Co-milling of a drug with a co-former is an efficient technique to improve the solubility of drugs. Besides the particle size reduction, the co-milling process induces a structural disorder and the creation of amorphous regions. The extent of drug solubility enhancement is dependent on the proper choice of co-milling co-former. The aim of this work was to compare the effects of different co-formers (meglumine and polyvinylpyrrolidone) on the dissolution rates of glass forming (indomethacin) and non-glass forming (mefenamic acid) model drugs. A positive impact of the co-milling on the dissolution behavior was observed in all co-milled mixtures, even if no substantial amorphization was observed. While meglumine exhibited pronounced effects on the dissolution rate of both drugs, the slightest enhancement was observed in mixtures with polyvinylpyrrolidone. The evaluation of specific release rate revealed the surface activation of drug particle is responsible for improving the dissolution rate of both drug types, but for the glass former, this surface activation could be persistent while maintaining a high dissolution rate even until a high fraction of drug is released. Our results, therefore, indicate that adequate co-former choice and consideration of drug glass forming ability are important for a successful co-milling approach to poorly water-soluble drugs.
- MeSH
- Indomethacin MeSH
- Pharmaceutical Preparations * MeSH
- Povidone * MeSH
- Drug Compounding MeSH
- Solubility MeSH
- Particle Size MeSH
- Publication type
- Journal Article MeSH
To enhance dissolution rate of meloxicam (MX), a poorly soluble model drug, a natural polysaccharide excipient chitosan (CH) is employed in this work as a carrier to prepare binary interactive mixtures by either mixing or co-milling techniques. The MX-CH mixtures of three different drug loads were characterized for morphological, granulometric, and thermal properties as well as drug crystallinity. The relative dissolution rate of MX was determined in phosphate buffer of pH 6.8 using the USP-4 apparatus; a significant increase in MX dissolution rate was observed for both mixed and co-milled mixtures comparing to the raw drug. Higher dissolution rate of MX was evidently connected to surface activation by mixing or milling, which was pronounced by the higher specific surface energy as detected by inverse gas chromatography. In addition to the particle size reduction, the carrier effect of the CH was confirmed for co-milling by linear regression between the MX maximum relative dissolution rate and the total surface area of the mixture (R2 = 0.863). No MX amorphization or crystalline structure change were detected. The work of adhesion/cohesion ratio of 0.9 supports the existence of preferential adherence of MX to the coarse particles of CH to form stable interactive mixtures.
- MeSH
- Chitosan * MeSH
- Meloxicam MeSH
- Excipients MeSH
- Solubility MeSH
- Publication type
- Journal Article MeSH
CONTEXT: The preparation of liquisolid systems (LSS) represents a promising method for enhancing a dissolution rate and bioavailability of poorly soluble drugs. The release of the drug from LSS tablets is affected by many factors, including the disintegration time. OBJECTIVE: The evaluation of differences among LSS containing varying amounts and types of commercially used superdisintegrants (Kollidon® CL-F, Vivasol® and Explotab®). MATERIALS AND METHODS: LSS were prepared by spraying rosuvastatin solution onto Neusilin® US2 and further processing into tablets. Varying amounts of superdisintegrants were used and the differences among LSS were evaluated. The multiple scatter plot method was used to visualize the relationships within the obtained data. RESULTS AND DISCUSSION: All disintegrants do not showed negative effect on the flow properties of powder blends. The type and concentration of superdisintegrant had an impact on the disintegration time and dissolution profiles of tablets. Tablets with Explotab® showed the longest disintegration time and the smallest amount of released drug. Fastest disintegration and dissolution rate were observed in tablets containing Kollidon® CL-F (≥2.5% w/w). Also tablets with Vivasol® (2.5-4.0% w/w) showed fast disintegration and complete drug release. CONCLUSION: Kollidon® CL-F and Vivasol® in concentration ≥2.5% are suitable superdisintegrants for LSS with enhanced release of drug.
- MeSH
- Anticholesteremic Agents administration & dosage chemistry MeSH
- Pharmaceutic Aids chemistry MeSH
- Povidone chemistry MeSH
- Drug Compounding MeSH
- Rosuvastatin Calcium administration & dosage chemistry MeSH
- Solubility MeSH
- Silicates chemistry MeSH
- Starch analogs & derivatives chemistry MeSH
- Aluminum Compounds chemistry MeSH
- Magnesium Compounds chemistry MeSH
- Tablets chemistry MeSH
- Drug Liberation MeSH
- Publication type
- Journal Article MeSH
Meloxicam (MLX) is a poorly soluble drug exhibiting strong hydrophobicity. This combination of properties makes dissolution enhancement by particle size reduction ineffective; therefore, combined formulation approaches are required. Various approaches were investigated in this study, including milling, solid dispersions, and self-emulsified lipid formulations. Whereas milling studies of MLX and its co-milling with various polymers have been reported in recent literature, this study is focused on investigating the dissolution kinetics of particulate formulations obtained by co-milling MLX with sodium lauryl sulfate (SLS) in a planetary ball mill with 5-25 wt.% SLS content. The effects of milling time and milling ball size were also investigated. No significant reduction in drug crystallinity was observed under the investigated milling conditions according to XRD data. For the dissolution study, we used an open-loop USP4 dissolution apparatus, and recorded dissolution profiles were fitted according to the Weibull model. The Weibull parameters and a novel criterion-surface utilization factor-were used to evaluate and discuss the drug release from the perspective of drug particle surface changes throughout the dissolution process. The most effective co-milling results were achieved using smaller balls (2 mm), with a co-milling time of up to 15 min SLS content of up to 15 wt.% to increase the dissolution rate by approximately 100 times relative to the physical mixture reference. The results suggest that for hydrophobic drugs, particle performance during dissolution is very sensitive to surface properties and not only to particle size. Co-milling with SLS prepares the surface for faster drug release than that achieved with direct mixing.
