In vitro and in vivo evaluation of hydrophilic and hydrophobic polymers-based nicorandil-loaded peroral tablet compared with its once-daily commercial sustained-release tablet

Context: Hydrophilic and hydrophobic polymer-based nicorandil (10 mg)-loaded peroral tablets were prepared using the wet granulation technique. The influence of varying amounts of hydroxypropyl methylcellulose (HPMC) (30–50 mg), ethylcellulose (2–4 mg), microcrystalline cellulose (5–20 mg) and Aerosil^® (5–12 mg) in conjunction with the constant amounts (3 mg) of glidant and lubricant (magnesium stearate and talc) on the in vitro performances of the tablets (hardness, friability, weight variation, thickness uniformity, drug content, and drug release behavior) were investigated. Objective: The objectives of this study were (i) to select a nicorandil-loaded peroral tablet that matched the in vitro dissolution profile of once-daily commercial sustained-release tablet, and (ii) to compare the in vivo sustaining/controlling efficacy of the selected peroral tablet with that of its commercial counterparts. Results and Discussion: Because the nicorandil (10 mg)-loaded tablet prepared based on F-IX composition (50 mg HPMC, 4 mg ethylcellulose, 10 mg MCC and 3 mg glidant and lubricant) showed a release profile comparable to that of the Nikoran^® OD SR tablet release profile, the tablet with this composition was considered to be the optimized/selected formulation and, therefore, was subjected to stability study and in vivo study in rabbits. Despite of the higher C_max and AUC values obtained with the optimized tablet, there was no sign of difference between the optimized- and Nikoran^® OD SR- tablets following a single-dose crossover oral administration into rabbit. Conclusion: The optimized tablet could be used as an alternative to the commercial once-daily tablet.     

Nanocarrier-based topical drug delivery for an antifungal drug

Objective: The conventional liposomal amphotericin B causes many unwanted side effects like blood disorder, nephrotoxicity, dose-dependent side effects, highly variable oral absorption and formulation-related instability. The objective of the present investigation was to develop cost-effective nanoemulsion as nanocarreir for enhanced and sustained delivery of amphotericin B into the skin.

Methods and characterizations: Different oil-in-water nanoemulsions were developed by varying the composition of hydrophilic (Tween® 80) surfactants and co-surfactant by the spontaneous titration method. The developed formulation were characterized, optimized, evaluated and compared for the skin permeation with commercial formulation (fungisome 0.01% w/w). Optimized formulations loaded with amphotericin B were screened using varied concentrations of surfactants and co-surfactants as decided by the ternary phase diagram.

Results and discussion: The maximum % transmittance obtained were 96.9?±?1.0%, 95.9?±?3.0% and 93.7?±?1.2% for the optimized formulations F-I, F-III and F-VI, respectively. These optimized nanoemulsions were subjected to thermodynamic stability study to get the most stable nanoemulsions (F-I). The results of the particle size and zeta potential value were found to be 67.32?±?0.8 nm and –3.7?±?1.2?mV for the final optimized nanoemulsion F-I supporting transparency and stable nanoemulsion for better skin permeation. The steady state transdermal flux for the formulations was observed between 5.89?±?2.06 and 18.02?±?4.3?µg/cm²/h whereas the maximum enhancement ratio were found 1.85- and 3.0-fold higher than fungisome and drug solution, respectively, for F-I. The results of the skin deposition study suggests that 231.37?±?3.6?µg/cm² drug deposited from optimized nanoemulsion F-I and 2.11-fold higher enhancement ratio as compared to fungisome. Optimized surfactants and co-surfactant combination-mediated transport of the drug through the skin was also tried and the results were shown to have facilitated drug permeation and skin perturbation (SEM).

Conclusion: The combined results suggested that amphotericin B nanoemulsion could be a better option for localized topical drug delivery and have greater potential as an effective, efficient and safe approach.     

