Effect of particle size and diluent type on critical parameters for disintegration of tablets containing croscarmellose sodium as a disintegrant

Purpose: The aim of the present work was to determine the effect of particle size and type of diluents on critical concentration for the disintegration of tablet formulations containing a physical binary mixture of a superdisintegrant (croscarmellose sodium, CS) and a diluent.Methods: The diluents used in this study were microcrystalline cellulose (MCC), dibasic calcium phosphate (DCP) and pregelatinized starch (PGS). Each diluent was divided into 2 different size ranges (small and large size)) and further mixed with 0 - 100 % CS. The binary mixture was compressed at controlled pressure, and the disintegration time and physical characteristic of the tablets were evaluated.Results: The point of CS concentration that markedly affected the disintegration time of the tablets was recorded as the critical concentration for disintegration. The results showed that the particle size of the diluent did not affect the disintegration time. The critical CS concentrations were 2 % for DCP and MCC tablets and 5 % for PGS tablet. Adding a small amount of CS improved the disintegration of the tablets. However, increasing the amount of CS in the formulation also affected the hardness of the tablets. The particle size of diluents had a significant effect on the critical concentration for tablet disintegration.Conclusion: Determining the type and appropriate amounts of diluent and disintegrant (percolating component) may be useful in the design of tablet formulations.Keywords: Disintegration, Percolation threshold, Croscarmellose sodium, Microcrystalline cellulose, Dibasic calcium phosphate, Pre-gelatinized starc

Preparation and assessment of poly(methacrylic acid-coethylene glycol dimethacrylate) as a novel disintegrant

Purpose: To prepare and evaluate poly(methacrylic acid (MAA)-co-ethylene glycol dimethacrylate (EGD)) as a tablet disintegrant.Methods: Poly(MAA-co-EGD) in acid (H) and sodium (Na) forms at cross-linker (EGD) levels of 0.25 -16 % were synthesized and subjected to Fourier transform infrared spectroscopy. Swelling capacity, disintegration efficiency and cytotoxicity to Caco-2 cells were determined using standard procedures.Results: Poly(MAA-co-EGD) in acid (H) and sodium (Na) forms were successfully prepared. In contact with water, the polymers in Na form swelled more than those in H form. The swelling capacities of polymers in H and Na forms decreased with increasing amounts of cross-linker. Incorporation of the polymers accelerated the disintegration of microcrystalline cellulose tablets (placebo), and the disintegration efficiency depended on the salt form and amount of cross-linker. The Na salt form of the polymer crosslinked at 16 % EGD was the best candidate disintegrant. When used at 2.5 and 10 %, the selected polymer effectively promoted the disintegration and drug release of propranolol hydrochloride tablets. Moreover, cytotoxicity tests showed that it was non-toxic to Caco-2 cells.Conclusion: The developed poly(MAA-co-EGD) possesses good disintegration and dissolution functionalities. Thus, it may be adopted as a new super-disintegrant for fast-release tablets.Keywords: Tablet disintegrant, Methacrylic acid, Ethylene glycol dimethacrylate, Propranolol hydrochlorid

Preparation and characterization of N-benzyl-N,O-succinyl chitosan polymeric micelles for solubilization of poorly soluble non-steroidal anti-inflammatory drugs

Purpose: To investigate the solubilization of poorly water-soluble non-steroidal  anti-inflammatory drugs (NSAIDs) in N-benzyl-N,O-succinyl chitosan (BSCS)  polymeric micellesMethods: BSCS was synthesized by reductive amination and succinylation,  respectively. NSAIDs; meloxicam (MX), piroxicam (PRX), ketoprofen (KP) and indomethacin (IND) were entrapped in the hydrophobic inner cores by evaporation method. The effects of drug structure on loading efficiency, particle size and surface charge of micelles were investigated.Results: The critical micelle concentration of BSCS micelles was 0.0385 mg/mL and cytotoxicity on Caco-2 cells depends on the polymer concentration (IC50 = 3.23 ± 0.08 mg/mL). BSCS micelles were able to entrap MX, PRX, KP and IND and also improve the solubility of drugs. Drug loading efficiency was highly dependent on the drug molecules. The drug loading capacity of these BSCS micelles was in the following rank order: KP (282.9 μg/mg) > PRX (200.8 μg/mg) > MX (73.7 μg/mg) > IND (41.2 μg/mg). The highest loading efficiency was observed in KP-loaded BSCS micelles due to the attractive force between phenyl groups of KP and benzyl groups of the polymer. Particle size and surface charge were in the range of 312 - 433 nm and -38 to -41 mV, respectively.Conclusion: BSCS copolymer presents desirable attributes for enhancing the  solubility of hydrophobic drugs. Moreover, BSCS polymeric micelles might be beneficial carrier in a drug delivery system.Keywords: BSCS, polymeric micelles, solubilization, non-steroidal anti-inflammatory drug

Evaluation of a Weakly Cationic Exchange Poly (Methacrylic Acid-Co-Divinylbenzene) Resin as Filler-Binder for Direct Compression Tablets