- Publication type
- Journal Article MeSH
Polysaccharides based nanocomplexes have been developed for encapsulation, controlled delivery and to enhance the phototoxicity of the photosensitizer 5-aminolevulinic acid for application in photodynamic therapy. The nanocomplexes were prepared by coacervation in a solvent free environment using chitosan as polycation while alginic and polygalacturonic acid as polyanions. The complexes showed average dimension in the range 90-120nm, good stability in simulated physiological media and high drug encapsulation efficiency, up to 800μg per mg of carrier. Release studies demonstrate the possibility to tune the overall release rate and the intensity of the initial burst by changing the external pH. Cytotoxicity and photocytotoxicity tests confirmed the not toxicity of the used polysaccharides. Cell viability results confirmed the improvement of 5-aminolevulinic acid phototoxicity when loaded into the carrier compared to the free form. No effect of the irradiation on the nanocomplexes structure and on the release kinetics of the drug was observed. The results demonstrate that the prepared formulations have suitable properties for future application in photodynamic therapy and to ameliorate the therapeutic efficacy and overcome the side-effects related to the use of the photosensitizer 5-aminolevulinic acid.
- MeSH
- Chitosan chemistry MeSH
- Photosensitizing Agents chemistry toxicity MeSH
- HeLa Cells MeSH
- Hydrogen-Ion Concentration MeSH
- Aminolevulinic Acid chemistry toxicity MeSH
- Humans MeSH
- Nanoparticles chemistry MeSH
- Drug Carriers chemistry MeSH
- Light MeSH
- Temperature MeSH
- Drug Liberation MeSH
- Particle Size MeSH
- Cell Survival drug effects radiation effects MeSH
- Check Tag
- Humans MeSH
- Publication type
- Journal Article MeSH
The sorption of poorly aqueous soluble active pharmaceutical ingredients (API) to mesoporous silica carriers is an increasingly common formulation strategy for dissolution rate enhancement for this challenging group of substances. However, the success of this approach for a particular API depends on an array of factors including the properties of the porous carrier, the loading method, or the attempted mass fraction of the API. At present, there is no established methodology for the rational selection of these parameters. In the present work, we report a systematic comparison of four well-characterised silica carriers and seven APIs loaded by the same solvent evaporation method. In each case, we find the maximum amorphization capacity by x-ray powder diffraction analysis and measure the in vitro drug release kinetics. For a selected case, we also demonstrate the potential for bioavailability enhancement by a permeation essay.
- MeSH
- Kinetics MeSH
- Drug Carriers * MeSH
- Silicon Dioxide * MeSH
- Porosity MeSH
- Solvents MeSH
- Solubility MeSH
- Drug Liberation MeSH
- Publication type
- Journal Article MeSH
One of the conventional methods of alleviating the problem of poor drug solubility is the particle size reduction. The efficiency of this approach depends on successful formulation suppressing the drug agglomeration. The aim of this study was to circumvent the dissolution problems of model hydrophobic meloxicam drug (MLX) by using liquid media of different wetting capacity to comminute and formulate a rapidly dissolving carrier system without the use of surfactants. Micro-suspensions of MLX were prepared by ball milling, using water or n-Heptane as a liquid medium. The suspensions were used as granulation liquids to formulate granulate from microcrystalline cellulose and lactose mixture. The release kinetics from prepared granulates were studied using the USP-4 dissolution apparatus. Micro-suspensions prepared via wet milling in non-water liquid media exhibited a massive improvement of release rate compared with source meloxicam and they outperformed their water-milled counterparts. The release rates from those formulations, despite not comprising any surfactant, were comparable to those obtained by different authors using surfactant stabilized nanosuspension formulations. Thus, they can present an interesting formulation alternative for hydrophobic drugs that are dissolution limited.
