Aptamer-dendrimer bioconjugate: a nanotool for therapeutics,diagnosis, and imaging

Introduction: Aptamers hold great promise as molecular tool in biomedical applications due to the therapeutic utility exhibited by their target specificity and sensitivity. Although current development of aptamer is hindered by its probable in vivo degradation, inefficient immobilization on probe surface, and generation of low detection signal, bioconjugation with nanomaterials can feasibly solve these problems. Nanostructures such as dendrimers, with multivalency and nonimmunogenicity, bioconjugated with aptamers have opened newer vistas for better pharmaceutical applications of aptamers.

Areas covered: This review covers brief overview of aptamers and dendrimers, with specific focus on recent progresses of aptamer-dendrimer (Apt-D) bioconjugate in areas of targeted drug delivery, diagnosis, and molecular imaging along with the discussion on the currently available conjugates, using their in vitro and in vivo results.

Expert opinion: The novel Apt-D bioconjugates have led to advances in targeting cancer cell, have amplified biosensing, and offered in vivo cell imaging. Because of the unique properties and applications, Apt-D bioconjugate propose an exciting future. However, further research in synthesis of new target-specific aptamers and their conjugation with dendrimers is required to establish full potential of Apt-D bioconjugate.     

Nanotechnology based platforms for survivin targeted drug discovery

Introduction: Development of an effective, safe and targeted drug delivery system to fight cancer and other diseases is a prime focus in the area of drug discovery. The emerging field of nanotechnology has revolutionised the way cancer therapy and diagnosis is achieved primarily due to the recent advances in material engineering and drug availability. Further, the recognition of the crucial role played by anti-apoptotic proteins such as survivin, has initiated the development of therapeutics that can target this protein as an attempt to develop alternative cancer therapies. However, a key challenge faced in drug development is the efficient delivery of survivin-targeted molecules to specific areas in the body.

Areas covered: This review primarily focuses on the different strategies employing nanotechnology for targeting survivin expressed in human cancers. Different nanomaterials incorporating nucleic molecules or drugs targeted at survivin are discussed and the results obtained from studies are highlighted.

Expert opinion: There are extensive studies reporting different treatment regimens for cancer, however, they still result in systemic toxicity, reduced bioavailability and ineffective delivery. Novel approaches involve the use of biocompatible nanomaterials together with gene or drug molecules to target proteins such as survivin, which is overexpressed in cancerous cells. These nanoformulations allow the benefits of protecting easily degradable molecules, allow controlled release, and enhance targeted delivery and effectiveness. Hence, nanotherapy utilizing survivin targeting can be considered to play a key role in the development of personalized nanomedicine for cancer.     

Drug delivery from gelatin-based systems

Introduction: Carriers for controlled drug release offer many advantages compared with conventional dosage forms. Gelatin has been investigated extensively as a drug delivery carrier, due to its properties and history of safe use in a wide range of medical applications.

Areas covered: Gelatin was shown to be versatile due to its intrinsic features that enable the design of different carrier systems, such as microparticles and nanoparticles, fibers and even hydrogels. Gelatin microparticles can serve as vehicles for cell amplification and for delivery of large bioactive molecules, whereas gelatin nanoparticles are better suited for intravenous delivery or for drug delivery to the brain. Gelatin fibers contain a high surface area-to-volume ratio, whereas gelatin hydrogels can trap molecules between the polymer’s crosslink gaps, allowing these molecules to diffuse into the blood stream. Another interesting area is the combination of tissue bioadhesive-based gelatin with controlled drug release for pain management and wound healing.

Expert opinion: The modification of gelatin and its combinations with other biomaterials have demonstrated the flexibility of these systems and can be employed for meeting the challenges of finding ideal carrier systems that enable specific, targeted and controlled release in response to demands in the body.     

Bisphosphonate-modified biomaterials for drug delivery and bone tissue engineering

Introduction: Bisphosphonates (BPs) were introduced 45 years ago as anti-osteoporotic drugs and during the last decade have been utilized as bone-targeting groups in systemic treatment of bone diseases. Very recently, strategies of chemical immobilization of BPs in hydrogels and nanocomposites for bone tissue engineering emerged. These strategies opened new applications of BPs in bone tissue engineering.

