A Review of Multi-Responsive Membranous Systems for Rate-Modulated Drug Delivery

Membrane technology is broadly applied in the medical field. The ability of membranous systems to effectively control the movement of chemical entities is pivotal to their significant potential for use in both drug delivery and surgical/medical applications. An alteration in the physical properties of a polymer in response to a change in environmental conditions is a behavior that can be utilized to prepare ‘smart’ drug delivery systems. Stimuli-responsive or ‘smart’ polymers are polymers that upon exposure to small changes in the environment undergo rapid changes in their microstructure. A stimulus, such as a change in pH or temperature, thus serves as a trigger for the release of drug from membranous drug delivery systems that are formulated from stimuli-responsive polymers. This article has sought to review the use of stimuli-responsive polymers that have found application in membranous drug delivery systems. Polymers responsive to pH and temperature have been extensively addressed in this review since they are considered the most important stimuli that may be exploited for use in drug delivery, and biomedical applications such as in tissue engineering. In addition, dual-responsive and glucose-responsive membranes have been also addressed as membranes responsive to diverse stimuli.     

生长抑素受体介导的肿瘤靶向治疗

许多肿瘤,如神经内分泌肿瘤、甲状腺癌、乳腺癌等能高表达生长抑素受体,从而为生长抑素及其类似物的治疗提供了靶点。生长抑素受体介导的肿瘤靶向治疗主要包括放射性核素治疗、放射导向手术治疗、细胞毒素治疗和溶瘤病毒治疗。目前,生长抑素受体介导的放射性核素治疗已应用于神经内分泌肿瘤,尤其在胃肠胰神经内分泌肿瘤的诊断和治疗中占据重要地位。另外,生长抑素受体介导的放射导向手术治疗、细胞毒素治疗和溶瘤病毒治疗的潜在价值也越来越引起研究者们的重视。本文通过查阅近五年来关于生长抑素受体介导的肿瘤靶向治疗的国内外文献,综述了生长抑素受体介导的肿瘤靶向治疗的最新研究进展。     

Rational engineering and applications of functional bioadhesives in biomedical engineering

For the past decades, several bioadhesives have been developed to replace conventional wound closure medical tools such as sutures, staples, and clips. The bioadhesives are easy to use and can minimize tissue damage. They are designed to provide strong adhesion with stable mechanical support on tissue surfaces. However, this monofunctionality of the bioadhesives hinders their practical applications. In particular, a bioadhesive can lose its intended function under harsh tissue environments or delay tissue regeneration during wound healing. Based on several natural and synthetic biomaterials, functional bioadhesives have been developed to overcome the aforementioned limitations. The functional bioadhesives are designed to have specific characteristics such as antimicrobial, cell infiltrative, stimuli-responsive, electrically conductive, and self-healing to ensure stability under harsh tissue conditions, facilitate tissue regeneration, and effectively monitor biosignals. Herein, we thoroughly review the functional bioadhesives from their fundamental background to recent progress with their practical applications for the enhancement of tissue healing and effective biosignal sensing. Furthermore, the future perspectives on the applications of functional bioadhesives and current challenges in their commercialization are also discussed.     

Correction to: A novel melittin nano-liposome exerted excellent anti-hepatocellular carcinoma efficacy with better biological safety

Poor targeting of therapeutics leading to severe adverse effects on normal tissues is considered one of the obstacles in cancer therapy. To help overcome this, nanoscale drug delivery systems have provided an alternative avenue for improving the therapeutic potential of various agents and bioactive molecules through the enhanced permeability and retention (EPR) effect. Nanosystems with cancer-targeted ligands can achieve effective delivery to the tumor cells utilizing cell surface-specific receptors, the tumor vasculature and antigens with high accuracy and affinity. Additionally, stimuli-responsive nanoplatforms have also been considered as a promising and effective targeting strategy against tumors, as these nanoplatforms maintain their stealth feature under normal conditions, but upon homing in on cancerous lesions or their microenvironment, are responsive and release their cargoes. In this review, we comprehensively summarize the field of active targeting drug delivery systems and a number of stimuli-responsive release studies in the context of emerging nanoplatform development, and also discuss how this knowledge can contribute to further improvements in clinical practice.     

