丙戊酸钠缓释片的制备及其释放度的测定

目的 研制丙戊酸钠缓释片并进行体外释放度测定。方法 采用喷雾干燥法制备丙戊酸钠微囊，通过电镜和X-射线衍射等检测方法对微囊进行质量评价。采用永停滴定法测定丙戊酸钠微囊含量及缓释片的体外释放度。结果 喷雾干燥法制备的丙戊酸钠微囊质量较好，所制缓释片体外释放符合一级动力学过程。结论 运用丙戊酸钠微囊制备缓释片的工艺简便、可靠，体外释放证明有明显的缓释作用。     

Investigating the interactions of amino acid components on a mannitol-based spray-dried powder formulation for pulmonary delivery: A design of experiment approach

Combining an amino acid and a sugar is a known strategy in the formulation of spray or freeze dried biomolecule powder formulations. The effect of the amino acid leucine in enhancing performance of spray-dried powders has been previously demonstrated, but interaction effects of several constituents which may provide multiple benefits, are less well-understood. A 3 factor 2 level (2³) factorial design was used to study the effects of leucine, glycine and alanine in a mannitol-based dry powder formulation on particle size, aerosolisation, emitted dose and cohesion. Other qualitative tests including scanning electronic microscopy and X-ray powder diffraction were also conducted on the design of experiment (DoE) trials. The results show that the use of glycine and/or alanine, though structurally related to leucine, did not achieve similar aerosol performance enhancing effects, rather the particle formation was hindered. However, when used in appropriate concentrations with leucine, the combination of amino acids produced an enhanced performance regardless of the presence of glycine and/or alanine, yielding significantly modified particle properties. The results from the DoE analyses also revealed the lack of linearity of effects for certain responses with a significant curvature in the model which would otherwise not be discovered using a trial-and-error approach.     

Analysis of co-spray-dried meloxicam-mannitol systems containing crystalline microcomposites

The crystal size, form, wettability and rate of dissolution of a drug are factors limiting its nasal or pulmonary administration. The aim of this work was to achieve an ideal crystal habit, good wettability and the rapid release of meloxicam (MEL), a poorly water-soluble non-steroidal anti-inflammatory drug. The structures of MEL and the carrier-based systems were analysed by differential scanning calorimetry, X-ray diffractometry and Fourier transform infrared spectroscopy. The particle size and morphology were investigated by laser diffraction and SEM analyses. The novelty of this work was the use of a co-spray-drying technique, which resulted in mannitol-based crystalline microcomposites (1-6 μm) containing MEL microcrystals (1-5 μm). The particle size and form of the MEL microcrystals were adjusted by a top-down method. The presence of mannitol (with a MEL:mannitol mass ratio of 1:1) with additives ensured the homogeneous distribution of MEL in the microcomposites with good wettability and rapid release (100% MEL within 5 min).     

Inclusion complexation of glibenclamide with 2-hydroxypropyl-β-cyclodextrin in solution and in solid state

Phase solubility diagrams have been used to investigate complexation between 2-hydroxypropyl-β-cyclodextrin (HPBCD) and glibenclamide (GM) in aqueous medium. More stable GM-HPBCD complexes were formed in alkaline medium (in which the drug is in ionized form) than in acid medium (in which the drug is in non-ionized form). The formation of solid GM-HPBCD inclusion complexes has been evaluated by using kneading, spray-drying and freeze-drying methods. Characterization of the resulting mixtures by X-ray diffraction, infrared spectroscopy and differential scanning calorimetry indicated that inclusion complexes can be obtained by spray drying and freeze drying but not by kneading. According to the phase solubility results, drug solubility in alkaline medium was greatly improved by inclusion with HPBCD, whereas in acid medium inclusion with HPBCD had no appreciable effect. Cyclodextrin complexation of ionized drug molecules in alkaline medium resulted in greater total solubilization, i.e., solubilization of the drug due to both cyclodextrin complexation and ionization.     

Preparation of prolonged release clarithromycin microparticles for oral use and theirin vitro evaluation

Prolonged release microparticles of clarithromycin (CL) were prepared using Eudragit RL 100 and RS 100 by spray-drying and casting-drying techniques. For the characterization of those microparticles, preparation yield, particle size distribution, X-ray diffraction, thermal behavior, active agent content and in vitro dissolution from the microparticles were performed. HPLC was used for the assay of clarithromycin and the assay method was validated. All the formulations obtained showed prolonged release when compared to pure clarithromycin. Microparticles prepared by spray-drying method had a slower release compared to those of casting-drying method. Spray-drying method seems to be a more suitable method to prepare microparticles for prolongation in release.     

