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.     

Structure and Dry Binding Activity of Different Polymers,Including Kollidon® VA 64

The dry binding activity of copolyvidone (Kollidon® VA 64), povidone (Kollidon® 30), microcrystalline cellulose (Avicel® PH-101), hydroxypropylmethylcellulose (HPMC) 2910 (Pharmacoat® 606), and maltodextrin (Maldex® 18) was investigated using a variety of formulations and methods. The effect of the dry binders in direct tableting and compaction was studied using a dicalcium phosphate formulation (water-insoluble ingredients) and a vitamin C formulation (water-soluble ingredients) applying three compression forces. The binder content was varied between 5% and 15% in both formulations, and the tablet properties were determined. All the tablets showed an improvement in mechanical properties (hardness, friability) with increasing dry binder concentration, with Kollidon VA 64 showing by far the greatest binding efficacy. A significant influence (prolongation) on drug release was observed only with HPMC 2910. The drying binding properties were analyzed for correlations with various powder and material properties. Especially, particle size, surface/surface structure, and plasticity were found to influence binding activity. The ideal dry binder should have small particles, high plasticity, and a large surface area.     

In vitro and in vivo evaluation of controlled-release matrix tablets of highly water-soluble drug applying different mw polyethylene oxides (PEO) as retardants

The aim of the work presented is to prepare a controlled-release hydrophilic matrix tablet (CMT) controlling release of highly water-soluble drug applying pure combination of high- and low-Mw PEO as matrix materials, to avoid the lag time of drug release, and to overcome incomplete release in later stages. The influences of types and amounts of different Mw PEOs used, drug loading, pH of release medium and agitation rate on drug release were evaluated. The study of uptake and erosion of matrix was conducted and mechanism of improving drug release was discussed. In vivo pharmacokinetics of the CMT and reference preparation self-made controlled-release osmotic pump tablets (COPT) were performed in beagle dogs. The optimized formulation containing 43% PEO WSR 303 and 32% PEO N750 showed a zero order release from 1?h to 12?h. In vivo results demonstrated that the CMT had similar AUC_0-48?h and C_max with the COPT but smaller T_max than the COPT and provided a more stable therapeutic concentration compared to the COPT. In conclusion, hydrophilic matrix tablet combining only different Mw PEOs as matrix materials had very good potential to be developed into a controlled-release drug delivery system for highly water-soluble drug. Besides, its manufacturing processes were succinct which would be preferable for modern medicine industry.     

Structure and dry binding activity of different polymers, including Kollidon VA 64

The dry binding activity of copolyvidone (Kollidon® VA 64), povidone (Kollidon® 30), microcrystalline cellulose (Avicel® PH-101), hydroxypropylmethylcellulose (HPMC) 2910 (Pharmacoat® 606), and maltodextrin (Maldex® 18) was investigated using a variety of formulations and methods. The effect of the dry binders in direct tableting and compaction was studied using a dicalcium phosphate formulation (water-insoluble ingredients) and a vitamin C formulation (water-soluble ingredients) applying three compression forces. The binder content was varied between 5% and 15% in both formulations, and the tablet properties were determined. All the tablets showed an improvement in mechanical properties (hardness, friability) with increasing dry binder concentration, with Kollidon VA 64 showing by far the greatest binding efficacy. A significant influence (prolongation) on drug release was observed only with HPMC 2910. The drying binding properties were analyzed for correlations with various powder and material properties. Especially, particle size, surface/surface structure, and plasticity were found to influence binding activity. The ideal dry binder should have small particles, high plasticity, and a large surface area.     

Preparation and pharmacokinetics study on gastro-floating sustained-release tablets of troxipide

The purpose of this research aimed at preparing gastro-floating sustained-release tablets of troxipide and a further study on in vitro release and in vivo bioavailability. Under the circumstances of direct powder compression, the floating tablets were successfully prepared with HPMC as main matrix material, Carbopol as assistant matrix material, octadecanol as floating agent and sodium bicarbonate as foaming agent to float by gas-forming. The floating time and accumulative release amount as evaluation indexes were utilized to perform pre-experiment screening and single-factor test, respectively, while central composite design response surface method was applied for formulation optimization, followed by in vivo pharmacokinetic study in beagles after oral administration for floating tablets and commercial tablets used as the control. The results indicated that the floating sustained-release tablets held a better capability for floating and drug release and more satisfactory pharmacokinetic parameters, such as a lower C_max, a prolonged T_max, but an equivalent bioavailability calculated by AUC_0–24 compared to commercial tablets. So a conclusion was finally drawn that the floating sustained-release tablets possessing a good release property could be suitable for demands of design.     

