聚合物胶束药物传递系统的研究进展

综述了聚合物胶束的自组装原理和结构、制备方法、体内过程和应用等。与传统的表面活性剂胶束比较，聚合物胶束具有良好的生物相容性和稳定性、较长的体循环时间，尤其在经过表面修饰后，还可有靶向和定位传递作用。     

壳聚糖衍生物及其胶束：特性、功能化修饰和在药物传递系统中的应用

壳聚糖是一种天然多糖,具有无毒、可生物降解、生物相容性等诸多优点,但水溶性差的自身特点限制了其在药剂学中的应用,而其经合理的结构设计、修饰和优化,可获得性能良好的两亲性壳聚糖衍生物,这些衍生物在水溶液中能自组装成具有良好药物传输性能（如载药量、稳定性、刺激敏感性、靶向性等）的胶束,并被广泛应用于构建药物传递系统,以改善药物的溶解性、靶向性、生物利用度及耐药性．降低药物的毒副作用。综述壳聚糖衍生物结构对其胶束药物传输性能的影响以及壳聚糖衍生物及其胶束的功能化修饰和在药物传递系统中的应用。     

聚合物胶束在肿瘤靶向给药系统中的研究进展

摘 要 聚合物胶束作为一种有效的药物运送载体已经受到广泛关注,其在肿瘤治疗方面具有高效,长效和高载药量等优势。本文综述了聚合物胶束的类型,制备材料,载药方法,主要讨论了肿瘤靶向载药系统中的靶向策略和应用实例。     

Polymeric micelles with stimuli-triggering systems for advanced cancer drug targeting

Abstract

Since the 1990s, nanoscale drug carriers have played a pivotal role in cancer chemotherapy, acting through passive drug delivery mechanisms and subsequent pharmaceutical action at tumor tissues with reduction of adverse effects. Polymeric micelles, as supramolecular assemblies of amphiphilic polymers, have been considerably developed as promising drug carrier candidates, and a number of clinical studies of anticancer drug-loaded polymeric micelle carriers for cancer chemotherapy applications are now in progress. However, these systems still face several issues; at present, the simultaneous control of target-selective delivery and release of incorporated drugs remains difficult. To resolve these points, the introduction of stimuli-responsive mechanisms to drug carrier systems is believed to be a promising approach to provide better solutions for future tumor drug targeting strategies. As possible trigger signals, biological acidic pH, light, heating/cooling and ultrasound actively play significant roles in signal-triggering drug release and carrier interaction with target cells. This review article summarizes several molecular designs for stimuli-responsive polymeric micelles in response to variation of pH, light and temperature and discusses their potentials as next-generation tumor drug targeting systems.     

PEG–lipid micelles as drug carriers: physiochemical attributes,formulation principles and biological implication

PEG–lipid micelles, primarily conjugates of polyethylene glycol (PEG) and distearyl phosphatidylethanolamine (DSPE) or PEG–DSPE, have emerged as promising drug-delivery carriers to address the shortcomings associated with new molecular entities with suboptimal biopharmaceutical attributes. The flexibility in PEG–DSPE design coupled with the simplicity of physical drug entrapment have distinguished PEG–lipid micelles as versatile and effective drug carriers for cancer therapy. They were shown to overcome several limitations of poorly soluble drugs such as non-specific biodistribution and targeting, lack of water solubility and poor oral bioavailability. Therefore, considerable efforts have been made to exploit the full potential of these delivery systems; to entrap poorly soluble drugs and target pathological sites both passively through the enhanced permeability and retention (EPR) effect and actively by linking the terminal PEG groups with targeting ligands, which were shown to increase delivery efficiency and tissue specificity. This article reviews the current state of PEG–lipid micelles as delivery carriers for poorly soluble drugs, their biological implications and recent developments in exploring their active targeting potential. In addition, this review sheds light on the physical properties of PEG–lipid micelles and their relevance to the inherent advantages and applications of PEG–lipid micelles for drug delivery.     

聚合物胶束作为药物载体及其在肿瘤靶向方面的研究进展

聚合物胶束具有粒径小、稳定性高、滞留时间长、良好的生物相容性等特点,这些优良性质使得聚合物胶束作为药物载体具有许多独特的优势。近年来,涌现了许多围绕聚合物胶束设计肿瘤靶向给药系统的报道,包括利用肿瘤的病理学性质,设计被动靶向给药系统和对聚合物胶束进行表面修饰,设计主动靶向给药系统。本文主要综述了聚合物胶束作为肿瘤靶向药物载体的研究进展。     

RGD肽在肿瘤靶向纳米给药系统中的应用

RGD肽是一类含有精氨酸一甘氨酸一天冬氨酸(Arg-Gly-Asp)的短肽,作为肿瘤细胞或者新生血管特异表达的整合素和其配体相互作用的识别位点,可介导肿瘤的靶向治疗.抗肿瘤药物及其递送系统经过RGD肽修饰.可增加药物的肿瘤主动靶向特性,达到更有效、精确和安全的治疗.本文主要综述了RGD肽在脂质体、聚合物胶束、基因载体等...     