PURPOSE: Imaging methods were used as tools to provide an understanding of phenomena that occur during dissolution experiments, and ultimately to select the best ratio of two polymers in a matrix in terms of enhancement of the dissolution rate and prevention of crystallization during dissolution. METHODS: Magnetic resonance imaging, ATR-FTIR spectroscopic imaging and Raman mapping have been used to study the release mechanism of a poorly water soluble drug, aprepitant, from multicomponent amorphous solid dispersions. Solid dispersions were prepared based on the combination of two selected polymers - Soluplus, as a solubilizer, and PVP, as a dissolution enhancer. Formulations were prepared in a ratio of Soluplus:PVP 1:10, 1:5, 1:3, and 1:1, in order to obtain favorable properties of the polymer carrier. RESULTS: The crystallization of aprepitant during dissolution has occurred to a varying degree in the polymer ratios 1:10, 1:5, and 1:3, but the increasing presence of Soluplus in the formulation delayed the onset of crystallization. The Soluplus:PVP 1:1 solid dispersion proved to be the best matrix studied, combining the abilities of both polymers in a synergistic manner. CONCLUSIONS: Aprepitant dissolution rate has been significantly enhanced. This study highlights the benefits of combining imaging methods in order to understand the release process.
- MeSH
- Chemistry, Pharmaceutical methods MeSH
- Crystallization MeSH
- Magnetic Resonance Imaging methods MeSH
- Morpholines chemistry MeSH
- Drug Carriers chemistry MeSH
- Polyethylene Glycols chemistry MeSH
- Polymers chemistry MeSH
- Polyvinyls chemistry MeSH
- Pyrrolidines chemistry MeSH
- Solubility MeSH
- Spectroscopy, Fourier Transform Infrared methods MeSH
- Drug Liberation MeSH
- Water chemistry MeSH
- Publication type
- Journal Article MeSH
PURPOSE: Imaging methods were used as tools to provide an understanding of phenomena that occur during dissolution experiments, and ultimately to select the best ratio of two polymers in a matrix in terms of enhancement of the dissolution rate and prevention of crystallization during dissolution. METHODS: Magnetic resonance imaging, ATR-FTIR spectroscopic imaging and Raman mapping have been used to study the release mechanism of a poorly water soluble drug, aprepitant, from multicomponent amorphous solid dispersions. Solid dispersions were prepared based on the combination of two selected polymers - Soluplus, as a solubilizer, and PVP, as a dissolution enhancer. Formulations were prepared in a ratio of Soluplus:PVP 1:10, 1:5, 1:3, and 1:1, in order to obtain favorable properties of the polymer carrier. RESULTS: The crystallization of aprepitant during dissolution has occurred to a varying degree in the polymer ratios 1:10, 1:5, and 1:3, but the increasing presence of Soluplus in the formulation delayed the onset of crystallization. The Soluplus:PVP 1:1 solid dispersion proved to be the best matrix studied, combining the abilities of both polymers in a synergistic manner. CONCLUSIONS: Aprepitant dissolution rate has been significantly enhanced. This study highlights the benefits of combining imaging methods in order to understand the release process.
- MeSH
- Aprepitant MeSH
- Chemistry, Pharmaceutical methods MeSH
- Crystallization MeSH
- Magnetic Resonance Imaging methods MeSH
- Morpholines chemistry MeSH
- Drug Carriers chemistry MeSH
- Polyethylene Glycols chemistry MeSH
- Polymers chemistry MeSH
- Polyvinyls chemistry MeSH
- Pyrrolidines chemistry MeSH
- Solubility MeSH
- Spectroscopy, Fourier Transform Infrared methods MeSH
- Drug Liberation MeSH
- Water chemistry MeSH
- Publication type
- Journal Article MeSH
Drug amorphisation by loading to inorganic mesoporous carriers represents an emerging area of improving the dissolution rate and bioavailability of poorly water-soluble active pharmaceutical ingredients (APIs). In this work, for the first time, a molecular-level insight into the process of API loading to mesoporous SiO2 (silica) carriers by the hot-melt impregnation method and its subsequent release during dissolution was obtained using ATR-FTIR spectroscopic imaging. A physical mixture of ibuprofen crystals and mesoporous silica particles was heated and the dynamics of melt loading into the silica pore structure was directly observed in situ by ATR-FTIR spectroscopic imaging. The loss of crystallinity, the redistribution of the API in the silica pore network and the subsequent stabilisation of the amorphous form upon cooling were proven. The API was involved in two different kinds of molecular-level interactions: API dimers in the amorphous bulk, and individual API molecules adsorbed on the silica surface. The melt-loaded silica carriers were comprehensively characterised by DSC, SEM and dissolution tests, which proved dissolution rate enhancement due to amorphisation of the API. Drug release form the hot-melt loaded mesoporous silica carriers was observed in real time and the conditions leading to local re-crystallisation of super-saturated solution of the API were identified.
- MeSH
- Adsorption MeSH
- Biological Availability MeSH
- Calorimetry, Differential Scanning MeSH
- Chemistry, Pharmaceutical methods MeSH
- Ibuprofen administration & dosage chemistry MeSH
- Crystallization MeSH
- Microscopy, Electron, Scanning MeSH
- Drug Carriers chemistry MeSH
- Silicon Dioxide chemistry MeSH
- Porosity MeSH
- Solubility MeSH
- Spectroscopy, Fourier Transform Infrared MeSH
- Drug Liberation MeSH
- Water chemistry MeSH
- Hot Temperature MeSH
- Publication type
- Journal Article MeSH
