Lipid-based systems for the intracellular delivery of genetic drugs.

Currently available delivery systems for genetic drugs have limited utility for systemic applications. Cationic liposome/plasmid DNA or oligonucleotide complexes are rapidly cleared from circulation, and the highest levels of activity are observed in 'first pass' organs, such as the lungs, spleen and liver. Engineered viruses can generate an immune response, which compromises transfection resulting from subsequent injections and lack target specificity. A carrier, which can accumulate at sites of diseases such as infections, inflammations and tumours, has to be a small, neutral and highly serum-stable particle, which is not readily recognized by the fixed and free macrophages of the reticuloendothelial system (RES). This review summarizes lipid-based technologies for the delivery of nucleic acid-based drugs and introduces a new class of carrier systems, which solve, at least in part, the conflicting demands of circulation longevity and intracellular delivery. Plasmid DNA and oligonucleotides are entrapped into lipid particles that contain small amounts of a positively charged lipid and are stabilized by the presence of a polythylene glycol (PEG) coating. These carriers protect nucleic acid-based drugs from degradation by nucleases, are on average 70 nm in diameter, achieve long circulation lifetimes and are capable of transfecting cells.     

核酸自组装纳米递送载体的研究进展

随着核酸纳米技术的飞速发展,核酸自组装纳米载体已成为药物递送领域的研究热点。针对核酸自组装纳米载体在药物递送中的应用进展进行了系统综述,讨论了不同的核酸自组装策略,阐述了多种靶向递送和药物控制释放方法,同时,总结了核酸自组装纳米递送载体在蛋白质药物、核酸药物、小分子药物和纳米药物递送中的应用,并针对该领域的挑战和未来发展趋势进行了总结和展望,以期为药物递送领域和新型药物系统研究提供参考。     

Nonantibody-based recognition: alternative molecules for detection of pathogens

Immunoassays have been well established for many years as the cornerstone of detection technologies. These assays are sensitive, selective and, in general, highly resistant to interference from complex sample matrices when compared with nucleic acid-based tests. However, both antibody- and nucleic acid-based detection systems require a priori knowledge of the target and development of specific reagents; multiplexed assays can become increasingly problematic when attempting to detect a plethora of different targets, the identities of which are unknown. In an effort to circumvent many of the limitations inherent in these conventional assays, other recognition reagents are being explored as alternatives, or indeed as adjuncts, to antibodies for pathogen and toxin detection. This article will review a number of different recognition systems ranging in complexity from small molecules, such as nucleic-acid aptamers, carbohydrates and peptides, to systems as highly complicated as whole cells and organisms. All of these alternative systems have tremendous potential to achieve superior sensitivity, selectivity, and stability, but are also subject to their own limitations, which are also discussed. In short, while in its infancy, this field holds great promise for the development of rapid, fieldable assays that are highly complementary to existing antibody- and nucleic acid-based technologies.     

Nonantibody-based recognition: alternative molecules for detection of pathogens

Immunoassays have been well established for many years as the cornerstone of detection technologies. These assays are sensitive, selective and, in general, highly resistant to interference from complex sample matrices when compared with nucleic acid-based tests. However, both antibody- and nucleic acid-based detection systems require a priori knowledge of the target and development of specific reagents; multiplexed assays can become increasingly problematic when attempting to detect a plethora of different targets, the identities of which are unknown. In an effort to circumvent many of the limitations inherent in these conventional assays, other recognition reagents are being explored as alternatives, or indeed as adjuncts, to antibodies for pathogen and toxin detection. This article will review a number of different recognition systems ranging in complexity from small molecules, such as nucleic-acid aptamers, carbohydrates and peptides, to systems as highly complicated as whole cells and organisms. All of these alternative systems have tremendous potential to achieve superior sensitivity, selectivity, and stability, but are also subject to their own limitations, which are also discussed. In short, while in its infancy, this field holds great promise for the development of rapid, fieldable assays that are highly complementary to existing antibody- and nucleic acid-based technologies.     

