Senshang Lin

Effect of HPMC and Carbopol on the release and floating properties of Gastric Floating Drug Delivery System using factorial design.

The purpose of this study is to investigate the effect of formulation variables on drug release and floating properties of the delivery system. Hydroxypropyl methylcellulose (HPMC) of different viscosity grades and Carbopol 934P (CP934) were used in formulating the Gastric Floating Drug Delivery System (GFDDS) employing 2 x 3 full factorial design. Main effects and interaction terms of the formulation variables could be evaluated quantitatively by a mathematical model. It was found that both HPMC viscosity, the presence of Carbopol and their interaction had significant impact on the release and floating properties of the delivery system. The decrease in the release rate was observed with an increase in the viscosity of the polymeric system. Polymer with lower viscosity (HPMC K100LV) was shown to be beneficial than higher viscosity polymer (K4M) in improving the floating properties of GFDDS. Incorporation of Carbopol, however, was found to compromise the floating capacity of GFDDS and release rate of calcium. The observed difference in the drug release and the floating properties of GFDDS could be attributed to the difference in the basic properties of three polymers (HPMC K4M, K100LV and CP934) due to their water uptake potential and functional group substitution.

Effect of formulation variables on the floating properties of gastric floating drug delivery system.

ABSTRACT Purpose. To evaluate the contribution of formulation variables on the floating properties of a gastric floating drug delivery system (GFDDS) using a continuous floating monitoring system and statistical experimental design. Methods. A modified continuous floating monitoring system, which consisted of an electric balance interfacing with a PC, was designed to perform the continuous monitoring of floating kinetics of GFDDS. Several formulation variables, such as different types of hydroxypropyl methylcellulose (HPMC), varying HPMC/Carbopol ratio, and addition of magnesium stearate, were evaluated using Taguchi design, and the effects of these variables were subjected to statistical analysis. Results. The continuous floating monitoring system developed was validated, using capsules with different density, and a good correlation between theoretical and experimental values was obtained (R2 = 0.9998), indicating the validity of the setup. The statistical analysis indicated that magnesium stearate had a significant effect on the floating property of GFDDS (p<0.05), and addition of magnesium stearate could significantly improve the floating capacity of the GFDDS. It was found that the HPMC of higher viscosity grade generally exhibited a greater floating capacity, but the effect was not statistically significant. For polymers with the same viscosity, i.e., K4M and E4M, the degree of substitution of the function group did not show any significant contribution. A better floating behavior was achieved at higher HPMC/Carbopol ratio. Carbopol appeared to have a negative effect on the floating behavior of GFDDS. Conclusions. It was concluded that by using a validated continuous floating monitoring system, the effect of formulation variables on the floating property of the delivery system and their ranges could be identified. Incorporation of hydrophobic agents, such as magnesium stearate, could significantly improve the floating capacity of the GFDDS.

Solubility and dissolution enhancement strategies: current understanding and recent trends

Abstract Identification of lead compounds with higher molecular weight and lower aqueous solubility has become increasingly prevalent with the advent of high throughput screening. Poor aqueous solubility of these lipophilic compounds can drastically affect the dissolution rate and subsequently the drug absorbed in the systemic circulation, imposing a significant burden of time and money during drug development process. Various pre-formulation and formulation strategies have been applied in the past that can improve the aqueous solubility of lipophilic compounds by manipulating either the crystal lattice properties or the activity coefficient of a solute in solution or both, if possible. However, despite various strategies available in the armor of formulation scientist, solubility issue still remains an overriding problem in the drug development process. It is perhaps due to the insufficient conceptual understanding of solubility and dissolution phenomenon that hinders the judgment in selecting suitable strategy for improving aqueous solubility and/or dissolution rate. This article, therefore, focuses on (i) revisiting the theoretical and mathematical concepts associated with solubility and dissolution, (ii) their application in making rationale decision for selecting suitable pre-formulation and formulation strategies and (iii) the relevant research performed in this field in past decade.

