肿瘤基因治疗的靶向策略

对肿瘤组织的靶向性可以提高基因治疗的效果 ,避免对正常组织的损伤 ,并且能降低作为载体的微生物对机体的危害。对于瘤内注射的给药方法 ,靶向性似乎显得不是特别重要 ,但是如果要系统给药 ,靶向性是很关键的一个问题。靶向基因治疗肿瘤可以通过靶向基因导入和靶向基因表达来实现。近年来 ,在靶向基因导入方面的研究有很多进展 ,例如 ,用双亲性的桥连分子协助腺病毒和逆转录病毒靶向转导 ;在各种病毒载体的衣壳蛋白中插入靶向性的小肽或较大的多肽靶向结构域 ;增殖病毒作为一种很有前途的抗肿瘤制剂可有效地靶向杀伤肿瘤细胞。受体介导的DNA或DNA 脂质体复合物的靶向系统和其他一些靶向性的有疗效的载体 ,如细菌 ,也处于研究中。其中的一些载体已经进入临床实验。为了实现基因的靶向可调控表达 ,组织或肿瘤特异性的启动子和人工合成的可调控表达系统被用来调控治疗基因的表达。反义核酸、核酶以及脱氧核酶 (DNAzyme)被用来靶向抑制与肿瘤发生密切相关基因的表达。     

Promising approaches in using magnetic nanoparticles in oncology

The development of new and effective drug delivery systems for cancer treatment represents one of the significant challenges facing biomedical technology in the last decade. Among the different methods of drug delivery, magnetic drug targeting, by enabling specific delivery of chemotherapeutic agents through the use of magnetic nanoparticles and magnetic field gradient, could be a promising approach. Recently, magnetic nanoparticles have attracted additional attention because of their potential as contrast agents for magnetic resonance imaging and heat mediators for cancer therapy. This review summarizes these approaches in the use of magnetic nanoparticles in biomedical applications and novel methods for their optimization.     

Ultrasound: mechanical gene transfer into plant cells by sonoporation

Development of nonviral gene transfer methods would be a valuable alternative of gene therapy or transformation. Ultrasound can produce a variety of nonthermal bioeffects via acoustic cavitation. Cavitation bubbles can induce cell death or transient membrane permeabilization (sonoporation) on cells. Application of sonoporation for gene transfer into cells or tissues develops quickly in recent years. Many studies have been performed in vitro exposure systems to a variety of cell lines transfected successfully. In vivo, cavitation initiation and control are more difficult, but can be enhanced by ultrasound contrast agents (microbubbles). The use of ultrasound for nonviral gene delivery has been applied for mammalian systems, which provides a fundamental basis and strong promise for development of new gene therapy methods for clinical medicine. In this paper, ultrasound applied to plant cell transformation or gene transfer is reviewed. Recently, most researches are focused on sonication-assisted Agrobacterium-mediated transformation (SAAT) in plant cells or tissues. Microbubbles are also proposed to apply to gene transfer in plant cells and tissues.     

Nanodrug Delivery Systems: A Promising Technology for Detection,Diagnosis, and Treatment of Cancer

Nanotechnology has enabled the development of novel therapeutic and diagnostic strategies, such as advances in targeted drug delivery systems, versatile molecular imaging modalities, stimulus responsive components for fabrication, and potential theranostic agents in cancer therapy. Nanoparticle modifications such as conjugation with polyethylene glycol have been used to increase the duration of nanoparticles in blood circulation and reduce renal clearance rates. Such modifications to nanoparticle fabrication are the initial steps toward clinical translation of nanoparticles. Additionally, the development of targeted drug delivery systems has substantially contributed to the therapeutic efficacy of anti-cancer drugs and cancer gene therapies compared with nontargeted conventional delivery systems. Although multifunctional nanoparticles offer numerous advantages, their complex nature imparts challenges in reproducibility and concerns of toxicity. A thorough understanding of the biological behavior of nanoparticle systems is strongly warranted prior to testing such systems in a clinical setting. Translation of novel nanodrug delivery systems from the bench to the bedside will require a collective approach. The present review focuses on recent research efforts citing relevant examples of advanced nanodrug delivery and imaging systems developed for cancer therapy. Additionally, this review highlights the newest technologies such as microfluidics and biomimetics that can aid in the development and speedy translation of nanodrug delivery systems to the clinic.     

