A Comparison of Trehalose Dihydrate and Mannitol as Stabilizing Agents for Dicalcium Phosphate Dihydrate Based Tablets

This study investigated the possible utility of trehalose dihydrate (TD) as a tablet stabilizing agent. Acetylsalicylic acid was used as the model hydrolyzable drug and dicalcium phosphate dihydrate (DCPD) as the base excipient, because it is well documented that ASA/DCPD tablets are unstable during storage at low temperature and high relative humidity; DCPD is usually combined with mannitol in order to improve tablet stability.

Tablets comprising DCPD, 10% ASA, and 0%, 10%, or 20% w/w of TD were prepared by direct compression and stored at 35°C and 82.9% relative humidity for 6 months. Additionally, control tablets with DCPD and ASA, only, or with DCPD, ASA and 20% mannitol, were also evaluated. At predetermined time intervals, formulations were tested for drug content, mechanical, microstructural, and drug dissolution properties. Additionally, thermal analyses and ASA solution stability studies were carried out. Results reveal that both TD and mannitol significantly reduce degradation of ASA included in DCPD-based tablets, but neither effectively protects against the marked decline in tablet mechanical properties on aging. The ASA stabilization effects of TD and mannitol were also observed in solution, indicating an interaction between these sugars and ASA.     

Effect of diluents on tablet integrity and controlled drug release

The objective of this study was to evaluate the effect of diluents and wax level on tablet integrity during heat treatment and dissolution for sustained-release formulations and the resultant effect on drug release. Dibasic calcium phosphate dihydrate (DCPD), microcrystalline cellulose (MCC), and lactose were evaluated for their effect on tablet integrity during drug dissolution and heat treatment in wax matrix formulations. A newly developed direct compression diluent, dibasic calcium phosphate anhydrous (DCPA), was also evaluated. Compritol® 888 ATO was used as the wax matrix material, with phenylpropanolamine hydrochloride (PPA) as a model drug. Tablets were made by direct compression and then subjected to heat treatment at 80°C for 30 min. The results showed that MCC, lactose, and DCPA could maintain tablets intact during heat treatment above the melting point of wax (70°C-75°C). However, DCPD tablets showed wax egress during the treatment. MCC tablets swelled and cracked during drug dissolution and resulted in quick release. DCPD and lactose tablets remained intact during dissolution and gave slower release than MCC tablets. DCPA tablets without heat treatment disintegrated very quickly and showed immediate release. In contrast, heat-treated DCPA tablets remained intact through the 24-hr dissolution test and only released about 80% PPA at 6 hr. In the investigation of wax level, DCPD was used as the diluent. The drug release rate decreased as the wax content increased from 15% to 81.25%. The dissolution data were best described by the Higuchi square-root-of-time model. Diluents showed various effects during heat treatment and drug dissolution. The integrity of the tablets was related to the drug release rate. Heat treatment retarded drug release if there was no wax egress.     

Use of Dicalcium Phosphate Dihydrate for Sustained Release of Highly Water Soluble Drugs

The utilituy of Dicalcium phosphate dihydrate (DCPD), a commonly used water insoluble pharmaceutical excipient, has been investigated for its use in formulating a controlled release matrix type tablet for highly water soluble drugs. Various drugs were formulated into a tablet by direcly compressing mixture of the drug, dicalcium phosphate dihydrate, and magnecium stearate on a single punch tablet machine. Effects of drug concentation and tablet weight on the release profiles were studied using USP II dissolution machine.

The release from these matrices followed first order kinetics rather than square root time rule. The release profile and the first order rate constant seemed to be dependent upon the the size of the tablet. Incorporation of drug in a quantity excess of 5% w/w of the tablet resulted in disintegration of the tablet and subsequent rapid release of the drug.

Dicalcium phosphate may be a simpler, cheaper, and a viable way to formulating directly compressible sustained release formulations.     

Use of Dicalcium Phosphate Dihydrate for Sustained Release of Highly Water Soluble Drugs

The utilituy of Dicalcium phosphate dihydrate (DCPD), a commonly used water insoluble pharmaceutical excipient, has been investigated for its use in formulating a controlled release matrix type tablet for highly water soluble drugs. Various drugs were formulated into a tablet by direcly compressing mixture of the drug, dicalcium phosphate dihydrate, and magnecium stearate on a single punch tablet machine. Effects of drug concentation and tablet weight on the release profiles were studied using USP II dissolution machine.