Areas covered: Conjugates of BPs to different drug molecules, imaging agents, proteins and polymers are discussed in terms of specific targeting to bone and therapeutic affect induced by the resulting prodrugs in comparison with the parent drugs. Conversion of these conjugates into hydrogel scaffolds is also presented along with the application of the resulting materials for bone tissue engineering.

Expert opinion: Calcium-binding properties of BPs can be successfully extended via different conjugation strategies not only for purposes of bone targeting, but also in supramolecular assembly affording either new nanocarriers or bulk nanocomposite scaffolds. Interaction between carrier-linked BPs and drug molecules should also be considered for the control of release of these molecules and their optimized delivery. Bone-targeting properties of BP-functionalized nanomaterials should correspond to bone adhesive properties of their bulk analogs.     

Targeted cancer drug delivery with aptamer-functionalized polymeric nanoparticles

Abstract

Based on exceptional advantages of aptamers, increasing attention has been presented in the utilise of them as targeted ligands for cancer drug delivery. Recently, the progress of aptamer-targeted nanoparticles has presented new therapeutic systems for several types of cancer with decreased toxicity and improved efficacy. We highlight some of the promising formulations of aptamer-conjugated polymeric nanoparticles for specific targeted drug delivery to cancer cells. This review paper focuses on the current progresses in the use of the novel strategies to aptamer-targeted drug delivery for chemotherapy. An extensive literature review was performed using internet database, mainly PubMed based on MeSH keywords. The searches included full-text publications written in English without any limitation in date. The abstracts, reviews, books as well as studies without obvious relating of aptamers as targeted ligands for cancer drug delivery were excluded from the study. The reviewed literature revealed that aptamers with ability to modify and conjugate to various molecules can be used as targeted cancer therapy agents. However, development of aptamers unique to each individual’s tumour to the development of personalised medicine seems to be needed.     

Drug delivery/imaging multifunctionality of mesoporous silica-based composite nanostructures

Introduction: Biocompatible mesoporous silica nanoparticles (MSNs) are regarded as one of the most promising inorganic drug delivery systems (DDSs) to concurrently enhance the therapeutic efficiency and mitigate the side effects of anticancer drugs. Elaborately combining multicomponents with MSNs will endow them with specific functionalities for cancer therapy and diagnosis, such as targeted drug delivery, intelligent on-demand drug releasing, synergistic therapy, diagnostic imaging and so on.

Areas covered: This review discusses the state-of-the-art potential obstacles and further perspectives of the chemical design/synthesis, in vitro/in vivo pharmaceutical evaluations and potential clinical translations of multifunctional mesoporous silica-based nanomaterials for biotechnological and biomedical applications, especially against cancer. These topics cover the years from 2001 to 2013.

Expert opinion: Through the comprehensive evaluations of the biosafety and pharmaceutical efficiency, elaborately designed/fabricated mesoporous silica-based composite nanoparticles show great potentials in clinical applications for efficient diagnostic imaging and chemotherapy of cancer.     

The advancing uses of nano-graphene in drug delivery

Introduction: Graphene has been received with great interest in various fields including biomedical applications. Due to its ultrahigh surface area and easy surface functionalization, single-layered graphene has been intensively explored for drug and gene delivery. Utilizing their intrinsic high near-infrared absorbance, graphene and its derivatives have been found to be excellent candidates for multimodal imaging guided combined cancer photothermal and chemo- and/or photodynamic therapies.

Areas covered: This review summarizes recent studies on the biomedical applications of various graphene-based nanomaterials. The authors provide a comprehensive summary on using properly functionalized nano-graphene and its derivatives for drug and gene delivery, as well as combination therapy of cancer.

Expert opinion: Regarding biomedical applications, the authors find that proper surface functionalization and controlled sizes of graphene-based nanomaterials are two crucial factors for efficient drug and gene delivery. Although a lot of work has demonstrated the successful delivery of anticancer drugs and genes using graphene-based nanomaterials as carriers, the correlations of their surface functionalization and size distribution and their therapeutic outcomes need more exploration. On the other hand, the long-term toxicological and metabolic behaviors of nano-graphene still merit significantly more effort before clinical use.     