外泌体在小RNA基因治疗中的研究进展

小RNA,包括小干扰RNA以及微小RNA,已成为多种疾病的潜在治疗药物。目前,小RNA的运输载体主要是病毒或者合成试剂。然而这类载体往往毒性高且特异性低。外泌体是由内源细胞分泌出来的天然纳米材料,本身能够穿越生物膜并在细胞间传递小RNA。以外泌体为基础的小RNA递送作为一种新的转运方式,能够克服低效率,低特异性以及免疫反应等缺陷,有望成为新型载体。本文简要论述了以外泌体为载体的小RNA递送系统在临床治疗研究中的前沿进展。     

Research Advances on Stimuli-responsive Liposomes in the Targeted Drug Delivery System

Liposome, a kind of nanoscale vesicle, is applied in the drug delivery systems (DDS) extensively because of its low toxicity, biodegradability and biocompatibility. However, defects of liposome drugs, such as low rates of drug release, insufficiency in active targeting and inefficient bioavailability still remain to be solved. Therefore, stimuli-responsive liposomes are brought to DDS to improve the efficacy of controlled drug release, assure specific release in targeted sites and alleviate side-effects as much as possible. Stimuli-responsive liposomes could maintain stability in circulation, tissues and cells under physiological conditions. Once delivered, they could be activated by relevant internal or external stimuli to release cargos accurately in target areas. This review highlights the design, functional principles and recent advances on application of pH-sensitive liposomes and thermosensitive liposomes respectively, which are two typical stimuli-responsive liposomes. Common targeting modifications of liposomes are discussed as well. We also summarize recent challenges of stimuli-responsive liposomes and their further applications.     

Antimicrobial peptides with cell-penetrating peptide properties and vice versa

Antimicrobial peptides (AMPs) are a group of peptides that are active against a diverse spectrum of microorganisms. Due to their mode of action, AMPs are a promising class of molecules that could overcome the problems of increasing resistance of bacteria to conventional antibiotics. Furthermore, AMPs are strongly membrane-active and some are able to translocate into cells without the necessity for permanent membrane permeabilization. This feature has brought them into focus for use as transport vectors in the context of drug delivery. Since the plasma membrane restricts transport of bioactive substances into cells, great research interest lies in the development of innovative ways to overcome this barrier and to increase bioavailability. In this context, peptide-based transport systems, such as cell-penetrating peptides (CPPs), have come into focus, and their efficiency has been demonstrated in many different applications. However, more recently, also some AMPs have been used as efficient vectors for intracellular translocation of various active molecules. This review summarizes recent efforts in this interesting field of drug delivery. Moreover, some examples of the application of CPPs as efficient antimicrobial substances will be discussed.     

Breast Tumor Microenvironment: Emerging target of therapeutic phytochemicals

Triple negative breast cancer (TNBC) is the most aggressive and challenging form of breast cancers. Tumor microenvironment (TME) of TNBC is associated with induction of metastasis, immune system suppression, escaping immune detection and drug resistance. TME is highly complex and heterogeneous, consists of tumor cells, stromal cells and immune cells. The rapid expansion of tumors induce hypoxia, which concerns the reprogramming of TME components. The reciprocal communication of tumor cells and TME cells predisposes cancer cells to metastasis by modulation of developmental pathways, Wnt, notch, hedgehog and their related mechanisms in TME. Dietary phytochemicals are non-toxic and associated with various human health benefits and remarkable spectrum of biological activities. The phytochemicals serve as vital resources for drug discovery and also as a source for breast cancer therapy. The novel properties of dietary phytochemicals propose platform for modulation of tumor signaling, overcoming drug resistance, and targeting TME. Therefore, TME could serve as promising target for the treatment of TNBC. This review presents current status and implications of experimentally evaluated therapeutic phytochemicals as potential targeting agents of TME, potential nanosystems for targeted delivery of phytochemicals and their current challenges and future implications in TNBC treatment. The dietary phytochemicals especially curcumin with significant delivery system could prevent TNBC development as it is considered safe and well tolerated in phase II clinical trials.     

