逆转肿瘤多药耐药策略进展

多药耐药MDR是肿瘤治疗的一大障碍 ,本文简述了MDR的可能机制与逆转克服策略及开发临床可应用的低毒有效逆转剂的新方向     

基因逆转肿瘤多药耐药的研究进展

化疗在恶性肿瘤的综合治疗中占有非常重要的地位,而耐药性是严重影响肿瘤病人化疗效果及生存的主要原因之一,其中多药耐药(multi-drug resistance,MDR)最具临床意义。多药耐药是指肿瘤细胞对某一化疗药物产生耐药性后,对其他化学结构及机理不同的化疗药物也产生交叉耐药性。研究表明MDR是一个多阶段发展、多因素参与的复杂事件。逆转肿瘤多药耐药是目前肿瘤化疗的研究热点之一。近年随着基础科学研究的不断深入,基因逆转肿瘤多药耐药的研究已从分子水平上,定点、多位点阻断多药耐药基因的表达,已取得一些显著的进展。本文对肿瘤多药耐药机制以及逆转肿瘤多药耐药性的相关基因做一简要综述。     

肿瘤多药耐药中的细胞色素P450

肿瘤化学治疗是目前抗肿瘤治疗最常用且最有效的方法,而在肿瘤化疗过程中出现的多药耐药现象,是导致治疗失败的主要原因.肿瘤多药耐药由多种机制共同作用而成,其中由酶类介导的多药耐药愈显重要.目前的研究发现,有多类细胞色素P450酶与肿瘤多药耐药的发生密切相关.本文着重对近年来有关细胞色素P450与肿瘤多药耐药的相关研究进行阐述,以期为肿瘤治疗提供一个新的方向.     

肿瘤靶向纳米载药系统的设计与构建

近年来将纳米载药系统应用于肿瘤靶向递药的研究层出不穷。与正常组织相比,肿瘤组织具有较低的pH环境、大量新生血管生成、 不规则的血流灌注、局部缺氧等特异性的微环境,利用这些特点进行合理的纳米载药系统设计能够实现肿瘤部位的高效递药及深层穿透, 显著提高肿瘤治疗效果。针对现有的肿瘤靶向纳米载药系统的构建与设计方法进行综述,以阐述纳米载药系统在肿瘤靶向传递中的研究进展     

多药耐药基因产物在宫颈癌中的研究进展

化疗多药耐药是影响宫颈癌化疗疗效的重要因素.目前关于多药耐药(multidmgresistance,MDR)产生机制的研究报道很多,主要包括以下几个方面:(1)典型性多药耐药:如多药耐药基因1(multidrug resistance gene 1,MDRI)及其编码的蛋白P糖蛋白(P-glycoprotein,P-gp)、多药耐药相关蛋白(multidrug resistance-associated protein,MRP)和肺耐药蛋白(lung resistance-related protein,LRP)基因及其编码的蛋白的过度表达;(2)谷胱苷肤-S-转移酶-π的表达;(3)非典型性多药耐药:由拓扑异构酶Ⅱ(Topo Ⅱ)介导的耐药机制;(4)细胞凋亡抑制(例如:突变型P53和癌基因Her-2/neu/C-erbB-2表达增加)等.这些因素之问还可以相互影响、共同作用,造成宫颈癌对多种抗肿瘤药物的耐药[2].本文就多药耐药基因产物在宫颈癌中的研究进展进行综述.     

葡萄糖神经酰胺合成酶与肿瘤多药耐药

多药耐药（multidrug resistenee,MDR）是肿瘤化疗失败的主要原因,多年来医学界一直致力于多药耐药机制的研究。神经酰胺信号系统在细胞凋亡中的作用逐渐引起人们的重视,神经酰胺是细胞凋亡过程中的第二信使,葡萄糖神经酰胺合成酶（glucosylceramide synthase,GCS）可以催化神经酰胺糖基化,使其转变为无细胞毒性的葡萄糖神经酰胺,进而促进鞘糖脂的合成,大量研究表明细胞内GCS水平的增高与MDR表型有关。     

肿瘤多药耐药:机制及逆转剂

肿瘤细胞多药耐药性(multidrug resistance,MDR)的产生是临床上导致肿瘤化疗失败的主要原因之一,因此寻找高效低毒的MDR逆转剂已成为肿瘤药物开发领域的热点。MDR的作用机制主要包括P-糖蛋白、多药耐药相关蛋白、乳腺癌耐药蛋白、肺耐药相关蛋白等等。多药耐药逆转剂包括钙离子通道阻滞剂、维拉帕米及其衍生物等等。本文主要介绍了MDR的作用机制以及肿瘤多药耐药逆转剂的研究进展。     

原发性肝癌的多药耐药

肝癌多药耐药的产生是多基因、多因素、多途径、多步骤综合作用的复杂过程,因此研究引起肝癌多药耐药的相关因素、作用机制及逆转MDR,提高肝癌化疗效果成为目前肝癌研究的热点,但不同的肝癌耐药细胞株有不同的多药耐药基因表型,如何针对不同的基因表型来逆转肝癌的多药耐药,是临床治疗肝癌需要面对的一个问题.     

