Subcellular targeting: a new frontier for drug-loaded pharmaceutical nanocarriers and the concept of the magic bullet

The ability of a pharmacologically active molecule selectively to find its target is closely linked with its potential as a successful therapeutic drug. It has become increasingly evident that there are several pharmacologically active molecules that exert their action on molecular targets inside cell organelles. In the case of a drug molecule with no defined specificity for a particular organelle, the molecule would either need to have sufficiently long metabolic stability to allow for random interaction with the organelle to occur, or a targeting strategy for the intended subcellular compartment would need to be devised in order to potentiate therapeutic effect. In the case of molecules with a stronger affinity for a non-target subcellular compartment, there exists even greater need for the ability to control subcellular disposition. Subcellular or organelle-specific targeting has thus emerged as a new frontier in drug delivery. In this review selected examples of recent work are discussed that the authors believe might eventually lead to the application of pharmaceutical nanocarriers to create the next generation of ‘magic bullets’ that are capable of delivering a drug payload to a molecular target at a subcellular location.     

Vesicular systems for delivering conventional small organic molecules and larger macromolecules to and through human skin

The history of using vesicular systems for drug delivery to and through skin started nearly three decades ago with a study utilising phospholipid liposomes to improve skin deposition and reduce systemic effects of triamcinolone acetonide. Subsequently, many researchers evaluated liposomes with respect to skin delivery, with the majority of them recording localised effects and relatively few studies showing transdermal delivery effects. Shortly after this, transfersomes were developed with claims about their ability to deliver their payload into and through the skin with efficiencies similar to subcutaneous administration. Since these vesicles are ultradeformable, they were thought to penetrate intact skin deep enough to reach the systemic circulation. Their mechanisms of action remain controversial, with diverse processes being reported. Parallel to this development, other classes of vesicles were produced, with ethanol being included into the vesicles to provide flexibility (as in ethosomes); vesicles were constructed from surfactants and cholesterol (as in niosomes). The ultradeformable vesicles showed variable efficiency in delivering low-molecular-weight and macromolecular drugs. This article will critically evaluate vesicular systems for dermal and transdermal delivery of drugs, considering both their efficacy and their potential mechanisms of action.     

Development of magnetic anionic liposome/atelocollagen complexes for efficient magnetic drug targeting

Magnetic nanoparticle-incorporated liposomes (magnetic liposomes) are considered a promising site-specific drug delivery carrier vehicle. With regard to their surface charge, magnetic anionic liposomes (Mag-AL) demonstrate little toxicity in comparison with magnetic cationic liposomes (Mag-CL), whereas their cellular association and uptake efficiency are low. In the current study, we constructed complexes of Mag-AL and atelocollagen (ATCOL), which is a biocompatible and minimally immunogenic biomaterial, to improve the cellular uptake properties of Mag-AL in vitro and in vivo. The cellular association and/or uptake of Mag-AL in RAW264 cells, a murine macrophage-like cell line, under a magnetic field was significantly increased when Mag-AL was complexed with ATCOL, and the highest cellular association was observed with complexes constructed using 5?µg/mL of ATCOL. The complexes showed liposome concentration-dependent and time-dependent cellular association under a magnetic field, and their cellular uptake efficiency was comparable with that of Mag-CL. In addition, Mag-CL showed significant cytotoxicity in a liposome concentration-dependent manner, whereas Mag-AL/ATCOL complexes produced no cytotoxic effect against RAW264 cells. Furthermore, the efficient cellular association of Mag-AL/ATCOL complexes in RAW264 cells was observed even in the presence of serum, and their liver accumulation was significantly increased at a magnetic field-exposed region after intravenous injection in rats. These results indicate that Mag-AL/ATCOL complexes could be a safe and efficient magnetic responsive drug carrier.     

皮肤真菌病新型局部给药系统研究进展

皮肤真菌病是易发病、易传染、易复发的疾病,严重影响患者生活质量。局部给药制剂直接作用于病变部位,使用方便,患者顺应性好,是皮肤真菌病临床治疗的首选。以脂质体、醇质体、微乳和脂质纳米粒等为代表的新型给药系统,可以提高药物的渗透性,减小药物透过,使其在皮肤局部蓄积,从而能够增强疗效、缩短疗程和减少不良反应,使皮肤真菌病的局部治疗更具有应用前景。本文综述了近年来国内外皮肤真菌病新型局部给药系统的研究进展。     

Interest of glycolipids in drug delivery: from physicochemical properties to drug targeting

Importance of the field: The need for new products derived from natural sources for the replacement of the commonly used non-ionic surfactants containing ethylene oxide units with degradable carbohydrate headgroups has become an important area of research. Glycolipids offer a wide range of applications in the pharmaceutical and cosmetic fields and can compete with the most commonly used surfactants. Involved in molecular recognition mechanisms at the surface of cells, glycolipids are also used for drug targeting.