Small interfering RNA–mediated gene suppression as a therapeutic intervention in hepatocellular carcinoma

Hepatocellular carcinoma (HCC) is one of the lethal and difficult-to-cure cancers worldwide. Owing to the late diagnosis and drug resistance of malignant hepatocytes, treatment of this cancer by conventional chemotherapy agents is challenging, and researchers are seeking new alternative treatment options to overcome therapy resistance in this neoplasm. RNA interference (RNAi) is a potent and specific approach in targeting gene expression and has emerged as a novel therapeutic tool for many diseases, including cancers. Small interfering RNA (siRNA) is a type of RNAi that is produced intracellularly from exogenous synthetic oligonucleotides and can selectively knock down target gene expression in a sequence-specific manner. Various factors play roles in the initiation and progression of HCC and provide multiple candidate targets for siRNA intervention. In addition, due to the liver's unique architecture and availability of some hepatic siRNA delivery methods, this organ has received much more attention as a target tissue for such oligonucleotide action. Recent advances in designing nanoparticle systems for the in vivo delivery of siRNAs have markedly enhanced the potency of siRNA-mediated gene silencing under clinical development for HCC therapy. The utility of siRNAs as anti-HCC agents is the subject of the current review. siRNA-based gene therapies could be one of the main feasible approaches for HCC therapy in the future.     

Potent and selective gene inhibition using antisense oligodeoxynucleotides

The development of antisense technology as a generally useful tool relies on the use of potent agents and the utilization of many controls in experiments. Here we describe our experience using oligodeoxynucleotides (ODNs) containing C-5 propynyl pyrimidine and phosphorothioate modifications as broadly applicable gene inhibition agents in cell culture. Methods include selection of antisense sequences, synthesis and purification of ODNs, choice of controls, delivery methods (microinjection, cationic lipid transfection, and electroporation), and analysis of gene inhibition.     

新的药物传递系统:外泌体作为药物载体递送*

外泌体(exosomes)是细胞分泌的囊泡,在细胞与细胞之间通信中发挥重要作用。由于其固有的长距离通信能力和出色的生物相容性而具有很大的潜力作为药物递送载体,尤其适合递送蛋白质、核酸、基因治疗剂等治疗药物。许多研究表明外泌体可以有效地将许多不同种类的货物递送至靶细胞,因此,它们常被作为药物载体用于治疗。对外泌体作为药物递送系统中面临的外泌体分离,药物装载和靶向治疗应用的进展与挑战作一介绍,以期更好为外泌体药物递送系统开发提供新思路。     

Viral vectors for gene therapy: Current state and clinical perspectives

Gene therapy is the straightforward approach for the application of recent advances in molecular biology into clinical practice. One of the major obstacles in the development of gene therapy is the delivery of the effector to and into the target cell. Unfortunately, most methods commonly used in laboratory practice are poorly suited for clinical use. Viral vectors are one of the most promising methods for gene therapy delivery. Millions of years of evolution of viruses have resulted in the development of various molecular mechanisms for entry into cells, long-term survival within cells, and activation, inhibition, or modification of the host defense mechanisms at all levels. The relatively simple organization of viruses, small genome size, and evolutionary plasticity allow modifying them to create effective instruments for gene therapy approaches. This review summarizes the latest trends in the development of gene therapy, in particular, various aspects and prospects of the development of clinical products based on viral delivery systems.     

基因药物纳米给药系统的设计与研究进展

基因药物的传递面临着体内外稳定性差、缺乏靶向性、难入胞、在细胞内难以释放等一系列障碍和挑战。因此,要实现基因药物在 体内有效传递需构建能克服这些障碍的药物传递系统。随着材料科学和纳米科技的发展,大量新型的纳米载体已被用于基因药物的传递。 综述目前基因药物传递所面临的障碍和挑战,基因药物纳米给药系统的设计思路及研究进展。     

Engineered nanoparticles as precise drug delivery systems

With the remarkable development of nanotechnology in recent years, new drug delivery approaches based on the state-of-the-art nanotechnology have been receiving significant attention. Nanoparticles, an evolvement of nanotechnology, are increasingly considered as a potential candidate to carry therapeutic agents safely into a targeted compartment in an organ, particular tissue or cell. These particles are colloidal structures with a diameter smaller than 1,000 nm, and therefore can penetrate through diminutive capillaries into the cell's internal machinery. This innovative delivery technique might be a promising technology to meet the current challenges in drug delivery. When loaded with a gene or drug agent, nanoparticles can become nanopills, which can effectively treat problematical diseases such as cancer. This article summarizes different types of nanoparticles drug delivery systems under investigation and their prospective therapeutic applications. Also, this article presents a closer look at the advances, current challenges, and future direction of nanoparticles drug delivery systems.     