Current strategies for targeted delivery of bio-active drug molecules in the treatment of brain tumor

Brain tumor is one of the most challenging diseases to treat. The major obstacle in the specific drug delivery to brain is blood–brain barrier (BBB). Mostly available anti-cancer drugs are large hydrophobic molecules which have limited permeability via BBB. Therefore, it is clear that the protective barriers confining the passage of the foreign particles into the brain are the main impediment for the brain drug delivery. Hence, the major challenge in drug development and delivery for the neurological diseases is to design non-invasive nanocarrier systems that can assist controlled and targeted drug delivery to the specific regions of the brain. In this review article, our major focus to treat brain tumor by study numerous strategies includes intracerebral implants, BBB disruption, intraventricular infusion, convection-enhanced delivery, intra-arterial drug delivery, intrathecal drug delivery, injection, catheters, pumps, microdialysis, RNA interference, antisense therapy, gene therapy, monoclonal/cationic antibodies conjugate, endogenous transporters, lipophilic analogues, prodrugs, efflux transporters, direct conjugation of antitumor drugs, direct targeting of liposomes, nanoparticles, solid–lipid nanoparticles, polymeric micelles, dendrimers and albumin-based drug carriers.     

Thermo-responsive systems for controlled drug delivery

Controlled drug delivery systems represent advanced systems that can be tightly modulated by stimuli in order to treat diseases in which sustained drug release is undesirable. Among the many different stimuli-sensitive delivery systems, temperature-sensitive drug delivery systems offer great potential over their counterparts due to their versatility in design, tunability of phase transition temperatures, passive targeting ability and in situ phase transitions. Thus, thermosensitive drug delivery systems can overcome many of the hurdles of conventional drug delivery systems in order to increase drug efficacies, drug targeting and decrease drug toxicities. In an effort to further control existing temperature-responsive systems, current innovative applications have combined temperature with other stimuli such as pH and light. The result has been the development of highly sophisticated systems, which demonstrate exquisite control over drug release and represent huge advances in biomedical research.     

The development of stimuli-responsive polymeric micelles for effective delivery of chemotherapeutic agents

Stimuli-responsive polymeric micelles, a novel category of polymeric micelles with response to endogenous or exogenous environments, show variable physicochemical properties as the variation of endogenous or exogenous circumstances. Because of differences between tumour tissues and normal tissues in physicochemical properties and sensitivity to variation of endogenous or exogenous environments, the application of chemotherapeutic agents loaded stimuli-responsive polymeric micelles are regarded as promising strategies for tumour treatment. In this article, the recent developments of chemotherapeutic agents loaded stimuli-responsive polymeric micelles, for example the preparation of novel stimuli-responsive polymeric micelles and the research progresses of action mechanisms of chemotherapeutic agents loaded micelles, were reviewed and discussed in detail. The advantages of stimuli-responsive chemotherapeutic agents loaded polymeric micelles in practical tumour treatment were also illustrated with the assistance of examples of stimuli-responsive polymeric micelles for antitumor agents delivery.     

Drug delivery targets and systems for targeted treatment of rheumatoid arthritis

Rheumatoid arthritis (RA) is an immune-mediated inflammatory disease that selectively attacks human joints. The common non-targeted treatment approaches lead to obvious side effect and systemtic complication for RA patients. Therefore, targeted drug delivery for treatment of RA has gained much attetntion in the past few years. In this paper, we reviewed the potential targets (folate receptor, angiogenesis, matrix metalloproteases, selectins, vasoactive intestinal peptide receptor andFc-γ receptor) that could be utilised to facilitate the specific delivery of drugs to the inflammed synovium and also presented different drug delivery systems for targeting RA, including the liposomes, various types of nanoparticles, polymeric micelles and the macromolecular prodrugs. The strategies combining nanotechnologies and ligand mediated active targeting for RA would be emphatically illustrated, which was expected to be helpful for identifying technologies and drug delivery methods for targeted treatment of RA.     

Nanocarriers for cancer-targeted drug delivery

Nanoparticles as drug delivery system have received much attention in recent years, especially for cancer treatment. In addition to improving the pharmacokinetics of the loaded poorly soluble hydrophobic drugs by solubilizing them in the hydrophobic compartments, nanoparticles allowed cancer specific drug delivery by inherent passive targeting phenomena and adopted active targeting strategies. For this reason, nanoparticles-drug formulations are capable of enhancing the safety, pharmacokinetic profiles and bioavailability of the administered drugs leading to improved therapeutic efficacy compared to conventional therapy. The focus of this review is to provide an overview of various nanoparticle formulations in both research and clinical applications with a focus on various chemotherapeutic drug delivery systems for the treatment of cancer. The use of various nanoparticles, including liposomes, polymeric nanoparticles, dendrimers, magnetic and other inorganic nanoparticles for targeted drug delivery in cancer is detailed.     

