Lipid-based systems for the intracellular delivery of genetic drugs

Currently available delivery systems for genetic drugs have limited utility for systemic applications. Cationic liposome/ plasmid DNA or oligonucleotide complexes are rapidly cleared from circulation, and the highest levels of activity are observed in `first pass' organs, such as the lungs, spleen and liver. Engineered viruses can generate an immune response, which compromises transfection resulting from subsequent injections and lack target specificity. A carrier, which can accumulate at sites of diseases such as infections, inflammations and tumours, has to be a small, neutral and highly serum-stable particle, which is not readily recognized by the fixed and free macrophages of the reticuloendothelial system (RES). This review summarizes lipid-based technologies for the delivery of nucleic acid-based drugs and introduces a new class of carrier systems, which solve, at least in part, the conflicting demands of circulation longevity and intracellular delivery. Plasmid DNA and oligonucleotides are entrapped into lipid particles that contain small amounts of a positively charged lipid and are stabilized by the presence of a polyethylene glycol (PEG) coating. These carriers protect nucleic acid-based drugs from degradation by nucleases, are on average 70 nm in diameter, achieve long circulation lifetimes and are capable of transfecting cells.     

Chitosan nanoparticles for oral drug and gene delivery

Chitosan is a widely available, mucoadhesive polymer that is able to increase cellular permeability and improve the bioavailability of orally administered protein drugs. It can also be readily formed into nanoparticles able to entrap drugs or condense plasmid DNA. Studies on the formulation and oral delivery of such chitosan nanoparticles have demonstrated their efficacy in enhancing drug uptake and promoting gene expression. This review summarizes some of these findings and highlights the potential of chitosan as a component of oral delivery systems.     

Lipid-based systems for the intracellular delivery of genetic drugs.

Currently available delivery systems for genetic drugs have limited utility for systemic applications. Cationic liposome/plasmid DNA or oligonucleotide complexes are rapidly cleared from circulation, and the highest levels of activity are observed in 'first pass' organs, such as the lungs, spleen and liver. Engineered viruses can generate an immune response, which compromises transfection resulting from subsequent injections and lack target specificity. A carrier, which can accumulate at sites of diseases such as infections, inflammations and tumours, has to be a small, neutral and highly serum-stable particle, which is not readily recognized by the fixed and free macrophages of the reticuloendothelial system (RES). This review summarizes lipid-based technologies for the delivery of nucleic acid-based drugs and introduces a new class of carrier systems, which solve, at least in part, the conflicting demands of circulation longevity and intracellular delivery. Plasmid DNA and oligonucleotides are entrapped into lipid particles that contain small amounts of a positively charged lipid and are stabilized by the presence of a polythylene glycol (PEG) coating. These carriers protect nucleic acid-based drugs from degradation by nucleases, are on average 70 nm in diameter, achieve long circulation lifetimes and are capable of transfecting cells.     

Milk caseins as useful vehicle for delivery of dipyridamole drug

The interaction of bovine milk α- and β-caseins as an efficient drug carrier system with Dipyridamole (DIP) was investigated using spectroscopy and molecular docking studies at different temperatures (20–37 °C). FTIR, CD, and fluorescence spectroscopy methods demonstrated that α- and β-caseins interact with DIP molecule mainly via hydrophobic and hydrophilic interactions and change in secondary structure of α- and β-caseins. DIP showed a higher quenching efficiency and binding constant of α-casein than β-casein. There was only one binding site for DIP and it was located on the surface of the protein molecule. The thermodynamic parameters of calculation showed that the binding process occurs spontaneously and demonstrated that α- and β-caseins provide very good binding and entrapment to DIP via hydrogen bonds, Van der Waals forces, and hydrophobic interactions. Fluorescence resonance energy transfer, synchronous fluorescence spectroscopy, and docking study showed that DIP binds to the Trp residues of α- and β-casein molecules with short distances. Docking study showed that DIP molecule made several hydrogen bonds and van der Waals interactions with α- and β-caseins. The study of cell culture and micellar solubility of DIP demonstrated α- and β-caseins relatively the same helping in delivery of DIP. Milk α- and β-caseins are considered as a useful vehicle for the solublization and stabilization of DIP in aqueous solution at natural pH.     