综述: siRNA脂质纳米输送载体的研究进展

siRNA能高效且特异地阻断内源性同源基因的表达即RNA干涉(RNAi)．RNAi在临床中的应用需要开发安全有效的输送系统,脂质纳米输送载体是一种具有发展潜力的siRNA输送系统．siRNA-脂质复合物的形成主要通过静电相互作用,静电作用必须足够强以至于载体在运输过程中不释放siRNA,而载体到达治疗部位时,解聚释放出siRNA．载体的粒径应小于100 nm,以利于细胞的摄取和透过特定部位的血管开窗．为了减少网状内皮系统(RES)的摄取和延长载体的循环时间,载体的表面由聚乙二醇修饰．本文主要综述了构建siRNA输送载体的基本要求．     

综述——纳米材料与药物输递：脂质纳米粒在口服给药系统中的应用

脂质纳米粒是由固体脂肪酸或其酯类制成的一类纳米制剂,其生物相容性好、安全性好,所以在药物递送领域受到广泛关注．难溶性药物、多肽及蛋白质药物由于溶解度、跨膜能力以及稳定性等问题,导致口服生物利用度低,而利用脂质纳米粒作为其载体,口服给药后能显著改善药物的生物利用度,这使得脂质纳米粒在口服给药系统中得到了广泛的应用与研究．本文从口服脂质纳米粒的处方、制备工艺、吸收机制以及应用四个方面对其进行了详细的综述．     

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.     

Physicochemical and biological characterization of targeted, nucleic acid-containing nanoparticles

Nucleic acid-based therapeutics have the potential to provide potent and highly specific treatments for a variety of human ailments. However, systemic delivery continues to be a significant hurdle to success. Multifunctional nanoparticles are being investigated as systemic, nonviral delivery systems, and here, we describe the physicochemical and biological characterization of cyclodextrin-containing polycations (CDP) and their nanoparticles formed with nucleic acids including plasmid DNA (pDNA) and small interfering RNA (siRNA). These polycation/nucleic acid complexes can be tuned by formulation conditions to yield particles with sizes ranging from 60 to 150 nm, zeta potentials from 10 to 30 mV, and molecular weights from approximately 7 x 107 to 1 x 109 g mol-1 as determined by light scattering techniques. Inclusion complexes formed between adamantane (AD)-containing molecules and the beta-cyclodextrin molecules enable the modular attachment of poly(ethylene glycol) (AD-PEG) conjugates for steric stabilization and targeting ligands (AD-PEG-transferrin) for cell-specific targeting. A 70 nm particle can contain approximately 10 000 CDP polymer chains, approximately 2000 siRNA molecules, approximately 4000 AD-PEG5000 molecules, and approximately 100 AD-PEG5000-Tf molecules; this represents a significant payload of siRNA and a large ratio of siRNA to targeting ligand (20:1). The particles protect the nucleic acid payload from nuclease degradation, do not aggregate at physiological salt concentrations, and cause minimal erythrocyte aggregation and complement fixation at the concentrations typically used for in vivo application. Uptake of the nucleic acid-containing particles by HeLa cells is measured by flow cytometry and visualized by confocal microscopy. Competitive uptake experiments show that the transferrin-targeted particles display enhanced affinity for the transferrin receptor through avidity effects (multiligand binding). Functional efficacy of the delivered pDNA and siRNA is demonstrated through luciferase reporter protein expression and knockdown, respectively. The analysis of the CDP delivery vehicle provides insights that can be applied to the design of targeted nucleic acid delivery vehicles in general.     