The release from these matrices followed first order kinetics rather than square root time rule. The release profile and the first order rate constant seemed to be dependent upon the the size of the tablet. Incorporation of drug in a quantity excess of 5% w/w of the tablet resulted in disintegration of the tablet and subsequent rapid release of the drug.

Dicalcium phosphate may be a simpler, cheaper, and a viable way to formulating directly compressible sustained release formulations.     

Freeze drying: exploring potential in development of orodispersible tablets of sumatriptan succinate

The present investigation is aimed at development and characterization of sumatriptan succinate orodispersible tablets (ODTs) prepared by freeze drying technology. The tablet excipients were screened and the composition was optimized based on parameters which involved general appearance, tablet size and shape, uniformity of weight, mechanical properties, surface pH, moisture analysis, drug content, wetting time, in vitro and in vivo disintegration time. Furthermore, fourier transform infrared spectroscopy, differential scanning calorimetry, scanning electron micrograph of cross-section of the tablet and in vitro dissolution studies were performed. Studies revealed that formulation containing gelatin–mannitol (3.75% w/v and 3.5% w/v, respectively) with camphor as a volatile pore forming agent exhibited superior properties with disintegration time of less than 10?s. Furthermore, in vitro release studies revealed 90% release of drug from developed dosage form within 10?min, thus suggesting rapid drug dissolution followed by faster onset of action, which forms a strong rationale for development of ODTs of sumatriptan succinate. The developed technology is simple, which involves few steps and can be easily scaled up. Thus, it holds enormous potential for commercial exploitation.     

Continuous direct tablet compression: effects of impeller rotation rate,total feed rate and drug content on the tablet properties and drug release

Context: Continuous processing is becoming popular in the pharmaceutical industry for its cost and quality advantages.

Objective: This study evaluated the mechanical properties, uniformity of dosage units and drug release from the tablets prepared by continuous direct compression process.

Materials and methods: The tablet formulations consisted of acetaminophen (3–30% (w/w)) pre-blended with 0.25% (w/w) colloidal silicon dioxide, microcrystalline cellulose (69–96% (w/w)) and magnesium stearate (1% (w/w)). The continuous tableting line consisted of three loss-in-weight feeders and a convective continuous mixer and a rotary tablet press. The process continued for 8?min and steady state was reached within 5?min. The effects of acetaminophen content, impeller rotation rate (39–254?rpm) and total feed rate (15 and 20?kg/h) on tablet properties were examined.

Results and discussion: All the tablets complied with the friability requirements of European Pharmacopoeia and rapidly released acetaminophen. However, the relative standard deviation of acetaminophen content (10% (w/w)) increased with an increase in impeller rotation rate at a constant total feed rate (20?kg/h). A compression force of 12?kN tended to result in greater tablet hardness and subsequently a slower initial acetaminophen release from tablets when compared with those made with the compression force of about 8?kN.

Conclusions: In conclusion, tablets could be successfully prepared by a continuous direct compression process and process conditions affected to some extent tablet properties.     

Mucoadhesive delivery systems. II. Formulation and in-vitro/in-vivo evaluation of buccal mucoadhesive tablets containing water-soluble drugs

From the previous work (Part I), mucoadhesive formulae containing 5% CP/65% HPMC/30% lactose and 2% PC/68% HPMC/30% mannitol as well as formulae based on sodium carboxymethyl cellulose (SCMC) were selected. Medicated tablets were prepared using diltiazem hydrochloride (DZ) and metclopramide hydrochloride (MP) in two different doses (30 and 60 mg). The effect of drug and dose on the mucoadhesive properties and in-vitro drug release was evaluated. All formulae produced extended drug release (over 8 to 12 h). Polyacrylic acid based matrices (PAA) showed Fickian's diffusion release pattern for both drugs. SCMC ensured zero-order release for DZ, which deviated to anomalous behavior in case of MP. Doubling the dose significantly reduced the bioadhesion strength (p<0.05) with a slight improvement in drug release rate. The formulation of bilayer tablets containing drug-free layer and medicated layer enhanced the drug release without affecting the bioadhesive performance. The bilayer tablet formulated with 2% PC/68% HPMC/30% mannitol (PC2) was selected for studying the in-vivo metoclopramide release in four healthy volunteers. The tablet ensured controlled drug release for 12 h, in addition, good correlation (r=0.9398) was observed between in-vitro and in-vivo data. The effect of ageing on selected formulae containing DZ and MP, respectively, was studied. Storage at 40 degrees C and 75% relative humidity for 6 months didn't influence the mucoadhesive performance, however, an enhanced released rate was observed.     

