Polymer nanogels: a versatile nanoscopic drug delivery platform

In this review we put the spotlight on crosslinked polymer nanogels, a promising platform that has the characteristics of an "ideal" drug delivery vehicle. Some of the key aspects of drug delivery vehicle design like stability, response to biologically relevant stimuli, passive targeting, active targeting, toxicity and ease of synthesis are discussed. We discuss several delivery systems in this light and highlight some examples of systems, which satisfy some or all of these design requirements. In particular, we point to the advantages that crosslinked polymeric systems bring to drug delivery. We review some of the synthetic methods of nanogel synthesis and conclude with the diverse applications in drug delivery where nanogels have been fruitfully employed.     

Dendrimers as versatile platform in drug delivery applications

About forty percent of newly developed drugs are rejected by the pharmaceutical industry and will never benefit a patient because of poor bioavailability due to low water solubility and/or cell membrane permeability. New delivery technologies could help to overcome this challenge. Nanostructures with uniform and well-defined particle size and shape are of eminent interest in biomedical applications because of their ability to cross cell membranes and to reduce the risk of premature clearance from the body. The high level of control over the dendritic architecture (size, branching density, surface functionality) makes dendrimers ideal carriers in these applications. Many commercial small molecule drugs with anticancer, anti-inflammatory, and antimicrobial activity have been successfully associated with dendrimers such as poly(amidoamine) (PAMAM), poly(propylene imine) (PPI or DAB) and poly(etherhydroxylamine) (PEHAM) dendrimers, either via physical interactions or through chemical bonding (‘prodrug approach’). Targeted delivery is possible via targeting ligands conjugated to the dendrimer surface or via the enhanced permeability and retention (EPR) effect. The biocompatibility of dendrimers follows patterns known from other small particles. Cationic surfaces show cytotoxicity; however, derivatization with fatty acid or PEG chains, reducing the overall charge density and minimizing contact between cell surfaces and dendrimers, can reduce toxic effects.     

Polysaccharide-based micro/nanocarriers for oral colon-targeted drug delivery

Oral colon-targeted drug delivery has attracted many researchers because of its distinct advantages of increasing the bioavailability of the drug at the target site and reducing the side effects. Polysaccharides that are precisely activated by the physiological environment of the colon hold greater promise for colon targeting. Considerable research efforts have been directed towards developing polysaccharide-based micro/nanocarriers. Types of polysaccharides for colon targeting and in vitro/in vivo assessments of polysaccharide-based carriers for oral colon-targeted drug delivery are summarised. Polysaccharide-based microspheres have gained increased importance not just for the delivery of the drugs for the treatment of local diseases associated with the colon (colon cancer, inflammatory bowel disease (IBD), amoebiasis and irritable bowel syndrome (IBS)), but also for it’s potential for the delivery of anti-rheumatoid arthritis and anti-chronic stable angina drugs. Besides, Polysaccharide-based micro/nanocarriers such as microbeads, microcapsules, microparticles, nanoparticles, nanogels and nanospheres are also introduced in this review.     

Filled carbon nanotubes in biomedical imaging and drug delivery

Introduction: Carbon nanotubes have been advocated as promising candidates in the biomedical field in the areas of diagnosis and therapy. In terms of drug delivery, the use of carbon nanotubes can overcome some limitations of ‘free’ drugs by improving the formulation of poorly water-soluble drugs, allowing targeted delivery and even enabling the co-delivery of two or more drugs for combination therapy. Two different approaches are currently being explored for the delivery of diagnostic and therapeutic agents by carbon nanotubes, namely attachment of the payload to the external sidewalls or encapsulation into the inner cavities. Although less explored, the latter confers additional stability to the chosen diagnostic or therapeutic agents, and leaves the backbone structure of the nanotubes available for its functionalization with dispersing and targeting moieties. Several drug delivery systems and diagnostic agents have been developed in the last years employing the inner tubular cavities of carbon nanotubes.

Areas covered: The research discussed in this review focuses on the use of carbon nanotubes that contain in their interior drug molecules and diagnosis-related compounds. The approaches employed for the development of such nanoscale vehicles along with targeting and releasing strategies are discussed.

Expert opinion: The encapsulation of both biomedical contrast agents and drugs inside carbon nanotubes is further expanding the possibilities to allow an early diagnosis and treatment of diseases.     

