Formulation and evaluation of meloxicam oral disintegrating tablet with dissolution enhanced by combination of cyclodextrin and ion exchange resins

Context: The bitter taste of drug is masked by the exchange of ionized drugs with counter ions of ion exchange resin, forming “resinate”. Cyclodextrin reduces the unpleasant taste and enhances the drug solubility by encapsulating drug molecules into its central cavity.

Objective: Oral disintegrating tablets (ODTs) using the combination of ion exchange resin and cyclodextrin was developed, to mask the bitter taste and enhance drug dissolution.

Methods: Meloxicam (MX) was selected as a model drug. Formulations containing various forms of MX (free drug, MX-loaded resin or resinate, complexes of MX and 2-hydroxypropyl-β-cyclodextrin (HPβCD) or MX/HPβCD complexes, and a mixture of resinate and MX/HPβCD complexes) were made by direct compression. The ODTs were evaluated for weight variation, thickness, diameter, hardness, friability, disintegration time, wetting time, MX content, MX release, degree of bitter taste and stability.

Results and discussion: The tablet hardness was ～3?kg/in², and the friability was <1%. Tablets formulated with resinate and the mixture of resinate and MX/HPβCD complexes disintegrated rapidly within 60?s, which is the acceptable limit for ODTs. These results were corresponded to the in vivo disintegration and wetting times. However, only tablets containing the mixture of resinate and MX/HPβCD complexes provided complete MX dissolution and successfully masked the bitter taste. In addition, this tablet was stable at least 6 months.

Conclusions: The combination of ion exchange resin and cyclodextrin could be used in ODTs to mask the bitter taste and enhance the dissolution of drugs that are weakly soluble in water.     

Preparation and in vivo evaluation of spray dried matrix type controlled-release microparticles of tamsulosin hydrochloride for orally disintegrating tablet

The objective of this study was to achieve an optimal formulation of spray dried matrix type controlled-release (MTCR) microparticles containing tamsulosin hydrochloride for orally disintegrating tablet. To control the release rate of tamsulosin hydrochloride, Acrylate-methacrylate copolymer (Eudragit^® L-100 or Eudragit^® S-100) and ethylcellulose were employed on the composition of MTCR microparticles. Physicochemical properties of MTCR microparticles such as particle size and SEM were characterized. Pharmacokinetic parameters of tamsulosin hydrochloride were evaluated in the rats after oral administration. MTCR microparticles were spherical microparticles of around 10 µm diameter with a corrugated surface. ODTs containing MTCR microparticles were disintegrated within 30 s and MTCR microparticles were able to control the release rate of tamsulosin hydrochloride following Fickian diffusion mechanism. The in vitro release rates of tamsulosin hydrochloride from MTCR microparticles were proportional to the ratio of Acrylate-methacrylate copolymer to ethylcellulose. Moreover, MTCR microparticles retarded the in vivo release rate of tamsulosin hydrochloride without reducing the bioavailability. Our results suggest that MTCR microparticles may be potential oral dosage forms to control the release and to improve the bioavailability of tamsulosin hydrochloride.     

Evaluation of Chlorpheniramine Maleate microparticles in orally disintegrating film and orally disintegrating tablet for pediatrics

Objective: To mask the bitterness of Chlorpheniramine Maleate via encapsulating drug into Eudragit EPO microparticles, and then incorporate these microparticles into orally disintegrating films (ODF) and orally disintegrating tablets (ODT) for pediatric uses.

Methods: Spray drying of water-in-oil emulsion was utilized to encapsulate Chlorpheniramine Maleate into Eudragit EPO microparticles. Based on an orthogonal experimental design L₉ (3³), polynomial regression models were developed to evaluate correlation between microparticle properties (encapsulation efficiency and drug release) and variables (X₁: weight ratio of polymer to drug, X₂: volume ratio of oil to water and X₃: Q-flow of spray dryer). ODF and ODT formulations were evaluated including weight variation, content uniformity, tensile strength, disintegration time, friability and dissolution profiles. The bitterness taste test was evaluated in 10 adult volunteers.