Preparation and physicochemical evaluation of a new tacrolimus tablet formulation for sublingual administration

The aim of this study was to develop a new fast-disintegrating tablet formulation containing 1?mg tacrolimus for sublingual application. First, solid dispersions containing tacrolimus (2.5%, 5% and 10% w/w) incorporated in Ac-Di-Sol(?) and carriers (inulin 1.8?kDa and 4?kDa, and polyvinylpyrrolidone (PVP) K30) were prepared by freeze drying. Subsequently, a tablet formulation composed of a mixture of the solid dispersions, Ac-Di-Sol(?), mannitol, Avicel(?) PH-101 and sodium stearyl fumarate was optimized concerning drug load in the solid dispersions and the type of carrier. Tablet weight was kept constant at 75?mg by adjusting the amount of Avicel(?) PH-101. Differential scanning calorimetry (DSC) and X-ray powder diffraction (XRPD) results indicated the absence of the drug in the crystalline state, which was confirmed by the scanning electron microscopy (SEM). These results suggest that tacrolimus incorporated in all of the solid dispersions was fully amorphous. Dissolution of the tablets containing solid dispersions with a low drug load highly depends on the type of carrier and increased in the order: PVP K30 < inulin 4?kDa < inulin 1.8?kDa. Solid dispersions with a drug load of 10% w/w incorporated in the carriers yielded optimal formulations. In addition, the physicochemical characteristics and the dissolution behavior of the tablet formulation containing inulin 1.8 kDa-based solid dispersions with a drug load of 10% w/w did not change after storage at 20°C/45%RH for 6 months indicating excellent storage stability.     

Comparative Evaluations of Aqueous Film Coated Tablet Formulations by High Humidity Aging

Compressed tablets of ticlopidine hydrochloride were coated with three aqueous film coating formulations and aged under 95% relative humidity at 23° and 37°. The in vitro dissolution of the drug from tablets coated with the formulation containing polymethacrylic acid esters before aging was slower than the tablets coated with the formulations containing hydroxypropyl methylcellulose or ethylcellulose dispersion. On aging, the in vitro drug dissolution of the coated and uncoated tablets decreased and the decrease depended on the film forming excipient in the coating formulation and the temperature of aging. The tablets coated with the formulation containing polymethacrylic acid esters dissolved very slowly after aging. Higher moisture contents of the tablets after aging under 95% relative humidity at 23° compared to 37° resulted in a consistently lower tablet crushing strength. The tablets coated with the formulation containing 10% hydroxypropy1 methylcellulose showed a smaller decrease in the tablet crushing strength on aging compared to the other two formulations.     

Comparative Evaluations of Aqueous Film Coated Tablet Formulations by High Humidity Aging

Compressed tablets of ticlopidine hydrochloride were coated with three aqueous film coating formulations and aged under 95% relative humidity at 23° and 37°. The in vitro dissolution of the drug from tablets coated with the formulation containing polymethacrylic acid esters before aging was slower than the tablets coated with the formulations containing hydroxypropyl methylcellulose or ethylcellulose dispersion. On aging, the in vitro drug dissolution of the coated and uncoated tablets decreased and the decrease depended on the film forming excipient in the coating formulation and the temperature of aging. The tablets coated with the formulation containing polymethacrylic acid esters dissolved very slowly after aging. Higher moisture contents of the tablets after aging under 95% relative humidity at 23° compared to 37° resulted in a consistently lower tablet crushing strength. The tablets coated with the formulation containing 10% hydroxypropy1 methylcellulose showed a smaller decrease in the tablet crushing strength on aging compared to the other two formulations.     

