Non-viral nucleic acid containing nanoparticles as cancer therapeutics

ABSTRACT

Introduction: The delivery of nucleic acids such as DNA and short interfering RNA (siRNA) is promising for the treatment of many diseases, including cancer, by enabling novel biological mechanisms of action. Non-viral nanoparticles are a promising class of nucleic acid carriers that can be designed to be safer and more versatile than traditional viral vectors.

Areas covered: In this review, recent advances in the intracellular delivery of DNA and siRNA are described with a focus on non-viral nanoparticle-based delivery methods. Material properties that have enabled successful delivery are discussed as well as applications that have directly been applied to cancer therapy. Strategies to co-deliver different nucleic acids are highlighted, as are novel targets for nucleic acid co-delivery.

Expert opinion: The treatment of complex genetically-based diseases such as cancer can be enabled by safe and effective intracellular delivery of multiple nucleic acids. Non-viral nanoparticles can be fabricated to deliver multiple nucleic acids to the same cell simultaneously to prevent tumor cells from easily compensating for the knockdown or overexpression of one genetic target. The continued innovation of new therapeutic modalities and non-viral nanotechnologies to provide target-specific and personalized forms of gene therapy hold promise for genetic medicine to treat diseases like cancer in the clinic.     

Nanotechnology in ocular delivery: current and future directions

Our knowledge in the field of ocular drug delivery is rapidly expanding. An increase in the understanding of ocular drug absorption and disposition vis-à-vis developments in nanotechnology has led to the emergence of many of the nanotechnology-based ocular drug delivery systems including nanoparticles, microemulsions, liposomes, solid lipid nanoparticles, light-sensitive nanocarrier systems, etc. The need to develop effective treatments for posterior eye segment diseases is more important than surface delivery. Treatment of blinding diseases of the eye, such as proliferative retinopathy or macular degeneration, requires effective and safe delivery of drugs to posterior eye segment tissues, and recent advances in nanotechnology have demonstrated successful outcomes. Nanoscientists should focus their efforts on nano-ophthalmology. This review describes the current status and progress made so far, and the course that needs to be pursued in the future.     

Peptides in DNA delivery: current insights and future directions

Peptides are emerging as attractive alternatives to cationic polymers and lipids for nonviral DNA delivery. Their remarkable properties such as efficient condensation of DNA, translocation across the cellular membrane, pH-sensitive membrane disruption, and efficient targeting of attached cargoes to the nucleus make them lucrative for researchers to explore their application in DNA delivery. In this review article, we focus on how the chemical nature, structural features and DNA complexation strategies of different peptides have been utilized for efficient DNA delivery. We also discuss their potential problems hindering in vivo application.     

Insights, challenges, and future directions in irinogenetics

Irinotecan is widely used in the treatment of metastatic colorectal cancer and extensive small-cell lung cancer. Its use is limited by severe toxicities such as neutropenia and delayed-type diarrhea. Irinotecan is converted to its active metabolite SN-38. SN-38 is further metabolized to SN-38G by various hepatic and extrahepatic UGT1A isozymes, mainly UGT1A1. Impaired glucuronidation activity of the UGT1A1 enzyme has been linked with elevated levels of SN-38, leading to toxicities. UGT1A1*28 involves an extra TA repeat in the UGT1A1 promoter region and is the variant most frequently contributing to interpatient variability in irinotecan pharmacokinetics and toxicities. This information led to the revision of the irinotecan label by the US Food and Drug Administration. Recently, UGT1A1*6 seems to contribute to the risk of toxicity of irinotecan in Asian patients. The pharmacogenetics of irinotecan (irinogenetics) is one of few promising examples of the application of pharmacogenetics to individualized drug therapy. This review summarizes ongoing studies and unanswered questions on irinogenetics.     

Molecular targeted therapy in recurrent glioblastoma: current challenges and future directions

Introduction: The survival of patients with glioblastoma (GBM), which is the most common primary brain malignancy, remains poor with current treatment modalities. However, an enhanced understanding of gliomagenesis is supporting the development of targeted molecular therapies with the potential for improving clinical outcomes.

