Mousa Jafari

Biocompatibility of engineered nanoparticles for drug delivery

The rapid advancement of nanotechnology has raised the possibility of using engineered nanoparticles that interact within biological environments for treatment of diseases. Nanoparticles interacting with cells and the extracellular environment can trigger a sequence of biological effects. These effects largely depend on the dynamic physicochemical characteristics of nanoparticles, which determine the biocompatibility and efficacy of the intended outcomes. Understanding the mechanisms behind these different outcomes will allow prediction of the relationship between nanostructures and their interactions with the biological milieu. At present, almost no standard biocompatibility evaluation criteria have been established, in particular for nanoparticles used in drug delivery systems. Therefore, an appropriate safety guideline of nanoparticles on human health with assessable endpoints is needed. In this review, we discuss the data existing in the literature regarding biocompatibility of nanoparticles for drug delivery applications. We also review the various types of nanoparticles used in drug delivery systems while addressing new challenges and research directions. Presenting the aforementioned information will aid in getting one step closer to formulating compatibility criteria for biological systems under exposure to different nanoparticles.

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.

Biocompatibility of hydrogel-based scaffolds for tissue engineering applications

Recently, understanding of the extracellular matrix (ECM) has expanded rapidly due to the accessibility of cellular and molecular techniques and the growing potential and value for hydrogels in tissue engineering. The fabrication of hydrogel-based cellular scaffolds for the generation of bioengineered tissues has been based on knowledge of the composition and structure of ECM. Attempts at recreating ECM have used either naturally-derived ECM components or synthetic polymers with structural integrity derived from hydrogels. Due to their increasing use, their biocompatibility has been questioned since the use of these biomaterials needs to be effective and safe. It is not surprising then that the evaluation of biocompatibility of these types of biomaterials for regenerative and tissue engineering applications has been expanded from being primarily investigated in a laboratory setting to being applied in the multi-billion dollar medicinal industry. This review will aid in the improvement of design of non-invasive, smart hydrogels that can be utilized for tissue engineering and other biomedical applications. In this review, the biocompatibility of hydrogels and design criteria for fabricating effective scaffolds are examined. Examples of natural and synthetic hydrogels, their biocompatibility and use in tissue engineering are discussed. The merits and clinical complications of hydrogel scaffold use are also reviewed. The article concludes with a future outlook of the field of biocompatibility within the context of hydrogel-based scaffolds.

Oral, ultra–long-lasting drug delivery: Application toward malaria elimination goals

A newly developed platform capable of oral, ultra–long-acting drug delivery could be applied against the malaria vector in elimination programs. Toward malaria eradication Although we know how to prevent malaria, we have failed to eliminate this damaging disease. To help the millions of individuals still affected around the world, Bellinger et al. have designed an easy-to-administer device that provides long-lasting delivery of an antimalarial drug. A star-shaped, drug-containing material is packaged into a capsule. When swallowed, the capsule dissolves in the stomach, and the star unfolds, assuming a shape that cannot pass further down the intestine. The star delivers a drug toxic to malaria-carrying mosquitoes for weeks but eventually falls apart and passes harmlessly out of the body. Modeling studies show that long-term delivery of this drug may move us closer to the elimination of this problematic disease by improving patient adherence to treatment. Efforts at elimination of scourges, such as malaria, are limited by the logistic challenges of reaching large rural populations and ensuring patient adherence to adequate pharmacologic treatment. We have developed an oral, ultra–long-acting capsule that dissolves in the stomach and deploys a star-shaped dosage form that releases drug while assuming a geometry that prevents passage through the pylorus yet allows passage of food, enabling prolonged gastric residence. This gastric-resident, drug delivery dosage form releases small-molecule drugs for days to weeks and potentially longer. Upon dissolution of the macrostructure, the components can safely pass through the gastrointestinal tract. Clinical, radiographic, and endoscopic evaluation of a swine large-animal model that received these dosage forms showed no evidence of gastrointestinal obstruction or mucosal injury. We generated long-acting formulations for controlled release of ivermectin, a drug that targets malaria-transmitting mosquitoes, in the gastric environment and incorporated these into our dosage form, which then delivered a sustained therapeutic dose of ivermectin for up to 14 days in our swine model. Further, by using mathematical models of malaria transmission that incorporate the lethal effect of ivermectin against malaria-transmitting mosquitoes, we demonstrated that this system will boost the efficacy of mass drug administration toward malaria elimination goals. Encapsulated, gastric-resident dosage forms for ultra–long-acting drug delivery have the potential to revolutionize treatment options for malaria and other diseases that affect large populations around the globe for which treatment adherence is essential for efficacy.