Local drug and gene delivery through microbubbles and ultrasound

Although gene therapy has great potential as a treatment for diseases, clinical trials are slowed down by the development of a safe and efficient gene delivery system. In this review, we will give an overview of the viral and nonviral vehicles used for drug and gene delivery, and the different nonviral delivery techniques, thereby focusing on delivery through ultrasound contrast agents.The development of ultrasound contrast agents containing encapsulated microbubbles has increased the possibilities not only for diagnostic imaging, but for therapy as well. Microbubbles have been shown to be able to carry drugs and genes, and destruction of the bubbles by ultrasound will result in local release of their contents. Furthermore, ligands can be attached so that they can be targeted to a specific target tissue. The recent advances of microbubbles as vehicles for delivery of drugs and genes will be highlighted.     

Nanoparticles and cancer therapy: Perspectives for application of nanoparticles in the treatment of cancers

Rapid growth in nanotechnology toward the development of nanomedicine agents holds massive promise to improve therapeutic approaches against cancer. Nanomedicine products represent an opportunity to achieve sophisticated targeting strategies and multifunctionality. Nowadays, nanoparticles (NPs) have multiple applications in different branches of science. In recent years, NPs have repetitively been reported to play a significant role in modern medicine. They have been analyzed for different clinical applications, such as drug carriers, gene delivery to tumors, and contrast agents in imaging. A wide range of nanomaterials based on organic, inorganic, lipid, or glycan compounds, as well as on synthetic polymers has been utilized for the development and improvement of new cancer therapeutics. In this study, we discuss the role of NPs in treating cancer among different drug delivery methods for cancer therapy.     

Nanomaterials for ocular drug delivery

Efficient drug delivery to the eye remains a challenging task for pharmaceutical scientists. Due to the various anatomical barriers and the clearance mechanisms prevailing in the eye, conventional drug delivery systems, such as eye drop solutions, suffer from low bioavailability. More invasive methods, such as intravitreal injections and implants, cause adverse effects in the eye. Recently, an increasing number of scientists have turned to nanomaterial-based drug delivery systems to address the challenges faced by conventional methods. This paper highlights recent applications of various nanomaterials, such as polymeric micelles, hydrogels, liposomes, niosomes, dendrimers, and cyclodextrins as ocular drug delivery systems to enhance the bioavailability of ocular therapeutic agents.     

Biotechnology: impact on biological warfare and biodefense

Advances in biological research likely will permit development of a new class of advanced biological warfare (ABW) agents engineered to elicit novel effects. In addition, biotechnology will have applications supporting ABW weaponization, dissemination, and delivery. Such new agents and delivery systems would provide a variety of new use options, expanding the BW paradigm. Although ABW agents will not replace threats posed by traditional biological agents such as Bacillus anthracis (anthrax) and Variola (smallpox), they will necessitate novel approaches to counterproliferation, detection, medical countermeasures, and attribution.     

抑制血管生成治疗肿瘤的策略和展望

新生血管生成是绝大多数肿瘤得以生长和转移的必要前提。所以 ,通过抑制肿瘤血管生成来抑制肿瘤是非常有前途的一种方法 ,有望发展成为一种新型的癌症疗法。主要可以分为两大类 :一是通过抑制促血管生成信号或扩大抑制血管生成因子的作用来干扰肿瘤新生血管的形成过程 ,这领域的广泛研究已经发现了一系列促血管生成因子及其抑制剂和血管生成抑制因子 ;二是利用肿瘤血管与正常血管的差别来携带杀伤性药物直接特异性破坏已形成的肿瘤血管 ;另外 ,内皮细胞及其前体细胞制成疫苗也可起到直接杀伤作用。到目前为止 ,虽然很多抑制肿瘤血管的药物已经被用于临床试验 ,但结果往往不尽如人意 ,从长远来看 ,需要更有效的治疗方法。包括抗血管基因治疗策略 ,靶向药物导入系统的研究 ,以及抗血管生成药物和免疫疗法、化疗和放射治疗的联合应用都在探讨中。随着肿瘤模型评估系统的发展 ,抗血管治疗肿瘤的方法在不久的将来一定会广泛进入临床应用。     

Adeno-associated viral vectors for gene transfer and gene therapy.