Enhanced Dispersibility and Deposition of Spray-dried Powders for Pulmonary Gene Therapy

Spray-drying represents a viable alternative to freeze-drying for preparing dry powder dispersions for delivering macromolecules to the lung. The dispersibility of spray-dried powders is limited however, and needs to be enhanced to improve lung deposition and subsequent biological activity. In this study, we investigate the utility of leucine as a dry powder dispersibility enhancer when added prior to spray-drying a model non-viral gene therapy formulation (lipid:polycation:pDNA, LPD). Freeze-dried lactose–LPD, spray-dried lactose–LPD and spray-dried leucine–lactose–LPD powders were prepared. Scanning electron microscopy showed that leucine increased the surface roughness of spray-dried lactose particles. Particle size analysis revealed that leucine-containing spray-dried powders were unimodally dispersed with a mean particle diameter of 3.12 μm. Both gel electrophoresis and in vitro cell (A549) transfection showed that leucine may compromise the integrity and biological functionality of the gene therapy vector. The deposition of the leucine containing powder was however significantly enhanced as evidenced by an increase in gene expression mediated by dry powder collected at lower stages of a multistage liquid impinger (MSLI). Further studies are required to determine the potential of leucine as a ubiquitous dispersibility enhancer for a variety of pulmonary formulations.     

Design of an inhalable dry powder formulation of DOTAP-modified PLGA nanoparticles loaded with siRNA

Matrix systems based on biocompatible and biodegradable polymers like the United States Food and Drug Administration (FDA)-approved polymer poly(DL-lactide-co-glycolide acid) (PLGA) are promising for the delivery of small interfering RNA (siRNA) due to favorable safety profiles, sustained release properties and improved colloidal stability, as compared to polyplexes. The purpose of this study was to design a dry powder formulation based on cationic lipid-modified PLGA nanoparticles intended for treatment of severe lung diseases by pulmonary delivery of siRNA. The cationic lipid dioleoyltrimethylammoniumpropane (DOTAP) was incorporated into the PLGA matrix to potentiate the gene silencing efficiency. The gene knock-down level in vitro was positively correlated to the weight ratio of DOTAP in the particles, and 73% silencing was achieved in the presence of 10% (v/v) serum at 25% (w/w) DOTAP. Optimal properties were found for nanoparticles modified with 15% (w/w) DOTAP, which reduced the gene expression with 54%. This formulation was spray-dried with mannitol into nanocomposite microparticles of an aerodynamic size appropriate for lung deposition. The spray-drying process did not affect the physicochemical properties of the readily re-dispersible nanoparticles, and most importantly, the in vitro gene silencing activity was preserved during spray-drying. The siRNA content in the powder was similar to the theoretical loading and the siRNA was intact, suggesting that the siRNA is preserved during the spray-drying process. Finally, X-ray powder diffraction analysis demonstrated that mannitol remained in a crystalline state upon spray-drying with PLGA nanoparticles suggesting that the sugar excipient might exert its stabilizing effect by sterical inhibition of the interactions between adjacent nanoparticles. This study demonstrates that spray-drying is an excellent technique for engineering dry powder formulations of siRNA nanoparticles, which might enable the local delivery of biologically active siRNA directly to the lung tissue.     

Formulation and testing of vancomycin loaded albumin microspheres prepared by spray-drying

Microparticles are widely employed as carriers of biologically active compounds with many possible applications. For targeted drug delivery and sustained release purposes, biopolymers (i.e. polysaccharides and proteins) have been proposed. In this study, microsphere formulations of vancomycin were prepared by the spray-drying method. Bovine serum albumin (BSA) was used as a polymer matrix and was cross-linked with glutaraldehyde after microsphere preparation. The product yield obtained from the spray-drying method was ～75%. The mean particle size was 5?±?1.6?µm, with the majority of particles between 4 and 8?µm. The extent of cross-linking affected the release of vancomycin from microspheres. Moreover, both rate and extent of vancomycin release from microspheres decreased with increasing glutaraldehyde concentration. Encapsulation of vancomycin did not alter the bioactivity of the drug and it was more effective in killing Staphylococcus aureus than the solution form.     

Technological considerations related to the up-scaling of protein microencapsulation by spray-drying

Research and development of therapeutics and vaccines based on biodegradable polymers are intensive and one of the most promising fields in controlled drug delivery. However, new applications necessitate successful technology transfer and industrial scale-ups. In an endeavour to produce clinical samples of a single-administration tetanus vaccine based on poly(lactide-co-glycolide) microspheres, we report on technological parameters that are of importance in the up-scaling of the spray-drying process. The results show that an up-scaling of the encapsulation of protein vaccines or drug by spray-drying is feasible, but that additives, the type of polymer solvent, the polymer concentration, the w/o ratio and the product collection method influence process and product quality.     

Quantification of microparticle coating quality by confocal laser scanning microscopy (CLSM)

In this work, a novel protocol was developed for determining film coating thickness and coating quality of microparticles, based on the use of confocal laser scanning microscopy (CLSM). CLSM was found to be an adequate non-destructive technique for the quantification of the coating thickness and coating quality of individual thin-coated small particles. Combined with image analysis, it was possible to derive with high accuracy the coating thickness distribution of a representative number of microparticles. The performance of the novel methodology was assessed by the quantification of the coating thickness and coating quality of protein-coated microparticles produced by fluidized bed coating. It was found that the CLSM data on coating layer thickness were generally in good agreement with the results from chemical analysis, down to a thickness of 1–1.5 μm. Using CLSM the importance of setting up the appropriate distance between the coating nozzle and the powder bed with respect to microparticle coating quality in fluidized bed processing was illustrated. Coating quality was found to decrease with increasing distance the coating droplets have to travel before impinging onto the core particles as a result of spray-drying of the coating droplets. Also, coating quality decreased with increasing viscosity of the coating droplets, resulting in reduced spreading on the cores.