Physicochemical characterization of siRNA-peptide complexes

Short interfering RNAs (siRNAs) trigger RNA interference (RNAi), where the complementary mRNA is degraded, resulting in silencing of the encoded protein. A delivery carrier is desired to increase the solution stability of siRNA and improve its cellular uptake to overcome its rapid enzymatic degradation and low transfection efficiency. In this study, Arginine‐9 (R9), a cell‐penetrating peptide derived from the HIV 1 Tat protein, was investigated as a potential carrier for siRNAs. A connective tissue growth factor (CTGF) encoding siRNA was used because of its therapeutic potential of treating breast cancer. The interaction between R9 and siRNA was studied by UV/vis spectroscopy and circular dichroism (CD). The hydrodynamic diameter of the siRNA‐R9 complexes was determined by dynamic light scattering (DLS), and the Zeta potential of the complexes was obtained by measuring the electrophoretic mobility. The effect of salt addition is also quantified using UV–vis spectroscopy. The siRNA and R9 readily formed complexes/aggregates through molecular association, accompanying a change in surface charge with increasing peptide concentration, reaching a maximum hydrodynamic diameter of ∼1 μm at siRNA saturation. The highest binding ratio of R9 to siRNA determined from the UV/vis spectra and CD is 10.3:1 and 39.1:1 from DLS (corresponds to charge ratios of 2.2:1 (+/−) and 8.4:1, respectively). The difference in binding ratio is possibly because of the difference in signal contribution between absorption and light scattering. The physicochemical characterization of CTGF siRNA‐R9 complexes presented here have shown that various methods can be used to control the properties of the siRNA‐peptide complexes, which provide a basis for the formulation of siRNA therapeutics with peptide carriers.

Peptide Mediated siRNA Delivery

Applying RNA interference to silence a specific gene has opened a new and promising avenue of gene therapy. But a key bottleneck is the poor stability and inability of naked siRNA to translocate through cell membranes. Among several delivery systems, cationic peptides capable of penetrating cell membranes have drawn attention due to their structural and functional versatility, potential biocompatibility and ability to target cells. In this review, different classes of peptides employed in siRNA delivery are reviewed. In particular, a new class of siRNA delivery peptides with high transfection efficiency and low cytotoxicity is introduced.

Self-Assembling Peptides: Potential Role in Tumor Targeting

This review focuses on the application of two classes of peptides, i.e., self-assembling peptides (SAPs) and cell-targeting peptides (CTPs), in the development of nanocarrier delivery systems. Self-assembling peptides are emerging in a wide range of biomedical and bioengineering applications and fall into several classes, including peptide amphiphilies, bolaamphiphile peptides, cyclic peptides, and ionic complementary peptides, which can be found naturally or synthesized. The advantage of synthesizing peptides is that their self-assembling properties can be exploited to form desirable structures for various applications. Another, unique property of self-assembling peptides, is stimuli-responsibility in different environments including various pHs, temperatures, ionic strengths, etc. These characteristics make peptides applicable in a wide range of biomaterials in drug discovery. This study reviews the design principles of well-known self-assembling peptides, as well as their physical/chemical properties. In addition, it discusses the therapeutic cancer-targeting peptides and current combinatorial peptide library methods used to identify targeting peptides. Cancer-targeting peptides can target either tumor cell surfaces or tumor vasculature. The RGD peptide is one of the first tumor-targeting peptides that can bind to self-assembling peptides or any other nanocarrier to improve the therapeutic efficiency of targeting drug delivery systems.