Results and discussion: From polynomial regression analysis, the best values of variables leading to the optimized microparticles were X₁?=?10, X₂?=?3 and X₃?=?45. The optimized microparticles were incorporated into ODF and ODT with satisfactory weight and drug content uniformity, and acceptable physical strength. Both dosage forms disintegrated immediately (less than 40?s) in simulated saliva solutions. The outcome of taste-masking test indicated that microparticles alleviated drug bitterness significantly; bitterness was not discernible with microparticles incorporated in ODT, whereas only slight bitterness was detected from microparticles incorporated into ODF.

Conclusion: Both ODF and ODT are shown to be suitable vehicles for taste masked Chlorpheniramine Maleate microparticles with potential for pediatric uses.     

Preparation and in vitro/in vivo evaluation of a ketoprofen orally disintegrating/sustained release tablet

Context: Orally disintegrating tablets (ODTs) with sustained release profiles are a new generation of ODTs called orally disintegrating/sustained release tablets (ODSRTs), which are convenient in use and able to slowly release drugs to maintain effective blood concentrations over a prolonged period of time. Ketoprofen, one of non-steroidal anti-inflammatory drugs, is an ideal model drug for ODSRTs.

Methods: We designed a simple two-step process to develop novel ketoprofen orally disintegrating/sustained release tablets (KODSRTs). Firstly, sustained release ketoprofen fine granules were developed by spray drying the aqueous dispersions composed of Eudragit RS-30D, Starch 1500 and PEG 6000. The optimal parameters of spray drying were 100°C for inlet air temperature and 1.5 mL/min for feed rate. Subsequently, the obtained granules were directly compressed into KODSRTs after mixing with lactose, mannitol and a superdisintegrant, crosslinked polyvinylpyrrolidone (PVPP). The characteristics of KODSRTs, especially their potential for extended drug release, were evaluated.

Results: Results of an in vitro release test demonstrated that KODSRTs could slowly release ketoprofen for 24 h after disintegrating within 30 s. Extended release properties of KODSRTs were decided by the ketoprofen sustained release fine granules in tablets. Besides, the disintegration time of KODSRTs depended on the percentage of PVPP in tablets. In vivo pharmacokinetic studies in beagles also showed that KODSRTs possessed a significantly extended release profile compared with ketoprofen normal capsules.

Conclusion: KODSRTs were successfully prepared using a simple two-step process: spray drying and direct compression.     

Taste-masked and affordable donepezil hydrochloride orally disintegrating tablet as promising solution for non-compliance in Alzheimer’s disease patients

Context: Manufacturing process and superdisintegrants used in orally disintegrating tablet (ODT) formulation are often time discussed. However, the effect of suitable filler for ODT formulation is not explored thoroughly.

Objective: The aim of this study was to develop a novel taste masked and affordable donepezil hydrochloride ODT with fast disintegration time and stable to improve medication compliance of Alzheimer’s disease patient.

Methods and materials: The ODT was manufactured using simple wet-granulation method. Crospovidone XL-10 was used as superdisintegrant and optimization was done by comparing the effect of three grades of lactose monohydrate compound as filler: Starlac®, Flowlac® and Tablettose®.

Results and discussion: Formulations containing higher amount of colloidal silicon dioxide showed increase in hardness, weight, disintegration time and wetting time after stability study. Formulation E which containing 50% of Starlac® was found with shortest in vitro disintegration time (21.7?±?1.67?s), in vivo disintegration time (24.0?±?1.05?s) and in vitro disintegration time in artificial salvia (22.5?±?1.67?s). Physical stability studies at 40?°C/75% RH for 6 months, Fourier transform infrared spectroscopy analysis and X-ray diffraction results showed that the formulation was stable. The drug-released profile showed that 80% of donepezil hydrochloride was released within 1?min. A single-dose, fasting, four-period, seven-treatment, double-blinded study involving 16 healthy human volunteers was performed to evaluate the palatability of ODT. Formulation VII containing 10?mg of ammonium glycyrrhizinate was able to mask the bitter taste of the drug.

Conclusion: The product has the potential to be commercialized and it might serve as solution for non-compliance among the Alzheimer’s disease patients.     