Areas covered in this review: The structure and pharmaceutical applications of the main glycolipid categories are summarized. The review focuses on marketed glycolipids, biosurfactants and compounds developed at laboratory scale for applications such as self-assembly or drug targeting.

What the reader will gain: This article aims to provide an overview of the different sugar-based surfactant classes and their potential uses.

Take home message: Beside their use as surfactants or absorption enhancers in basic formulations, glycolipids can build gels, niosomes, hexosomes and cubosomes, whose structure is directly related to lyotropic properties. These systems allow solubilization and entrapment of drugs. In innovative delivery systems, glycolipids are also used for drug targeting because their sugar moieties can be specifically recognized by carbohydrate-binding proteins exposed at the surface of cells.     

Lymphatic system: a prospective area for advanced targeting of particulate drug carriers

Introduction: The lymphatic system has a critical role in the immune system's recognition and response to disease and it is an additional circulatory system throughout the entire body. Extensive multidisciplinary investigations have been carried out in the area of lymphatic delivery, and lymphatic targeting has attracted a lot of attention for providing preferential chemotherapy and improving bioavailability of drugs that undergo hepatic first-pass metabolism.

Areas covered: This review focuses on progress in the field of lymphatic therapeutics and diagnosis. Moreover, the anatomy and physiology of the lymphatic system, particulate drug carriers and different physicochemical parameters of both modified and unmodified particulate drug carriers and their effect on lymphatic targeting are addressed.

Expert opinion: Particulate drug carriers have encouraged lymphatic targeting, but there are still challenges in targeting drugs and bioactives to specific sites, maintaining desired action and crossing all the physiological barriers. Lymphatic therapy using drug-encapsulated lipid carriers, especially liposomes and solid lipid nanoparticles, emerges as a new technology to provide better penetration into the lymphatics where residual disease exists. Size is the most important criteria when designing nanocarriers for targeting lymphatic vessels as the transportation of these particles into lymphatic vessels is size dependent. By increasing our understanding of lymphatic transport and uptake, and the role of lymphatics in various diseases, we can design new therapeutics for effective disease control.     

Liposomal cancer therapy: exploiting tumor characteristics

Importance of the field: More than 10 million people worldwide are diagnosed with cancer each year, and the development of effective cancer treatments is consequently of great significance. Cancer therapy is unfortunately hampered by severe dose-limiting side effects that reduce the efficacy of cancer treatments. In the search for more effective cancer treatments, nanoparticle-based drug delivery systems, such as liposomes, that are capable of delivering their drug payload selectively to cancer cells are among the most promising approaches.

Areas covered in this review: This review provides an overview of current strategies for improving the different stages of liposomal cancer therapy, which involve transporting drug-loaded liposomes through the bloodstream, increasing tumor accumulation, and improving drug release and cancer cell uptake after accumulation at the tumor target site.

What the reader will gain: The review focuses on strategies that exploit characteristic features of solid tumors, such as abnormal vasculature, overexpression of receptors and enzymes, as well as acidic and thiolytic characteristics of the tumor microenvironment.

Take home message: It is concluded that the design of new liposomal drug delivery systems that better exploit tumor characteristic features is likely to result in more efficacious cancer treatments.     

Vesicular carriers for dermal drug delivery

The skin can offer several advantages as a route of drug administration although its barrier nature makes it difficult for most drugs to penetrate into and permeate through it. During the past decades there has been a lot of interest in lipid vesicles as a tool to improve drug topical delivery. Vesicular systems such as liposomes, niosomes, ethosomes and elastic, deformable vesicles provide an alternative for improved skin drug delivery. The function of vesicles as topical delivery systems is controversial with variable effects being reported in relation to the type of vesicles and their composition. In fact, vesicles can act as drug carriers controlling active release; they can provide a localized depot in the skin for dermally active compounds and enhance transdermal drug delivery. A wide variety of lipids and surfactants can be used to prepare vesicles, which are commonly composed of phospholipids (liposomes) or non-ionic surfactants (niosomes). Vesicle composition and preparation method influence their physicochemical properties (size, charge, lamellarity, thermodynamic state, deformability) and therefore their efficacy as drug delivery systems. A review of vesicle value in localizing drugs within the skin at the site of action will be provided with emphasis on their potential mechanism of action.     