Advances in the methods for discovering novel painful bladder syndrome therapies

Introduction: Advances in the treatment of interstitial cystitis or bladder pain syndrome (IC/BPS) depend on a good understanding of its pathogenesis. Presently, oral medicine and intravesical drug instillations may be the most popular therapies in daily practice. To improve the efficacy of intravesical drug delivery, the system requires modulation through coupling them to novel carriers. Numerous investigators have attempted alternative reconstructive procedures for bladder replacement/repair using scaffolds. These scaffolds include acellular extracellular matrix grafts or tissue-derived cell-seeded extracellular matrix grafts as well as the transplantation of mesenchymal progenitor cells into the damaged bladder.

Areas covered: This review focuses on the current available IC/BPS treatments and the different strategies employing nanotechnology or tissue engineering in the discovery of novel IC/BPS therapies.

Expert opinion: Current studies in the discovery of novel IC/BPS therapies are still imperfect, with novel approaches that use biocompatible nanomaterials or tissue engineering still ongoing. These nanoformulations give the benefit of protecting easily degradable molecules and enhance targeted delivery. Tissue engineering holds the promise of regenerating damaged tissues and organs by replacing damaged tissue and/or by stimulating the body's own repair mechanisms to heal previously irreparable tissues and organs. For these reasons, nanotechnology and tissue engineering could play key roles in the discovery of novel painful bladder syndrome therapies.     

Advances in use of functionalized carbon nanotubes for drug design and discovery

Introduction: As a part of increasing interest in nanobiotechnology, nanoparticle-based drug discovery as well as development and drug delivery constitute an important area in nanomedicine, and it is also driven by search for new drugs by the pharmaceutical industry. Nanomaterials for pharmaceutical application include carbon nanotubes (CNTs).

Areas covered: This article describes the properties of CNTs, both single-walled CNTs (SWCNTs) and multiwalled CNTs (MWCNTs) with relevance to drug discovery and development. Pharmacokinetics of CNTs as well as CNT-based drug delivery is discussed. The article also looks at how the scope for pharmaceutical applications of CNTs is broadened by conjugation with other molecules and presents the potential therapeutic applications. Finally, the toxicology of CNTs is considered with measures under investigation for reducing it. Literature on CNTs, from the past 5 years, was reviewed and selected publications relevant to drug discovery, development, and delivery were included in the bibliography.

Expert opinion: Carbon nanotubes combine more properties relevant to drug development and delivery than any other nanomaterial. Although a tremendous amount of basic research has been done on CNTs during the past decade, little of this is nearing translation into human applications. No CNT-based medicine has reached clinical trials. Nevertheless, CNT conjugation with other molecules has extended the horizons for their potential therapeutic applications. The most promising of these is PEGylation, which extends the survival of CNTs in circulation. Potential future applications of CNTs include combination of diagnostics and therapeutic drug delivery as well as a component of multimodal therapies for tissue regeneration.     

Cellulose nanocrystals: a versatile nanoplatform for emerging biomedical applications

ABSTRACT

Introduction: Cellulose nanocrystals (CNCs) are bio-based nanomaterials typically derived from the acid hydrolysis of the most abundant natural polymer, cellulose. These nanomaterials have garnered significant interest due to their unique properties, such as uniform rod-like shape, high surface area, high strength, liquid crystalline behavior, tailored surface chemistry, biocompatibility, biodegradability, sustainability and non-toxic carbohydrate-based nature.

Areas covered: The recent developments in the use of unmodified and modified CNCs as versatile nanoplatforms for emerging biomedical applications such as drug delivery systems, enzyme/protein immobilization scaffolds, bioimaging, biosensing and tissue engineering are highlighted. A brief discussion of the biological and toxicity properties of CNCs is also presented.

Expert opinion: While a number of recent studies have indicated that CNCs are promising nanomaterials for biomedical applications, there is a substantial amount of work that still remains to be done before realizing the full therapeutic potential of CNCs. Major effort should be focused on detailed in vitro and in vivo studies of modified CNCs constructs in order to better understand the integration of CNCs in the biological systems.     