Silicone adhesive,a better matrix for tolterodine patches—a research based on in vitro/in vivo studies

Objective: To design and optimize a drug-in-adhesive (DIA) type transdermal patch for tolterodine (TOL) based on acrylic and silicone matrixes.

Methods: Initial in vitro studies were conducted to optimize the formulations. Two types of adhesive matrixes, drug loading, and enhancers were evaluated on the TOL transport across rabbit skin. For in vivo studies, patches were administered to rabbit abdominal skin. Pharmacokinetic assessments were performed based on plasma level of TOL up to 28?h for acrylic patch and 52?h for silicone patch after topical application.

Results: The final formulation of acrylic adhesive type patch consisted of 10% TOL (w/w) and 5.8?×?10^?4 mol isopropyl myristate (IPM) and 2.9?×?10^?4 mol Span 80 in per unit gram (mol/g) of adhesive, while 2.5% TOL (w/w) and 2.9?×?10^?4 mol/g IPM for silicone adhesive type patch. Comparison of the pharmacokinetic parameters between two types of patches showed that the steady-state concentration of silicone type patch was 2-fold higher than that of acrylic type patch being 0.97?mg/L versus 0.49?mg/L, and the absolute bioavailability was 27.5% for silicone type patch and 6.3% for acrylic type patch, respectively. In addition, the prediction of in vivo drug level from the in vitro permeation data of silicone adhesive formulation was in good agreement with actual observed concentration data in rabbits.

Conclusion: These results indicate that the silicone type of TOL patch is an appropriate delivery system for the treatment of overactive bladder (OAB).     

Vitamin B12 buccoadhesive tablets: auspicious non-invasive substitute for intra muscular injection: formulation,in vitro and in vivo appraisal

Attempting to prepare a convenient bioavailable formulation of vitamin B₁₂ (cyanocobalamin), 17 tablet formulations were prepared by direct compression. Different concentrations of hydroxypropyl methyl cellulose (HPMC), carbopol 971p (CP971p), and chitosan (Cs) were used. The tablets were characterized for thickness, weight, drug content, hardness, friability, surface pH, in vitro drug release, and mucoadhesion. Kinetic analysis of the release data was conducted. Vitamin B₁₂ bioavailability from the optimized formulations was studied on rabbits by the aid of enzyme-linked immunosorbent assay. Neurotone^® I.M. injection was used for comparison. HPMC (F1-F4), CP971p (F5-F8), and HPMC/CP971p (F12-F15)-based formulations showed acceptable mechanical properties. The formulated tablets showed maximum swelling indices of 232?±?0.13. The surface pH values ranged from 5.3?±?0.03 to 6.6?±?0.02. Bioadhesive force ranged from 66?±?0.6 to 150?±?0.5?mN. Results showed that CP971p-based tablets had superior in vitro drug release, mechanical, and mucoadhesive properties. In vitro release date of selected formulations were fitted well to Peppas model. HPMC/CP971p-based formulations showed bioavailability up to 2.7-folds that of Neurotone^® I.M. injection.     

Evaluation of hydrophilic,hydrophobic and waxy matrix excipients for sustained release tablets of Venlafaxine hydrochloride

Objective: Venlafaxine is freely soluble In water and administered orally as hydrochloride salt In two to three divided doses. In the present investigation different release retarding matrices have been evaluated for sustained release of venlafaxine hydrochloride (VH) from the formulated tablets.

Materials and methods: Sustained release matrix tablets were formulated using different hydrophilic, hydrophobic and waxy materials as matrix formers. Tableting was done by pre-compression, direct compression and hot melt granulation depending on the type of matrix material used and evaluated for different tests. The formulated tablets were compared with commercial venlafaxine products. In vitro drug dissolution profiles were fitted In different mathematical models to elucidate the release mechanism.

Results: Dissolution data showed that commercial formulations Venlor XR^® and Venfax PR^® released the entire drug withIn 8?h where as the formulated tablets with hydroxypropylmethylcellulose (HPMC) and cetyl alcohol as matrix formers provided sustained release of drug for 14–15?h. The release was found to follow Hixson Crowel and Higuchi kinetics for HPMC and cetyl alcohol tablets, respectively.