The effect of moisture on the physical characteristics of ranitidine hydrochloride tablets prepared by different binders and techniques

The effect of moisture on the physical properties of ranitidine hydrochloride tablets prepared by direct-compression and by wet-granulation method using PVP or EC as binders was studied. Tablets adsorped moisture at 50 and 75 % RH (relative humidity) but lost moisture at 30% RH. Except storage at 75% RH, however, tablet volumes did not change significantly during the test period. Moisture sorption caused a decrease in strength of tablets except low humidity (30% RH). Also, the disintegration time of tablets showed a decrease at all conditions except 30% RH. Furthermore, generally dissolution profiles of tablets prepared by direct-compression and by ethyl cellulose remained unchanged. Changes in the binder type in the tablet formulations changed the water uptake properties and also the physical properties of tablets. Directly-compressed tablets were much susceptible to change caused by humidity than tablets prepared by wet-granulation.     

Development of stabilized tenofovir disoproxil tablet: degradation profile,stabilization, and bioequivalence in beagle dogs

The purpose of this study was to develop a hydrolysis-resistant optimized oral formulation of tenofovir disoproxil (TD) using a stabilizer. To develop a stabilized TD tablet bioequivalent to the commercial TD fumarate (TDF, Viread^®) tablet, TD free base was prepared and its degradation profile and stability were investigated. The TD tablet showed antiviral activity, but its absorption was limited in the intestinal tract because of premature degradation. The drug subjected to severe conditions for the stress test was catalyzed under neutral, basic, oxidative, and thermolytic conditions, whereas it was comparatively stable under acidic, photolytic, and humid states. The compatibility study showed that sodium bisulfite (SB) stabilized TD by preventing its degradation in aqueous and 3% peroxide solutions compared with the unstabilized TD. According to the stability analysis and degradation profile, four TD tablet formulations were prepared. The selected TD tablets were composed of non-hygroscopic excipients (lipophilic-fumed silica, anhydrous lactose, and microcrystalline cellulose [MCC]), SB, croscarmellose sodium (CCS), and hydrogenated castor oil (HCO), and were manufactured using a dry granulation method because of their hydrolytic properties. The stabilized TD tablet showed similar dissolution properties as the TDF (Viread^®) reference tablet in pH 1.2, 4.0, and 6.8 and water. Moreover, the lower degradation rate of the tablet in simulated gastrointestinal fluid demonstrated that its intestinal absorption might have improved owing to prevention of its enzymatic hydrolysis and the pH effect. Finally, the formulated TD tablet was bioequivalent to the TDF (Viread^®) reference tablet in beagle dogs.     

Properties of Fujicalin®, a New Modified Anhydrous Dibasic Calcium Phosphate for Direct Compression: Comparison with Dicalcium Phosphate Dihydrate

The novel, commercially available, free-flowing spherically granulated dicalcium phosphate anhydrous (SGDCPA) Fujicalin for direct tableting was compared with directly compressible dicalcium phosphate dihydrate (DCPD), the properties of which are well known. The two excipients were investigated and compared with regard to their physical and powder properties, compressibility, and compactibility. As a consequence of the spherical shape of its particles, SGDCPA shows the same good flowability and even better compactibility. In contrast to DCPD, SGDCPA shows significant uptake of moisture when exposed to relative humidities (RHs) exceeding 70%. For both excipients, the main deformation mechanism is fragmentation, with SGDCPA yielding significantly stronger tablets.     

The effect of moisture on the physical characteristics of ranitidine hydrochloride tablets prepared by different binders and techniques

Abstract

The effect of moisture on the physical properties of ranitidine hydrochloride tablets prepared by direct-compression and by wet-granulation method using PVP or EC as binders was studied. Tablets adsorped moisture at 50 and 75 % RH (relative humidity) but lost moisture at 30% RH. Except storage at 75% RH, however, tablet volumes did not change significantly during the test period. Moisture sorption caused a decrease in strength of tablets except low humidity (30% RH). Also, the disintegration time of tablets showed a decrease at all conditions except 30% RH. Furthermore, generally dissolution profiles of tablets prepared by direct-compression and by ethyl cellulose remained unchanged. Changes in the binder type in the tablet formulations changed the water uptake properties and also the physical properties of tablets. Directly-compressed tablets were much susceptible to change caused by humidity than tablets prepared by wet-granulation.     