NF-κB targeting for overcoming tumor resistance and normal tissues toxicity

Radiotherapy and chemotherapy are two famous modalities in tumor-targeted therapy that lead to systemic and local toxicities for normal tissues. Moreover, several studies have confirmed that exposure of the tumor to radiation or chemotherapy drugs stimulate some signaling pathways in the tumor microenvironment (TME), leading to resistance of cancer cells to apoptosis, as well as promoting angiogenesis and tumor growth. Nuclear factor kappa B (NF-κB) plays a central role in the regulation of inflammatory responses in both normal tissues and tumors via the release of several cytokines, regulation of prostaglandins, reduction/oxidation (redox) reactions, angiogenesis, and cell death. Upregulation of NF-κB in normal tissues causes an appearance of inflammatory reactions and oxidative stress, whereas it regulates angiogenesis and suppresses apoptosis, leading to resistance to subsequent doses of radiation or chemotherapy. Selective inhibition of NF-κB in experimental studies has shown promising results for tumor sensitization via apoptosis induction, inhibition of angiogenesis, and increasing delay of tumor growth. The use of some agents for NF-κB inhibition has been shown to alleviate radiation/chemotherapy toxicities in normal cells/ tissues. In this current review, we explained the pivotal role of NF-κB in both normal tissue toxicity and tumor resistance. We also discussed the promising strategies for overcoming these problems with regard to chemotherapy and radiotherapy.     

卟啉金属有机骨架材料在肿瘤治疗中的应用

目前,恶性肿瘤严重威胁人类健康和生命。临床上常用放疗法和化疗法治疗肿瘤,在一定程度上抑制肿瘤的生长和转移。但是,传统的化疗药物在给药过程中缺乏靶向性、副作用大,而且大多数化疗药物水溶性差,效果有限,高剂量的重复给药会导致耐药,单一模式的治疗策略效果不佳。因此通过构建靶向智能多功能纳米载药系统实现肿瘤精准诊断和治疗成为近年来的研究热点。卟啉金属有机骨架（MOFs）材料具有多孔性、大比表面积、表面可修饰等特性,有望成为良好的靶向刺激响应型药物载体。而且卟啉MOFs可以避免卟啉分子的自聚集以及在激发态的自猝灭,还具有卟啉分子的宽光谱响应范围,是一类具有广阔应用前景的固体光敏剂,因此卟啉MOFs近年来成为构建靶向智能多功能纳米载药系统的重要平台。本论文综述了近年来基于卟啉金属有机骨架材料的肿瘤治疗策略,特别是基于肿瘤内源性组分（pH、酶、氧化还原）和外源性物理信号（声、磁、光）刺激触发的多功能纳米平台用于肿瘤精准诊断和治疗的最新研究进展,并讨论了卟啉MOFs在未来肿瘤治疗中面临的挑战和机遇。     

Polymer-based stimuli-responsive nanosystems for biomedical applications

The application of organic polymers and inorganic/organic hybrid systems in numerous fields of biotechnology has seen a considerable growth in recent years. Typically, organic polymers with diverse structures, compositional variations and differing molecular weights have been utilized to assemble polymeric nanosystems such as polymeric micelles, polymersomes, and nanohydrogels with unique features and structural properties. The architecture of these polymeric nanosystems involves the use of both hydrophobic and hydrophilic polymeric blocks, making them suitable as vehicles for diagnostic and therapeutic applications. Recently, “smart” or “intelligent” polymers have attracted significant attention in the biomedical field wherein careful introduction of specific polymeric modalities changes a banal polymeric nanosystem to an advanced stimuli-responsive nanosystem capable of performing extraordinary functions in response to an internal or external trigger such as pH, temperature, redox, enzymes, light, magnetic, or ultrasound. Further, incorporation of inorganic nanoparticles such as gold, silica, or iron oxide with surface-bound stimuli-responsive polymers offers additional advantages and multifunctionality in the field of nanomedicine. This review covers the physical properties and applications of both organic and organic/inorganic hybrid nanosystems with specific recent breakthroughs in drug delivery, imaging, tissue engineering, and separations and provides a brief discussion on the future direction.     