Pyrrhocoricin as a potential drug delivery vehicle for Cryptosporidium parvum

This study analysed the intracellular delivery capacity of insect derived pyrrhocoricin with a peptide cargo in Cryptosporidium parvum in vitro using fluorescence microscopy. Results revealed that pyrrhocoricin was capable of acting as a delivery vehicle in transducing peptides across the parasite cell membrane for multiple life-cycle stages. The successful transduction may aid in target validation and the delivery of future peptide-based drugs against this important human pathogen.     

pH-sensitive polymer nanospheres for use as a potential drug delivery vehicle

We report the development and characterization of pH-sensitive poly(2-tetrahydropyranyl methacrylate) [poly(THPMA)] nanospheres and demonstrate their feasibility as an effective drug delivery vehicle. Poly(THPMA) nanospheres were prepared using either the double emulsion or single emulsion method for the encapsulation of, respectively, water soluble (rhodamine B) or organic soluble (paclitaxel) payloads. The resulting nanospheres showed pH-dependent dissolution behavior, resulting in significant morphologic changes and loss of nanoparticle mass under mild acidic conditions (pH 5.1) with a half-life of 3.3 days, as compared to physiologic condition (pH 7.4) with a half-life of 6.2 days. The in vitro drug release profile of the paclitaxel-loaded poly(THPMA) nanospheres revealed that the rate of drug release in pH 5.1 acetate buffer was relatively faster than that in pH 7.4 HEPES buffer. Furthermore, poly(THPMA) nanospheres showed lower cytotoxicity and higher cellular uptake as compared to the FDA-approved PLGA-based nanospheres currently in clinical practice.     

Clostridial neurotoxins as a drug delivery vehicle targeting nervous system

Several neuronal disorders require drug treatment using drug delivery systems for specific delivery of the drugs for the targeted tissues, both at the peripheral and central nervous system levels. We describe a review of information currently available on the potential use of appropriate domains of clostridial neurotoxins, tetanus and botulinum, for effective drug delivery to neuronal systems. While both tetanus and botulinum neurotoxins are capable of delivering drugs the neuronal cells, tetanus neurotoxin is limited in clinical use because of general immunization of population against tetanus. Botulinum neurotoxin which is also being used as a therapeutic reagent has strong potential for drug delivery to nervous tissues.     

Polyketal nanoparticles: a new pH-sensitive biodegradable drug delivery vehicle

In this report, we present an acid-sensitive drug delivery vehicle, termed polyketal nanoparticles, which are designed to target therapeutics to the acidic environments of tumors, inflammatory tissues, and phagosomes. The polyketal nanoparticles are formulated from poly(1,4-phenyleneacetone dimethylene ketal) (PPADK), a new hydrophobic polymer which contains ketal linkages in its backbone. The polyketal nanoparticles undergo acid-catalyzed hydrolysis into low molecular weight hydrophilic compounds and should therefore release encapsulated therapeutics at an accelerated rate in acidic environments. Importantly, the polyketal nanoparticles do not generate acidic degradation products after hydrolysis, as with polyester-based biomaterials. Dexamethasone-loaded nanoparticles, 200-600 nm in diameter, were fabricated with PPADK via an emulsion procedure using chloroform and water. The hydrolysis half-life of PPADK was measured to be 102 h at pH 7.4 and 35 h at pH 5.0. PPADK was synthesized by a new polymerization strategy based on the acetal exchange reaction. This new delivery system should find numerous applications in the field of drug delivery because of its ease of synthesis and excellent degradation properties.     

Transport mechanisms in oral transmucosal drug delivery: implications for pain management

The mechanism for the oral transmucosal delivery of fentanyl citrate (OTFC) was investigated in this work. A developed mathematical model included the following transport characteristics: dissolution of the fentanyl citrate lozenge, diffusion through the saliva and oral mucosal membrane and equilibrium between adjacent layers. An orthogonal-collocation-based solution procedure was adopted to discretize the governing equations and boundary conditions. The Mathematica® built-in function, NDSolve, was applied to integrate the equations with respect to time. Simulations were conducted with a 200 μg-dosage. A novel fabrication method, aimed at maintaining a high flux for a prolonged period of time, was proposed based on the calculated delivery rate and cumulative amount of medicament absorbed into the systemic circulation. The model allows drug manufacturers to decide when to replace the unit based on estimated drug concentrations in the saliva and the mucosal membrane. Both the model and solution strategies were validated using serum fentanyl citrate concentration collected from adult subjects. The predicted profiles, based on parameters obtained from the literature, agree well with the experimental data.     

Chitosan graft copolymer nanoparticles for oral protein drug delivery: preparation and characterization

Several novel functionalized graft copolymer nanoparticles consisting of chitosan (CS) and the monomer methyl methacrylate (MMA), N-dimethylaminoethyl methacrylate hydrochloride (DMAEMC), and N-trimethylaminoethyl methacrylate chloride (TMAEMC), which show a higher solubility than chitosan in a broader pH range, have been prepared by free radical polymerization. The nanoparticles were characterized in terms of particle size, zeta potential, TEM, and FT-IR. These nanoparticles were 150-280 nm in size and carried obvious positive surface charges. Protein-loaded nanoparticles were prepared, and their maximal encapsulation efficiency was up to 100%. In vitro release showed that these nanoparticles provided an initial burst release followed by a slowly sustained release for more than 24 h. These graft copolymer nanoparticles enhanced the absorption and improved the bioavailability of insulin via the gastrointestinal (GI) tract of normal male Sprague-Dawley (SD) strain rats to a greater extent than that of the phosphate buffer solution (PBS) of insulin.     