Conclusion: The developed matrix tablet formulations with HPMC and cetyl alcohol provided sustained release profiles for prolonged periods than commercial formulations.     

Preparation and evaluation of valsartan by a novel semi-solid self-microemulsifying delivery system using Gelucire 44/14

The aim of the present study was to develop a novel semi-solid self-microemulsifying drug delivery system (SMEDDS) using Gelucire^® 44/14 as oil with strong solid character to improve the oral bioavailability of poorly soluble drug valsartan. The solubility of valsartan in various excipients was determined, the pseudo-ternary phase diagram was constructed in order to screen the optimal excipients, and DSC analysis was performed to evaluate the melting point of SMEDDS. The optimal drug-loaded SMEDDS formulation was consisted of 30% Gelucire^® 44/14 (oil), 40% Solutol^® HS 15 (surfactant), and 30% Transcutol^® P (cosurfactant) (w/w) with 80?mg valsartan/g excipients. The average droplet sizes of the optimized blank and drug-loaded SMEDDS formulations were 26.20?±?1.43 and 33.34?±?2.15?nm, and the melting points of them were 35.6 and 36.8?°C, respectively. The in vitro dissolution rate of optimal semi-solid SMEDDS was increased compared with commercial capsules, resulting in the 2.72-fold and 2.97-fold enhancement of C_max and AUC_0–t after oral administration in rats, respectively. These results indicated that the novel semi-solid SMEDDS formulation could potentially improve the oral bioavailability of valsartan, and the semi-solid SMEDDS was a desirable system than the traditional liquid SMEDDS because it was convenient for preparation, storage and transportation due to semi-solid state at room temperature and melted state at body temperature.     

Development of a HPMC-based controlled release formulation with hot melt extrusion (HME)

The objective of this study was to develop hydroxypropyl methylcellulose (HPMC) based controlled release (CR) formulations via hot melt extrusion (HME) with a highly soluble crystalline active pharmaceutical ingredient (API) embedded In the polymer phase. HPMC is considered a challenging CR polymer for extrusion due to its high glass transition temperature (T_g), low degradation temperature, and high viscosity. These problems were partially overcome by plasticizing the HPMC with up to 40% propylene glycol (PG). Theophylline was selected as the model API. By using differential scanning calorimetry (DSC), thermal gravimetric analysis (TGA), dynamic mechanical analysis (DMA), and X-ray powder diffraction (XRPD), the physical properties of the formulations were systematically characterized. Five grades of HPMC (Methocel^®) – E6, K100LV, K4M, K15M, and K100M – were tested. The extrusion trials were conducted on a 16?mm twIn screw extruder with HPMC/PG placebo and formulations containing theophylline/HPMC/PG (30:42:28, w/w/w). The dissolution results showed sustained release profiles without burst release for the HPMC K4M, K15M, and K100M formulations. The extrudates have good dissolution stability after being stressed for 2 weeks under 40°C/75% RH open dish conditions and the crystalline API form did not change upon storage. Overall, the processing windows were established for the HPMC based HME-CR formulations.     

Biopharmaceutical characterization of decursin and their derivatives for drug discovery