Prelimnaky Evaluation of Cissus Root Gum as a Binder in Sodium Salicylate Tablet Formulations

Abstract

Cissus root gum was processed and evaluated as a binder in lactose-based tablets each containing 100 mg of sodium salicylate as the active ingredient. Acacia binder was used as basis for comparison. Tablet hardness, friability, disintegration time and dissolution rate were the parameters investigated. The cissus gum gave hard and non-friable tablets at 1 - 3% w/w concentration of the tablet formula. Tablets containing above 2% w/w of the cissus gum gave high disintegration time values and the pattern of dissolution of the incorporated drug suggests that the gum may be useful in prolonged release tablet formulations. No significant changes in the tablet properties was observed after storage at 30°C for 16 weeks.     

Effect of moisture content,temperature and exposure time on the physical stability of chitosan powder and tablets

Context: Chitosan does not rank highly regarding its employment as tablet filler due to certain limitations. Undesirable properties that limit its utilization as excipient in solid dosage forms include its hydration propensity that negatively affects tablet stability, strength and disintegration.

Objective: The objective of this study was to investigate the physical stability of chitosan powder, mixtures, granules and tablets under accelerated conditions such as elevated temperatures and humidity over different periods of time.

Methods: Selected physico-chemical properties of pure chitosan powder, physical mixtures of chitosan with Kollidon® VA64 (BASF, Ludwigshafen, Germany), chitosan granules, as well as tablets were evaluated under conditions of elevated humidity and temperature.

Results and discussion: The physical stability of chitosan tablets exhibited sensitivity towards varying exposure conditions. It was furthermore evident that the presence of moisture (sorbed water) had a marked influence on the physical stability of chitosan powder and tablets. It was evident that the presence of Kollidon® VA64 as well as the method of inclusion of this binder influenced the properties of chitosan tablets. The physical stability of chitosan powder deteriorated to a greater extent compared to that of the chitosan tablets, which were subjected to the same conditions.

Conclusion: It is recommended that tablets containing chitosan should be stored at a temperature not exceeding 25?°C as well as at a relatively low humidity (<60%) to prevent deterioration of physical properties. Direct compression of chitosan granules which contained 5%w/w Kollidon® VA64 produced the best formulation in terms of physical stability at the different conditions.     

Hydrolysis of dicalcium phosphate dihydrate to hydroxyapatite

Dicalcium phosphate dihydrate (DCPD) was hydrolysed in water and in 1 M Na2HPO4 solution at temperatures from 25–60°C. Hydrolysis was incomplete in water. At 25 °C, DCPD partially hydrolysed to hydroxyapatite (HAp). Formation of HAp is indicative of incongruent DCPD dissolution. At the higher temperatures, hydrolysis to HAp was more extensive and was accompanied by the formation of anhydrous dicalcium phosphate (DCP). Both of these processes are endothermic. When hydrolysis was carried out in 1 M Na2HPO4 solution, heat absorption was greater at any given temperature than for hydrolysis in water. Complete hydrolysis to HAp occurred in this solution. The hydrolysis of DCPD to HAp in sodium phosphate solution was also endothermic. The complete conversion of DCPD to HAp in sodium phosphate solution would not be expected if the only effect of this solution was to cause DCPD dissolution to become congruent. Because of the buffering capacity of a dibasic sodium phosphate solution, DCPD hydrolysed completely to HAp. Complete conversion to HAp was accompanied by the conversion of dibasic sodium phosphate to monobasic sodium phosphate. The formation of DCP was not observed indicating that the sodium phosphate solution precluded the DCPD-to-DCP dehydration reaction. In addition to affecting the extent of hydrolysis, reaction in the sodium phosphate solution also caused a morphological change in the HAp which formed. HAp formed by hydrolysis in water was needle-like to globular while that formed in the sodium phosphate solution exhibited a florette-like morphology. © 1998 Chapman & Hall     

Optimization of Tablet Formulations Based on Starch/Lactose Granulations for Use in Tropical Countries

Abstract

Several granulations consisting of α-lactose monohydrate 200 mesh and native starch (corn, potato, rice or tapioca) were prepared. The influence of starch concentration, storage temperature and relative humidity on the physical properties of the tablets prepared from these granulations was estimated. Two granulations, which resulted in tablets with adequate initial values of crushing strength and disintegration time and with an acceptable physical stability were selected as standard granulations. The selected standard granulations were evaluated by incorporating a drug (diazepam, 2 mg or mebendazole, 100 mg). The tablet properties were determined one day after preparation. The crushing strength, the disintegration time and the microbiological quality were also measured after storage under tropical conditions. Both selected formulations proved to be adequate for the preparation of tablets by wet granulation, suitable for use in tropical countries.     