Propaedeutic study for the delivery of nucleic acid-based molecules from PLGA microparticles and stearic acid nanoparticles

We studied the mechanism governing the delivery of nucleic acid-based drugs (NABD) from microparticles and nanoparticles in zero shear conditions, a situation occurring in applications such as in situ delivery to organ parenchyma. The delivery of a NABD molecule from poly(DL-lactide-co-glycolide) (PLGA) microparticles and stearic acid (SA) nanoparticles was studied using an experimental apparatus comprising a donor chamber separated from the receiver chamber by a synthetic membrane. A possible toxic effect on cell biology, as evaluated by studying cell proliferation, was also conducted forjust PLGA microparticles. A mathematical model based on the hypothesis that NABD release from particles is due to particle erosion was used to interpret experimental release data. Despite zero shear conditions imposed in the donor chamber, particle erosion was the leading mechanism for NABD release from both PLGA microparticles and SA nanoparticles. PLGA microparticle erosion speed is one order of magnitude higher than that of competing SA nanoparticles. Finally, no deleterious effects of PLGA microparticles on cell proliferation were detected. Thus, the data here reported can help optimize the delivery systems aimed at release of NABD from micro- and nanoparticles.     

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。     

Receptor-Mediated Gene Delivery with Non-Viral DNA Carriers

Abstract

To achieve effective nucleic acid-based therapy, natural carriers, i.e. viruses, as well as synthetic carriers have been developed. The majority of the non-viral systems are based on DNA compaction into small particles by cationic compounds, which are most often polymers and lipids. Optimal in vitro gene delivery with the cationic carriers requires an excess of positive charges with respect to DNA phosphates. However, the overall positive charge of these particles limits their application in vivo because: i) the half-life of positively charged DNA complexes, injected intravenously, is very short, and ii) it does not allow site-specific delivery of the gene of interest. To overcome this problem, the most attractive strategy consists in replacing the non-specific electrostatic interactions between cells and the transfection complexes with a cell-specific interaction that triggers a receptor-mediated endocytosis of the targeted DNA complexes. Such an active targeting requires the identification of receptors present at the surface of the target cells and the use of ligands which binds with a high specificity and affinity to such recognition sites. In this review, we will focus on three examples of receptors that have been used for the targeting of DNA complexes: the Gal/GalNAc receptor followed by the integrin- and folate receptors. Some important principles underlying targeted transfection will also be evoked such as the importance of the conjugation chemistry, the nature of the ligand-receptor interactions, the occurrence of limited windows of the complex charge where targeting is observed.     

Diaminopropionic acid lipopeptides: Characterization studies of polyplexes aimed at pDNA delivery

Here we report a novel class of peptides-d-diaminopropionic acids (Dap)-for gene delivery. These peptides have attractive properties for gene delivery, and the advantage that they can be easily manipulated in relation to their composition, abiding with tailored-design. We characterized the toxicological and biophysical properties of DNA particles resulting from the interaction of the nucleic acid with a series of Dap(8) peptides conjugated to different alkyl groups. These peptides formed small and homogenous DNA particle populations that protected against DNase I degradation at non-toxic concentrations. However, despite the similarity between these peptides and others that are arginine-rich, and efficient vectors, functional studies suggest the need for additional modifications in the carriers to improve their DNA delivery efficiency. Taken together, these studies underscore the relevance of the overall structure of the carrier and the complexity of designing from scratch a carrier.     

Targeted gene delivery: the role of peptide nucleic acid

Receptor-mediated endocytosis can be exploited to achieve efficient cell-specific gene delivery. Our laboratory has used two approaches for targeted gene delivery. One uses polycation as a carrier for plasmid DNA and the other uses peptide nucleic acid (PNA) as a carrier. Targeted gene delivery using polycation carriers has been widely utilized with some success. This approach mainly suffers from large particle size and non-specific interaction with blood components. These drawbacks have limited use of this type of vector forin vivo applications. Using PNA as a carrier, on the other hand, allows for smaller particle size and less non-specific interactions. The stability of this vector in the circulation may be a limiting factor. In addition, both types of vector lack mechanisms for endosome escape and nuclear transport. In this chapter, current developments and uses for targeted gene delivery of each approach are reviewed.     