An exploration of aptamer internalization mechanisms and their applications in drug delivery

Introduction: As ‘chemical antibodies’, aptamers have some advantages, such as lack of immunogenicity, rapid tissue penetration, cell internalization and so on. Consequently, more and more aptamers have been screened out by the systematic evolution of ligands through exponential enrichment for the desired cells or membrane receptors. On the basis of the result, researchers use aptamers to guide drug targeting to the desired cells and internalization in vivo.

Areas covered: In this review, we explore the mechanisms of cargo- or aptamer-mediated internalization, and then briefly summarize five strategies for exploring the mechanism of aptamer internalization. Finally, we focus on four types of applications involving aptamer internalization: aptamers as drugs, aptamers as chemical drug-delivery systems, aptamer-based chimeras and aptamer-conjugated nanoparticles or block copolymer micelles.

Expert opinion: Two aptamer-internalization mechanisms are known, namely receptor-mediated endocytosis and macropinocytosis. The latter mechanism, which is has only been verified in the internalization of nucleolin aptamer shuttles between the nucleus and cytoplasm, may be important for nuclear internalization and cargo molecule escape from the endosomal compartment. Thus, it is feasible to use some strategies to further explore the macropinocytosis internalization mechanism and then to screen for aptamers similar to the nucleolin aptamer for use with the desired cell types as a targeted delivery tool.     

Silk-elastin-like protein biomaterials for the controlled delivery of therapeutics

Introduction: Genetically engineered biomaterials are useful for controlled delivery owing to their rational design, tunable structure–function, biocompatibility, degradability and target specificity. Silk-elastin-like proteins (SELPs), a family of genetically engineered recombinant protein polymers, possess these properties. Additionally, given the benefits of combining semi-crystalline silk-blocks and elastomeric elastin-blocks, SELPs possess multi-stimuli-responsive properties and tunability, thereby becoming promising candidates for targeted cancer therapeutics delivery and controlled gene release.

Areas covered: An overview of SELP biomaterials for drug delivery and gene release is provided. Biosynthetic strategies used for SELP production, fundamental physicochemical properties and self-assembly mechanisms are discussed. The review focuses on sequence–structure–function relationships, stimuli-responsive features and current and potential drug delivery applications.

Expert opinion: The tunable material properties allow SELPs to be pursued as promising biomaterials for nanocarriers and injectable drug release systems. Current applications of SELPs have focused on thermally-triggered biomaterial formats for the delivery of therapeutics, based on local hyperthermia in tumors or infections. Other prominent controlled release applications of SELPs as injectable hydrogels for gene release have also been pursued. Further biomedical applications that utilize other stimuli to trigger the reversible material responses of SELPs for targeted delivery, including pH, ionic strength, redox, enzymatic stimuli and electric field, are in progress. Exploiting these additional stimuli-responsive features will provide a broader range of functional biomaterials for controlled therapeutics release and tissue regeneration.     

The alluring potential of functionalized carbon nanotubes in drug discovery

Importance of the field: The possibility of carbon nanotube integration into living systems for therapeutic and diagnostic purposes has opened the way to explore their applications in drug delivery and discovery. A wide variety of chemical approaches has been developed to functionalize carbon nanotubes with therapeutic molecules towards different biomedical uses.

Areas covered in this review: This review covers the recent advances in the development of functionalized carbon nanotubes to offer improvements for different diseases, in particular for cancer therapy.

What the reader will gain: Functionalized carbon nanotubes are able to transport therapeutic agents. Targeted methodologies using carbon nanotube-based conjugates have been investigated to improve the efficacy of some drugs. The capacity of such nanomaterials to seamlessly translocate into cells with alternative various mechanisms and their pharmacokinetic properties is also discussed.

Take home message: Although at its infancy, functionalized carbon nanotubes are very promising as a new nanomedicine platform in the field of drug discovery and delivery. They have the capacity to cross biological barriers and can be eliminated via renal and/or fecal excretion. They can transport small drug molecules while maintaining – and in some cases improving – their therapeutic efficacy.     