A new self-microemulsifying mouth dissolving film to improve the oral bioavailability of poorly water soluble drugs

A new self-microemulsifying mouth dissolving film (SMMDF) for poorly water-soluble drugs such as indomethacin was developed by incorporating self-microemulsifying components with solid carriers mainly containing microcrystalline cellulose, low-substituted hydroxypropyl cellulose and hypromellose. The uniformity of dosage units of the preparation was acceptable according to the criteria of Chinese Pharmacopoeia 2010. The SMMDF was disintegrated within 20 s after immersion into water, released completely at 5?min in the dissolution medium and achieved microemulsion particle size of 28.81?±?3.26?nm, which was similar to that of liquid self- microemulsifying drug delivery system (SMEDDS). Solid state characterization of the SMMDF was performed by SEM, DSC and X-ray powder diffraction. Results demonstrated that indomethacin in the SMMDF was in the amorphous state, which might be due to self-microemulsifying ingredients. Pharmacokinetic parameters in rats including T_max, C_max, AUC were similar between the SMMDF and liquid SMEDDS. AUC and C_max from the SMMDF were significantly higher than those from the common mouth dissolving film or the conventional tablet, and T_max from SMMDF group was also significantly decreased. These findings suggest that the SMMDF is a new promising dosage form, showing notable characteristics of convenience, quick onset of action and enhanced oral bioavailability of poorly water-soluble drugs.     

Preliminary evaluation of the in vitro release and in vivo absorption in rabbits of the modified-release dosage forms

Objective: The suitability of the rabbit as an animal model for the primary screening and selection of the pilot scale batches during the early stages of the formulation development was studied.

Materials and methods: Three modified-release formulations of aminophylline consisted of Carbopol® 971P/HPMC K4M (F-I), and HPMC K100M (F-II) or HPMC K4M (F-III) were used. Commercial products were Aminofilin retard 350?mg tablets, Srbolek, Serbia (R-I) and Phyllocontin^® 350, tablets Purdue Frederic, Canada (R-II).

Results: Calculated release rate constants and the ?2 values between R-I/F-I (84.1) and R-II/F-III (83.4) indicated similar in vitro release while the coefficient n showed presence of different mechanisms of release from Anomalous transport, Fickian diffusion to Case-II transport. Higher T_max, was found in the rabbits, dosed with F-II (12.00?h), F-III (10.50?h), and R-II (15.00?h) formulation. The highest C_max (9.22?mg/L) was obtained with F-II, similar lower values was seen for F-I and F-III, while commercial products showed the lowest values R-I (5.58?mg/L) and R-II (4.18?mg/L). Higher AUC values were detected for all three formulations (from 115.90 to 204.06 mgh/L) in relation to commercial products (105.33 and 113.25 mgh/L).

Discussion and conclusion: The results demonstrated a good correlation of Level A (r² = 0.97) for the two formulations (F-I, F-III) and commercial product (R-I) indicates that there is a reasonable assumption that the rabbit might be use as a model for the preliminary comparison of scale up formulations in the early stages of the product development.     

Preparation and IVIVC evaluation of salvianolic acid B micro-porous osmotic pump pellets

Purpose: Salvianolic acid B micro-porous osmotic pump controlled release pellets (SalB-CRPs) with suitable in vitro release profiles and good in vitro and in vivo correlation (IVIVC) were developed.

Method: Extrusion-spheronization was used to prepare the starter cores containing SalB/MCC/Kollidon®CL-SF/Flowlac®100 of 30:40:15:15 [w/w, The formulation composition of SalB immediate-release pellets (SalB-IRPs)] and complexed with lactose. The pellets were subsequently coated with Surelease aqueous dispersion to achieve controlled-release properties. Furthermore, a single-dose pharmacokinetics study was carried out in New Zealand White (NZW) rabbits.