Targeted gene delivery: The role of peptide nucleic acid

Receptor-mediated endocytosis can be exploited to achieve efficient cell-specific gene delivery. Our laboratory has used two approaches for targeted gene delivery. One uses polycation as a carrier for plasmid DNA and the other uses peptide nucleic acid (PNA) as a carrier. Targeted gene delivery using polycation carriers has been widely utilized with some success. This approach mainly suffers from large particle size and non-specific interaction with blood components. These drawbacks have limited use of this type of vector for in vivo applications. Using PNA as a carrier, on the other hand, allows for smaller particle size and less non-specific interactions. The stability of this vector in the circulation may be a limiting factor. In addition, both types of vector lack mechanisms for endosome escape and nuclear transport. In this chapter, current developments and uses for targeted gene delivery of each approach are reviewed.     

Targeted gene delivery: the role of peptide nucleic acid

Receptor-mediated endocytosis can be exploited to achieve efficient cell-specific gene delivery. Our laboratory has used two approaches for targeted gene delivery. One uses polycation as a carrier for plasmid DNA and the other uses peptide nucleic acid (PNA) as a carrier. Targeted gene delivery using polycation carriers has been widely utilized with some success. This approach mainly suffers from large particle size and non-specific interaction with blood components. These drawbacks have limited use of this type of vector for in vivoapplications. Using PNA as a carrier, on the other hand, allows for smaller particle size and less non-specific interactions. The stability of this vector in the circulation may be a limiting factor. In addition, both types of vectorlack mechanisms for endosome escape and nuclear transport. In this chapter, current developments and uses for targeted gene delivery of each approach are reviewed.     

Effect of PEGylation on the diffusion and stability of chitosan-DNA polyplexes in collagen gels

Diffusion through the extracellular matrix (ECM) is a critical step for the delivery of nanoparticles and genes. Gene delivery requires a carrier that protects the nucleic acid from degradation and facilitates transport. Chitosan is a promising carrier. To increase the circulation time, PEGylation of the carrier is performed. However, the effect of PEGylation on the transport and stability of gene delivery systems in the ECM has only been studied in solutions containing ECM components. We used polymerized collagen and collagen-hyaluronic acid (HA) gels to study the effects of PEGylation on the diffusion and stability of chitosan-DNA polyplexes. We found that PEGylation of the polyplexes was required for diffusion to occur, and PEGylation increased the dissociation between DNA and chitosan to some extent. The presence of HA had a contradictory role: it decreased the penetration depth of PEGylated polyplexes into the gels and increased the diffusion of the polyplexes being mixed into the gels.     

Self-assembled nucleolipids: from supramolecular structure to soft nucleic acid and drug delivery devices

This short review aims at presenting some recent illustrative examples of spontaneous nucleolipids self-assembly. High-resolution structural investigations reveal the diversity and complexity of assemblies formed by these bioinspired amphiphiles, resulting from the interplay between aggregation of the lipid chains and base-base interactions. Nucleolipids supramolecular assemblies are promising soft drug delivery systems, particularly for nucleic acids. Regarding prodrugs, squalenoylation is an innovative concept for improving efficacy and delivery of nucleosidic drugs.     

Evaluation of tetraether lipid-based liposomal carriers for encapsulation and retention of nucleoside-based drugs

Although liposomal nanoparticles are one of the most versatile class of drug delivery systems, stable liposomal formulation of small neutral drug molecules still constitutes a challenge due to the low drug retention of current lipid membrane technologies. In this study, we evaluate the encapsulation and retention of seven nucleoside analog-based drugs in liposomes made of archaea-inspired tetraether lipids, which are known to enhance packing and membrane robustness compared to conventional bilayer-forming lipids. Liposomes comprised of the pure tetraether lipid generally showed improved retention of drugs (up to 4-fold) compared with liposomes made from a commercially available diacyl lipid. Interestingly, we did not find a significant correlation between the liposomal leakage rates of the molecules with typical parameters used to assess lipophilicity of drugs (such logD or topological polar surface area), suggesting that specific structural elements of the drug molecules can have a dominant effect on leakage from liposomes over general lipophilic character.