Towards a targeted multi-drug delivery approach to improve therapeutic efficacy in breast cancer

Importance of the field: Significant improvements in breast cancer treatments have resulted in a significant decrease in mortality. However, current breast cancer therapies, for example, chemotherapy, often result in high toxicity and nonspecific side effects. Other treatments, such as hormonal and antiangiogenic therapies, often have low treatment efficacy if used alone. In addition, acquired drug resistance decreases further the treatment efficacy of these therapies. Intra-tumor heterogeneity of the tumor tissue may be a major reason for the low treatment efficacy and the development of chemoresistance. Therefore, targeted multi-drug therapy is a valuable option for addressing the multiple mechanisms that may be responsible for reduced efficacy of current therapies.

Areas covered in this review: In this article, different classes of drugs for treating breast cancer, the possible reasons for the drug resistance in breast cancer, as well as different targeted drug delivery systems are summarized. The current targeting strategies used in cancer treatment are discussed.

What the reader will gain: This article considers the current state of breast cancer therapy and the possible future directions in targeted multi-drug delivery for treating breast cancer.

Take home message: A better understanding of tumor biology and physiological responses to nanoparticles, as well as advanced nanoparticle design, are needed to improve the therapeutic outcomes for treating breast cancer using nanoparticle-based targeted drug delivery systems. Moreover, selective delivery of multi-drugs to tumor tissue using targeted drug delivery systems may reduce systemic toxicity further, overcome drug resistances, and improve therapeutic efficacy in treating breast cancer.     

Biodegradable polymers: an update on drug delivery in bone and cartilage diseases

ABSTRACT

Introduction: The unique structure of bone and cartilage makes the systemic delivery of free drugs to those connective tissues very challenging. Consequently, effective and targeted delivery for bone and cartilage is of utmost importance. Engineered biodegradable polymers enable designing carriers for a targeted and temporal controlled release of one or more drugs in concentrations within the therapeutic range. Also, tissue engineering strategies can allow drug delivery to advantageously promote the in situ tissue repair.

Areas covered: This review article highlights various drug delivery systems (DDS) based on biodegradable biomaterials to treat bone and/or cartilage diseases. We will review their applications in osteoporosis, inflammatory arthritis (namely osteoarthritis and rheumatoid arthritis), cancer and bone and cartilage tissue engineering.

Expert opinion: The increased knowledge about biomaterials science and of the pathophysiology of diseases, biomarkers, and targets as well as the development of innovative tools has led to the design of high value-added DDS. However, some challenges persist and are mainly related to an appropriate residence time and a controlled and sustained release over a prolonged period of time of the therapeutic agents. Additionally, the poor prediction value of some preclinical animal models hinders the translation of many formulations into the clinical practice.     

Extended release formulations using silk proteins for controlled delivery of therapeutics

ABSTRACT

Introduction: Silk is a promising biomaterial for controlled delivery of therapeutics and has a unique protein chemistry that can be tuned to form different carrier formats. The protein has been studied for sustained release depot systems for the targeted or localized delivery of drugs.

Areas covered: An overview of natural silk proteins for controlled delivery of therapeutics is provided, with a focus on the features of silk proteins that allow them to be useful tools for controlled delivery. Recent applications of natural silk proteins as controlled delivery systems are also summarized.

Expert opinion: The versatility of silk proteins makes them desirable biomaterials for a broad range of applications for controlled delivery of both small and large molecules. Further, the degradation profile leading to peptides and amino acids provides compatibility with pH-sensitive therapeutics. While silk sericin and spider silks are under study, silk fibroin extracted from silkworms (e.g. Bombyx mori) dominates pharmaceutical studies with silk. Silk fibroin can be formed into drug delivery tools for systemic or local injections, topical and transdermal applications, and implantation; depending on the target disease and therapeutic molecule. In vitro to in vivo correlations and scale-up needs are the next steps towards clinical applications.     

Composite alginate microspheres as the next-generation egg-box carriers for biomacromolecules delivery

Introduction: Alginate microspheres are versatile tools for the delivery of a wide range of therapeutic biomacromolecules. This naturally occurring biopolymer has many unique properties making it an ideal candidate for tailoring with different composites of polymers leading to the formation of strong complexes for a broad range of applications.