Angelica gigas Nakai and its components are known to have neuroprotective, antiplatelet, and anticancer activities. The present study evaluated the in vitro and in vivo biopharmaceutical characterization of Angelica gigas component substances, including decursin (the main substance), decursinol angelate (decursin isomer), JH714 (ether form of decursin) and epoxide decursin (epoxide form of decursin). Decursin, decursinol angelate and JH714 exhibited acceptable metabolic stability (>50%) in liver microsomes from human and higher bound fraction (>90%) in human plasma operating ultrafiltration. Decursin and decursinol angelate in CYP1A2 and CYP2C19 indicated less than 50% CYP activity, suggesting inhibition of the CYP isoforms using Vivid^® CYP screening kit. JH714 only showed an apparent permeability coefficient of <10?×?10^?6 cm/s in MDCK cells, suggesting that it is poorly absorbed. Blood brain barrier permeability was examined after oral administration to male Sprague–Dawley (SD) rats, and pharmacokinetic studies were performed after oral and intravenous administration of 10?mg/kg compounds. Decursin, decursinol angelate and JH714 showed ratios of compound concentration in brain with respect to plasma (C_brain/C_plasma) of >1.5, suggesting good brain/plasma ratio at 0.5, 1, 3, and 5?h. In contrast, C_brain/C_plasma was <0.5 for epoxide decursin. For all test compounds, >1.5% of the dose remained in GI tract after 8?h, and the excretion rate in urine was <0.5% which suggests that gastro intestinal tract may be major site of disposition following oral administration. Finally, these results may be useful for the design of dosage regimens of decursin and its derivatives.     

New sustained release of Zidovudine Matrix tablets − cytotoxicity toward Caco-2 cells

Objective: The aim of this study was to adjust the zidovudine (AZT) release from solid tablets to an ideal profile, by developing matrices comprising swellable polymers with nonswellable ones.

Methods: Directly compressed matrices comprised different ratios of hydroxypropylmethylcellulose K15M and K100M, ethylcellulose, and methacrylic acid (Eudragit^® RS PO and Eudragit^® RL PO) were prepared. Technological characterization and evaluation of the in vitro release behavior were carried out. Cell density and viability following drug exposure were evaluated by the SRB method, for the Caco-2 line, while cell morphology was assessed upon Trypan blue staining.

Results: A specific formulation containing 5% of each excipient ? HPMC K15M, HPMC K100M, Eudragit^® RS PO, and Eudragit^® RL PO ? was found to yield the best release profile. Application of the Korsmeyer–Peppas model to the dissolution profile evidenced that a non-Fickian (anomalous) transport is involved in the drug release. Regarding the influence of the tablets’ composition on the drug’s cytotoxic effect toward the Caco-2 cell line, a reduction of cell biomass (0–15%) was verified for the distinct AZT formulations tested, F19 having displayed the highest cytotoxicity, after 24 and 48?h of incubation. Additionally, a high reversibility of the AZT effect was observed.

Conclusions: The results showed that the simultaneous application of both hydrophilic and hydrophobic polymers can modulate the drug release process, leading to an improved efficacy and patient compliance. All AZT formulations studied were found to be cytotoxic against Caco-2 cells, F19 being the most effective one.     

Influence of Hydroxypropyl Methylcellulose Mixture,Apparent Viscosity,and Tablet Hardness on Drug Release Using a 23 Full Factorial Design

ABSTRACT

This study investigates the effects of three factors: (1) use of a mixture of two different grades of hydroxypropyl methylcellulose (HPMC), (2) apparent viscosity, and (3) tablet hardness on drug release profiles of extended-release matrix tablets. The lot-to-lot apparent viscosity difference of HPMC K15M on in vitro dissolution was also investigated. Four test formulations were made, each containing 10% of a very water-soluble active pharmaceutical ingredient (API), 32% HPMC K15M, or a mixture of HPMC K100LV and HPMC K100M, 56% diluents, and 2% lubricants. Each formulation was made at two hardness levels. A 2³ full factorial design was used to study various combinations of the three factors using eight experiments conducted in a randomized order. Dissolution studies were performed in USP apparatus I. The values of t_50% (time in which 50% drug is released) and t_lag (lag time, the time taken by the matrix tablet edges to get hydrated and achieve a state of quasi-equilibrium before erosion and the advance of solvent front through the matrix occur) were calculated from each dissolution profile. The similarity factor (f₂) was also calculated for each dissolution profile against the target dissolution profile. A simple Higuchi-type equation was used to analyze the drug release profiles. Statistical analysis using analysis of variance (ANOVA) and similarity factor (f₂) values calculated from the data indicated no significant difference among the t_50% values and dissolution profiles respectively for all formulations. Within the 3.3–6 kp hardness range investigated, dissolution rates were found to be independent of tablet hardness for all the formulations. Although significantly shorter lag times were observed for the tablets formulated with low- and high-viscosity HPMC mixtures in comparison to those containing a single grade of HPMC, this change had no significant impact on the overall dissolution profiles indicated by the similarity factor f₂ values. From this study it can be concluded that lot-to-lot variability in apparent viscosity of HPMC should not be a concern in achieving similar dissolution profiles. Also, results indicated that within the viscosity range studied (12,000–19,500 cps) an HPMC mixture of two viscosity grades can be substituted for another HPMC grade if the apparent viscosity is comparable. Also, the drug release is diffusion-controlled and depends mostly on the viscosity of the gel layer formed.     