Mitochondria and neurodegenerative diseases: the promising role of nanotechnology in targeted drug delivery

Introduction: Neurodegenerative diseases (NDs) represent a group of different clinical entities that, despite the specific primary etiologies, share a common signature in terms of a general mitochondrial dysfunction with consequent oxidative stress accumulation. As these two events occur early during neurodegenerative process, they could be considered ideal therapeutic targets.

Areas covered: This review describes the nanotechnologies explored for the specific targeted delivery of drugs, in order to precisely direct molecules into the intended site, where they can practice their therapeutic effects.

Expert opinion: Conventional drug delivery systems cannot provide adequate restoration and connection patterns that are essential for a functional recovery in NDs. Since orally delivered antioxidants are easily destroyed by acids and enzymes, only a small portion of consumed antioxidants gets absorbed, leading to low bioavailability and low concentration at the target site. In this scenario, the identification of new proenergetic drugs, in combination with the development of methods for selectively delivering biologically active molecules into mitochondria, will potentially launch new therapeutic approaches for the treatment of NDs, where energetic imbalance plays a central role.     

新型经皮给药载体——醇质体的研究进展

醇质体作为一种新的经皮给药载体,是一种具有高变形性、高包封率、能完整地渗透过皮肤的新型脂质体。它性质稳定、制备简单,与普通脂质体相比,显著提高了透皮速率,能更有效地运送药物通过角质层进入皮肤更深层甚至血液循环,也为亲水和亲脂性药物提供有效的细胞内传递,近年已成为经皮给药研究的热点。文中根据国内外文献,对醇质经皮给药的促渗机制、特点及其应用现状进行综述,同时指出了其存在的问题和可能的发展趋势。     

Preparation and the in-vivo evaluation of paclitaxel liposomes for lung targeting delivery in dogs

Objectives The aim of this study was to develop paclitaxel liposomes for a lung targeting delivery system. Methods The liposomes composed of Tween‐80/HSPC/cholesterol (0.03 : 3.84 : 3.84, mol/mol), containing paclitaxel and lipids (1 : 40, mol/mol), were prepared by a combination of solid dispersion and effervescent techniques, and then subjected to ultrasonication. The pharmacokinetics and biodistribution of liposomal and injectable formulation of paclitaxel in dogs were studied after intravenous administration. Key findings The mean diameter, polydispersity index, zeta‐potential and entrapment efficiency of the liposomes were 501.60 ± 15.43 nm, 0.28 ± 0.02, ?20.93 ± 0.06 mV and 95.17 ± 0.32%, respectively. The liposomal formulation kept stable for at least 3 months at 6 ± 2°C and didn't cause haemolysis. The liposome carrier decreased the area under the curve and terminal half‐life of paclitaxel compared with paclitaxel injection ranging from 0.352 ± 0.031 mg/l*h and 0.0671 ± 0.144 h to 0.748 ± 0.062 mg/l*h and 1.978 ± 0.518 h, respectively. The paclitaxel liposomes produced a drug concentration in the lung that was markedly higher than that in other organs or tissues and was about 15‐fold of that of paclitaxel injection at 2 h. Conclusions To sum up, these results demonstrated that the paclitaxel liposomes are an effective lung targeted carrier in the treatment of lung cancer.     

Colon targeting: an emerging frontier for oral insulin delivery

Subcutaneous administration of insulin is associated with several limitations such as discomfort, local pain, irritation, infections, immune reactions and lipoatrophy as well as lipohypertrophy manifestations at the injection site. To overcome these drawbacks, enormous research is currently going on worldwide for designing of an alternative noninvasive route of administration. Pulmonary and oral route seem to be the most promising ones, with respect to the market value. However, after the letdown by pulmonary delivery of insulin, oral colon targeted delivery of insulin has gained tremendous interest among researchers. Although bioavailability remains a challenge for oral colon specific delivery of insulin, the employment of protease inhibitors, permeation enhancers and polymeric delivery systems have proved to be advantageous to overcome the said problem. This Editorial article is not intended to offer a comprehensive review on drug delivery, but shall familiarize the readers with the strategies employed for attaining non-erratic bioavailability of insulin, and to highlight some of the formulation technologies that have been developed for attaining oral colon-specific delivery of insulin.     

