磁性氧化铁纳米药物载体的研究进展

近年来,磁性氧化铁靶向纳米载体作为载药系统引起了人们的关注。磁性靶向载药系统和靶向药物治疗的目的是药物载体载药后,在外部磁场的作用下直接靶向富集在肿瘤或病损组织,杀伤病损细胞,对人体无害或减少毒副作用。本文介绍了影响磁纳米颗粒在体内作用的设计参数,并总结了被广泛应用于氧化铁纳米颗粒的制备,表面修饰,功能化的方法及氧化铁纳米载体在靶向载药体系中的应用。     

核酸适配体在靶向药物传递中的研究进展

抗癌药物的毒副作用限制了其临床应用,纳米药物载体可实现药物在病灶部位的聚集而不影响正常组织,从而降低药物毒副作用.在药物载体表面修饰靶向配体,以提高药物载体主动靶向进入到细胞的能力,可有效地将药物释放到靶细胞,大大提高药效.核酸适配体(aptamer)作为一种新型的靶向分子,近几年已被运用到靶向药物传递的研究中.本文介绍了几种适配体靶向载药体系,如适配体-药物、适配体-脂质体、适配体-聚合物胶束、适配体-聚合物纳米颗粒、适配体-金属颗粒以及适配体-支化聚合物等载药体系,并对当前研究的热点以及存在的问题和不足进行了评述.     

磁性纳米颗粒作为载体在基因转染中的研究进展

磁性纳米颗粒具有很强的结合、浓缩与保护DNA的作用,具有超顺磁性、较高的安全性和低的免疫原性,可以结合大片段DNA,在外加磁场的作用下可实现安全、高效的基因靶向性运输,提高外源基因的转染效率。由于磁性纳米颗粒的独特性质,使得其作为非病毒载体在基因治疗中的应用进展迅速。我们简要介绍磁性纳米材料的特点、种类及结构,磁性纳米基因载体的特点,以及磁性纳米颗粒作为载体在基因转染中的应用情况。     

Fe3O4磁性纳米粒子在生物医学领域的应用

Fe_3O_4磁性纳米粒子由于其良好的磁学性能,被广泛应用到了化学、生物、物理、环境保护等各个领域。尤其是在生物医学领域中的应用越来越受到研究者的关注。由于其所具有的优秀的超顺磁性性质,Fe_3O_4磁性纳米粒子可以作为造影剂,增强核磁共振成像的对比度和成像效果;也可以结合到纳米载药系统内用于药物的靶向输送;也可以包埋到蛋白内部用于蛋白的磁性分离;也可以用于基因治疗,提高靶细胞的转染效率;由于其在近红外光的作用下具有很好的光热转换效果,使温度升高,展现出的良好热疗效果,Fe_3O_4磁性纳米粒子又可以用于癌细胞的热疗。本文针对其在该领域中作为药物的靶向传递,蛋白的磁分离,核磁共振成像,热疗,以及基因治疗的载体等方面的研究应用进行了系统性的总结,阐述了Fe_3O_4磁性纳米粒子在生物医学领域中各种应用进展和优势。     

纳米颗粒作为基因载体的应用

随着纳米技术的发展,纳米颗粒因具有较高的转染效率、良好的靶向性及有效的基因保护作用而被用作基因载体。简要介绍了磁性纳米颗粒、硅纳米颗粒及阳离子多聚物颗粒等的研究进展。     

磁性氧化铁纳米颗粒及其磁共振成像应用

磁性氧化铁纳米颗粒在磁共振成像方面的应用,已经在全世界范围内得到了广泛的关注,相关研究也被各国科学家高度重视.目前,磁性氧化铁纳米颗粒正在从早期的基于被动识别的肝部磁共振造影,快速转向基于主动识别的磁共振分子影像应用.本文将围绕磁性氧化铁纳米颗粒的生物体内应用,着重介绍磁性纳米颗粒的制备及其在疾病诊断,尤其是在肿瘤早期...     

