Meiyan Yang

Microenvironmental pH-modified solid dispersions to enhance the dissolution and bioavailability of poorly water-soluble weakly basic GT0918, a developing anti-prostate cancer drug: Preparation, characterization and evaluation in vivo

The aim of the present work was to design a pH-modified solid dispersion (pH(M)-SD) that can improve the dissolution and bioavailability of poorly water-soluble weakly basic GT0918, a developing anti-prostate cancer drug. To select the appropriate acidifiers, a solubility test was carried out first. Solid dispersions (SDs) containing GT0918 and polyvinylpyrrolidone (PVP) were prepared using a solvent evaporation method and were characterized using dissolution studies in different media. The solid states of the SDs were investigated using scanning electron microscopy (SEM), powder X-ray diffraction (PXRD), differential scanning calorimetry (DSC) and Fourier transformed infrared spectroscopy (FTIR). The in vivo pharmacokinetics of the pH(M)-SDs tablets were also studied in beagle dogs compared to the conventional tablets. The optimized pH(M)-SD (GT0918/PVP/citric acid, 1:2:2 weight ratio) exhibited a significant improvement in the dissolution behavior compared to both the physical mixture and the binary SDs. Solid-state characterization revealed that the amorphous formation of GT0918 in the SDs and the strong H-bonding were only found in the pH(M)-SDs containing citric acid. Furthermore, the GT0918-loaded pH(M)-SD tablets showed a higher AUC and a lower tmax compared to the conventional tablets. Accordingly, the pH(M)-SD might be an efficient route for enhancing the dissolution and bioavailability of poorly water-soluble GT0918.

Effects of polyvinylpyrrolidone both as a binder and pore-former on the release of sparingly water-soluble topiramate from ethylcellulose coated pellets

Delivering sparingly water-soluble drugs from ethylcellulose (EC) coated pellets with a controlled-release pattern remains challenging. In the present study, hydrophilic polyvinylpyrrolidone (PVP) was used both as a binder and a pore-former in EC coated pellets to deliver sparingly water-soluble topiramate, and the key factors that influenced drug release were identified. When the binder PVP content in drug layers below 20% w/w was decreased, the physical state of topiramate changed from amorphous to crystalline, making much difference to drug solubility and dissolution rates while modifying the drug release profile from first-order to zero-order. In addition, without PVP in drug layering solution, drug layered particles were less sticky during layering process, thus leading to a shorter process and higher loading efficiency. Furthermore, PVP level as a pore-former in EC coating layers mainly governed drug release from the coated pellets with the sensitivity ranging from 23% to 29%. PVP leaching rate and water permeability from EC/PVP film increased with the PVP level, which was perfectly correlated with drug release rate. Additionally, drug release from this formulation was independent of pH of release media or of the paddle mixing speed, but inversely proportional to the osmolality of release media above the physiological range.

Preparation and evaluation of orally disintegrating tablets of taste masked phencynonate HCl using ion-exchange resin

Abstract This study was intended to design an orally disintegrating tablet (ODT) formulation that can mask the extremely bitter and metallic taste of phencynonate HCl by novel ion-exchange resins. The drug–resin complexes (DRCs) were prepared and characterized by scanning electron microscopy, X-ray powder diffraction and differential scanning calorimetry. In vitro properties (dissolution, wetting time and disintegration time) and in vivo behavior (disintegration time and taste-masking effect) in healthy volunteers of the prepared ODTs were also investigated. The drug was changed from the crystal structure to the amorphous form in the DRC. Compared with commercial tablets, the in vitro and in vivo disintegration of optimized DRC-loaded ODTs with a drug-resin ratio of 1:1 was greatly improved and better palatability with a low bitterness index (0.33) was obtained. The current DRC-loaded ODT could promise a good way to mask the unpleasant taste of certain drugs and accordingly improve the patient compliance.

Model Drug as Pore Former for Controlled Release of Water-Soluble Metoprolol Succinate from Ethylcellulose-Coated Pellets Without Lag Phase: Opportunities and Challenges

The objective of the present study was to evaluate the feasibility of using model drug metoprolol succinate (MS) as a pore former to modify the initial lag phase (i.e., a slow or non-release phase in the first 1–2 h) associated with the drug release from coated pellets. MS-layered cores with high drug-layering efficiency (97% w/w) were first prepared by spraying a highly concentrated drug aqueous solution (60% w/w, 70°C) on non-pareils without using other binders. The presence of MS in ethylcellulose (EC) coating solution significantly improved the coating process by reducing pellets sticking, which often occurs during organic coating. There may be a maximum physical compatibility of MS with EC, and the physical state of the drug in the functional coating layer of EC/MS (80:20) was simultaneously crystalline and non-crystalline (amorphous or solid molecule solution). The lag phase associated with hydroxypropylcellulose (HPC) as a pore former was not observed when MS was used as a pore former. The drug release from EC/MS-coated pellets was pH independent, inversely proportional to the coating levels, and directly related to the pore former levels. The functional coating layer with MS as a pore former was not completely stabilized without curing. Curing at 60°C for 1 day could substantially improve the stability of EC/MS-coated pellets. The physical state of the drug in the free film of EC/MS (85:15) changed partially from amorphous to crystal when cured at 60°C for 1 day, which should be attributed to the incompatibility of the drug with EC.