Development of Near Zero-Order Release Dosage Forms Using Three-Dimensional Printing (3-DP™) Technology

ABSTRACT

Three near zero-order controlled-release pseudoephedrine hydrochloride (PEH) formulations demonstrating proportional release rates were developed using 3-Dimensional Printing (3-DP?) technology. Mixtures of Kollidon SR and hydroxypropylmethyl cellulose (HPMC) were used as drug carriers. The release rates were adjusted by varying the Kollidon SR-HPMC ratio while keeping fabrication parameters constant. The dosage forms were composed of an immediate release core and a release rate regulating shell, fabricated with an aqueous PEH and an ethanolic triethyl citrate (TEC) binder, respectively. The dosage form design called for the drug to be released via diffusional pathways formed by HPMC in the shell matrix. The release rate was shown to increase correspondingly with the fraction of HPMC contained in the polymer blend. The designed formulations resulted in dosage forms that were insensitive to changes in pH of the dissolution medium, paddle stirring rate, and the presence/absence of a sinker. The near zero-order release properties were unchanged regardless of the dissolution test being performed on either single cubes or on a group of eight cubes encased within a gelatin capsule shell. The chemical and dissolution properties of the three formulations remained unchanged following 1 month's exposure to 25°C/60% RH or 40°C/75% RH environment under open container condition. The in vivo performance of the three formulations was evaluated using a single-dose, randomized, open-label, four-way crossover clinical study composed of 10 fasted healthy volunteers. The pharmacokinetic parameters were analyzed using a noncompartmental model. Qualitative rank order linear correlations between in vivo absorption profiles and in vitro dissolution parameters (with slope and intercept close to unity and origin, respectively) were obtained for all three formulations, indicating good support for a Level A in vivo/in vitro correlation.     

Prediction of in vivo plasma concentration–time profile from in vitro release data of designed formulations of milnacipran using numerical convolution method

The aim of this study was to predict the in vivo plasma drug level of milnacipran (MIL) from in vitro dissolution data of immediate release (IR 50?mg and IR 100?mg) and matrix based controlled release (CR 100?mg) formulations. Plasma drug concentrations of these formulations were predicted by numerical convolution method. The convolution method uses in vitro dissolution data to derive plasma drug levels using reported pharmacokinetic (PK) parameters of a test product. The bioavailability parameters (C_max and AUC) predicted from convolution method were found to be 106.90?ng/mL, 1138.96?ng/mL?h for IR 50?mg and 209.80?ng/mL, 2280.61?ng/mL?h for IR 100?mg which are similar to those reported in the literature. The calculated PK parameters were validated with percentage predication error (% PE). The % PE values for C_max and AUC were found to be 7.04 and ?7.35 for IR 50?mg and 11.10 and ?8.21 for IR 100?mg formulations. The C_max, T_max, and AUC for CR 100?mg were found to be 120?ng/mL, 10?h and 2112.60?ng/mL?h, respectively. Predicted plasma profile of designed CR formulation compared with IR formulations which indicated that CR formulation can prolong the plasma concentration of MIL for 24?h. Thus, this convolution method is very useful for designing and selection of formulation before animal and human studies.     