Areas covered: This article overviews various types of composite alginate microspheres, methods of preparation, new technologies available, physico-chemical characteristics, controlled release profiles, applications and the future directions of composite alginate microsphere delivery system for biomacromolecules.

Expert opinion: Composite alginate microsphere systems are the ideal carriers for controlled delivery applications because of their ability to encapsulate a myriad of therapeutic drugs, proteins, enzymes, DNA, antisense oligonucleotides, vaccines, growth factors and chemokines as well as the ease of processing, mechanical properties, biocompatibility, high bioavailability, controlled release rates, stability, suitability for different administration modes, targeted/localized delivery of different agents and large-scale production with cost-effectiveness. This article presents updated information of applying microalginate-based technologies and tools in the biomedical field which will benefit research scientists and clinical physicians or biopharmaceutical industries keen in the development of application-based new therapeutic and diagnostic strategies for various diseases. Furthermore, this technology will play more important roles in biosensors, vaccination, tissue engineering, cancer chemotherapeutics and stem cell research.     

Cell-mediated drug delivery

Introduction: Drug targeting to sites of tissue injury, tumor or infection with limited toxicity is the goal for successful pharmaceutics. Immunocytes (including mononuclear phagocytes (dendritic cells, monocytes and macrophages), neutrophils and lymphocytes) are highly mobile; they can migrate across impermeable barriers and release their drug cargo at sites of infection or tissue injury. Thus, immune cells can be exploited as Trojan horses for drug delivery.

Areas covered: This paper reviews how immunocytes laden with drugs can cross the blood–brain or blood–tumor barriers to facilitate treatments for infectious diseases, injury, cancer, or inflammatory diseases. The promises and perils of cell-mediated drug delivery are reviewed, with examples of how immunocytes can be harnessed to improve therapeutic end points.

Expert opinion: Using cells as delivery vehicles enables targeted drug transport and prolonged circulation times, along with reductions in cell and tissue toxicities. Such systems for drug carriage and targeted release represent a new disease-combating strategy being applied to a spectrum of human disorders. The design of nanocarriers for cell-mediated drug delivery may differ from those used for conventional drug delivery systems; nevertheless, engaging different defense mechanisms in drug delivery may open new perspectives for the active delivery of drugs.     

Delivering bioactive molecules as instructive cues to engineered tissues

Introduction : Growth factors and other bioactive molecules play a crucial role in the creation of functional engineered tissues from dissociated cells.

Areas covered : This review discusses the delivery of bioactive molecules – particularly growth factors – to affect cellular function in the context of tissue engineering. We discuss the primary biological themes that are addressed by delivering bioactives, the types of molecules that are to be delivered, the major materials used in producing scaffolds and/or drug delivery systems, and the principal drug delivery strategies.

Expert opinion : Drug delivery systems have allowed the sustained release of bioactive molecules to engineered tissues, with marked effects on tissue function. Sophisticated drug delivery techniques will allow precise recapitulation of developmental milestones by providing temporally distinct patterns of release of multiple bioactives. High-resolution patterning techniques will allow tissue constructs to be designed with precisely defined areas where bioactives can act. New biological discoveries, just as the development of small molecules with potent effects on cell differentiation, will likely have a marked impact on the field.     

Gold nanoparticles: opportunities and challenges in nanomedicine

Importance of the field: Site-specific drug delivery is an important area of research that is anticipated to increase the efficacy of the drug and reduce potential side effects. Owing to this, substantial work has been done developing non-invasive and targeted tumor treatment with nanoscale metallic particles.

Areas covered in this review: This review focuses on the work done in the last few years developing gold nanoparticles as cancer therapeutics and diagnostic agents. However, there are challenges in using gold nanoparticles as drug delivery systems, such as biodistribution, pharmacokinetics and possible toxicity. Approaches to limit these issues are proposed.

What the reader will gain: Different approaches from several different disciplines are discussed. Potential clinical applications of these engineered nanoparticles are also presented.

Take home message: As a result of their unique size-dependent physicochemical and optical properties, adaptability, subcellular size and biocompatibility, these nanosized carriers offer a suitable means of transporting small molecules as well as biomacromolecules to diseased cells/tissues.