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

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

A novel fast disintegrating tablet fabricated by three-dimensional printing

Background: Based on computer-aided models, three-dimensional printing (3DP) technology can exercise local control over the material composition, microstructure, and surface texture during it layer-by-layer manufacturing process to endow the products with special properties. It can be a useful tool in the development of novel solid dosage forms. Method: In this study, a novel fast disintegrating tablet (FDT) with loose powders in it was designed and fabricated using 3DP process. The inner powder regions were formed automatically by depositing the binder solutions onto selected regions during the layer-printing processes. Results: Environmental scanning electron microscope images clearly showed that the printed regions were bound together. The particle size was reduced or individual particles could no longer be distinguished. In contrast, the unprinted regions were uncompacted with cracks and fissures among the loose powders. The tablets had a hardness value of 54.5 N/cm² and 0.92%?mass loss during the friability tests. The disintegration time of the tablets was 21.8 seconds and the wetting time was 51.7 seconds. The in vitro dissolution tests showed that 97.7%?acetaminophen was released in the initial 2 min. Conclusion: 3DP process is able to offer novel methods for preparing FDTs.     

Evaluation of performance of co crystals of mefloquine hydrochloride in tablet dosage form

Objective: The objective of present investigation was to evaluate performance of cocrystals of Mefloquine Hydrochloride (MFL) in tablet dosage form. Our previous investigation showed significant effect of cocrystal formers on improving the solubility and dissolution rate of Mefloquine hydrochloride by cocrystallization method when prepared by solution cocrystallization method.

Materials and methods: Prepared cocrystals of MFL with different ratio of cocrystal formers were incorporated in tablet dosage form and evaluated for micrometric properties, drug content, hardness, disintegration test, vitro dissolution studies and stability studies. Performance was compared with laboratory prepared tablet of MFL 250 mg.

Results: The considerable improvement in the dissolution rate was observed in case of cocrystals based tablets than pure MFL tablets.

Discussion and conclusion: So we can incorporate cocrystals in tablet dosage form to enhance in vitro and in vivo performance. To the best of our knowledge, this is the first report, cocrystals has been evaluated in tablet dosage form.     

Effect of the filler grade on the characteristics and the sublingual permeability of atropine sulfate fast disintegrating sublingual tablets

Abstract

Context: AS FDSTs will provide an accessible alternative for AS autoinjector (ATROPEN^®), and a noninvasive first-aid antidote for the treatment of organophosphate (OP) poisoning and reduce the number of fatalities due to nerve gas attacks or OP pesticide poisoning.

Objective: The effects of changing the filler grade on the characteristics of atropine sulfate (AS) fast disintegrating sublingual tablets (FDSTs) and AS sublingual permeability were investigated in order to optimize the formulation of AS FDSTs and, therefore, AS sublingual permeability.

Methods: Two batches of AS FDSTs containing AS 8?mg were formulated and manufactured using two different filler grades: microcrystalline cellulose (MCC) UF-702 (formulation A) and MCC PH-301 (formulation B). Several United States Pharmacopeia (USP) and non-USP physical tests were performed to evaluate the AS FDSTs’ characteristics. The AS permeability from the two AS FDST batches were evaluated using Franz cells through excised porcine sublingual membranes. Results were statistically compared at p?<?.05.

Results: Both batches passed the content uniformity and friability tests. Formulation A tablets were significantly different from formulation A tablets and resulted in better powder flowability, higher breaking force, faster disintegration, faster dissolution rate, higher water uptake, and higher AS permeability.

Conclusion: The selection of the filler grade to be used in the formulation of AS FDSTs can significantly impact their characteristics and significantly affect AS sublingual permeability, which can be used to improve the sublingual delivery of AS and the potential of using AS FDSTs as an alternative dosage form for the first-aid treatment of OP poisoning.     

Formulation and evaluation of floating tablet of H2-receptor antagonist

Context: Conventional sustained dosage form of ranitidine hydrochloride (HCl) does not prevent frequent administration due to its degradation in colonic media and limited absorption in the upper part of GIT.

Objectives: Ranitidine HCl floating tablet was formulated with sublimation method to overcome the stated problem.

Methods: Compatibility study for screening potential excipients was carried out using Fourier transform infrared spectroscopy (FT-IR) and differential scanning chromatography (DSC). Selected excipients were further evaluated for optimizing the formulation. Preliminary screening of binder, polymer and sublimating material was based on hardness and drug release, drug release with release kinetics and floating lag time with total floatation time, respectively. Selected excipients were subjected to 3² factorial design with polymer and sublimating material as independent factors. Matrix tablets were obtained by using 16/32” flat-faced beveled edges punches followed by sublimation.