Preparation, in vitro evaluation and statistical optimization of carvedilol-loaded solid lipid nanoparticles for lymphatic absorption via oral administration

Abstract Carvedilol-loaded solid lipid nanoparticles (SLNs) were prepared using solubility parameter (δ) to select the lipid, and hot homogenization to fabricate SLNs. The effect of concentration of Compritol 888 ATO (COMP) and Poloxamer 188 (P-188) on the particle size of blank SLNs was studied using the design of experiments. Further narrow concentration range of COMP and P-188 was selected and carvedilol-loaded SLNs were prepared to obtain an optimized formulation which was lyophilized (L-SLNs), transformed into enteric compression-coated tablet and evaluated for drug release, X-ray diffraction and cellular uptake mechanism. COMP was chosen as lipid due to its least value of Δδ with carvedilol. The optimized formulation (7.5% COMP, 5.0% P-188 and 1.11% carvedilol) had 161 nm particle size and 94.8% entrapment efficiency. The enteric-coated carvedilol-loaded SLNs tablet protected carvedilol from acidic environment and similar prolonged release profiles were obtained from L-SLNs, core tablet and enteric-coated tablet. Absence of crystalline carvedilol XRD peak indicated the presence of amorphous carvedilol in SLNs. Higher carvedilol uptake from SLNs compared to drug solution in the Caco-2 cell line exhibited a potential prolonged drug release. Moreover, upon cellular uptake, SLNs could then enter the lymphatic system which will avoid first pass metabolism and hence higher oral bioavailability.

Transdermal delivery of diclofenac using water-in-oil microemulsion: formulation and mechanistic approach of drug skin permeation

Abstract The objective of the present investigation was to enhance skin permeation of diclofenac using water-in-oil microemulsion and to elucidate its skin permeation mechanism. The w/o microemulsion formulations were selected based on constructed pseudoternary phase diagrams depending on water solubilization capacity and thermodynamic stability. These formulations were also subjected to physical characterization based on droplet size, viscosity, pH and conductivity. Permeation of diclofenac across rat skin using side-by-side permeation cells from selected w/o microemulsion formulations were evaluated and compared with control formulations. The selected w/o microemulsion formulations were thermodynamically stable, and incorporation of diclofenac sodium into microemulsion did not affect the phase behavior of system. All microemulsion formulations had very low viscosity (11–17 cps) and droplet size range of 30–160 nm. Microemulsion formulations exhibited statistically significant increase in diclofenac permeation compared to oily solution, aqueous solution and oil–Smix solution. Higher skin permeation of diclofenac was observed with low Smix concentration and smaller droplet size. Increase in diclofenac loading in aqueous phase decreased the partition of diclofenac. Diclofenac from the oil phase of microemulsion could directly partition into skin, while diclofenac from the aqueous droplets was carried through skin by carrier effect.

Quality by design approach for formulation, evaluation and statistical optimization of diclofenac-loaded ethosomes via transdermal route

Abstract The objective of this study was to fabricate and understand ethosomal formulations of diclofenac (DF) for enhanced anti-inflammatory activity using quality by design approach. DF-loaded ethosomal formulations were prepared using 4 × 5 full-factorial design with phosphatidylcholine:cholesterol (PC:CH) ratios ranging between 50:50 and 90:10, and ethanol concentration ranging between 0% and 30% as formulation variables. These formulations were characterized in terms of physicochemical properties and skin permeation kinetics. The interaction of formulation variables had a significant effect on both physicochemical properties and permeation kinetics. The results of multivariate regression analysis illustrated that vesicle size and elasticity of ethosomes were the dominating physicochemical properties affecting skin permeation, and could be suitably controlled by manipulation of formulation variables to optimize the formulation and enhance the skin permeation of DF-loaded ethosomes. The optimized formulation had ethanol concentration of 22.9% and PC:CH ratio of 88.4:11.6, with vesicle size of 144 ± 5 nm, zeta potential of −23.0 ± 3.76 mV, elasticity of 2.48 ± 0.75 and entrapment efficiency of 71 ± 4%. Permeation flux for the optimized formulation was 12.9 ± 1.0 µg/h cm2, which was significantly higher than the drug-loaded conventional liposome, ethanolic or aqueous solution. The in vivo study indicated that optimized ethosomal hydrogel exhibited enhanced anti-inflammatory activity compared with liposomal and plain drug hydrogel formulations.

Statistical optimization of insulin-loaded Pluronic F-127 gels for buccal delivery of basal insulin.