Areas covered: Epidermal growth factor receptor (EGFR) and vascular endothelial growth factor receptor (VEGFR) initiate key signaling pathways in GBM; however, trials with anti-EGFR agents have failed to show improved outcomes. Bevacizumab, a monoclonal antibody targeting VEGF, remains the only FDA-approved molecular drug in GBM; yet its use has only improved progression-free survival without any improvement in overall survival. We review the evidence supporting the continued evaluation of targeted molecular therapies in recurrent GBM. In addition, newer potential therapies targeting other signaling pathways, heat shock proteins and proteosomes, as well as the concept of targeting glioma stem cells are discussed.

Expert opinion: The complex genetic origin of GBM makes it challenging to identify molecular subsets that may benefit from specific targeted therapies. Pathway inhibition, via multisite kinase inhibitors or a carefully selected combination of molecular drugs with or without cytotoxic agents, is currently undergoing evaluation in clinical trials and may improve outcomes in these patients.     

Molecular targeted therapy in recurrent glioblastoma: current challenges and future directions

Introduction: The survival of patients with glioblastoma (GBM), which is the most common primary brain malignancy, remains poor with current treatment modalities. However, an enhanced understanding of gliomagenesis is supporting the development of targeted molecular therapies with the potential for improving clinical outcomes. Areas covered: Epidermal growth factor receptor (EGFR) and vascular endothelial growth factor receptor (VEGFR) initiate key signaling pathways in GBM; however, trials with anti-EGFR agents have failed to show improved outcomes. Bevacizumab, a monoclonal antibody targeting VEGF, remains the only FDA-approved molecular drug in GBM; yet its use has only improved progression-free survival without any improvement in overall survival. We review the evidence supporting the continued evaluation of targeted molecular therapies in recurrent GBM. In addition, newer potential therapies targeting other signaling pathways, heat shock proteins and proteosomes, as well as the concept of targeting glioma stem cells are discussed. Expert opinion: The complex genetic origin of GBM makes it challenging to identify molecular subsets that may benefit from specific targeted therapies. Pathway inhibition, via multisite kinase inhibitors or a carefully selected combination of molecular drugs with or without cytotoxic agents, is currently undergoing evaluation in clinical trials and may improve outcomes in these patients.     

Lipid and polymeric carrier-mediated nucleic acid delivery

Importance of the field: Nucleic acids such as plasmid DNA, antisense oligonucleotide, and RNA interference (RNAi) molecules, have a great potential to be used as therapeutics for the treatment of various genetic and acquired diseases. To design a successful nucleic acid delivery system, the pharmacological effect of nucleic acids, the physiological condition of the subjects or sites, and the physicochemical properties of nucleic acid and carriers have to be thoroughly examined.

Areas covered in this review: The commonly used lipids, polymers and corresponding delivery systems are reviewed in terms of their characteristics, applications, advantages and limitations.

What the reader will gain: This article aims to provide an overview of biological barriers and strategies to overcome these barriers by properly designing effective synthetic carriers for nucleic acid delivery.

Take home message: A thorough understanding of biological barriers and the structure–activity relationship of lipid and polymeric carriers is the key for effective nucleic acid therapy.     

Optimization of siRNA delivery to target sites: issues and future directions

ABSTRACT

Introduction: The discovery of RNA interference (RNAi) earned the 2006 Nobel Prize in Physiology or Medicine for its biological significance and potential for developing novel therapeutics. The small interfering RNA (siRNA) is the most promising tool for translating RNAi to clinical use. Efforts are ongoing to improve siRNA delivery through developing novel biomaterials and delivery strategies. Given time, it appears that siRNA drugs will eventually become a reality.

Areas covered: The currently used approaches for siRNA delivery are discussed with a focus on siRNA therapeutics currently in clinical testing. A comparison of advantageous aspects of currently available platforms and the possibility of further optimization for increased efficiency and safety are presented. Future directions in siRNA delivery are also highlighted.

Expert opinion: The recent success in the field of siRNA delivery is based mainly on developing new biomaterials with extraordinarily high activities. Notably, the introduction of ionizable lipids and novel targeting ligands represent two huge steps for realizing siRNA therapy. The currently available systems are largely directed to the liver and the new challenge is to extend their applicability for treating diseases of other organs. Active targeting to different organs is the most promising approach for developing new siRNA-based therapeutics.     