Results: FT-IR and DSC indicated no significant incompatibility with selected excipients. Klucel-LF, POLYOX WSR N 60?K and l-menthol were selected as binder, polymer and sublimating material, respectively, for factorial design batches after preliminary screening. From the factorial design batches, optimum concentration to release the drug within 12?h was found to be 420?mg of POLYOX and 40?mg of l-menthol. Stability studies indicated the formulation as stable.

Conclusion: Ranitidine HCl matrix floating tablets were formulated to release 90% of drug in stomach within 12?h. Hence, release of the drug could be sustained within narrow absorption site. Moreover, the dosage form was found to be floating within a fraction of second independent of the pH of media ensuring a robust formulation.     

Systemic enhancement of papaverine transdermal gel for erectile dysfunction

To enhance the systemic transdermal delivery of papaverine for the treatment of erectile dysfunction, several factors that influence transdermal delivery of papaverine HCl were studied. The effects of membrane types for in vitro permeation study, human skin layers, solvent/cosolvent systems and the penetration enhancers on the transdermal permeation of papaverine HCl were investigated. A combination of caproic acid, ethanol and water in the volume ratio of 50%:30%:20% was chosen as penetration enhancer and incorporated in two gel bases: 18% Pluronic F-127 and 2% Carbopol 940. In vivo skin permeation studies were performed with two loading doses (0.6% and 2%) in rabbits. The flux and permeability coefficient of papaverine HCl through different human skin layers suggested that the major barrier layer for papaverine HCl was residing primarily in the stratum corneum. However, the viable epidermis and dermis layer also contributed certain degrees of diffusion resistance. Differential Scanning Calorimetry study showed that penetration enhancer exhibited a counter effect with papaverine HCl on the temperature and enthalpy in both gels. In vitro drug release study demonstrated significant increases in the steady-state flux, permeability coefficient and enhancement ratio in these gels. Faster drug transports and higher bioavailability were also observed in rabbits. Skin irritation test performed in rabbits demonstrated a mild skin reaction with mean PII scores of 2 and below; however the recovery was fast. In conclusion, caproic acid, ethanol and water in the volume ratio of 50%:30%:20% is an effective penetration enhancer to deliver papaverine HCl transdermally for systemic absorption.     

Development and evaluation of buccoadhesive tablet for selegiline hydrochloride based on thiolated polycarbophil

Selegiline hydrochloride (SHCl), a monoamine oxidase B inhibitor, is used as an adjunct in the therapy of Parkinson’s disease. This study is concerned with the preparation and evaluation of mucoadhesive buccal tablet for controlled systemic delivery of SHCl. Buccal absorption of selegiline can bypass its first-pass metabolism and improve bioavailability accompanied by greatly reduced metabolite formation, which is potentially of enhanced therapeutic value in patients with Parkinson’s disease. Polycarbophil–cysteine (PCP–cys) conjugate, which is a thiolated derivative of the mucoadhesive polymer polycarbophil, was synthesized by 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride-mediated amide bond coupling. Tablets of SHCl based on native and thiolated polycarbophil were prepared. The prepared tablets were evaluated for drug content, swelling behavior, mucoadhesive strength, in vitro drug release, ex vivo permeation and in vitro cytotoxicity. PCP–cys tablets showed enhanced mucoadhesion and retarded drug release compared to polycarbophil tablets. Permeation data of SHCl from matrices prepared using the PCP–cys polymer revealed a significantly higher value of apparent permeability in comparison to polycarbophil, which supported the information in literature that thiolation imparts permeation enhancing properties to mucoadhesive polymers. In vitro cytotoxicity studies on PCP–cys using L-929 mouse fibroblast cell line indicated that conjugation with cysteine does not impart any apparent toxicity to polycarbophil. The results from the study indicate that the buccal delivery of SHCl using thiolated polycarbophil tablet could provide a way for improved therapy of Parkinson’s disease.     

Biomechanics of male erectile function.