Results: In the starter cores, the lactose content was 25% based on the SalB-IRPs constituent. The optimal coating polymer ratio of Surelease aqueous dispersion and polyvinyl alcohol–polyethylene glycol (PVA–PEG) graft copolymer (EC/PVA–PEG) was found to be 70:30 (w/w, %) with a coating weight of 5%. The prepared SalB-CRPs had similar in vitro release under three different pH release mediums. A good IVIVC was characterized by a high coefficient of determination (r?=?0.9801). The in vivo study indicated that the maximum plasma concentration (C_max) of SalB-CRPs was decreased, peak concentration time (T_max) and mean residence time (MRT) were all prolonged, as that of SalB-IRPs. In addition, the area under concentration–time curve from 0 to 24?h (AUC_0–24?h) and 0 to infinity (AUC_0–∞) were significantly higher, compared with those of SalB-IRPs.

Conclusion: Collectively, these results manifested that SalB-CRPs were likely to be a more suitable formulation in treating cardiovascular disease with improved in vivo retention, decreased plasma drug concentration fluctuation.     

In vitro evaluation and in vivo performance of lyophilized gliclazide

Enhancement of the dissolution rate of the poorly water-soluble hypoglycemic agent, gliclazide, by the aid of lyophilization was investigated. Mannitol, sodium lauryl sulfate (SLS) and polyvinyl pyrrolidone (PVP-k-30) were employed in different weight ratios (43%, 56% and 64% w/w, respectively) as water-soluble excipients in the formulation. Lyophilized systems were found to exhibit extremely higher in vitro dissolution rate compared to the unprocessed drug powder. Solid state characterization of the lyophilized systems using X-ray powder diffraction, Fourier transform infrared spectroscopy and differential scanning calorimetry techniques revealed that dissolution enhancement was attributable to transformation of gliclazide from the crystalline to an amorphous state in the solid dispersion formed during the lyophilization process. The gastrointestinal absorption and hypoglycemic effect of the lyophilized gliclazide/SLS system were investigated following oral administration to Albino rabbits. C_max and area under the plasma concentration–time curve of gliclazide (AUC_0–12) after administration of the lyophilized formulations were significantly higher than those obtained after administration of the unprocessed gliclazide.     

Effect of aminoalkyl methacrylate copolymer E/ HCl on in vivo absorption of poorly water-soluble drug

This study aimed to investigate in vivo absorption of tacrolimus formulated as a solid dispersion using Eudragit E^®/HCl (E-SD). E-SD is an aminoalkyl methacrylate copolymer that can be dissolved under neutral pH conditions. E-SD was used alone as a solid dispersion carrier and/or was mixed with tacrolimus primarily dispersed with hydroxypropylmethylcellulose (HPMC). Tacrolimus was formulated with E-SD at several different ratios. Formulations with tacrolimus/E-SD ratio of 1/3 showed higher in vivo absorption, compared to tacrolimus dispersed in the excipients (primarily HPMC) found in commercially available tacrolimus capsules, using a rat in situ closed loop method. Good correlation was observed between in vitro drug solubility and in vivo drug absorption. In vitro solubility tests and rat oral absorption studies of tacrolimus/HPMC solid dispersion formulations were also conducted after mixing the HPMC dispersion with several ratios of E-SD. E-SD/tacrolimus/HPMC formulations yielded high in vitro drug solubility but comparatively low in vivo absorption. Dog oral absorption studies were conducted using capsules containing a formulation of tacrolimus/E-SD at a ratio of 1/5. The E-SD formulation-containing capsule showed higher in vivo drug absorption than tacrolimus dispersed in the standard HPMC capsule. These studies report enhancement of the in vivo absorption of a poorly water-soluble drug following dispersion with E-SD when compared to formulation in HPMC.     

Preparation of fenofibrate immediate-release tablets involving wet grinding for improved bioavailability

Objective: The purpose of this study was to investigate the dissolution and oral bioavailability of an immediate-release tablet involving wet grinding of a poorly water-soluble drug, fenofibrate. Methods: The milled suspension was prepared using a Basket Dispersing Mill in the presence of a hydrophilic polymer solution and then granulated with common excipients, and compressed into an immediate-release tablet with blank microcrystalline cellulose granules. Results: Compared with unmilled tablets (56% within 30 minutes), the dissolution of wet-milled tablets (about 98% in 30 minutes) was markedly enhanced. No significant decrease in the dissolution rate (96% in 30 minutes) of the wet-milled tablet was observed after 3 months under 40°C and 75% relative humidity storage. In addition, the oral bioavailability of the wet-milled tablets (test) and Lipanthyl® supra-bioavailability tablets (reference) was determined in beagle dogs after a single dose (160 mg fenofibrate) in a randomized crossover, own-control study. The results suggested that both the area under the plasma concentration–time curve (AUC_(0?t) = 46.83 ± 11.09 μg/mL h) and the mean peak concentration of the test (C_max = 4.63 ± 1.71 μg/mL) were higher than the reference (AUC_(0?t) = 35.12 ± 10.97 μg/mL h, C_max = 2.11 ± 0.08 μg/mL). The relative bioavailability of the wet-milled tablet was approximately 1.3-fold higher. Furthermore, the apparent rate of absorption of fenofibrate from the wet-milled tablet (T_max = 2.63 hours) was faster than that from Lipanthyl® (T_max = 3.75 hours). Conclusion: These results indicated that the dissolution and the bioavailability of fenofibrate were significantly enhanced by wet-grinding process. So, this shows that wet grinding is a powerful technique to improve the bioavailability for poorly water-soluble drugs, especially for Biopharmaceutics Classification System Class II compounds.     