Novel ethylcellulose-coated pellets for controlled release of metoprolol succinate without lag phase: characterization, optimization and in vivo evaluation

Abstract The objective of this study was to develop a novel ethylcellulose (EC)-coated pellet with partial active dose as a pore former for the controlled release of water-soluble metoprolol succinate (MS) without an initial lag phase (slow/non-drug release phase). MS-layered cores with a high drug-loading efficiency (97%, w/w), a smooth surface, and an acceptable level of resistance to abrasion were first obtained by spraying a concentrated drug solution (60% w/w at 70 °C) on non-pareils in the absence of other binders. The presence of the drug in an EC coating solution significantly improved the coating process by reducing pellet stickiness. Central composite design and response surface methodology was employed to optimize and explore the effect of pore former MS level (X1) and EC coating level (X2) on the drug release. The pore former level had a positive effect on the MS release and the coating level had a negative effect. The level of X1 and X2 of the optimization were 17% and 23%, respectively, and the cumulative percent of MS released within 1 h was up to 9.2%. Accordingly, the initial lag phase associated with in vitro drug release from EC-coated pellets was absent when MS drug was used as a pore former, which was further confirmed by in vivo drug release in beagle dogs. Thus, a novel approach for the controlled release of MS from coated pellets without lag phase has been successfully developed, which is valuable for the advancement of sustained-release pellets.

Enhancing in vivo Bioavailability in Beagle Dogs of GLM-7 as a Novel Anti-Leukemia Drug through a Self-Emulsifying Drug Delivery System for Oral Delivery.

GLM-7 is a novel anti-leukemia drug in the pre-clinical study. The previous study shows that GLM-7 is a poorly water-soluble drug with low oral bioavailability. In this study, we employed the self-emulsifying drug delivery system (SEDDS) to improve the oral bioavailability of GLM-7. The GLM-7 SEDDS formulation was prepared using MCT as oil, ovolecithin as surfactant and Transcutol as co-surfactant, and the formulation parameters were optimized by the response surface methodology. The optimized GLM-7 SEDDS formulation showed a stable liquid state, and can automatically emulsify to form the isotropic emulsion once exposure to the water phase. The generated emulsion showed the spherical shape, and had an average size of about 399 nm and a zeta potential of about -42 mV. Compared to the GLM-7 dissolution less than 1.4% from pure GLM-7 powder (reference), the GLM-7 SEDDS formulation could remarkably enhance the in vitro dissolution to 83% in the medium of 0.1N HCL. The in vivo oral bioavailability of GLM-7 SEDDS formulation was investigated in beagle dogs. The results demonstrated that the GLM-7 SEDDS formulation significantly enhanced the plasma concentrations of GLM-7, and the Cmax reached to 878 ng/ml and was 9.2 folds as high as the Cmax 95.85 ng/ml of reference. Moreover, the area under the curve (AUC) of GLM-7 SEDDS formulation was 13.6 times higher than that of reference, which suggested that the SEDDS formulation remarkably increased the oral bioavailability of GLM-7.

Comparison of pharmacokinetics in beagle dogs of nimesulide bilayer tablets with dispersible tablets

The purpose of this study was to compare the in vitro release and the in vivo pharmacokinetics of bilayer tablets with the conventional dispersible tablets of nimesulide. The tablets were administered to beagle dogs and the plasma levels of nimesulide were determined by high-performance liquid chromatography-MS/MS. The pharmacokinetic parameters were calculated using a noncompartmental model. The bilayer tablets showed a biphasic in vitro release pattern with initial burst release and sustained release following the quasi-Fickian diffusion-based release mechanism. The Cmax, tmax, mean residence time (MRT), and area under the curve from 0 to 36 h were 10.8 ± 4.2 μg/mL, 2.3 ± 1.0 h, 6.7 ± 2.1 h, 81.5 ± 26.7 μg·h/mL for the bilayer tablets and 14.8 ± 5.8 μg/mL, 2.7 ± 0.8 h, 5.6 ± 0.9 h, 95.4 ± 44.2 μg·h/mL for the dispersible tablets. Compared with the dispersible tablets, the bilayer tablets have lower Cmax, similar tmax, and longer MRT. The aforementioned pharmacokinetic parameters, especially the MRT demonstrated to be valuable for evaluating the biphasic characteristics. This study provides a promising in vivo evaluation method for the bilayer tablets with biphasic release pattern.