The advance of dendrimers--a versatile targeting platform for gene/drug delivery

The quest towards achieving a better understanding of underlying mechanisms by which genetic factors contribute to human disease has gathered considerable momentum, most notably due to the drafting of the complete human genome sequence. This has in turn accelerated research into identifying genes responsible for a plethora of genetic, infectious and metabolic diseases with the vision that therapies can then be developed. Although achieving a therapeutic intervention by gene delivery is perfectly feasible, the practical approach to achieving such a goal, at least in vivo, has proved far more challenging. Employing viruses as gene vectors has to-date proven to be the most effective method of delivery however concerns have emerged about both the short and long-term risks they pose. These fears being confirmed by incidents which led to the tragic deaths of subjects believed to have been triggered by adeno- & retroviral vectors used in clinical trials. This prompted many in the field to turn their research focus towards developing non-viral vectors deemed not only to be safer (non-immunogenic) than their viral counterparts but with a greater gene loading capacity. Polycationic dendrimers (PCDs) as vectors for this purpose have attracted significant interest due to their ease of synthesis, versatility and tolerability. This review will explore the physicochemical parameters crucial to PCD-mediated gene delivery and highlight some innovative strategies designed to maximise transfection efficacy and facilitate tissue-targeting of these elaborate macromolecules.     

Liposomes and inorganic nanoparticles for drug delivery and cancer imaging

Recently, there have been several advancements in material sciences and nanosciences. At the moment these new techniques are slowly entering into clinical settings in drug delivery and imaging. In this review, we will look more closely at the applications that are at the forefront of this translation and examine critical aspects that are involved in the process. Nanoparticles have been increasingly used in clinical settings for drug delivery over the past two decades. Lipid-based nanoparticles are front-runners, but other innovative strategies, such as small inorganic nanoparticles, are entering into the field, particularly for imaging applications. Lipid-based nanoparticles can be metabolized and consumed by the body and are regarded as safe for clinical use. They are usually large with hydrodynamic diameters of approximately 100-200 nm; however, phospholipid-containing particles such as microbubbles with diameters as low as 10 microm in size and micelles with diameters of 10-40 nm can also be used. Hollow liposomes with a large aqueous inner cavity can carry high payloads of drugs and imaging moieties, but are easily trapped by liver kupffer cells and can result in lower tissue penetration rates. New classes of particles with hydrodynamic diameters of < 10 nm, which are cleared by the kidneys, have recently been developed. These particles have been used primarily for imaging applications since they offer only small loading capacities for drugs. However, new strategies such as surface-coupled prodrugs have been developed to facilitate drug delivery in small nanoparticles. We describe different strategies for targeted delivery, imaging and controlled release, and discuss the ability of small inorganic particles as well as larger nanoparticles to be used broadly in human diagnostics and drug delivery.     

Magnetic nanoparticles in MR imaging and drug delivery

Magnetic nanoparticles (MNPs) possess unique magnetic properties and the ability to function at the cellular and molecular level of biological interactions making them an attractive platform as contrast agents for magnetic resonance imaging (MRI) and as carriers for drug delivery. Recent advances in nanotechnology have improved the ability to specifically tailor the features and properties of MNPs for these biomedical applications. To better address specific clinical needs, MNPs with higher magnetic moments, non-fouling surfaces, and increased functionalities are now being developed for applications in the detection, diagnosis, and treatment of malignant tumors, cardiovascular disease, and neurological disease. Through the incorporation of highly specific targeting agents and other functional ligands, such as fluorophores and permeation enhancers, the applicability and efficacy of these MNPs have greatly increased. This review provides a background on applications of MNPs as MR imaging contrast agents and as carriers for drug delivery and an overview of the recent developments in this area of research.     

Stents as a platform for drug delivery

Introduction: Drug delivery stents have proved their efficacy at preventing coronary restenosis and their potential in treating the occlusion or stricture of other body passageways, such as peripheral vessels and alimentary canals. The drug delivery systems on such stent platforms contribute to this improved therapeutic efficacy by providing improved drug delivery performance, along with reduced concerns encountered by current stents (e.g., in-stent restenosis, late thrombosis and delayed healing).

Areas covered: A wide variety of drug delivery stents (metallic drug-eluting stents, absorbable drug-eluting stents, and polymer-free drug-eluting stents for coronary and other applications) that are commercially available or under investigation are collected and summarized in this review, with emphasis on their drug delivery aspects. This review also gives insights into the progression of stent-based drug delivery strategies for the prevention of stent-related problems, or the treatment of local diseases. In addition, a critical analysis of the advantages and challenges of such strategies is provided.

Expert opinion: With an in-depth understanding of drug properties, tissue/organ biology and disease conditions, stent drug delivery systems can be improved further, to endow the stents with better efficacy and safety, along with lower toxicity. There is also a great need for stents that can simultaneously deliver multiple drugs, to treat complex diseases from multiple aspects, or to treat several diseases at the same time. Drug release kinetics greatly determines the stent performance, thus effective strategies should also be developed to achieve customized kinetics.     