Stimuli-responsive nanocarriers for intracellular delivery

The emergence of different nanoparticles (NPs) has made a significant revolution in the field of medicine. Different NPs in the form of metallic NPs, dendrimers, polymeric NPs, carbon quantum dots and liposomes have been functionalized and used as platforms for intracellular delivery of biomolecules, drugs, imaging agents and nucleic acids. These NPs are designed to improve the pharmacokinetic properties of the drug, improve their bioavailability and successfully surpass physiological or pathological obstacles in the biological system so that therapeutic efficacy is achieved. In this review I present some of the current approaches used in intracellular delivery systems, with a focus on various stimuli-responsive nanocarriers, including cell-penetrating peptides, to highlight their various biomedical applications.     

Pulmonary gene delivery using polymeric nonviral vectors

Pulmonary delivery provides an easy and well tolerated means of access for the administration of biomacromolecules to the pulmonary epithelium and could therefore be an attractive approach for local and systemic therapies. A growing number of reports, which are summarized in this review, mirror the viability of pulmonary gene delivery. Special attention has been paid to the biological barriers in the lung that must be overcome for successful delivery, and which can be divided into anatomic, physical, immunologic, and metabolic barriers. In light of these barriers, successful nonviral polymer-based formulations of therapeutic genes are presented depending on the chemical nature of the polymer. In addition to polyethyleneimine-based nonviral vectors, which have been most intensively studied for pulmonary gene delivery in the past, other polymeric, dendritic, and targeted materials are also described here, including novel and biodegradable polymers. As new materials need in vitro or ex vivo testing before in vivo application, sophisticated models for all three approaches have been illustrated. Although pulmonary siRNA delivery enjoys popularity in clinical trials, pulmonary gene delivery has so far not been translated into clinical applications. With this review, potential hurdles are demonstrated, but novel approaches that may lead to optimized systems are described as well.     

Oncolytic Immunotherapy: Can’t Start a Fire Without a Spark

Recent advances in cancer immunotherapy have renewed interest in oncolytic viruses (OVs) as a synergistic platform for the development of novel antitumor strategies. Cancer cells adopt multiple mechanisms to evade and suppress antitumor immune responses, essentially establishing a non-immunogenic (‘cold’) tumor microenvironment (TME), with poor T-cell infiltration and low mutational burden. Limitations to the efficacy of immunotherapy still exist, especially for a variety of solid tumors, where new approaches are necessary to overcome physical barriers in the TME and to mitigate adverse effects associated with current immunotherapeutics. OVs offer an attractive alternative by inducing direct oncolysis, immunogenic cell death, and immune stimulation. These multimodal mechanisms make OVs well suited to reprogram non-immunogenic tumors and TME into inflamed, immunogenic (‘hot’) tumors; enhanced release of tumor antigens by dying cancer cells is expected to augment T-cell infiltration, thereby eliciting potent antitumor immunity. Advances in virus engineering and understanding of tumor biology have allowed the optimization of OV-tumor selectivity, oncolytic potency, and immune stimulation. However, OV antitumor activity is likely to achieve its greatest potential as part of combinatorial strategies with other immune or cancer therapeutics.     

Cancer immunotherapy using cells modified with cytokine genes

The ability of various cytokines to hamper tumor growth or to induce anti-tumor immune response has resulted in their study as antitumor agents in gene therapy approaches. In this review we will concentrate on the costimulation of antitumor immune responses using modification of various cell types by cytokine genes. Several strategies have emerged such as (i). modification of tumor cells with cytokine genes ex vivo (whole tumor cell vaccines), (ii). ex vivo modification of other cell types for cytokine gene delivery, (iii). delivery of cytokine genes into tumor microenvironment in vivo, (iv). modification of dendritic cells with cytokine genes ex vivo. Originally single cytokine genes were used. Subsequently, multiple cytokine genes were applied simultaneously, or in combination with other factors such as chemokines, membrane bound co-stimulatory molecules, or tumor associated antigens. In this review we discuss these strategies and their use in cancer treatment as well as the promises and limitations of cytokine based cancer gene therapy. Clinical trials, including our own experience, employing the above strategies are discussed.     