The principle of statistical optimization was employed to fabricate insulin-loaded Pluronic F-127 (PF-127) gel formulations having the potential for buccal delivery of basal insulin. A two-level resolution III fractional factorial design was applied to simultaneously evaluate five independent formulation variables: PF-127 concentration, insulin concentration, sodium sulfate concentration, hydroxypropylmethyl cellulose (HPMC) concentration, and presence of sodium glycocholate. The amount of insulin released and permeated from gels as well as gelation time and mucoadhesion force of gels were measured and used as dependent response variables for formulation optimization. Optimization of a gel formulation was achieved by applying constrained optimization via regression analysis. In vitro permeation flux of insulin from the optimized formulation through procine buccal mucosa was 93.17 (±0.058, n = 3) μg/cm2. Plasma insulin levels following buccal administration of the optimized formulation at 10, 25 and 50 IU/kg to healthy rats were found to be dose dependent and basal insulin levels were maintained at least for 8 h. Furthermore, continuous hypoglycemia for at least 8 h was observed with 89%, 51% and 25% of blood glucose reduction, respectively, for these three doses. The results of this investigation conclude the feasibility of development of optimized buccal insulin-loaded Pluronic F-127 gels for basal insulin delivery.

Development and evaluation of controlled release ibuprofen matrix tablets by direct compression technique

This investigation reports the development and evaluation of controlled release ibuprofen matrix tablets. Matrix tablets weighing 400 mg were fabricated by directly compressing ibuprofen (100 mg) with Eudragit RSPO and Avicel PH 101. The release of ibuprofen was dependant on concentration of Eudragit in the formulation. Varying Eudragit concentration from 10–50% of the formulation (in increments of 5%) revealed that in 4 h, tablets containing 50% Eudragit released about 40% ibuprofen compared to 100% released from tablets containing 10% Eudragit. Following analysis of release mechanism using various models available in literature, release of ibuprofen from matrix tablets was dominated by polymer diffusion-controlled mechanism at least for first 4 h. Thereafter, the release mechanism became more complicated and lost controlled release by diffusion due to change of tablet integrity, such as erosion of polymer matrix. In conclusion, controlled release ibuprofen matrix tablets with desired drug release rate can be fabricated by various formulation variables with direct compression technique.

Development and in vitro evaluation of insulin-loaded buccal Pluronic F-127 gels

Insulin-loaded buccal Pluronic F-127 (PF-127) gel formulations were fabricated to study the effect of PF-127 concentration, insulin concentration, presence of salt, addition of polymer, and permeation enhancer on their gelation time, mucoadhesion force, release and permeation characteristics of insulin from the gels. Thereafter, the principle of statistical optimization to prepare a gel formulation having the potential for buccal delivery of basal insulin in diabetic patients was employed. The gelation time decreased as the concentration of PF-127 increased. Presence of salts as well as addition of polymer, such as methyl cellulose (MC) and hydroxypropylmethyl cellulose (HPMC) decreased the gelation time. An increase in PF-127 concentration and addition of MC and HPMC increased the mucoadhesion force of the gel formulations. Release and permeation of insulin from the gel formulations decreased with increased concentration of PF-127, presence of salts, and addition of MC and HPMC. Permeation of insulin from the optimized gel formulation was 93.17 (+/- 0.058, n = 3) microg/cm(2) which was not only found in close agreement with predicted results from the model equations used for the formulation optimization but also considered comparable to clinical setting. Therefore, the development of optimized buccal insulin-loaded Pluronic F-127 gels using a statistical experimental design is feasible.

Elucidation of intestinal absorption mechanism of carvedilol-loaded solid lipid nanoparticles using Caco-2 cell line as an in-vitro model

Abstract Enhanced oral bioavailability of poorly aqueous soluble drugs encapsulated in solid lipid nanoparticles (SLNs) via lymphatic delivery has been documented. Since no in-vitro lymphoid tissue is currently available, human excised Caco-2 cell monolayer could be alternative tissue for development of an in-vitro model to be used as a screening tool before animal studies are undertaken. Therefore, optimized carvedilol-loaded SLNs (FOPT-SLNs) were prepared, characterized, and evaluated using Caco-2 cell line as an in-vitro model. Physical mixture of components of FOPT-SLNs (FOPT-PM) and carvedilol solution were used as control groups. From the studies of effect of SLNs concentration and cells incubation time, suitable carvedilol concentration and incubation time were selected for the model in which cells were subjected to five pretreatments for 24 h or 1 h of cell incubation and then followed with treatment of FOPT-SLNs, FOPT-PM or 100 µg/mL solution of carvedilol, for additional 24 h of cell incubation. The results obtained in this model suggest that main absorption mechanism of FOPT-SLNs could be endocytosis and, more specifically, clathrin-mediated endocytosis. When Transwell® permeable supports were used for the cells, carrier-mediated mechanism for FOPT-SLNs and passive absorption mechanism (transcellular and paracellular) for FOPT-PM and drug solution were concluded.