Micro- and nanobubbles: A versatile non-viral platform for gene delivery

Micro- and nanobubbles provide a promising non-viral strategy for ultrasound mediated gene delivery. Microbubbles are spherical gas-filled structures with a mean diameter of 1–8 μm, characterised by their core–shell composition and their ability to circulate in the bloodstream following intravenous injection. They undergo volumetric oscillations or acoustic cavitation when insonified by ultrasound and, most importantly, they are able to resonate at diagnostic frequencies. It is due to this behaviour that microbubbles are currently being used as ultrasound contrast agents, but their use in therapeutics is still under investigation. For example, microbubbles could play a role in enhancing gene delivery to cells: when combined with clinical ultrasound exposure, microbubbles are able to favour gene entry into cells by cavitation. Two different delivery strategies have been used to date: DNA can be co-administered with the microbubbles (i.e. the contrast agent) or ‘loaded’ in purposed-built bubble systems – indeed a number of different technological approaches have been proposed to associate genes within microbubble structures. Nanobubbles, bubbles with sizes in the nanometre order of magnitude, have also been developed with the aim of obtaining more efficient gene delivery systems. Their small sizes allow the possibility of extravasation from blood vessels into the surrounding tissues and ultrasound-targeted site-specific release with minimal invasiveness. In contrast, microbubbles, due to their larger sizes, are unable to extravasate, thus and their targeting capacity is limited to specific antigens present within the vascular lumen. This review provides an overview of the use of microbubbles as gene delivery systems, with a specific focus on recent research into the development of nanosystems. In particular, ultrasound delivery mechanisms, formulation parameters, gene-loading approaches and the advantages of nanometric systems will be described.     

Stents as a platform for drug delivery

INTRODUCTION: Drug delivery stents have proved their efficacy at preventing coronary restenosis and their potential in treating the occlusion or stricture of other body passageways, such as peripheral vessels and alimentary canals. The drug delivery systems on such stent platforms contribute to this improved therapeutic efficacy by providing improved drug delivery performance, along with reduced concerns encountered by current stents (e.g., in-stent restenosis, late thrombosis and delayed healing). AREAS COVERED: A wide variety of drug delivery stents (metallic drug-eluting stents, absorbable drug-eluting stents, and polymer-free drug-eluting stents for coronary and other applications) that are commercially available or under investigation are collected and summarized in this review, with emphasis on their drug delivery aspects. This review also gives insights into the progression of stent-based drug delivery strategies for the prevention of stent-related problems, or the treatment of local diseases. In addition, a critical analysis of the advantages and challenges of such strategies is provided. EXPERT OPINION: With an in-depth understanding of drug properties, tissue/organ biology and disease conditions, stent drug delivery systems can be improved further, to endow the stents with better efficacy and safety, along with lower toxicity. There is also a great need for stents that can simultaneously deliver multiple drugs, to treat complex diseases from multiple aspects, or to treat several diseases at the same time. Drug release kinetics greatly determines the stent performance, thus effective strategies should also be developed to achieve customized kinetics.     

Design and fabrication of magnetic nanoparticles for targeted drug delivery and imaging

Magnetic nanoparticles (MNPs) represent a class of non-invasive imaging agents that have been developed for magnetic resonance (MR) imaging. These MNPs have traditionally been used for disease imaging via passive targeting, but recent advances have opened the door to cellular-specific targeting, drug delivery, and multi-modal imaging by these nanoparticles. As more elaborate MNPs are envisioned, adherence to proper design criteria (e.g. size, coating, molecular functionalization) becomes even more essential. This review summarizes the design parameters that affect MNP performance in vivo, including the physicochemical properties and nanoparticle surface modifications, such as MNP coating and targeting ligand functionalizations that can enhance MNP management of biological barriers. A careful review of the chemistries used to modify the surfaces of MNPs is also given, with attention paid to optimizing the activity of bound ligands while maintaining favorable physicochemical properties.     

Cyclodextrin-based nanosponges: a propitious platform for enhancing drug delivery

Introduction: Recently, Nanotechnology is receiving considerable acknowledgment due to its potential to combine features that are difficult to achieve by making use of a drug alone. Cyclodextrin-based nanosponges are yet another contemporary approach for highlighting the advancements which could be brought about in a drug delivery system. Statistical analyses have shown that around 40% of currently marketed drugs and about 90% of drugs in their developmental phase encounter solubility-related problems. Cyclodextrin-based nanosponges have the capacity to emerge as a productive approach over conventional cyclodextrins by overcoming the disadvantages associated with the latter.

Areas covered: This review is intended to give an insight regarding cyclodextrin-based nanosponges such as their physical and chemical properties. In addition, methods of preparation and characterization are discussed along with biocompatibility, and how these nanomeric elements can be exploited in developing effective drug formulations.