微针技术用于非经皮途径的药物递送研究进展

近年来,微针作为一种新兴的经皮给药技术,具有微创、无痛、使用方便和高效的特点,逐渐成为一种极具研究价值和应用潜力的给药策略。微针技术在过去20年中得到迅速发展并呈现出多样化的趋势,已可根据不同需求来定制微针的形状、组成、机械性能和其他特殊功能等。由于微针能以微创方式穿越各种生物屏障,因此许多研究人员探索了微针在除皮肤外各类组织和器官中的药物递送应用。本文综述了微针技术及其近年来在眼睛、血管、心脏等组织和器官的药物递送中的应用研究,以期推动微针技术的应用发展。     

Canine parvovirus-like particles, a novel nanomaterial for tumor targeting

Specific targeting of tumor cells is an important goal for the design of nanotherapeutics for the treatment of cancer. Recently, viruses have been explored as nano-containers for specific targeting applications, however these systems typically require modification of the virus surface using chemical or genetic means to achieve tumor-specific delivery. Interestingly, there exists a subset of viruses with natural affinity for receptors on tumor cells that could be exploited for nanotechnology applications. For example, the canine parvovirus (CPV) utilizes transferrin receptors (TfRs) for binding and cell entry into canine as well as human cells. TfRs are over-expressed by a variety of tumor cells and are widely being investigated for tumor-targeted drug delivery. We explored whether the natural tropism of CPV to TfRs could be harnessed for targeting tumor cells. Towards this goal, CPV virus-like particles (VLPs) produced by expression of the CPV-VP2 capsid protein in a baculovirus expression system were examined for attachment of small molecules and delivery to tumor cells. Structural modeling suggested that six lysines per VP2 subunit are presumably addressable for bioconjugation on the CPV capsid exterior. Between 45 and 100 of the possible 360 lysines/particle could be routinely derivatized with dye molecules depending on the conjugation conditions. Dye conjugation also demonstrated that the CPV-VLPs could withstand conditions for chemical modification on lysines. Attachment of fluorescent dyes neither impaired binding to the TfRs nor affected internalization of the 26 nm-sized VLPs into several human tumor cell lines. CPV-VLPs therefore exhibit highly favorable characteristics for development as a novel nanomaterial for tumor targeting.     

综述与专论: 适配体功能化外泌体在肿瘤靶向治疗中的应用

传统的肿瘤治疗方法因缺乏足够的靶向性而会产生严重的毒副作用。外泌体（exosome）是一种天然的纳米囊泡,参与细胞间的信息传递,并且作为药物递送载体具有出色的性能优势,包括低免疫原性、低毒性和能够穿越天然屏障等特点。然而以外泌体为载体的药物递送系统的靶向能力仍有不足。适配体（aptamer）是一类化学合成的单链核酸分子,具有分子质量小、易于修饰和免疫原性低等特点,可作为亲和性配体与靶向分子特异性结合。通过在外泌体表面修饰适配体,药物可以被精确递送到肿瘤细胞发生部位,从而实现对肿瘤的靶向治疗,提高肿瘤治疗效果,减少毒副作用。本篇综述将重点讨论适配体功能化外泌体药物靶向递送系统在各种肿瘤治疗方面的应用,并对其未来的挑战和机遇进行阐述。     

Antinucleosome antibody-modified liposomes and lipid-core micelles for tumor-targeted delivery of therapeutic and diagnostic agents

Liposomes and lipid-core micelles prepared of polyethylene glycol-phosphatidylethanolamine (PEG-PE) conjugates have been modified with nucleosome-specific monoclonal antinuclear autoantibody (ANA) 2C5 (mAb 2C5) specifically recognizing a broad variety of cancer cells through the cancer cell surface-bound nucleosomes. mAb 2C5 preserves its specific properties upon the binding with the lipid-based pharmaceutical nanocarriers, and 2C5-modified immunoliposomes and immunomicelles demonstrate an enhanced binding with tumor cells both in vitro and in vivo. We have investigated the delivery of therapeutic and diagnostic agents with such tumor-targeted immunoliposomes and immunomicelles to various tumors in vivo and in vitro. Both lipid-based nanocarriers provided enhanced tumor delivery of imaging agents ((111)In) and antitumor drugs (doxorubicin and photodynamic therapy agents) to tumor cells under different experimental settings. Pharmaceutical lipid-based nanoparticular carriers modified with mAb 2C5 could represent universal systems for tumor-specific delivery of various soluble and insoluble pharmaceuticals.