A New Amphipathic, Amino-Acid-Pairing (AAP) Peptide as siRNA Delivery Carrier: Physicochemical Characterization and in Vitro Uptake

RNA interference has emerged as a powerful tool in biological and pharmaceutical research; however, the enzymatic degradation and polyanionic nature of short interfering RNAs (siRNAs) lead to their poor cellular uptake and eventual biological effects. Among nonviral delivery systems, cell-penetrating peptides have been recently employed to improve the siRNA delivery efficiency. Here we introduce an 18-mer amphipathic, amino-acid-pairing peptide, C6, as an siRNA delivery carrier. Peptide C6 adopted a helical structure upon coassembling with siRNA. The C6-siRNA coassembly showed a size distribution between 50 and 250 nm, confirmed by dynamic light scattering and atomic force microscopy. The C6-siRNA interaction enthalpy and stoichiometry were 8.8 kJ·mol(-1) and 6.5, respectively, obtained by isothermal titration calorimetry. A minimum C6/siRNA molar ratio of 10:1 was required to form stable coassemblies/complexes, indicated by agarose gel shift assay and fluorescence spectroscopy. Peptide C6 showed lower toxicity and higher efficiency in cellular uptake of siRNA compared with Lipofectamine 2000. Fluorescence microscopy images also confirmed the localization of C6-siRNA complexes in the cytoplasm using Cy3-labeled siRNAs. These results indicate high capabilities of C6 in forming safe and stable complexes with siRNA and enhancing its cellular uptake.

Serum stability and physicochemical characterization of a novel amphipathic peptide C6M1 for siRNA delivery.

The efficient delivery of nucleic acids as therapeutic agents is a major challenge in gene therapy. Peptides have recently emerged as a novel carrier for delivery of drugs and genes. C6M1 is a designed amphipathic peptide with the ability to form stable complexes with short interfering RNA (siRNA). The peptide showed a combination of random coil and helical structure in water but mainly adopted a helical conformation in the presence of anions or siRNA. Revealed by dynamic light scattering (DLS) and microscopy techniques, the interaction of C6M1 and siRNA in water and HEPES led to complexes of ∼70 and ∼155 nm in size, respectively, but showed aggregates as large as ∼500 nm in PBS. The time-dependent aggregation of the complex in PBS was studied by DLS and fluorescence spectroscopy. At molar ratio of 15∶1, C6M1 was able to completely encapsulate siRNA; however, higher molar ratios were required to obtain stable complexes. Naked siRNA was completely degraded in 4 h in the solution of 50% serum; however C6M1 protected siRNA against serum RNase over the period of 24 h. Western blotting experiment showed ∼72% decrease in GAPDH protein level of the cells treated with C6M1-siRNA complexes while no significant knockdown was observed for the cells treated with naked siRNA.

Modification of a designed amphipathic cell-penetrating peptide and its effect on solubility, secondary structure, and uptake efficiency.

The development of safe and efficient nonviral gene delivery carriers has received a great deal of attention in the past decade. A class of amphipathic peptides has shown to be able to cross cell membranes and deliver cargo to the intracellular environment. Here, we introduce an 18-mer amphipathic peptide, C6M1, as a modified version of peptide C6 for short interfering RNA (siRNA) delivery. The importance of tryptophan residues and the effect of peptide sequence modification on its solubility, secondary structure, cytotoxicity, and uptake efficiency were investigated. The solubility of C6M1 in aqueous solutions was greatly enhanced compared to that of C6, confirmed by surface tension and anilinonaphthalene-8-sulfonic acid fluorescence measurements. C6M1 had a random/helical structure in water with the ability to attain a helical conformation in the presence of anionic components or membrane-mimicking environments. The modification significantly reduced the cytotoxicity of the peptide, making it a safer carrier for siRNA delivery. C6M1 was also found ∼90% more efficient than C6 in delivering Cy3-labeled siRNA in Chinese hamster ovary cells.