Development of Itraconazole Liquisolid Compact: Effect of Polyvinylpyrrolidone on the Dissolution Properties

The aim of this work was to utilize the liquisolid technique to enhance dissolution of itraconazole (ITZ). Liquisolid tablets of ITZ were formulated by using N-methyl-2-pyrrolidone as liquid vehicle, polyvinylpyrrolidone (PVP) as a precipitation inhibitor and magnesium aluminometasilicate Neusilin® as a carrier and coating material. The effect of PVP level on stability of liquid medication, physicomechnanical properties and dissolution rate of liquisolid compacts was studied in detail. The crystallinity of formulated drug and the interaction between excipients were examined by differential scanning calorimetry (DSC) and X-ray powder diffraction (XRPD). All the liquisolid tablets showed higher drug dissolution rates than the conventional, directly compressed tablets. The flowability of liquisolid powders was slightly improved as the proportion of PVP in ITZ-NMP mixture increased. Moreover, the stability of liquid medication and wetting ability of liquisolid tablets were improved by PVP. The presence of low amount of PVP (≤ 1%) in liquisolid formulation could enhance dissolution of ITZ liquisolid tablets, whereas the percentage of PVP over 5% decreased the dissolution of ITZ from liquisolid tablets. Both DSC and XRPD suggested reduction or loss of ITZ crystallinity upon liquisolid formulations indicating that the drug was almost solubilized and molecularly dispersed with excipients within the liquisolid matrix. It could be shown that increased solubility, wetting properties and surface area available for dissolution contributed to the improvement of the dissolution of ITZ from liquisolid tablets.

Preformulation characterization and in vivo absorption in beagle dogs of JFD, a novel anti-obesity drug for oral delivery

Abstract JFD (N-isoleucyl-4-methyl-1,1-cyclopropyl-1-(4-chlorine)phenyl-2-amylamine·HCl) is a novel investigational anti-obesity drug without obvious cardiotoxicity. The objective of this study was to characterize the key physicochemical properties of JFD, including solution-state characterization (ionization constant, partition coefficient, aqueous and pH-solubility profile), solid-state characterization (particle size, thermal analysis, crystallinity and hygroscopicity) and drug-excipient chemical compatibility. A supporting in vivo absorption study was also carried out in beagle dogs. JFD bulk powders are prismatic crystals with a low degree of crystallinity, particle sizes of which are within 2–10 μm. JFD is highly hygroscopic, easily deliquesces to an amorphous glass solid and changes subsequently to another crystal form under an elevated moisture/temperature condition. Similar physical instability was also observed in real-time CheqSol solubility assay. pKa (7.49 ± 0.01), log P (5.10 ± 0.02) and intrinsic solubility (S0) (1.75 μg/ml) at 37 °C of JFD were obtained using potentiometric titration method. Based on these solution-state properties, JFD was estimated to be classified as BCS II, thus its dissolution rate may be an absorption-limiting step. Moreover, JFD was more chemically compatible with dibasic calcium phosphate, mannitol, hypromellose and colloidal silicon dioxide than with lactose and magnesium stearate. Further, JFD exhibited an acceptable pharmacokinetic profiling in beagle dogs and the pharmacokinetic parameters Tmax, Cmax, AUC0–t and absolute bioavailability were 1.60 ± 0.81 h, 0.78 ± 0.47 μg/ml, 3.77 ± 1.85 μg·h/ml and 52.30 ± 19.39%, respectively. The preformulation characterization provides valuable information for further development of oral administration of JFD.

Systematic Development of Self-Nanoemulsifying Liquisolid Tablets to Improve the Dissolution and Oral Bioavailability of an Oily Drug, Vitamin K1

The purpose of this study is to improve the dissolution and oral bioavailability of an oily drug, vitamin K1 (VK1) by combination of self-nanoemulsifying and liquisolid technologies. The optimal liquid self-nanoemulsifying drug delivery systems (SNEDDS) formulation including VK1 (oil), mixture of soybean lecithin and glycocholic acid (surfactant) and Transcutol HP (cosurfactant) was obtained according to ternary phase diagrams and a central composite design. Based on compatibility, adsorption capacity and dissolution profile, liquid SNEDDS was then solidified on Fujicalin® to form solid SNEDDS by liquisolid technology and compressed directly with excipients into self-nanoemulsifying liquisolid (SNE-L) tablets. Uniform nano-emulsion suspension was formed rapidly when the SNE-L tablets disintegrated in dissolution media and higher drug dissolution was observed compared with the conventional tablets. The results of pharmacokinetic study in beagle dogs showed that the mean Cmax and the area under the curve of SNE-L tablets were remarkably higher than those of conventional tablets, which were consistent with the results of the in vitro dissolution. The relative bioavailability of SNE-L tablets and conventional tablets was approximately 200%. In conclusion, this combination method showed promise to improve the dissolution and oral bioavailability of oily drug vitamin K1.