|本期目录/Table of Contents|

[1]朱建强,郑志文,付青峰,等.人工纳米材料在膀胱癌诊疗中的研究进展[J].天津医科大学学报,2022,28(05):563-567.
点击复制

人工纳米材料在膀胱癌诊疗中的研究进展(PDF)
分享到:

《天津医科大学学报》[ISSN:1006-8147/CN:12-1259/R]

卷:
28卷
期数:
2022年05期
页码:
563-567
栏目:
综述
出版日期:
2022-09-20

文章信息/Info

Title:
-
文章编号:
1006-8147(2022)05-0563-05
作者:
朱建强郑志文付青峰柳乐意 综述张志宏徐勇 审校
(天津医科大学第二医院泌尿外科,天津市泌尿外科研究所,天津 300211)
Author(s):
-
关键词:
人工纳米材料膀胱癌诊断治疗
Keywords:
-
分类号:
R737.14
DOI:
-
文献标志码:
A
摘要:
目前,膀胱癌的临床诊疗技术进展缓慢,亟需寻求新的诊疗手段提高其疗效和预后。近年来,人工纳米材料在生物医药领域的研究与应用进展迅速,为恶性肿瘤的诊疗提供了新的视角,弥补了诸多传统技术手段的固有缺陷,具有重要的临床转化应用价值。现对人工纳米材料在膀胱癌诊疗中的应用研究进展进行综述,主要包括其在尿液学检查、膀胱镜检查、影像学检查、病理学检查、手术治疗和药物治疗等方面的研究进展,以期为改善膀胱癌的诊疗现状提供帮助。
Abstract:
-

参考文献/References:

[1] MIRSHAFIEE V,JIANG W,SUN B,et al. Facilitating translational nanomedicine via predictive safety assessment[J]. Mol Ther,2017,25(7):1522-1530.
[2] SHI J,KANTOFF P W,WOOSTER R,et al. Cancer nanomedicine:progress,challenges and opportunities[J]. Nat rev Cancer,2017,17(1):20-37.
[3] LENIS A T,LEC P M,CHAMIE K,et al. Bladder cancer:a review[J]. JAMA,2020,324(19):1980-1991.
[4] LEI Q,ZHAO L,YE S,et al. Rapid and quantitative detection of urinary Cyfra21-1 using fluorescent nanosphere-based immunochromatographic test strip for diagnosis and prognostic monitoring of bladder cancer[J]. Artif Cells Nanomed Biotechnol,2019,47(1):4266-4272.
[5] ISLAM M A,XU Y,TAO W,et al. Restoration of tumour-growth suppression in vivo via systemic nanoparticle-mediated delivery of PTEN mRNA[J]. Nat biomed engineer,2018,2(11):850-864.
[6] ZOU L,LI X,ZHANG J,et al. A highly sensitive catalytic hairpin assembly-based dynamic light-scattering biosensors for telomerase detection in bladder cancer diagnosis[J]. Analyt chem,2020,92(18):12656-12662.
[7] NOSSIER A I,EISSA S,ISMAIL M F,et al. Direct detection of hyaluronidase in urine using cationic gold nanoparticles:a potential diagnostic test for bladder cancer [J]. Bios Bioel,2014,54:7-14.
[8] YANG Y T,HSU I L,CHENG T Y,et al. Off-resonance sers nanoprobe-targeted screen of biomarkers for antigens recognition of bladder normal and aggressive cancer cells[J]. Analytchem,2019,91(13):8213-8220.
[9] DAVIS R M,KISS B,TRIVEDI D R,et al. Surface-enhanced raman scattering nanoparticles for multiplexed imaging of bladder cancer tissue permeability and molecular phenotype[J]. ACS nano,2018,12(10):9669-9679.
[10] FRAN?觭OIS A,BATTAH S,MACROBERT A J,et al. Fluorescence diagnosis of bladder cancer:a novel in vivo approach using 5-aminolevulinic acid(ALA)dendrimers[J]. BJU Int,2012,110(11 Pt C):E1155-E1162.
[11] BIRKH?覿USER F D,STUDER U E,FROEHLICH J M,et al. Combined ultrasmall superparamagnetic particles of iron oxide-enhanced and diffusion-weighted magnetic resonance imaging facilitates detection of metastases in normal-sized pelvic lymph nodes of patients with bladder and prostate cancer[J]. Eur Urol,2013,64(6):953-960.
[12] DING C,WU K,WANG W,et al. Synthesis of a cell penetrating peptide modified superparamagnetic iron oxide and MRI detection of bladder cancer [J]. Oncotarget,2017,8(3):4718-4729.
[13] SWEENEY S K,LUO Y,O′DONNELL M A,et al. Nanotechnology and cancer:improving real-time monitoring and staging of bladder cancer with multimodal mesoporous silica nanoparticles[J]. Cancer nanotechnol,2016,7:3.
[14] LIU H,MEI C,DENG X,et al. Rapid visualizing and pathological grading of bladder tumor tissues by simple nanodiagnostics [J]. Biomaterials,2021,264:120434.
[15] POLIKARPOV D,LIANG L,CARE A,et al. Functionalized upconversion nanoparticles for targeted labelling of bladder cancer cells[J]. Biomolecules,2019,9(12):820.
[16] FERREIRA L A B,GARCIA-FOSSA F,RADAIC A,et al. Biogenic silver nanoparticles:in vitro and in vivo antitumor activity in bladder cancer [J]. Eur J Pharm Biopharm,2020,151:162-170.
[17] SUN R,LIU X,LI G,et al. Photoactivated H(2)nanogenerator for enhanced chemotherapy of bladder cancer[J]. ACS nano,2020, 14(7):8135-8148.
[18] KATES M,DATE A,YOSHIDA T,et al. Preclinical evaluation of intravesical cisplatin nanoparticles for non-muscle-invasive bladder cancer [J]. Clin Cancer Res,2017,23(21):6592-6601.
[19] HORTEL?觔O A C,CARRASCOSA R,MURILLO-CREMAES N,et al. Targeting 3D bladder cancer spheroids with urease-powered nanomotors [J]. ACS nano,2019,13(1):429-439.
[20] XU X,LIU K,JIAO B,et al. Mucoadhesive nanoparticles based on ROS activated gambogic acid prodrug for safe and efficient intravesical instillation chemotherapy of bladder cancer[J].J Control Release,2020,324:493-504.
[21] WANG B,ZHANG K,WANG J,et al. Poly(amidoamine)-modified mesoporous silica nanoparticles as a mucoadhesive drug delivery system for potential bladder cancer therapy[J]. Coll Surf B Bioint,2020,189:110832.
[22] WHANG Y M,YOON D H,HWANG G Y,et al. Liposome-encapsulated bacillus calmette-guérin cell wall skeleton enhances antitumor efficiency for bladder cancer in vitro and in vivo via induction ofAMP-activated Protein Kinase[J]. Cancers,2020,12(12):3679.
[23] SAMADDAR S,MAZUR J,SARGENT J,et al. Immunostimulatory response of RWFV peptide-targeted lipid nanoparticles on bladder tumor associated cells[J]. ACS Appl Bio Mater,2021,4(4):3178-3188.
[24] LIANG Y,WANG Y,WANG L,et al. Self-crosslinkable chitosan-hyaluronic acid dialdehyde nanoparticles for CD44-targeted siRNA delivery to treat bladder cancer[J]. Bioact Mater,2021,6(2):433-446.
[25] ZENG S,GAO H,LI C,et al. Boosting Photothermal theranostics via tict and molecular motions for photohyperthermia therapy of muscle-invasive bladder cancer[J]. Adv Healthc Mater,2021,10(24):e2101063.
[26] LIN T,ZHAO X,ZHAO S,et al. O(2)-generating MnO(2) nanoparticles for enhanced photodynamic therapy of bladder cancer by ameliorating hypoxia[J]. Theranostics,2018,8(4):990-1004.
[27] LIN T Y,LI Y,LIU Q,et al. Novel theranostic nanoporphyrins for photodynamic diagnosis and trimodal therapy for bladder cancer[J]. Biomaterials,2016,104:339-351.
[28] LI G,WANG S,DENG D,et al. Fluorinated chitosan to enhance transmucosal delivery of sonosensitizer-conjugated catalase for sonodynamic bladder cancer treatment post-intravesical instillation[J]. ACS Nano,2020,14(2):1586-1599.
[29] QI A,WANG C,NI S,et al. Intravesical mucoadhesive hydrogel induces chemoresistant bladder cancer ferroptosis through delivering iron oxide nanoparticles in a three-tier strategy[J]. ACS Appl Mat Interf,2021.
[30] ZHU G,WANG K,QIN H,et al. Internal cross-linked polymeric nanoparticles with dual sensitivity for combination therapy of muscle-invasive bladder cancer[J]. J Nanobiotechnol,2020,18(1):124.
[31] TAN P,CAI H,WEI Q,et al. Enhanced chemo-photodynamic therapy of an enzyme-responsive prodrug in bladder cancer patient-derived xenograft models[J]. Biomaterials,2021,277:121061.
[32] WEI S,GAO J,ZHANG M,et al. Dual delivery nanoscale device for miR-451 and adriamycin co-delivery to combat multidrug resistant in bladder cancer[J]. Biom Pharm,2020,122:109473.
[33] LIN T,ZHANG Q,YUAN A,et al. Synergy of tumor microenvironment remodeling and autophagy inhibition to sensitize radiation for bladder cancer treatment[J].Theranostics,2020,10(17):7683-7696.