Dry powder aerosol delivery systems: current and future research directions.

Development of dry powder aerosol delivery system involves powder production, formulation, dispersion, delivery, and deposition of the powder aerosol in the airways. Insufficiency of conventional powder production by crystallization and milling has led to development of alternative techniques. Over the last decade, performance of powder formulations has been improved significantly through the use of engineered drug particles and excipient systems which are (i) of low aerodynamic diameters (being porous or of low particle density), and/or (ii) less cohesive and adhesive (via corrugated surfaces, low bulk density, reduced surface energy and particle interaction, hydrophobic additives, and fine carrier particles). Early insights into particle forces and surface energy that help explain the improvement have been provided by analytical techniques such as the atomic force microscopy (AFM) and inverse gas chromatography (IGC). Relative humidity is critical to the performance of dry powder inhaler (DPI) products via capillary force and electrostatic interaction. Electrostatic charge of different particle size fractions of an aerosol can now be measured using a modified electrical low-pressure impactor (ELPI). Compared with powders, much less work has been done on the inhaler devices at the fundamental level. Most recently, computational fluid dynamics has been applied to understand how the inhaler design (such as mouthpiece, grid structure, air inlet) affects powder dispersion. The USP throat is known to under-represent the oropharyngeal deposition of DPI aerosols. Studies using magnetic resonance imaging (MRI) model casts have been undertaken to explain the inter- and intra- subject variation in oropharyngeal deposition. Most of the lung deposition studies performed on commercial products did not allow a thorough understanding of the determinants affecting in vivo lung deposition. A more systematic approach would be necessary to build a useful database on the dependence of lung deposition on the breathing parameters, inhaler design, and powder formulation properties.     

Challenges in SN38 drug delivery: current success and future directions

Introduction: Clinical use of SN38 is limited by its poor aqueous solubility and hydrolysis of the lactone ring at pH > 6 to inactive carboxylate form. A variety of drug delivery systems have been developed to improve the solubility and stability of SN38, and reduce its toxicity. A few noteworthy formulations with some success in initial phases of clinical trials are reported.

Areas covered: This work aims to provide a comprehensive review on the various techniques and strategies employed (physical, chemical and biological methods) to improve physicochemical properties and to deliver the drug efficiently to the cancer cells. Physical methods such as nanoparticle encapsulation, cyclodextrin complexation; chemical methods such as prodrugs, polymer-, albumin- and immunoconjugates; and enzyme activated prodrug therapy are discussed.

Expert opinion: The challenges in SN38 drug delivery may be overcome by two ways: ensuring multiple layers of protection against degradation and slow but sustained release of therapeutically effective drug concentrations. It may also be achieved by preparing a polymer–drug conjugate and further encapsulating the conjugate in suitable carrier system; tumor-targeted SN38 delivery by using immunoconjugates, enzyme-activated prodrug therapy and antibody-directed nanoparticle delivery. However, selection of a suitable ligand for tumor targeting and use of safe and biocompatible nanoparticle systems play an important role in realizing this goal.     

Directed evolution for drug and nucleic acid delivery

Directed evolution is a term used to describe a variety of related techniques to rapidly evolve peptides and proteins into new forms that exhibit improved properties for specific applications. In this process, molecular biology techniques allow the creation of up to billions of mutants in a single experiment, which are then subjected to high-throughput screening to identify those with enhanced activity. Applications of directed evolution to drug and gene delivery have been recently described, including those that improve the effectiveness of therapeutic enzymes, targeting peptides and antibodies, and the effectiveness or tropism of viral vectors for use in gene therapy. This review first introduces fundamental concepts of directed evolution, and then discusses emerging applications in the field of drug and gene delivery.     