Spray-dried high-amylose sodium carboxymethyl starch: impact of α-amylase on drug-release profile

Spray-dried high-amylose sodium carboxymethyl starch (SD HASCA) is a promising pharmaceutical excipient for sustained-release (SR) matrix tablets produced by direct compression. The presence of α-amylase in the gastrointestinal tract and the variations of the gastric residence time of non-disintegrating dosage forms may affect the presystemic metabolism of this excipient and, consequently, the drug-release profile from formulations produced with SD HASCA. In this study, the influence of α-amylase and the residence time in acidic conditions on the drug-release profile was evaluated for a once-daily acetaminophen formulation (Acetaminophen SR) and a once-daily tramadol hydrochloride formulation (Tramadol SR). Both formulations were based on SD HASCA. α-Amylase concentrations ranging from 0?IU/L to 20000?IU/L did not significantly affect the drug-release profiles of acetaminophen and tramadol hydrochloride from SD HASCA tablets (f_2?>_?50) for all but only one of the studied conditions (f_2?=_?47). Moreover, the drug-release properties from both SD HASCA formulations were not significantly different when the residence time in acidic medium was 1?h or 3?h. An increase in α-amylase concentration led to an increase in the importance of polymer erosion as the main mechanism of drug-release instead of drug diffusion, for both formulations and both residence times, even if release profiles remained comparable. As such, it is expected that α-amylase concentration and residence time in the stomach will not clinically affect the performance of both SD HASCA SR formulations, even if the mechanism of release itself may be affected.     

Hydrogel containing dexamethasone-loaded nanocapsules for cutaneous administration: preparation,characterization, and in vitro drug release study

Context: Our group previously reported the development of dexamethasone-loaded polymeric nanocapsules as an alternative for topical dermatological treatments. Objective: Our study aimed to prepare and characterize a hydrogel containing this system to improve the effectiveness of the glucocorticoid for cutaneous disorders. Methods: For the antiproliferative activity assay, a dexamethasone solution and D-NC were tested on Allium cepa root meristem model. D-NC were prepared by the interfacial deposition of preformed polymer. Hydrogels were prepared using Carbopol Ultrez® 10 NF, as polymer, and characterized according to the following characteristics: pH, drug content, spreadability, viscosity, and in vitro drug release. Results and Discussion: Nanocapsules showed mean particle size and zeta potential of 201 ± 6 and ?5.73 ± 0.42 nm, respectively. They demonstrated a lower mitotic index (4.62%) compared to free dexamethasone (8.60%). Semisolid formulations presented acidic pH values and adequate drug content (between 5.4% and 6.1% and 100% and 105%, respectively). The presence of nanocapsules in hydrogels led to a decrease in their spreadability factor. Intact nanoparticles were demonstrated by TEM as well as by dynamic light scattering (mean particle size < 300 nm). In vitro studies showed a controlled dexamethasone release from hydrogels containing the drug associated to the nanocapsules following the Higuchi's squared root model (k = 20.21 ± 2.96 mg/cm²/h^1/2) compared to the hydrogels containing the free drug (k = 26.65 ± 2.09 mg/cm²/h^1/2). Conclusion: Taking all these results together, the hydrogel containing D-NC represent a promising approach to treat antiproliferative-related dermatological disorders.     

Development and evaluation of dexibuprofen formulation with fast onset and prolonged effect