Current trends in the use of vitamin E-based micellar nanocarriers for anticancer drug delivery

Introduction: Owing to the complexity of cancer pathogenesis, conventional chemotherapy can be an inadequate method of killing cancer cells effectively. Nanoparticle-based drug delivery systems have been widely exploited pre-clinically in recent years.

Areas covered: Incorporation of vitamin-E in nanocarriers have the advantage of (1) improving the hydrophobicity of the drug delivery system, thereby improving the solubility of the loaded poorly soluble anticancer drugs, (2) enhancing the biocompatibility of the polymeric drug carriers, and (3) improving the anticancer potential of the chemotherapeutic agents by reversing the cellular drug resistance via simultaneous administration. In addition to being a powerful antioxidant, vitamin E demonstrated its anticancer potential by inducing apoptosis in various cancer cell lines. Various vitamin E analogs have proven their ability to cause marked inhibition of drug efflux transporters.

Expert opinion: The review discusses the potential of incorporating vitamin E in the polymeric micelles which are designed to carry poorly water-soluble anticancer drugs. Current applications of various vitamin E-based polymeric micelles with emphasis on the use of α-tocopherol, D-α-tocopheryl succinate (α-TOS) and its conjugates such as D-α-tocopheryl polyethylene glycol-succinate (TPGS) in micellar system is delineated. Advantages of utilizing polymeric micelles for drug delivery and the challenges to treat cancer, including multiple drug resistance have been discussed.     

聚合物胶束在经皮给药系统中的应用

摘 要 目的：综述聚合物胶束作为药物载体在经皮传递系统中的应用进展。方法: 根据国内外发表的最新文献,对聚合物胶束的制备方法、促进皮肤渗透的机制、释药过程及其在经皮给药系统中的应用进行分析与讨论。结果: 聚合物胶束具有增加难溶性药物的溶解度,促进药物的经皮吸收等作用,作为药物载体在经皮传递系统的应用越来越广泛。结论:聚合物胶束可作为药物载体被广泛用于经皮给药系统的研究中,具有较好的发展前景。     

多功能聚合物胶束的最新研究进展

由两亲性聚合物形成的胶束是一种很有发展前景的纳米级药物载体。聚合物胶束作为药物载体具有许多优势,如载药能力强、粒径小、体内循环时间长、具有主动和被动靶向性等特点。聚合物胶束的最新研究主要集中在使其功能更加完善方面,即多功能聚合物胶束的研究。现按照多功能聚合物胶束到达目标部位后发挥效用的方式对其进行分类,并对其最新研究进展和应用进行综述。     

Enhanced tumor-targeted delivery of anticancer drugs by folic acid-conjugated pH-sensitive polymeric micelles

In order to enhance the targeted delivery of anticancer drugs by polymeric micelles, folic acid (FA), the ligand of folate receptor (FR) over-expressed in the most cancer cells, modified pH-sensitive polymeric micelles were designed and fabricated to encapsulate doxorubicin (DOX) by combination of pH-sensitive amphiphilic polymer poly(2-ethyl-2-oxazoline)-poly(D,L-lactide) with FA-conjugated poly(2-ethyl-2-oxazoline)-poly(D,L-lactide). The prepared micelles were characterized to have about 36 nm in diameter with narrow distribution, well-defined spherical shape observed under TEM and pH-responsive drug release behavior. Moreover, the tumor targeting ability of the FA-modified pH-sensitive polymeric micelles was demonstrated by the cellular uptake, in vitro cytotoxicity to FR-positive KB cells and in vivo real time near-infrared fluorescence imaging in KB tumor-bearing nude mice. The efficient drug delivery by the micelles was ascribed to the synergistic effects of FR-mediated targeting and pH-triggered drug release. In conclusion, the designed FR-targeted pH-sensitive polymeric micelles might be of great potential in tumor targeted delivery of water-insoluble anticancer drugs.     

Polymeric networks for controlled release of drugs: a patent review

Introduction: Polymeric networks for controlled drug delivery possess wide pharmaceutical and biomedical applications.

Areas Covered: In this review, we explore the diversity of polymeric networks that exist, from simple to highly complex and ‘smart’ embodiments. The patented delivery systems reviewed reflect this, based on both conventional polymeric networks and stimulus-responsive networks where engineering of a controlled molecular architecture of polymeric networks enables a defined response to external or internal stimuli. Future trends in terms of nano-sized polymeric network patents are also highlighted.

Expert Opinion: A critical analysis of challenges potentially facing extended propulsion of the research and development of polymeric networks is provided. The significant therapeutic potential of polymer networks for controlled drug delivery is highlighted in the patented drug delivery systems examined; however, there needs to be enhanced representation of such systems in the market and thus available to patients. Concerted efforts are therefore necessary to propel these systems from the experimental setting to pilot scale production, and preclinical and clinical testing, for extension of their practicality.