新型纳米靶向给药系统载体材料的设计

新型纳米靶向给药系统的研究与开发对于难治愈性疾病（尤其是肿瘤）的治疗具有重大意义,而其发展很大程度上取决于载体材料 的设计。构思巧妙、设计合理的载体材料能使载体实现靶向功能,将药物定位浓集于病灶部位,并最大限度地发挥高效低毒的作用。基于 不同的靶向策略,包括被动靶向、主动靶向和响应肿瘤微环境的靶向,综述了近年来一些新型纳米载体材料的设计,为新型纳米靶向给药 系统的研究提供参考。     

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。     

聚乙二醇-聚乳酸嵌段共聚物在药物递送系统中的应用

聚乙二醇-聚乳酸嵌段共聚物具备良好的生物相容性和生物可降解性,是良好的纳米级药物载体。嵌段共聚物具有载药能力强、粒径小、体内循环时间长、主动靶向性和被动靶向性等特点,因此在药物递送系统中得到广泛应用。简要介绍了聚乙二醇-聚乳酸嵌段共聚物的合成和性质,及其作为脂质体、胶束、微球等载体在药物递送系统中的最新进展。     

纳米载药系统在肿瘤多药耐药中的应用

当今世界,肿瘤已经成为威胁人类健康的重大疾病。在肿瘤疾病中,化疗可控制肿瘤的生长和转移,增强放疗的疗效,是治疗肿瘤疾病的主要手段之一。而肿瘤多药耐药是影响化疗药物疗效、引起化疗失败的重要原因,影响肿瘤患者的治愈效果,降低生存率。如何提高化疗的疗效,延长肿瘤患者的寿命成为医学界的难题。纳米载药系统是生物医学领域研究的热点,相对于单一药物,纳米载药体现了许多优越性,具有良好的应用前景。纳米级颗粒更有利于药代动力学,这些纳米载药颗粒通过被动和主动的机制表现出在全身血液循环寿命延长,持续的药物释放动力,使其能更好的在肿瘤细胞中积累而发挥作用,提高化疗的疗效。本文综述了肿瘤多药耐药研究中主要的纳米载体以及它们在逆转多药耐药方面的应用,并展望载药系统的有更多更好的发展趋势。     

Magnetically controlled targeted micro-carrier systems

Magnetically controlled targeted drug delivery systems are aimed at concentrating drugs at a defined target site, with the aid of a magnetic field. This technique has been developed specifically for directing drugs away from the reticuloendothelial system (RES). Literature on this topic suggests that these delivery systems are capable of altering the distribution of chemotherapeutic agents in the body. Hence these delivery devices offer the possibility of improving the therapeutic efficacy of the associated drugs. This paper reviews the work done to date towards the development and evaluation of biodegradable and non-biodegradable magnetic targeted drug delivery systems and outlines their future prospects and limitations in cancer chemotherapy.     

Comparative disposition of adriamycin delivered via magnetic albumin microspheres in presence and absence of magnetic field in rats

The multiple tissue disposition of adriamycin hydrochloride delivered via magnetic albumin microspheres, in absence (control) and presence of magnetic field (experimental), has been investigated in rats. The animal tail was demarcated into three segments: T1, the dosing-site; T2, the target-site; and T3, the post target-site. Following the arterial cannulation at T1, 0.4 mg/kg of microsphere associated drug was administered to the control as well as the experimental animals. In experimental group, the target-site T2 was exposed to a 8000 G magnetic field for 30 min. In both groups the animals were sacrificed in triplicates over a 48 hr period and their various tissues monitored for drug concentrations using HPLC. In presence of magnetic field, the microspheres demonstrated 16 fold increase in the maximum drug concentration, 6 fold increase in drug exposure and 6 fold increase in the drug targeting efficiency for T2. Drug delivery to most non-target tissues, including heart and liver, was substantially reduced. The results quantitatively suggest that the efficacy of magnetic albumin microspheres in the targeted delivery of incorporated therapeutic agent is predominantly due to the magnetic effects, and not alone due to the characteristics of the micro-carrier system.     

Newly engineered magnetic erythrocytes for sustained and targeted delivery of anti-cancer therapeutic compounds

Cytotoxic chemotherapy of cancer is limited by serious, sometimes life-threatening, side effects that arise from toxicities to sensitive normal cells because the therapies are not selective for malignant cells. So how can they be selectively improved? Alternative pharmaceutical formulations of anti-cancer agents have been investigated in order to improve conventional chemotherapy treatment. These formulations are associated with problems like severe toxic side effects on healthy organs, drug resistance and limited access of the drug to the tumor sites suggested the need to focus on site-specific controlled drug delivery systems. In response to these concerns, we have developed a new drug delivery system based on magnetic erythrocytes engineered with a viral spike fusion protein. This new erythrocyte-based drug delivery system has the potential for magnetic-controlled site-specific localization and highly efficient fusion capability with the targeted cells. Here we show that the erythro-magneto-HA virosomes drug delivery system is able to attach and fuse with the target cells and to efficiently release therapeutic compounds inside the cells. The efficacy of the anti-cancer drug employed is increased and the dose required is 10 time less than that needed with conventional therapy.     