Adeno-associated virus (AAV) is a defective, non-pathogenic human parvovirus that depends for growth on coinfection with a helper adenovirus or herpes virus. Recombinant adeno-associated viruses (rAAVs) have attracted considerable interest as vectors for gene therapy. In contrast to other gene delivery systems, rAAVs lack all viral genes and show long-term gene expression in vivo without immune response or toxicity. Over the past few years, many applications of rAAVs as therapeutic agents have demonstrated the utility of this vector system for long-lasting genetic modification and gene therapy in preclinical models of human disease. New production methods have increased rAAV vector titers and eliminated contamination by adenovirus. In addition, vectors for regulatable gene expression and vectors retargeted to different cells have been engineered. These advancements are expected to accelerate and facilitate further animal model studies, providing validation for use of rAAVs in human clinical trials.     

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.     

Translocating peptides and proteins and their use for gene delivery

A dramatic surge in the development of peptides for gene delivery in vitro and in vivo has been witnessed in the past decade. A better understanding of the structural and mechanistic properties of peptides has been an important step for the rational design of optimal peptide-based gene delivery systems. Research has focused on the design of short synthetic peptides that overcome both extracellular and intracellular limitations of other gene delivery systems by binding reversibly and condensing DNA, specifically targeting cells and/or tissues, rapidly releasing plasmids into the cytoplasm and mediating efficient nuclear translocation.     

A miniaturized nebulization catheter for improved gene delivery to the mouse lung

BACKGROUND: The available methods for administration of gene delivery systems to the lungs of small animals via nebulization have several drawbacks. These include lack of control over the delivered dose and a negative impact on the stability of the formulation. This paper describes a new nebulization catheter device for the administration of plasmid-based gene delivery systems (polyplexes) as aerosols to the mouse lung in vivo. METHODS: The physical stability of naked pDNA and polyplexes formulated with chitosan oligomers and PEI was examined following nebulization with the catheter device. We also examined the in vitro transfection efficiency of the polyplexes recovered after nebulization. Lung distribution and gene expression after administration of the selected gene delivery systems to the mouse lung were also investigated. RESULTS: In contrast to previously described nebulization methods, the structural integrity of the unprotected naked pDNA was maintained following nebulization by the catheter device, which indicates relatively mild nebulization conditions. In addition, the nebulization procedure did not affect the physical stability of the formulated polyplexes. Small volumes of the pDNA aerosol (10-20 microl) were delivered in a highly controlled and reproducible manner. The aerosol droplet size varied with the molecular weight of the polycations. Aerosol delivery via this method resulted in improved lung distribution of pDNA polyplexes and a six-fold increase in the efficiency of gene delivery in vivo over that seen with the commonly used intratracheal instillation method. CONCLUSION: The use of the nebulization catheter device provides a promising alternative for aerosol gene delivery to the mouse lung.     

Novel non-viral vectors for gene delivery: synthesis of a second-generation library of mono-functionalized poly-(guanidinium)amines and their introduction into cationic lipids

The development of new gene delivery technologies is a prerequisite towards gene therapy clinical trials. Because gene delivery mediated by viral vectors remains of limited scope due to immunological and propagation risks, the development of new non-viral gene delivery systems is of crucial importance. We have synthesized a secondary library of mono-functionalized poly-(guanidinium)amines generated from a library of mono-functionalized polyamines applying the concept of "libraries from libraries." The method allows a quick and easy access to mono-functionalized geometrically varied poly-(guanidinium)amines. The new building blocks were introduced into cationic lipids to obtain novel poly-(guanidinium)amine lipids, which are potential DNA vectors for gene delivery.