Localized,non-viral delivery of nucleic acids: Opportunities,challenges and current strategies

Localized delivery of drugs is an emerging field both with regards to drug delivery during disease as well as in tissue engineering. Despite significant achievements made in the last decades, the efficient delivery of proteins and peptides remains challenging, especially in cases requiring long-term release of proteins after application. The localized delivery of nucleic acids (NA) represents an interesting alternative due to higher physicochemical stability of NA, increased efficiency by harnessing cells as bioreactors for the production of required proteins and improved versatility with regards to expression of specific proteins through plasmid DNA or repression of gene products through siRNA. However, unlike most proteins and peptides, NA must be delivered to the cytoplasm or nucleus to be efficacious, resulting in significant delivery challenges. We herein describe frequently used non-viral vectors for the delivery of NA including polyplexes, lipoplexes and lipopolyplexes and summarize recent developments in the field of nucleic acid delivery systems for local application based on hydrogels, solid scaffolds and physical delivery methods. The challenges associated with the different approaches are identified and options to address these challenges are discussed.     

Nonviral approach for targeted nucleic acid delivery

Despite their relatively lower efficiency, nonviral approaches are emerging as safer alternatives in gene therapy to viral vectors. Delivery of nucleic acids to the target site is an important factor for effective gene expression (plasmid DNA) or knockdown (siRNA) with minimal side effects. Direct deposition at the target site by physical methods, including ultrasound, electroporation and gene gun, is one approach for local delivery. For less accessible sites, the development of carriers that can home into the target tissue is required. Cationic peptides, lipoplexes, polyplexes and nanoplexes have been used as carriers for delivery of nucleic acids. Targeting ligands, such as cell targeting peptides, have also been applied to decorate delivery vehicles in order to enhance their efficacy. This review focuses on delivery strategies and recent progress in non-viral carriers and their modifications to improve their performance in targeting and transfection.     

Reducible HPMA-co-oligolysine copolymers for nucleic acid delivery

Biodegradability can be incorporated into cationic polymers via use of disulfide linkages that are degraded in the reducing environment of the cell cytosol. In this work, N-(2-hydroxypropyl)methacrylamide (HPMA) and methacrylamido-functionalized oligo-l-lysine peptide monomers with either a non-reducible 6-aminohexanoic acid (AHX) linker or a reducible 3-[(2-aminoethyl)dithiol] propionic acid (AEDP) linker were copolymerized via reversible addition-fragmentation chain transfer (RAFT) polymerization. Both of the copolymers and a 1:1 (w/w) mixture of copolymers with reducible and non-reducible peptides were complexed with DNA to form polyplexes. The polyplexes were tested for salt stability, transfection efficiency, and cytotoxicity. The HPMA-oligolysine copolymer containing the reducible AEDP linkers was less efficient at transfection than the non-reducible polymer and was prone to flocculation in saline and serum-containing conditions, but was also not cytotoxic at charge ratios tested. Optimal transfection efficiency and toxicity were attained with mixed formulation of copolymers. Flow cytometry uptake studies indicated that blocking extracellular thiols did not restore transfection efficiency and that the decreased transfection of the reducible polyplex is therefore not primarily caused by extracellular polymer reduction by free thiols. The decrease in transfection efficiency of the reducible polymers could be partially mitigated by the addition of low concentrations of EDTA to prevent metal-catalyzed oxidation of reduced polymers.     

靶向哺乳动物细胞线粒体的核酸转运

线粒体DNA(mitochondrial DNA,mtDNA)的遗传性突变和缺陷是多种线粒体功能失调相关疾病的根本原因。靶向线粒体递送核酸,可从根本上纠正mtDNA突变、挽救mtDNA损伤、阻断疾病进程。哺乳细胞内线粒体的核酸转运途径与细胞核的基因转染大不相同。该文综述了向哺乳动物细胞线粒体递送DNA和RNA(tRNA、rRNA、mRNA和反义RNA)的有效策略,并对其存在问题和发展趋势做一阐述。     

脂质体在介导核酸传递时存在的问题及解决方法

脂质体在介导核酸传递方面已成为当今研究热点,而在传递过程中所遇到的一些问题严重限制了核酸发挥治疗作用。本文综述了脂质体在介导核酸传递时所遇到的问题,如血液稳定性差、网状内皮系统吸附、脂质体的低靶向性、内涵体逃逸的阻碍等,并针对近几年对这些问题所采取的解决方案如PEG化、配体修饰、光化学内化作用(PCI)、降解脂质体和膜融合肽的应用等进行了详细的阐述。