Physicochemical Characterization and Evaluation of Buccal Adhesive Tablets Containing Omeprazole

The objective of this study was to develop an effective omeprazole buccal adhesive tablet with excellent bioadhesive force and good drug stability in human saliva. The omeprazole buccal adhesive tablets were prepared with various bioadhesive polymers, alkali materials, and croscarmellose sodium. Their physicochemical properties, such as bioadhesive force and drug stability in human saliva, were investigated. The release and bioavailability of omeprazole delivered by the buccal adhesive tablets were studied. As bioadhesive additives for the omeprazole tablet, a mixture of sodium alginate and hydroxypropylmethylcellulose (HPMC) was selected. The omeprazole tablets prepared with bioadhesive polymers alone had bioadhesive forces suitable for a buccal adhesive tablet, but the stability of omeprazole in human saliva was not satisfactory. Among alkali materials, only magnesium oxide could be an alkali stabilizer for omeprazole buccal adhesive tablets due to its strong waterproofing effect. Croscarmellose sodium enhanced the release of omeprazole from the tablets; however, it decreased the bioadhesive forces and stability of omeprazole tablets in human saliva. The tablet composed of omeprazole/sodium alginate/HPMC/magnesium oxide/croscarmellose sodium (20/24/6/50/10 mg) could be attached on the human cheek without disintegration, and it enhanced the stability of omeprazole in human saliva for at least 4 h and gave fast release of omeprazole. The plasma concentration of omeprazole in hamsters increased to a maximum of 370 ng/ml at 45 min after buccal administration and continuously maintained a high level of 146–366 ng/ml until 6 h. The buccal bioavailability of omeprazole in hamsters was 13.7% ± 3.2%. These results demonstrate that the omeprazole buccal adhesive tablet would be useful for delivery of an omeprazole that degrades very rapidly in acidic aqueous medium and undergoes hepatic first-pass metabolism after oral administration.     

Physicochemical Characterization and Evaluation of Buccal Adhesive Tablets Containing Omeprazole

The objective of this study was to develop an effective omeprazole buccal adhesive tablet with excellent bioadhesive force and good drug stability in human saliva. The omeprazole buccal adhesive tablets were prepared with various bioadhesive polymers, alkali materials, and croscarmellose sodium. Their physicochemical properties, such as bioadhesive force and drug stability in human saliva, were investigated. The release and bioavailability of omeprazole delivered by the buccal adhesive tablets were studied. As bioadhesive additives for the omeprazole tablet, a mixture of sodium alginate and hydroxypropylmethylcellulose (HPMC) was selected. The omeprazole tablets prepared with bioadhesive polymers alone had bioadhesive forces suitable for a buccal adhesive tablet, but the stability of omeprazole in human saliva was not satisfactory. Among alkali materials, only magnesium oxide could be an alkali stabilizer for omeprazole buccal adhesive tablets due to its strong waterproofing effect. Croscarmellose sodium enhanced the release of omeprazole from the tablets; however, it decreased the bioadhesive forces and stability of omeprazole tablets in human saliva. The tablet composed of omeprazole/sodium alginate/HPMC/magnesium oxide/croscarmellose sodium (20/24/6/50/10 mg) could be attached on the human cheek without disintegration, and it enhanced the stability of omeprazole in human saliva for at least 4 h and gave fast release of omeprazole. The plasma concentration of omeprazole in hamsters increased to a maximum of 370 ng/ml at 45 min after buccal administration and continuously maintained a high level of 146-366 ng/ml until 6 h. The buccal bioavailability of omeprazole in hamsters was 13.7% ± 3.2%. These results demonstrate that the omeprazole buccal adhesive tablet would be useful for delivery of an omeprazole that degrades very rapidly in acidic aqueous medium and undergoes hepatic first-pass metabolism after oral administration.