In the present study, in order to improve the solubility and bioavailability of poorly water-soluble dexibuprofen, a novel dexibuprofen-loaded solid dispersion was developed using the spray-drying technique. The controlled-release dexibuprofen formulation was developed by combining the immediate-release dispersion powder and the sustained-release formula. The solid dispersion composed of dexibuprofen/poloxamer 407/hydroxypropyl methylcellulose (HPMC) 2910 (50?cps)/sodium lauryl sulfate (SLS) (10/1/4/0.1?mg) was selected as the immediate-release formulation due to its increased solubility and dissolution rate. This immediate-release formulation showed a significantly higher initial plasma concentration, AUC, and C_max of dexibuprofen than those of dexibuprofen powder. Based on the prolonged effect of high plasma concentration, the formulation consisting of dexibuprofen/ethylcellulose/HPMC 2910 (4000?cps)/magnesium stearate (66/16.5/16.5/1?mg) was selected as the sustained-release formulation. Finally, the controlled-release (CR) formulation was prepared by encapsulating the immediate-release and sustained-release formulations in hard gelatin capsules. The proposed CR formulation showed enhanced AUC (5.5-fold) and C_max (3.5-fold) compared to dexibuprofen powder. The results of the present study suggest that the CR formulation containing dexibuprofen may be a potential oral dosage form for a fast onset and a prolonged effect of poorly water-soluble dexibuprofen.     

Sustained-release of Cyclosporin A pellets: preparation,in vitro release,pharmacokinetic studies and in vitro–in vivo correlation in beagle dogs

The aim of this study was to develop Cyclosporin A (CsA) sustained-release pellets which could maintain CsA blood concentration within the therapeutic window throughout dosing interval and to investigate the in vitro–in vivo correlation (IVIVC) in beagle dogs. The CsA sustained-release pellets (CsA pellets) were prepared by a double coating method and characterized in vitro as well as in vivo. Consequently, the CsA pellets obtained were spherical in shape, with a desirable drug loading (7.18?±?0.17?g/100?g), good stability and showed a sustained-release effect. The C_max, T_max and AUC_0–24 of CsA pellets from the in vivo pharmacokinetics evaluation was 268.22?±?15.99?ng/ml, 6?±?0?h and 3205.00?±?149.55?ng·h/ml, respectively. Compared with Neoral®, CsA pellets significantly prolonged the duration of action, reduced the peak blood concentration and could maintain a relatively high concentration level till 24?h. The relative bioavailability of CsA pellets was 125.68?±?5.37% that of Neoral®. Moreover, there was a good correlation between the in vitro dissolution and in vivo absorption of the pellets. In conclusion, CsA pellets which could ensure a constant systemic blood concentration within the therapeutic window for 24?h were prepared successfully. Meanwhile, this formulation possessed a good IVIVC.     

Preparation and characterization of enteric microparticles by coacervation

The aim of this study was to produce cinnarizine loaded Eudragit^® L100-55 microparticles by coacervation technique in order to achieve pH responsive drug release using hydroxypropyl methycellulose (HPMC) as stabilizer. The effect of enteric polymer: HPMC ratio on properties of microparticles was investigated with regard to particle size distribution, morphology, yield, encapsulation efficiency, in vitro drug release profiles and interaction between cinnarizine and Eudragit^® L100-55. High drug encapsulation efficiency was seen in all microparticles. Particle diameter increased when the enteric polymer content was higher relative to HPMC. In vitro dissolution studies demonstrated that the drug release from the microparticles was dependent upon enteric polymer: HPMC ratio and particle size distribution. At the ratio of at least 3.75:1 of enteric polymer: HPMC, drug release was suppressed most significantly in low pH (hydrochloric acid as medium) while rapid drug release was observed in pH 7.4.     

The effect of lipid and aqueous solubilities on flux of nicotinic acid esters from water through silicone membrane

Objective: The maximum fluxes (J_M) of nicotinic acid esters (NAE) across silicone membranes from water (J_MPAQ) have been measured to determine how well they correlate with J_M of NAE across human skin from water in vitro (J_MHAQ) and in vivo (J_MHAQ1) and with J_M of NAE across hairless mouse skin from water (J_MMAQ).

Materials and methods: The NAE were all commercially available. Solubilities in water (S_AQ), isopropyl myristate (S_IPM) and octanol (S_OCT) were obtained from literature sources. J_MPAQ were measured at saturation for all the esters except the methyl ester. In that case, flux was measured at a concentration (C) less than saturation (J_PAQ) and converted to J_MPAQ = (J_PAQ)(S_AQ/C_AQ).

