-photothermal combination therapy. Statement of Significance: The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed novel pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs triggered DOX release in response to acid pH and reduction environment and exhibited excellent temperature conversion with laser irradiation. The results indicated FA Co-PMs achieved significant targeting to BEL-7404 cells in vitro and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs displayed great potential in imaging-guided cancer chemo-photothermal combination therapy as theranostic nanocarriers.

AB - The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed new pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs exhibited nano-sized structure (∼100 nm) with good monodispersity, high encapsulation efficiency of both ICG and DOX, triggered DOX release in response to acid pH and reduction environment, and excellent temperature conversion with laser irradiation. In vitro cellular uptake study indicated FA Co-PMs achieved significant targeting to BEL-7404 cells via folate receptor-mediated endocytosis, and laser-induced hyperthermia further enhanced drug accumulation into cancer cells. In vivo biodistribution study indicated that FA Co-PMs prolonged drug circulation and enhanced drug accumulation into the tumor via EPR effect and FA targeting. Furthermore, the ICG-based photo-triggered hyperthermia combined with DOX-based chemotherapy synergistically induced the BEL-7404 cell death and apoptosis, and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs were promising theranostic nanocarriers for versatile antitumor drug delivery and imaging-guided cancer chemo-photothermal combination therapy. Statement of Significance: The combination of chemotherapy and photothermal therapy in multifunctional nanovesicles has emerged as a promising strategy to improve cancer therapeutic efficacy. Herein, we designed novel pH/reduction dual-responsive and folate decorated polymeric micelles (FA Co-PMs) as theranostic nanocarrier to co-encapsulate doxorubicin (DOX) and indocyanine green (ICG) for targeted NIR imaging and chemo-photothermal combination therapy. The Co-PMs triggered DOX release in response to acid pH and reduction environment and exhibited excellent temperature conversion with laser irradiation. The results indicated FA Co-PMs achieved significant targeting to BEL-7404 cells in vitro and efficiently suppressed the BEL-7404 xenografted tumor growth while significantly reduced systemic toxicity in vivo. Therefore, the designed dual-responsive Co-PMs displayed great potential in imaging-guided cancer chemo-photothermal combination therapy as theranostic nanocarriers.

KW - Chemo-photothermal therapy

KW - Doxorubicin

KW - Dual-responsive

KW - Hybrid polymeric micelles

KW - Indocyanine green

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Dual pH/reduction-responsive hybrid polymeric micelles for targeted chemo-photothermal combination therapy

Abstract

Bibliographical note

Keywords

UN SDGs

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