Expert opinion: This emerging technology of cyclodextrin-based nanosponges is expected to provide technical solutions to the formulation arena and to come up with some successful products in the pharmaceutical market. It also has an exciting future in the field of therapeutics wherein it can cater site-directed drug delivery and hence it possesses vibrant opportunities.     

ROS-responsive drug delivery systems for biomedical applications

In the field of biomedicine, stimuli-responsive drug delivery systems (DDSs) have become increasingly popular due to their site-specific release ability in response to a certain physiological stimulus, which may result in both enhanced treatment outcome and reduced side effects. Reactive oxygen species (ROS) are the unavoidable consequence of cell oxidative metabolism. ROS play a crucial part in regulating biological and physiological processes, whereas excessive intracellular ROS usually lead to the oxidation stress which has implications in several typical diseases such as cancer, inflammation and atherosclerosis. Therefore, ROS-responsive DDSs have elicited widespread popularity for their promising applications in a series of biomedical research because the payload is only released in targeted cells or tissues that overproduce ROS. According to the design of ROS-responsive DDSs, the main release mechanisms of therapeutic agents can be ascribed to ROS-induced carrier solubility change, ROS-induced carrier cleavage or ROS-induced prodrug linker cleavage. This review summarized the latest development and novel design of ROS-responsive DDSs and discussed their design concepts and the applications in the biomedical field.     

Bioconjugation of polymers: a novel platform for targeted drug delivery

Bioconjugation, a novel technique is usually exploited to improve the biopharmaceutical aspects of a bioactive as well as afford its spatial and temporal distribution. The strategy enlightens newer vistas for delivery of drugs, peptides, enzymes, and oligonucleotides. Site specific delivery may be obtained by tailoring the conjugates as an inactive prodrug and designing polymer drug linkages susceptible to cleavage by specific enzymes or pH. These prodrugs substantially change the mechanisms of cellular entry, pharmacokinetic disposition and ultimately target the drug. The conjugate vehicles are being exploited for targeting pharmacological agents to visceral tissues viz brain, colon etc. These biomaterials are bringing into play, novel drug delivery systems for selectively and specifically ferrying drugs to the desired organ. Noteworthy contributions reported with bioconjugated nanoparticles for biosensing and bioimaging incorporate cell staining, DNA detection, separation and recombination relevance in DNA protection. Only recently, these tailor-made polymers have also gained impetuous for enzyme therapy, gene therapy, insulin therapy, cancer therapy and management of AIDS with the interception of minimal side effects. The present review exhaustively provides an insight to the polymer bioconjugates and their implications for targeted delivery. The article also discusses the therapeutic aspects of these conjugates and that these may serve as fascinating tools for drug delivery.     

His-tagged norovirus-like particles: A versatile platform for cellular delivery and surface display

In addition to vaccines, noninfectious virus-like particles (VLPs) that mimic the viral capsid show an attractive possibility of presenting immunogenic epitopes or targeting molecules on their surface. Here, functionalization of norovirus-derived VLPs by simple non-covalent conjugation of various molecules is shown. By using the affinity between a surface-exposed polyhistidine-tag and multivalent tris-nitrilotriacetic acid (trisNTA), fluorescent dye molecules and streptavidin–biotin conjugated to trisNTA are displayed on the VLPs to demonstrate the use of these VLPs as easily modifiable nanocarriers as well as a versatile vaccine platform. The VLPs are able to enter and deliver surface-displayed fluorescent dye into HEK293T cells via a surface-attached cell internalization peptide (VSV-G). The ease of manufacturing, the robust structure of these VLPs, and the straightforward conjugation provide a technology, which can be adapted to various applications in biomedicine.     

Contact lenses as a platform for ocular drug delivery

Introduction: Most ophthalmic drugs are delivered through eye drops even though only about 1 – 5% of the drug reaches the target tissue and the patient compliance is not good. Drug-eluting contact lenses could significantly increase bioavailability, reduce side effects and improve patient compliance.

Areas covered: Recent research on drug-eluting contact lenses has focused on increasing the release duration through molecular imprinting, dispersion of barriers or nanoparticles, increasing drug binding to the polymer, sandwiching a PLGA (poly[lactic-co-glycolic acid]) layer in a lens and developing novel materials. This review covers all these studies with a specific focus on the transport mechanisms and advantages and disadvantages of each approach.

Expert opinion: The main reason for prior failures was the short duration of release from the lenses. The new technologies can provide extended drug release for hours to days. The in vivo animal and clinical studies have proven the safety and efficacy of drug-eluting contact lenses, while showing considerable improvements compared to eye drops. The future appears to be promising but several challenges remain such as processing and storage issues, regulatory hurdles, high costs of clinical studies, potential lack of acceptance by the elderly, etc.