Preparation and characterization of a biodegradable drug targeting system for anticancer drug delivery: Microsphere-antibody conjugate

Targeted delivery of anticancer drugs is one of the most actively pursued goals in anticancer chemotherapy. A major disadvantage of anticancer drugs is their lack of selectivity for tumour tissue, which causes severe side effects and results in low cure rates. Any strategy by which a cytotoxic drug is targeted to the tumour, thus increasing the therapeutic index of the drug, is a way of improving cancer chemotherapy and minimizing systematic toxicity. This study covers the preparation of the gelatin microsphere (GM)-anti-bovine serum albumin (anti-BSA) conjugate for the development of a drug targeting approach for anticancer drug delivery. Microspheres of 5% (w/v) gelatin content were prepared by crosslinking with glutaraldehyde (GTA) at 0.05 and 0.50% (v/v) concentration. Microspheres were in the size range of 71–141 μm. The suitability of these microspheres as drug carriers for anticancer drug delivery was investigated in vitro by studying the release profiles of loaded methotrexate (MTX) and 5-fluorouracil (5-FU) and the cytotoxicities on cancer cell lines. The in vitro MTX release profiles (～22–46% released in 24 h depending on the amount of GTA used) were much slower compared to 5-FU (～42–91% released in 24 h). Both drugs demonstrated an initial fast release, which was followed by gradual, sustained drug release. The MTT cytotoxicity test results of GMs loaded with 5-FU and MTX showed ～54–70% and ～52–67% cytotoxicities in 4 days. In general, incorporation of MTX and 5-FU in microspheres enhanced the cytotoxic effect in a more prolonged manner compared to the free drugs. Gelatin micospheres were chemically conjugated to anti-BSA and the antigen–antibody activities were studied by immunofluorescence. Results indicated ～80% binding with conjugated anti-BSA and BSA-FITC. Based on their low cytotoxicity and the high antigen binding efficiencies, anti-BSA conjugated gelatin microspheres could be suitable targeted drug carrier systems for selective and long-term delivery of anticancer drugs to a specific body compartment (i.e. bladder cancer).     

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。     

Targeting pulmonary tuberculosis using nanocarrier-based dry powder inhalation: current status and futuristic need

Tuberculosis (TB) is a disease caused by the pathogen Mycobacterium tuberculosis. Prolonged administration of high dose antibiotics using oral and injectable routes and their associated side effects show limitations to successful treatment outcome of TB. Nanocarrier-based dry powder inhalers (DPIs) may provide a breakthrough as an alternative therapeutic approach because of their stable, non-invasive nature and ability to target the drug at the site of infection. The current review focuses on the roadmap of the respiratory system, drug deposition and targeting at the site of infection via the pulmonary route. This review will provide readers with an overview of the existing literature of nanocarrier-based DPIs of anti-TB drugs. Among different nanocarriers, results of most of the proliposomes and polymeric particles-based DPIs with respect to their characterisation parameters like encapsulation efficiency, drug loading, storage stability and aerodynamic properties are not encouraging, whereas surface engineered, nanostructured lipid carriers (NLCs), i.e. ligand attached-NLCs-based dry powder inhalers (NLCs-DPI) show promising results. But still, there is a need to investigate them for in vitro, ex vivo, in vivo and toxicity studies to achieve a market approval.     

经鼻脑靶向递药系统的研究进展

鼻腔与脑在解剖生理上的独特联系使得鼻腔给药作为脑内递药途径成为可能.鼻腔给药作为脑靶向的途径之一,可有效地使通过其他给药途径不易透过血脑屏障的药物绕过血脑屏障到达脑部,为中枢神经系统疾病的治疗提供了一种极有发展前景的脑内递药途径.就鼻腔给药脑靶向的依据、影响因素、评价方法、剂型等方面对经鼻脑靶向递药系统的研究现状进行总结.     