Results and discussion: J_MPAQ values predicted from the previously reported coefficients to the parameters in the Roberts-Sloan (RS) equation (PRE J_MPAQ) were substantially lower than the experimental J_MPAQ values (EXP J_MPAQ) values obtained here. The EXP J_MPAQ were incorporated into the previous J_MPAQ database and new coefficients were obtained: x = ?1.837; y = 0.742; z = 0.00435; r² = 0.86. Correlation of J_MPAQ values with J_MHAQ, J_MHAQ1, and J_MMAQ values show the same trend as the J_MPAQ values.

Conclusions: The inclusion of the NAE n = 6 data into the previous n = 32 database for the permeation of the prodrugs through a silicone membrane from water (J_MPAQ) greatly improved the fit of the n = 38 database to the RS equation: r² = 0.86 vs r² = 0.77. The correlation between log J_MHAQ and log J_MPAQ gave r² = 0.98. This suggests that J_MPAQ values are good predictors of J_MHAQ values.     

Antifungal ME1111 in vitro human onychopharmacokinetics

Abstract

This study determined ME1111 onychopharmacokinetics and possible topical antifungals’ clinical efficacy in human great toenails using an in vitro finite dose model. ME1111 topical formulations in 1, 5, 10 or 15% for 3 days observation and 1, 5 or 10% for 14 days observation, respectively, were used to determine ME1111 penetration rate and transungual kinetics. ME1111 concentrations in the deeper nail (ventral/intermediate layers) and a cotton pad/nail bed, were several orders of magnitude greater than MIC₉₀ and MFC₉₀ for three major dermatophytes. ME1111 concentrations 3 days after a single and 14 days after multiple dosing of 10% formulation were 253 and 7991?μg/g nail, respectively, and superior to those of 8% ciclopirox control. ME1111 concentration (μg equivalent/cm³) in the cotton pad following 10% ME1111 multiple applications increased linearly throughout the 336?h experiment and was significantly greater than that of 8% ciclopirox. Flux rate of ME1111 averaged as 50.9?μg/cm³/day, which was ca. two orders of magnitude greater than the MIC₉₀ values. The novel antifungal ME1111 penetrated well into human nail plate and its concentrations in the deeper nail and cotton pad after application of 10% formulation were significantly greater than those of ciclopirox.     

In vitro and in vivo investigation of taste-masking effectiveness of Eudragit E PO as drug particle coating agent in orally disintegrating tablets

Abstract

Context: Considering that bitter taste of drugs incorporated in orally disintegrating tablets (ODTs) can be the main reason for avoiding drug therapy, it is of the utmost importance to achieve successful taste-masking. The evaluation of taste-masking effectiveness is still a major challenge.

Objective: The objective of this study was to mask bitter taste of the selected model drugs by drug particle coating with Eudragit^® E PO, as well as to evaluate taste-masking effectiveness of prepared ODTs using compendial dissolution testing, dissolution in the small-volume shake-flask assembly and trained human taste panel.

Materials and methods: Model drugs were coated in fluidized bed. Disintequik? ODT was used as a novel co-processed excipient for ODT preparation. Selected formulations were investigated in vitro and in vivo using techniques for taste-masking assessment.

Results and discussion: Significantly slower drug dissolution was observed from tablets with coated drug particles during the first 3?min of investigation. Results of in vivo taste-masking assessment demonstrated significant improvement in drug bitterness suppression in formulations with coated drug. Strong correlation between the results of drug dissolution in the small-volume shake-flask assembly and in vivo evaluation data was established (R?≥?0.970).

Conclusion: Drug particle coating with Eudragit^® E PO can be a suitable approach for bitter taste-masking. Strong correlation between in vivo and in vitro results implicate that small-volume dissolution method may be used as surrogate for human panel taste-masking assessment, in the case of physical taste-masking approach application.