Bacterially-Derived Nanocells for Tumor-Targeted Delivery of Chemotherapeutics and Cell Cycle Inhibitors

Chemotherapeutic drug therapy in cancer is seriously hampered by severe toxicity primarily due to indiscriminate drug distribution and consequent collateral damage to normal cells. Molecularly targeted drugs such as cell cycle inhibitors are being developed to achieve a higher degree of tumor cell specificity and reduce toxic side effects. Unfortunately, relative to the cytotoxics, many of the molecularly targeted drugs are less potent and the target protein is expressed only at certain stages of the cell cycle thus necessitating regimens like continuous infusion therapy to arrest a significant number of tumor cells in a heterogeneous tumor mass. Here we discuss targeted drug delivery nanovectors and a recently reported bacterially-derived 400nm sized minicell that can be packaged with therapeutically significant concentrations of chemotherapeutic drugs, targeted to tumor cell surface receptors and effect intracellular drug delivery with highly significant anti-tumor effects in-vivo. We also report that molecularly targeted drugs can also be packaged in minicells and targeted to tumor cells with highly significant tumor growth-inhibition and regression in mouse xenografts despite administration of minute amounts of drug. This targeted intracellular drug delivery may overcome many of the hurdles associated with the delivery of cytotoxic and molecularly targeted drugs.     

Magnetic nanoparticles for gene and drug delivery

Investigations of magnetic micro- and nanoparticles for targeted drug delivery began over 30 years ago. Since that time, major progress has been made in particle design and synthesis techniques, however, very few clinical trials have taken place. Here we review advances in magnetic nanoparticle design, in vitro and animal experiments with magnetic nanoparticle-based drug and gene delivery, and clinical trials of drug targeting.     

Cell Labeling and Targeting with Superparamagnetic Iron Oxide Nanoparticles

Targeted delivery of cells and therapeutic agents would benefit a wide range of biomedical applications by concentrating the therapeutic effect at the target site while minimizing deleterious effects to off-target sites. Magnetic cell targeting is an efficient, safe, and straightforward delivery technique. Superparamagnetic iron oxide nanoparticles (SPION) are biodegradable, biocompatible, and can be endocytosed into cells to render them responsive to magnetic fields. The synthesis process involves creating magnetite (Fe₃O₄) nanoparticles followed by high-speed emulsification to form a poly(lactic-co-glycolic acid) (PLGA) coating. The PLGA-magnetite SPIONs are approximately 120 nm in diameter including the approximately 10 nm diameter magnetite core. When placed in culture medium, SPIONs are naturally endocytosed by cells and stored as small clusters within cytoplasmic endosomes. These particles impart sufficient magnetic mass to the cells to allow for targeting within magnetic fields. Numerous cell sorting and targeting applications are enabled by rendering various cell types responsive to magnetic fields. SPIONs have a variety of other biomedical applications as well including use as a medical imaging contrast agent, targeted drug or gene delivery, diagnostic assays, and generation of local hyperthermia for tumor therapy or tissue soldering.     

纳米靶向给药系统载体材料的研究进展

纳米靶向给药系统可以增强药物在病变部位的浓度和疗效,同时也可以最大限度地降低药物的毒副作用,因此已成为现代药剂学研 究的重要内容,其中对纳米载体材料的研究也越来越多。对2013年度国内学者在纳米靶向给药制剂中载体材料的研究与开发进展进行综述。     

载药脂质体的研究与应用进展

载药脂质体给药系统已成为国内外的研究热点。传统脂质体经修饰和改良后表现出良好的生物相容性,缓释性和靶向性。新型脂质体在经皮给药,肺部给药,脑部靶向治疗,基因治疗等方面的应用研究结果显示,集药物缓释、靶向于一体的具有良好生物安全性的脂质体给药系统具有很大发展潜力。本文综述了该领域中的最新研究进展。