质膜蛋白与肿瘤多药耐药现象

多药耐药(MDR)是影响肿瘤化疗效果的主要障碍,是由于在耐药细胞质膜上的一系列蛋白是使细胞免受有害因素的攻击。通过30年的研究．证实了肿瘤细胞逃逸化疗药物攻击的许多途径．很显然,多药耐药已经成为肿瘤阻碍各种化疗药物有效治疗的途径。因此．评价肿瘤多药耐药机制及其耐药程度,探讨新的逆转肿瘤多药耐药方法有助于提高化疗效果。本文就MDR中质膜蛋白的分子结构和表型、耐药机制及其逆转方法的研究进展进行综述。     

纳米技术在药物靶向治疗方面的现状和应用前景

纳米技术应用于药物载体的研究一直是近年生物医学所关注的热点。纳米药物载体在实现靶向性给药、缓释药物、提高难溶性药物与多肽药物的生物利用度、降低药物的毒副作用等方面表现出明显的优势。本文就近些年常见的纳米载药体的种类及其特性、常用制备方法、靶向治疗方面的研究进行综述,并对未来发展前景进行展望。     

Development of amphiphilic gamma-PGA-nanoparticle based tumor vaccine: potential of the nanoparticulate cytosolic protein delivery carrier

Nanoscopic therapeutic systems that incorporate biomacromolecules, such as protein and peptides, are emerging as the next generation of nanomedicine aimed at improving the therapeutic efficacy of biomacromolecular drugs. In this study, we report that poly(γ-glutamic acid)-based nanoparticles (γ-PGA NPs) are excellent protein delivery carriers for tumor vaccines that delivered antigenic proteins to antigen-presenting cells and elicited potent immune responses. Importantly, γ-PGA NPs efficiently delivered entrapped antigenic proteins through cytosolic translocation from the endosomes, which is a key process of γ-PGA NP-mediated anti-tumor immune responses. Our findings suggest that the γ-PGA NP system is suitable for the intracellular delivery of protein-based drugs as well as tumor vaccines.     

转铁蛋白导向脂质体核磁造影剂纳米粒子（TfNIR-LipNBD-Magnevist）——一种肿瘤靶向磁共振造影剂

造影剂辅助的核磁共振成像是目前肿瘤诊断的最吁方法之一。但是由于核磁共振成像内在的低灵敏性以及造影剂的非特异性,导致肿瘤早期诊断较为困难。文章将一种新的肿瘤靶向核磁造影剂纳米粒子应用于早期肿瘤的影像诊断。这种新的肿瘤靶向核磁造影剂纳米粒子由配体转铁蛋白（Tf）、纳米水平的正电脂质体（Lip）载体和临床常用的造影剂Magnevist（Tf^NIR-Lip^NBD-Magnevist）三部分构成。另外转铁蛋白和脂质体粒子上,亦标记了荧光物质用于确定转铁蛋白一脂质体一造影剂纳米粒子的靶向性,以及肿瘤的光学影像诊断。在体外实验中,利用激光共聚焦显微镜和光学影像证明了靶向纳米粒子介导的细胞内吞和特异性结合。在裸鼠肿瘤模型中,造影剂纳米粒子Tf^NIR-Lip^NBD-Magnevist经尾静脉注入后,显著增强了肿瘤内信号与周围组织的对比度。由造影剂纳米粒子介导的肿瘤内信号显著强于单独Magnevist辅助的肿瘤内信号。同时,利用光学影像方法,在肿瘤内检测到特异的荧光信号。其结果进一步支持了转铁蛋白一脂质体一造影利（Tf^NIR-Lip^NBD-Magnevist）纳米粒子的靶向性和肿瘤影像诊断的有效性。     

外泌体靶向递药在肿瘤治疗中的进展

外泌体是由细胞分泌、粒径为30～ 150 nm的纳米囊泡.外泌体具有优越的生物相容性、良好的载药功能以及便于修饰的膜表面,是一种具有潜力的药物递送载体.在肿瘤治疗研究中,可利用具有靶向识别功能的外泌体来降低脱靶效应,减少不良反应,达到增强治疗效果的目的 .归纳了用不同修饰方法增强外泌体靶向性的研究进展,总结了近五年来利...     

Toward a molecular understanding of nanoparticle–protein interactions

Wherever nanoparticles (NPs) come in contact with a living organism, physical and chemical interactions take place between the surfaces of the NPs and biomatter, in particular proteins. When NP are exposed to biological fluids, an adsorption layer of proteins, a “protein corona” forms around the NPs. Consequently, living systems interact with the protein-coated NP rather than with a bare NP. To anticipate biological responses to NPs, we thus require comprehensive knowledge of the interactions at the bio–nano interface. In recent years, a wide variety of biophysical techniques have been employed to elucidate mechanistic aspects of NP–protein interactions. In this brief review, we present the latest findings regarding the composition of the protein corona as it forms on NPs in the blood stream. We also discuss molecular aspects of this adsorption layer and its time evolution. The current state of knowledge is summarized, and issues that still need to be addressed to further advance our understanding of NP–protein interactions are identified.     

