Citation: | Xiaopeng Li, Yang Zhong, Pengyuan Qi, Daoming Zhu, Chenglong Sun, Nan Wei, Yang Zhang, Zhanggui Wang. Platelet membrane biomimetic nanomedicine induces dual glutathione consumption for enhancing cancer radioimmunotherapy[J]. Journal of Pharmaceutical Analysis. doi: 10.1016/j.jpha.2024.01.003 |
[1] |
W. Deng, K.J. McKelvey, A. Guller, et al., Application of mitochondrially targeted nanoconstructs to neoadjuvant x-ray-induced photodynamic therapy for rectal cancer, ACS Central Science 6(2020) 715-726.
|
[2] |
D. Zhu, M. Lyu, Q. Huang, et al., Stellate plasmonic exosomes for penetrative targeting tumor nir-ii thermo-radiotherapy, ACS Appl. Mater. Interfaces 12(2020) 36928-36937.
|
[3] |
T. Ma, Y. Liu, Q. Wu, et al., Quercetin-modified metal-organic frameworks for dual sensitization of radiotherapy in tumor tissues by inhibiting the carbonic anhydrase ix, ACS Nano 13(2019) 4209-4219.
|
[4] |
G. Song, L. Cheng, Y. Chao, et al., Emerging nanotechnology and advanced materials for cancer radiation therapy, Adv. Mater. 29(2017) 1700996.
|
[5] |
Q. Chen, J. Chen, Z. Yang, et al., Nanoparticle-enhanced radiotherapy to trigger robust cancer immunotherapy, Adv. Mater. 31(2019) e1802228.
|
[6] |
Y. Xiong, C. Xiao, Z. Li, et al., Engineering nanomedicine for glutathione depletion-augmented cancer therapy, Chem. Soc. Rev. 50(2021) 6013-6041.
|
[7] |
B. Niu, K. Liao, Y. Zhou, et al., Application of glutathione depletion in cancer therapy: Enhanced rosbased therapy, ferroptosis, and chemotherapy, Biomaterials 277(2021) 121110.
|
[8] |
C. Huang, Z. Liu, M. Chen, et al., Tumor-derived biomimetic nanozyme with immune evasion ability for synergistically enhanced low dose radiotherapy, J Nanobiotechnology 19(2021) 457.
|
[9] |
D. Zhu, T. Zhang, Y. Li, et al., Tumor-derived exosomes co-delivering aggregation-induced emission luminogens and proton pump inhibitors for tumor glutamine starvation therapy and enhanced type-i photodynamic therapy, Biomaterials 283(2022) 121462.
|
[10] |
T.A. Mishchenko, I.V. Balalaeva, M.V. Vedunova, et al., Ferroptosis and photodynamic therapy synergism: Enhancing anticancer treatment, Trends Cancer 7(2021) 484-487.
|
[11] |
A. Meister, M.E. Anderson, Glutathione, Annual Review of Biochemistry 52(1983) 711-760.
|
[12] |
D. Zhu, R. Ling, H. Chen, et al., Biomimetic copper single-atom nanozyme system for self-enhanced nanocatalytic tumor therapy, Nano Res. 15(2022) 7320-7328.
|
[13] |
Y. Chen, G. Zhao, S. Wang, et al., Platelet-membrane-camouflaged bismuth sulfide nanorods for synergistic radio-photothermal therapy against cancer, Biomater Sci 7(2019) 3450-3459.
|
[14] |
S. Ning, M. Lyu, D. Zhu, et al., Type-i aie photosensitizer loaded biomimetic system boosting cuproptosis to inhibit breast cancer metastasis and rechallenge, ACS Nano 17(2023) 10206-10217.
|
[15] |
B. Yang, Y. Chen, J. Shi, Tumor-specific chemotherapy by nanomedicine-enabled differential stress sensitization, Angew. Chem., Int. Ed. 59(2020) 9693-9701.
|
[16] |
Z. Zhou, H. Liang, R. Yang, et al., Gsh depletion-induced activation of dimersomes for potentiating the ferroptosis and immunotherapy of "cold" tumor, Angew. Chem., Int. Ed. 61(2022) e202202843.
|
[17] |
D. Suveera, D. Rajesh Kumar, P. Paolo Ettore, et al., Multiple biological activities of lactic acid in cancer: Influences on tumor growth, angiogenesis and metastasis, Current Pharmaceutical Design 18(2012) 1319-1330.
|
[18] |
D. Zhu, H. Chen, C. Huang, et al., H2o2 self-producing single-atom nanozyme hydrogels as light-controlled oxidative stress amplifier for enhanced synergistic therapy by transforming “ cold” tumors, Adv. Funct. Mater. 32(2022) 2110268.
|
[19] |
X. Yu, G. Xing, S. Sheng, et al., Neutrophil camouflaged stealth nanovehicle for photothermal-induced tumor immunotherapy by triggering pyroptosis, Adv. Sci. 10(2023) e2207456.
|
[20] |
Y. Ke, J. Zhu, Y. Chu, et al., Bifunctional fusion membrane-based hydrogel enhances antitumor potency of autologous cancer vaccines by activating dendritic cells, Adv. Funct. Mater. 32(2022) 2201306.
|