CLC number:
On-line Access: 2022-06-16
Received: 2022-03-28
Revision Accepted: 2022-05-19
Crosschecked: 2022-09-16
Cited: 0
Clicked: 677
Tianjiao PENG, Jun YAO. Development and application of bionic systems consisting of tumor-cell membranes[J]. Journal of Zhejiang University Science B,in press.Frontiers of Information Technology & Electronic Engineering,in press.https://doi.org/10.1631/jzus.B2200156 @article{title="Development and application of bionic systems consisting of tumor-cell membranes", %0 Journal Article TY - JOUR
一种潜在的技术--肿瘤细胞膜仿生系统1河南科技大学临床医学院,中国洛阳市,471003 2河南科技大学第一附属医院,肿瘤医院,中国洛阳市,471003 3河南科技大学第一附属医院,表观遗传学与分子生物学实验室,中国洛阳市,471003 摘要:恶性肿瘤严重威胁人类健康,近十年间,肿瘤治疗取得了突破性进展。肿瘤细胞膜仿生系统的发展进一步增强了肿瘤靶向策略。来源于自体的肿瘤细胞膜能够消除非生物因素,并显示出高度的生物相容性。此外,肿瘤的快速增殖和易于培养使肿瘤细胞膜比其他类型的生物膜更容易获得。本文首先介绍并回顾细胞膜仿生纳米系统的提出及发展,并且重点描述了在药物递送、光热和成像、肿瘤疫苗方面的应用。其次,对其安全性及可能存在的问题进行讨论。最后提出未来发展的可能方向。 关键词组: Darkslateblue:Affiliate; Royal Blue:Author; Turquoise:Article
Reference[1]BarenholzY, 2012. Doxil®—the first FDA-approved nano-drug: lessons learned. J Control Release, 160(2):117-134. [2]BlassE, OttPA, 2021. Advances in the development of personalized neoantigen-based therapeutic cancer vaccines. Nat Rev Clin Oncol, 18(4):215-229. [3]BurchPA, CroghanGA, GastineauDA, et al., 2004. Immunotherapy (APC8015, Provenge®) targeting prostatic acid phosphatase can induce durable remission of metastatic androgen-independent prostate cancer: a phase 2 trial. Prostate, 60(3):197-204. [4]CaoSY, PetersonSM, MüllerS, et al., 2021. A membrane protein display platform for receptor interactome discov [5]ery. Proc Natl Acad Sci USA, 118(39):e2025451118. [6]ChenL, QinH, ZhaoRF, et al., 2021. Bacterial cytoplasmic membranes synergistically enhance the antitumor activity of autologous cancer vaccines. Sci Transl Med, 13(601):eabc2816. [7]ChenM, ChenM, HeJT, 2019. Cancer cell membrane cloaking nanoparticles for targeted co-delivery of doxorubicin and PD-L1 siRNA. Artif Cells Nanomed Biotechnol, 47(1):1635-1641. [8]ChenZ, ZhaoPF, LuoZY, et al., 2016. Cancer cell membrane-biomimetic nanoparticles for homologous-targeting dual-modal imaging and photothermal therapy. ACS Nano, 10(11):10049-10057. [9]FangRH, HuCMJ, LukBT, et al., 2014. Cancer cell membrane-coated nanoparticles for anticancer vaccination and drug delivery. Nano Lett, 14(4):2181-2188. [10]GarberK, 2022. The PROTAC gold rush. Nat Biotechnol, 40(1):12-16. [11]GongC, YuX, YouB, et al., 2020. Macrophage-cancer hybrid membrane-coated nanoparticles for targeting lung metastasis in breast cancer therapy. J Nanobiotechnology, 18:92. [12]HanahanD, 2022. Hallmarks of cancer: new dimensions. Cancer Discov, 12(1):31-46. [13]HuCMJ, ZhangL, AryalS, et al., 2011. Erythrocyte membrane-camouflaged polymeric nanoparticles as a biomimetic delivery platform. Proc Natl Acad Sci USA, 108(27):10980-10985. [14]HuQY, SunWJ, QianCE, et al., 2015. Anticancer platelet-mimicking nanovehicles. Adv Mater, 27(44):7043-7050. [15]JiangQ, LiuY, GuoRR, et al., 2019. Erythrocyte-cancer hybrid membrane-camouflaged melanin nanoparticles for enhancing photothermal therapy efficacy in tumors. Biomaterials, 192:292-308. [16]JiangY, KrishnanN, ZhouJR, et al., 2020. Engineered cell-membrane-coated nanoparticles directly present tumor antigens to promote anticancer immunity. Adv Mater, 32(30):2001808. [17]KantoffPW, HiganoCS, ShoreND, et al., 2010. Sipuleucel-T immunotherapy for castration-resistant prostate cancer. N Engl J Med, 363(5):411-422. [18]KeskinDB, AnandappaAJ, SunJ, et al., 2019. Neoantigen vaccine generates intratumoral T cell responses in phase Ib glioblastoma trial. Nature, 565(7738):234-239. [19]LiAX, ZhaoYN, LiYX, et al., 2021. Cell-derived biomimetic nanocarriers for targeted cancer therapy: cell membranes and extracellular vesicles. Drug Deliv, 28(1):1237-1255. [20]LiBW, WangF, GuiLJ, et al., 2018. The potential of biomimetic nanoparticles for tumor-targeted drug delivery. Nanomedicine (Lond), 13(16):2099-2118. [21]LiRX, HeYW, ZhangSY, et al., 2018. Cell membrane-based nanoparticles: a new biomimetic platform for tumor diagnosis and treatment. Acta Pharm Sin B, 8(1):14-22. [22]LinYY, ChenCY, MaDL, et al., 2022. Cell-derived artificial nanovesicle as a drug delivery system for malignant mela [23]noma treatment. Biomed Pharmacother, 147:112586. [24]LiuCH, WangDD, ZhangSY, et al., 2019. Biodegradable biomimic copper/manganese silicate nanospheres for chemodynamic/photodynamic synergistic therapy with simultaneous glutathione depletion and hypoxia relief. ACS Nano, 13(4):4267-4277. [25]LiuHJ, WangJF, WangMM, et al., 2021. Biomimetic nanomedicine coupled with neoadjuvant chemotherapy to suppress breast cancer metastasis via tumor microenvironment remodeling. Adv Funct Mater, 31(25):2100262. [26]LiuZW, WangFM, LiuXP, et al., 2021. Cell membrane-camouflaged liposomes for tumor cell-selective glycans engineering and imaging in vivo. Proc Natl Acad Sci USA, 118(30):e2022769118. [27]MengXZ, WangJJ, ZhouJD, et al., 2021. Tumor cell membrane-based peptide delivery system targeting the tumor microenvironment for cancer immunotherapy and diagnosis. Acta Biomater, 127:266-275. [28]ParodiA, QuattrocchiN, van de VenAL, et al., 2013. Synthetic nanoparticles functionalized with biomimetic leukocyte membranes possess cell-like functions. Nat Nanotechnol, 8(1):61-68. [29]PeiWY, WanX, ShahzadKA, et al., 2018. Direct modulation of myelin-autoreactive CD4+ and CD8+ T cells in EAE mice by a tolerogenic nanoparticle co-carrying myelin peptide-loaded major histocompatibility complexes, CD47 and multiple regulatory molecules. Int J Nanomed, 13:3731-3750. [30]TanSW, WuTT, ZhangD, et al., 2015. Cell or cell membrane-based drug delivery systems. Theranostics, 5(8):863-881. [31]WangHJ, LiuY, HeRQ, et al., 2020. Cell membrane biomimetic nanoparticles for inflammation and cancer targeting in drug delivery. Biomater Sci, 8(2):552-568. [32]WangJ, ZhuMT, NieGJ, 2021. Biomembrane-based nanostructures for cancer targeting and therapy: from synthetic liposomes to natural biomembranes and membrane-vesicles. Adv Drug Deliv Rev, 178:113974. [33]WuLL, LiQ, DengJJ, et al., 2021. Platelet-tumor cell hybrid membrane-camouflaged nanoparticles for enhancing therapy efficacy in glioma. Int J Nanomed, 16:8433-8446. [34]ZhaoQC, BarclayM, HilkensJ, et al., 2010. Interaction between circulating galectin-3 and cancer-associated MUC1 enhances tumour cell homotypic aggregation and prevents anoikis. Mol Cancer, 9:154. [35]ZhuJY, ZhengDW, ZhangMK, et al., 2016. Preferential cancer cell self-recognition and tumor self-targeting by coating nanoparticles with homotypic cancer cell membranes. Nano Lett, 16(9):5895-5901. [36]ZhuangJ, HolayM, ParkJH, et al., 2019. Nanoparticle delivery of immunostimulatory agents for cancer immunotherapy. Theranostics, 9(25):7826-7848. [37]ZitvogelL, RegnaultA, LozierA, et al., 1998. Eradication of established murine tumors using a novel cell-free vaccine: dendritic cell derived exosomes. Nat Med, 4(5):594-600. [38]ZouMZ, LiZH, BaiXF, et al., 2021. Hybrid vesicles based on autologous tumor cell membrane and bacterial outer membrane to enhance innate immune response and personalized tumor immunotherapy. Nano Lett, 21(20):8609-8618. Journal of Zhejiang University-SCIENCE, 38 Zheda Road, Hangzhou
310027, China
Tel: +86-571-87952783; E-mail: cjzhang@zju.edu.cn Copyright © 2000 - 2024 Journal of Zhejiang University-SCIENCE |
Open peer comments: Debate/Discuss/Question/Opinion
<1>