Cryo-electron tomography of nanoparticle transmigration into liposome

Nanoparticle transport across cell membrane plays a crucial role in the development of drug delivery systems as well as in the toxicity response induced by nanoparticles. As hydrophilic nanoparticles interact with lipid membranes and are able to induce membrane perturbations, hypothetic mechanisms based on membrane curvature or hole formation have been proposed for activating their transmigration. We report on the transport of hydrophilic silica nanoparticles into large unilamellar neutral DOPC liposomes via an internalization process. The strong adhesive interactions of lipid membrane onto the silica nanoparticle triggered liposome deformation until the formation of a curved neck. Then the rupture of this membrane neck led to the complete engulfment of the nanoparticle. Using cryo-electron tomography we determined 3D architectures of intermediate steps of this process unveiling internalized silica nanoparticles surrounded by a supported lipid bilayer. This engulfing process was achieved for a large range of particle size (from 30 to 200 nm in diameter). These original data provide interesting highlights for nanoparticle transmigration and could be applied to biotechnology development.     

七甲川花菁染料作为肿瘤靶向和光动力治疗载体的研究进展

七甲川花菁近红外荧光染料(NIRF)可直接被肿瘤细胞特异性吸收,具有肿瘤靶向性。与化疗药物偶联后,该类染料可通过血脑屏障将药物转运至肿瘤部位,不仅可以减少化疗药物使用剂量,降低药物的毒副作用,也可通过近红外荧光成像实现对肿瘤治疗的实时监控。七甲川花菁染料所展示的线粒体毒性和光敏特性,可直接杀死肿瘤细胞,抑制肿瘤新生血管的形成。通过纳米包裹,能够显著增强该类染料的肿瘤靶向能力,实现实时跟踪药物释放情况。七甲川花菁染料特异性识别肿瘤细胞的能力与有机阴离子转运肽的作用密切相关,缺氧和线粒体膜电位也参与了染料吸收的调控。这些发现有利于将近红外荧光染料应用于肿瘤的靶向治疗。     

超声靶向微泡破坏与载药/载基因纳米粒联合应用的生物物理学机制及应用研究进展

超声靶向微泡破坏(ultrasound-targeted microbubble destruction, UTMD)能够安全、高效、简便地递送药物与基因,是当前超声医学领域的研究热点,其机制主要涉及超声辐照微泡引起的空化效应及其二级效应、内吞作用与声辐射力。近年来,随着生物医学材料科学迅猛发展,纳米载药系统取材更加广泛,制备方法愈发精良,载药量日益提高。将纳米载药系统与UTMD进行联合,可以扬长避短,为肿瘤等多种疾病的治疗带来新的思路与希望。本文旨在对UTMD与载药/载基因纳米粒联合应用的生物物理学机制及应用研究进行综述并提出展望。     

Multifunctional Nanoparticles Delivering Small Interfering RNA and Doxorubicin Overcome Drug Resistance in Cancer

Drug resistance is a major challenge to the effective treatment of cancer. We have developed two nanoparticle formulations, cationic liposome-polycation-DNA (LPD) and anionic liposome-polycation-DNA (LPD-II), for systemic co-delivery of doxorubicin (Dox) and a therapeutic small interfering RNA (siRNA) to multiple drug resistance (MDR) tumors. In this study, we have provided four strategies to overcome drug resistance. First, we formed the LPD nanoparticles with a guanidinium-containing cationic lipid, i.e. N,N-distearyl-N-methyl-N-2-(N′-arginyl) aminoethyl ammonium chloride, which can induce reactive oxygen species, down-regulate MDR transporter expression, and increase Dox uptake. Second, to block angiogenesis and increase drug penetration, we have further formulated LPD nanoparticles to co-deliver vascular endothelial growth factor siRNA and Dox. An enhanced Dox uptake and a therapeutic effect were observed when combined with vascular endothelial growth factor siRNA in the nanoparticles. Third, to avoid P-glycoprotein-mediated drug efflux, we further designed another delivery vehicle, LPD-II, which showed much higher entrapment efficiency of Dox than LPD. Finally, we delivered a therapeutic siRNA to inhibit MDR transporter. We demonstrated the first evidence of c-Myc siRNA delivered by the LPD-II nanoparticles down-regulating MDR expression and increasing Dox uptake in vivo. Three daily intravenous injections of therapeutic siRNA and Dox (1.2 mg/kg) co-formulated in either LPD or LPD-II nanoparticles showed a significant improvement in tumor growth inhibition. This study highlights a potential clinical use for the multifunctional nanoparticles with an effective delivery property and a function to overcome drug resistance in cancer. The activity and the toxicity of LPD- and LPD-II-mediated therapy are compared.