Poly(fumaric-co-sebacic) microspheres as oral drug delivery systems

The current study focuses on the development of bioadhesive oral delivery systems based on bioerodible polyanhydrides. The polymers were studied and characterized using a novel tensiometer based on a very sensitive electrobalance. The system was designed to mimic in vivo interactions, thus all experiments were conducted with freshly excised tissue immersed in physiological saline at 37 degrees C. Poly(fumaric-co-sebacic) [P(FA:SA)] was found to be the most bioadhesive polymer from a series of different thermoplastic materials evaluated. Correlation with in vivo performance was investigated by determining gastrointestinal (GI) residence time of barium-loaded microspheres. Residence times of 24 to 36 h provided a strong indication that these microspheres were good candidates for bioadhesive drug delivery systems. To evaluate the effect of these materials on bioavailability, the anticoagulant drug, dicumarol, was encapsulated. Systemic blood levels demonstrated increased bioavailability for the encapsulated dicumarol formulation as compared with unencapsulated drug. (c) 1996 John Wiley & Sons, Inc.     

Nanotransporters for drug delivery

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Development of a pH-responsive particulate drug delivery vehicle for localized biologic therapy in inflammatory bowel disease

The treatment of inflammatory bowel disease (IBD) recently has been revolutionized by the introduction of protein-based biologic therapies. However, biologic therapy is complicated by the requirement for administration with a needle, systemic side effects, and high cost. Particulate drug delivery systems have been shown to deliver drugs locally to the intestinal mucosa via oral administration. However, these systems have been largely unexplored for the delivery of biologics due to harsh particle fabrication conditions and the tendency of many particulate formulations to dissolve in the acidic upper GI tract. We have, therefore, fabricated an inexpensive and non-toxic novel microparticle capable of encapsulating proteins. We establish that the particle retains its contents at acidic pH and releases them at neutral pH. We also demonstrate particulate encapsulation of interleukin-10 (IL-10), a protein relevant to the treatment of IBD, at an encapsulation efficiency of 14.3 percent. Such a vehicle is promising for its oral route of administration and potential to decrease side effects and increase potency of biologics.     

Nanoparticles incorporated in bilaminated films: a smart drug delivery system for oral formulations

A novel smart drug delivery system (NP-Film) consisting of carboxylation chitosan-grafted nanoparticles (CCGNs) and bilaminated films, which were composed of the mucoadhesive chitosan-ethylenediaminetetraacetic acid hydrogel layer and the hydrophobic ethylcellulose layer, was developed for oral delivery of protein drugs. NP-Film was characterized by electron microscopy and fluorescence microscopy, and the results showed that the solid, spherical nanoparticles dispersed evenly in the porous structures of films. The properties of nanoparticles and films were investigated. The mucoadhesive force, CCGNs released from the NP-Film, and the toxicity of NP-Film were also evaluated. Results showed that the nanoparticles could reversibly open the tight junction of the intestine and inhibit trypsin activity. The release behavior of the nanoparticles from the NP-Film exhibited pH sensitivity. The drug delivery system possessed high mucoadhesive force and low intestinal toxicity. Therefore, the NP-Film would be a promising delivery carrier for protein drugs via oral administration.     

Chocolate,an effective means of oral drug delivery in rats

Oral gavage is an important procedure for drug discovery and efficacy studies using rodents. However, there are welfare issues related to the use of the method by inexperienced persons or for long-term studies. The authors describe an effective method of administering drugs to rats by mixing the drug with chocolate to provide a consistent and reliable method of oral drug delivery to large groups of rats for a long period of time.     

Molecular aptamers for drug delivery

The active targeting of drugs in a cell-, tissue- or disease-specific manner represents a potentially powerful technology with widespread applications in medicine, including the treatment of cancers. Aptamers have properties such as high affinity and specificity for targets, easy chemical synthesis and modification, and rapid tissue penetration. They have become attractive molecules in diagnostics and therapeutics rivaling and, in some cases, surpassing other molecular probes, such as antibodies. In this review, we highlight the recent progress in aptamer-mediated delivery for therapeutics and disease-targeting based on aptamer integration with a variety of nanomaterials, such as gold nanorods, DNA micelles, DNA hydrogels and carbon nanotubes.