Two major branches of engineering mechanics are fluid mechanics and structural mechanics, with many practical problems involving the effect of the first on the second. An example is the design of an aircraft's wings to bend within reasonable limits without breaking under the action of lift forces exerted by the air flowing over them; another is the maintenance of the structural integrity of a dam designed to hold back a water reservoir which would exert very large forces on it. Similarly, fluid and structural mechanics are involved in the engineering analysis of erectile function: it is the hydraulic action of increased blood flow into the corpora cavernosa that creates the structural rigidity necessary to prevent collapse of the penile column.     

SeDeM expert system a new innovator tool to develop pharmaceutical forms

Context: The SeDeM expert system is based on the experimental study and quantitative determination of the characterization parameters of powdered substances, the aim being to determine whether a substance is suitable for producing tablets by means of direct compression (DC) technology, thereby reducing the lead time for pre-formulation studies. Additionally, this expert system also provides formulations with a minimum number of excipients.

Objective: We used this system to analyze suitable formulas for the production of orodispersible ibuprofen tablets.

Method: Twenty-one disintegrants and ibuprophen were characterized using SeDeM methodology.

Results: The results indicated that production of ibuprofen tablets by DC would require improvements in the dimension and compressibility factors of the active pharmaceutical ingredient. The expert system analysis provided the specific percentage of disintegrant needed to blend with ibuprofen and a standardized formula of lubricants in order to obtain a powder mix that would successfully produce tablets by DC. The eight formulas proposed by SeDeM were produced and tested in the laboratory.

Conclusion: All eight formulas successfully produced tablets by DC, but only four of them could be considered suitable for use as an orodispersible tablet and accomplishes all the pharmaceutical quality parameters. So, in fact, the use of the SeDeM system reduced the time of medicine’s development and therefore the cost of the activity.     

Release of cyclobenzaprine hydrochloride from osmotically rupturable tablets

Osmotically rupturable systems were developed and the release of cyclobenzaprine hydrochloride (model drug) from the systems was investigated. Systems were designed using mannitol (osmotic agent) and increasing amounts of polyethylene oxide (PEO, a water-swellable polymer) surrounded by a semipermeable membrane. When placed in an aqueous environment, osmotic water imbibition into the systems distended and swelled the systems until the membrane ruptured and released the active compound to the outside environment. Tablets with increasing amount of PEO exhibited longer rupture times. This may be due to osmotic pressure-modulating properties of the polymer, changing the rate of water imbibition into the systems.

The integrity of the membranes was investigated using high-pressure mercury intrusion porosimetry. Minimal mercury intrusion into the membrane structure and core tablet indicated membrane integrity and lack of defective areas or pinholes. The results were in agreement with the release profiles where no drug release was detected prior to membrane rupture. Mercury intrusion porosimetry appears to be a promising technique for evaluation of membrane integrity.

Once the systems ruptured, drug was released by osmotic pumping and diffusion mechanisms through the ruptured area. There was a decrease in drug release rate with inclusion of PEO in the core.

The effects of film thickness on rupture and release times were also investigated. Devices with thicker films produced longer rupture times. This is in agreement with the theoretical prediction.     

Release of Cyclobenzaprine Hydrochloride from Osmotically Rupturable Tablets

ABSTRACT

Osmotically rupturable systems were developed and the release of cyclobenzaprine hydrochloride (model drug) from the systems was investigated. Systems were designed using mannitol (osmotic agent) and increasing amounts of polyethylene oxide (PEO, a water-swellable polymer) surrounded by a semipermeable membrane. When placed in an aqueous environment, osmotic water imbibition into the systems distended and swelled the systems until the membrane ruptured and released the active compound to the outside environment. Tablets with increasing amount of PEO exhibited longer rupture times. This may be due to osmotic pressure-modulating properties of the polymer, changing the rate of water imbibition into the systems.

The integrity of the membranes was investigated using high-pressure mercury intrusion porosimetry. Minimal mercury intrusion into the membrane structure and core tablet indicated membrane integrity and lack of defective areas or pinholes. The results were in agreement with the release profiles where no drug release was detected prior to membrane rupture. Mercury intrusion porosimetry appears to be a promising technique for evaluation of membrane integrity.

Once the systems ruptured, drug was released by osmotic pumping and diffusion mechanisms through the ruptured area. There was a decrease in drug release rate with inclusion of PEO in the core.

The effects of film thickness on rupture and release times were also investigated. Devices with thicker films produced longer rupture times. This is in agreement with the theoretical prediction.     

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.