相似文献/References:

[1]陈可新,郝晓东,薄志强,等.≤pT2N0M0膀胱癌根治术后近期复发的影响因素分析[J].天津医科大学学报,2017,23(04):357.
 CHEN Ke-xin,HAO Xiao-dong,BO Zhi-qiang,et al.Influencing factors and prognosis of short-term relapse after radical cystectomy of primary bladder cancer(≤pT2N0M0)[J].Journal of Tianjin Medical University,2017,23(05):357.
[2]孟旭英,李珍瑾,郭剑超.组蛋白甲基转移酶EZH2抑制剂联合抗癌药物对膀胱癌细胞功能影响的研究[J].天津医科大学学报,2018,24(01):25.
 MENG Xu-ying,LI Zhen-jin,GUO Jian-chao.Effect of histone methyltransferase EZH2 inhibitor combined with anticancer drugs on migration and proliferation of bladder cancer cells[J].Journal of Tianjin Medical University,2018,24(05):25.
[3]刘 莉 康家旗 综 述,刘晓强 审 校.膀胱癌外周血生物标志物研究进展[J].天津医科大学学报,2018,24(06):566.
[4]刘志飞,张志宏,邢力永,等.RRM1 mRNA与吉西他滨药物膀胱灌注治疗膀胱癌疗效的关系[J].天津医科大学学报,2019,25(01):51.
 LIU Zhi-fei,ZHANG Zhi-hong,XING Li-yong,et al.The relationship between expression of RRM1 mRNA and efficacy of intravesical of gemcitabine in patients with nonmuscle-insive bladder caner[J].Journal of Tianjin Medical University,2019,25(05):51.
[5]付真睿,盛 飞,张昌文,等.SOX6在膀胱癌发生发展中的作用及相关机制[J].天津医科大学学报,2019,25(04):373.
 FU Zhen-rui,SHENG Fei,ZHANG Chang-wen,et al.The characteristics of SOX6 in development of bladder cancer and relevant mechanism[J].Journal of Tianjin Medical University,2019,25(05):373.
[6]王银蕾,杨 瀚,高 杰,等.PITX2启动子甲基化及其与膀胱癌临床病理的关系[J].天津医科大学学报,2020,26(01):39.
 WANG Yin-lei,YANG Han,GAO Jie,et al.Methylation of PITX2 promoter and relationship with clinical pathology of bladder cancer[J].Journal of Tianjin Medical University,2020,26(05):39.
[7]王玉杰,沈冲,高深,等.长链非编码RNA-FENDRR在膀胱癌组织中的表达及临床意义[J].天津医科大学学报,2020,26(05):445.
 WANG Yu-jie,SHEN Chong,GAO Shen,et al.Expression of long non-coding RNA FENDRR in human bladder cancer tissues and Clinical significance[J].Journal of Tianjin Medical University,2020,26(05):445.
[8]陆益,于佳熙,梁政.氯丙嗪对膀胱癌BT-B细胞迁移功能的影响[J].天津医科大学学报,2022,28(06):621.
 LU Yi,YU Jia-xi,LIANG Zheng.The effect of chlorpromazine on the migration of BT-B cellsin bladder cancer[J].Journal of Tianjin Medical University,2022,28(05):621.
[9]孙晓宇 张志宏 张昌文.膀胱癌类器官模型的研究进展[J].天津医科大学学报,2023,29(05):564.
[10]朱 亮,陈业刚.基于失巢凋亡相关标志物预测膀胱癌患者预后[J].天津医科大学学报,2024,30(01):56.[doi:10.20135/j.issn.1006-8147.2024.01.0056]
 ZHU Liang,CHEN Yegang.Prognosis of patients with bladder cancer predicted by biomarker associated with anoikis[J].Journal of Tianjin Medical University,2024,30(05):56.[doi:10.20135/j.issn.1006-8147.2024.01.0056]

备注/Memo

备注/Memo:
基金项目 国家自然科学基金(21806123,22176142,22076138);天津市青年人才托举工程(TJSQNTJ-2020-07)
作者简介 朱建强(1988-),男,主治医师,博士,研究方向:泌尿系统肿瘤诊疗;通信作者:徐勇,E-mail:yongxutianjin@126.com。
更新日期/Last Update: 2022-09-20