An insight on hyaluronic acid in drug targeting and drug delivery

Hyaluronic acid (HA) has recently been studied for its use in drug delivery applications. Medically, HA is used as a surgical aid in ophthalmology. It also possesses therapeutic potential in the treatment of arthritis and wound healing. HA-binding receptors, CD44 and receptor for hyaluronan-mediated motility have attracted much enthusiasm, mainly because they are believed to be involved in cancer metastasis. This review unravels the role of HA in drug delivery and targeting. Designing of various novel drug delivery systems using HA as a biopolymer will also be reviewed in the present article.     

Advances in non-invasive drug delivery for atherosclerotic heart disease

Introduction: Apart from statins, anti-platelet agents and invasive procedures, the anti-atherosclerotic medical weaponry for coronary heart disease (CHD) is scarce and only partially protects CHD patients from major adverse cardiac events.

Areas covered: Several novel non-invasive strategies are being developed to widen the therapeutic options. Among them, drug delivery tools were tested in vivo encompassing liposomes, micelles, polymeric, metallic and lipid nanoparticles used as carriers of statins, corticosteroids, a bisphosphonate, a glitazone, anti-cancer agents, a mycotoxin, a calcium channel blocker and a compound of traditional Chinese medicine. All preparations improved parameters related to atherosclerotic lesions induced in rabbits, rats and mice and reduced neointima formation in experiments aiming to prevent post-stenting restenosis. In subjects submitted to percutaneous coronary intervention, nanoparticle formulations of paclitaxel and alendronate showed safety but are still not conclusive regarding in-stent late loss. The experience of our group in atherosclerotic rabbits treated with non-protein lipid nanoparticles associated with anti-cancer drugs such as paclitaxel, etoposide and methotrexate is summarized, and preliminary safety data in CHD patients are anticipated.

Expert opinion: Taken together, these studies show that non-invasive drug-delivery systems may become promising tools to rescue CHD patients from the risks of severe and life-threatening lesions that should be more energetically treated.     

Advances in brain drug targeting and delivery: limitations and challenges of solid lipid nanoparticles

Introduction: With the advancement in the field of medical colloids and interfacial sciences, the life expectancy has been greatly improved. In addition, changes in the human lifestyle resulted in development of various organic and functional disorders. Central nervous system (CNS) disorders are most prevalent and increasing among population worldwide. The neurological disorders are multi-systemic and difficult to treat as portal entry to brain is restricted on account of its anatomical and physiological barrier.

Areas covered: The present review discusses the limitations to CNS drug delivery, and the various approaches to bypass the blood brain barrier (BBB), focusing on the potential use of solid lipid nanoparticles (SLN) for drug targeting to brain. The methods currently in use for SLN production, physicochemical characterization and critical issues related to the formulation development suitable for targeting brain are also discussed.

Expert opinion: The potential advantages of the use of SLN over polymeric nanoparticles are due to their lower cytotoxicity, higher drug loading capacity and scalability. In addition, their production is cost effective and the systems provide a drug release in a controlled manner up to several weeks. Drug targeting potential of SLN can be enhanced by attaching ligands to their surface.     

Sialic acid as a potential approach for the protection and targeting of nanocarriers

Introduction: Nanocarriers are considered to be one of the most innovative drug delivery systems, owing to their high potential in drug protection, delivery and targeting to the diseased site. Unfortunately, their applicability is hampered mainly by their uptake, due to macrophagic recognition and lack of specificity, if not properly engineered.

Areas covered: Sialic acid (SA) and its derivatives have recently been studied in order to govern their stealthness as carriers and their effectiveness as targeting moieties. In this review, the most outstanding research (in vitro and in vivo) dealing with the use of SA or its derivatives to modify the surface carriers, in order to achieve targeted or stealth nanosystems, is summarized. Moreover, the application of SA or its derivatives as modifiers in cancer targeting and therapy, and in recognition purposes, is considered.

Expert opinion: The application of SA-based strategies for nanocarrier engineering represents one of the most stimulating challenges in drug delivery and drug targeting. Both in vivo and in vitro results on stealth or targeted nanocarriers, modified with different kinds of SA or SA derivative, have highlighted the great potential of this approach. These studies have drawn attention to both the advantages (stealth properties, targeting ability, cancer inhibition, viral and inflammation recognition, brain targeting) and the possible disadvantages (i.e., presence of possible multi-target side effect outputs) of this strategy, and overall suggests that further investigations on this strategy are required.