Study of controlled-release floating tablets of dipyridamole using the dry-coated method

Dipyridamole (DIP), having a short biological half-life, has a narrow absorption window and is primarily absorbed in the stomach. So, the purpose of this study was to prepare controlled-release floating (CRF) tablets of dipyridamole by the dry-coated method. The influence of agents with different viscosity, hydroxypropylmethylcellulose (HPMC) and polyvinylpyrollidon K30 (PVP K30) in the core tablet and low-viscosity HPMC and PVP K30 in the coating layer on drug release, were investigated. Then, a study with a three-factor, three-level orthogonal experimental design was used to optimize the formulation of the CRF tablets. After data processing, the optimized formulation was found to be: 80?mg HPMC K4M in the core tablet, 80?mg HPMC E15 in core tablet and 40?mg PVP K30 in the coating layer. Moreover, an in vitro buoyancy study showed that the optimized formulation had an excellent floating ability and could immediately float without a lag time and this lasted more than 12?h. Furthermore, an in vivo gamma scintigraphic study showed that the gastric residence time of the CRF tablet was about 8?h.     

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.     

Formulation and pharmacokinetics of gelucire solid dispersions of flurbiprofen

Context: Development of solid dispersions is to improve the therapeutic efficacy by increasing the drug solubility, dissolution rate, bioavailability as well as to attain rapid onset of action.

Objective: The present research deals with the development of solid dispersions of flurbiprofen which is poorly water soluble to improve the solubility and dissolution rate using gelucires.

Materials and methods: In this study, solid dispersions were prepared following solvent evaporation method using gelucire 44/14 and gelucire 50/13 as carriers in different ratios. Then the formulations were evaluated for different physical parameters, solubility studies, DSC, FTIR studies and in vitro dissolution studies to select the best formulation that shows rapid dissolution rate and finally subjected to pharmacokinetic studies.

Results and discussion: From the in vitro dissolution study, formulation F3 showed the better improvement in solubility and dissolution rate. From the pharmacokinetic evaluation, the control tablets produced peak plasma concentration (C_max) of 9140.84?±?614.36?ng/ml at 3?h T_max and solid dispersion tablets showed C_max?=?11?445.46?±?149.23?ng/ml at 2?h T_max. The area under the curve for the control and solid dispersion tablets was 31?495.16?±?619.92 and 43?126.52?±?688.89?ng h/ml and the mean resident time was 3.99 and 3.68?h, respectively.

Conclusion: From the above results, it is concluded that the formulation of gelucire 44/14 solid dispersions is able to improve the solubility, dissolution rate as well as the absorption rate of flurbiprofen than pure form of drug.     

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.     

Preparation,characterization and in vitro and in vivo evaluation of a solid dispersion of Naringin

Naringin (NA) is one of typical flavanone glycosides widely distributed in nature and possesses several biological activities including antioxidant, anti-inflammatory, and antiapoptotic. The aim of this study was to develop solid dispersion (SD) and to improve the dissolution rate and oral bioavailability of NA. NA–SD was prepared by the traditional preparation methods using PEG6000, F68, or PVP K30 as carrier at different drug to carrier ratios. According to the results of solubility and in vitro dissolution test, the NA–PEG6000 (1:3) SD was considered as an optimal formulation to characterize by Fourier transform infrared spectroscopy (FT-IR), differential scanning calorimetry and powder X-ray diffraction. Furthermore, oral bioavailabilities of NA–PEG6000 (1:3) SD and NA–suspension with the same dosage were investigated in SD rats. The results confirmed the formation of SD and the pharmacokinetic parameters of NA–PEG6000 (1:3) SD (C_max?=?0.645?±?0.262?µg/ml, AUC_0–t?=?0.471?±?0.084?µg/ml?h) were higher than that of NA–suspension (C_max?=?0.328?±?0.183?µg/ml, AUC_0–t =?0.361?±?0.093?µg/ml?h). Based on the results, the SD is considered as a promising approach to enhance the dissolution rate and oral bioavailability of NA.     

Design,preparation, and evaluation of liposomal gel formulations for treatment of acne: in vitro and in vivo studies

The study highlights the significance of co-application of bioactive components into liposomal gel formulations and their comparison to azithromycin for treatment of Acne. A Design of Experiments (DoE) approach was utilized to obtain optimized liposomal formulation encapsulating curcumin, with size and zeta potential of ～100?nm and ～14?mV, respectively, characterized by DLS, HR-TEM, FESEM, and AFM. The curcumin liposomal dispersion depicted excellent stability over the period of 60?days, which was further converted in gel form using Carbopol. Pharmacokinetics of curcumin-loaded liposomal gel showed that T_max for curcumin was achieved within 1?h of post application in both stratum corneum and skin, indicating quick penetration of nano-sized liposomes. Stratum corneum depicted C_max of 688.3?ng/mL and AUC_0-t of 5857.5?h?×?ng/mL, while the skin samples displayed C_max of 203.3?ng/gm and AUC_0-t of 2938.1?h?×?ng/gm. Lauric acid and azithromycin liposomal gel formulations were prepared as per the optimum parameters obtained by DoE. In antibacterial activity using agar diffusion assay, lauric acid gel formulation revealed ～1.5 fold improved antibacterial effect than curcumin gel formulation. Interestingly, their co-application (1:1) exhibited significantly enhanced antibacterial effect against both macrolide-sensitive (1.81 versus 1.25 folds) and resistant strains of P. acnes (2.93 versus 1.22 folds) than their individual counterparts. The in vivo studies in rat ear model displayed a ～2 fold reduction in comedones count and cytokines (TNF-α and IL-1β) on co-application with curcumin and lauric acid liposomal gel compared to placebo treated group.     

Preparation and evaluation of a sustained-release formulation of nifedipine HPMC tablets

A nifedipine (NF) polyethylene glycol (PEG) solid dispersion was prepared. Using this solid dispersion, NF hydroxypropylmethylcellulose (HPMC) matrix tablets were prepared. Both the high-viscosity grade HPMC (Methocel K15M) and low-viscosity grade HPMC (Methocel K100) were applied in the tablets to form the matrix. The dissolution and absorption of NF from the tablet were evaluated as a formulation that had a sustained release over 24 hr. The Hixson-Crowell equation and Higuchi equation were used to investigate the dissolution mechanism, and the erosion and diffusion codependent mechanism was established. Adalat GITS 30 was used as a reference dosage form. Each beagle dog was also administered an intravenous injection to obtain the pharmacokinetics parameters. The Loo-Riegelman method was applied to study the in vitro/in vivo correlation of the tested tablets and Adalat GITS 30, and significant correlation was proved. Absolute bioavailability and comparative bioavailability of the tested tablet were studied. The results indicated that the NF HPMC tablet could be an ideal 24-hr sustained-release formulation.     

Preparation and Evaluation of a Sustained-Release Formulation of Nifedipine HPMC Tablets

A nifedipine (NF) polyethylene glycol (PEG) solid dispersion was prepared. Using this solid dispersion, NF hydroxypropylmethylcellulose (HPMC) matrix tablets were prepared. Both the high-viscosity grade HPMC (Methocel K15M) and low-viscosity grade HPMC (Methocel K100) were applied in the tablets to form the matrix. The dissolution and absorption of NF from the tablet were evaluated as a formulation that had a sustained release over 24 hr. The Hixson-Crowell equation and Higuchi equation were used to investigate the dissolution mechanism, and the erosion and diffusion codependent mechanism was established. Adalat GITS 30 was used as a reference dosage form. Each beagle dog was also administered an intravenous injection to obtain the pharmacokinetics parameters. The Loo-Riegelman method was applied to study the in vitro/in vivo correlation of the tested tablets and Adalat GITS 30, and significant correlation was proved. Absolute bioavailability and comparative bioavailability of the tested tablet were studied. The results indicated that the NF HPMC tablet could be an ideal 24-hr sustained-release formulation.     

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.