Purpose: To evaluate a weakly cationic exchange poly(methacrylic acid-co-divinylbenzene) resin (PMD) as a new filler-binder for direct compression tablets. Methods: Powder properties of PMD and MCC were characterized. Tablets made from PMD and MCC with and without propranolol hydrochloride were evaluated for diameter, thickness, friability, assay, disintegration, dissolution and compression behavior. Results: Tablets made from PMD (thickness: 3.54 - 4.46 mm) were thicker than those of MCC (2.93 - 3.33 mm). At compression pressures ≥ 309 MPa, the crushing strength of PMD tablets was so high that it exceeded the capacity of the tester (500 N). PMD tablets rapidly disintegrated (0.43 - 9.56 min), but MCC tablets did not disintegrate within 60 min. The crushing strength of PMD tablets containing 10 and 100 mg propranolol hydrochloride was 406.1 and 177.9 N, respectively, which were lower than that of tablets without the drug. Tablets made from PMD also exhibited faster drug dissolution. The slopes of the linear portions of Heckel plots for PMD and MCC were comparable (5.02×10-3 and 5.12×10-3 MPa-1), respectively. Conclusion: PMD has good compressibility at high compression pressures, which should make it a suitable filler-binder for direct compression tablet

Development and Optimization of <i>Andrographis paniculata</i> Extract-Loaded Self-Microemulsifying Drug Delivery System Using Experimental Design Model

The objectives of this study were to develop an optimized formulation for an Andrographis paniculata extract (AGPE)-loaded self-microemulsifying drug delivery system (SMEDDS) using an experimental design and evaluate the characteristics of the developed SMEDDS. The solubility of andrographolide (AGP) in various solvents was investigated. The pseudo-ternary phase was constructed to provide an optimal range for each component to form microemulsions (MEs). The formulation was optimized using an I-optimal design mixture type, where the physical stability, droplet size, polydispersity index, and zeta potential were examined. Soft capsules of the optimized AGPE-loaded SMEDDS were manufactured. The dissolution and ex vivo membrane permeation were studied. Oleic acid, Tween® 80, and PEG 400 were the best solubilizers for AGP. The promising surfactant to co-surfactant ratio to generate ME was 3:1. The optimized SMEDDS contained 68.998% Tween® 80, with 13.257% oleic acid and 17.745% PEG 400. The assayed content of AGP, uniformity of dosage unit, and stability complied with the expected specifications. The dissolution and membrane permeability of AGPE-loaded SMEDDS was significantly improved from the A. paniculata extract (p < 0.05). All in all, the developed optimized AGPE-loaded SMEDDS was proven to contain optimal composition and AGP content where a stable ME could spontaneously be formed with enhanced delivery efficacy

Fabrication and characterization of spearmint oil loaded nanoemulsions as cytotoxic agents against oral cancer cell

Spearmint oil (SMO), a commonly used essential oil for oral care products, possesses various interesting functions, especially for anticancer property. However, the application of SMO for cancer treatment is limited due to water insoluble. In the present study, nanoemulsions, which have been widely accepted as dosage forms for poorly water-soluble drugs, were selected as candidate carriers for SMO to inhibit oral cancer cell. The nanoemulsions were fabricated using phase inversion temperature method. The factors affecting formation and properties of nanoemulsions including type and amount of surfactants, oil loading and ratio of SMO to virgin coconut oil (VCO) were investigated. Among the surfactants used, the nanoemulsions containing polyoxyethylene castor oil derivatives (Kolliphor®EL; PCO35, Cremophor®RH40; PCO40, Eumulgin®CO60; PCO60) and polyoxyethylene sorbitan fatty acid esters (PSF80) showed 100% creaming after temperature cycling test indicating excellent physical stability while those containing PCO40 demonstrated more transparency and better physical stability. With an increasing amount of PCO40, the droplet size tended to decrease and was in the nano-size range (<1000 nm) after increasing to more than 5% (w/w). SMO-VCO loading also influenced on the droplet size. At 5% (w/w) PCO40, the maximum SMO-VCO loading of 25% (w/w) to attain nanoemulsions was observed. Moreover, the composition of oils had an impact on size of emulsions. The transparent nanoemulsions were only prepared in the range of SMO-VCO from 40:60 to 80:20, suggesting the optimum ratio of SMO to surfactant and the composition of oils were the critical factors for formation of nanoemulsions. NMR study disclosed that the interaction between PCO40 with both VCO and SMO should be a possible stabilization mechanism. Furthermore, the SMO-VCO nanoemulsions exhibited significant cytotoxic effect against oral carcinoma (KON) cell line using MTT assay. The finding, therefore, revealed the good feasibility of SMO-VCO nanoemulsions as novel carriers for treating of oral cancer. Keywords: Nanoemulsions, Spearmint oil, Coconut oil, Surfactants, Anticancer, NM

Pluronic lecithin organogel with d-limonene as a transdermal delivery system for

Kaempferia parviflora (KP) extract has been used in the Thai medicinal plant recipe, which the methoxyflavones are the main active compound. These compounds have low water solubility, high lipophilicity, and low bioavailability. The aim of this study was to develop the pluronic lecithin organogel (PLO) and PLO with d-limonene (PLO-L) for enhancing transdermal delivery of KP extract. These formulations were prepared and their physicochemical properties, stability, and in vitro skin permeation were evaluated. For the result, all formulations exhibited good physicochemical properties and stable under storage condition for 3 months. The permeation of KP extract-loaded PLO-L and PLO formulation showed significantly higher total methoxyflavones permeated through the skin than KP extract in water, which PLO-L provided the highest permeated flux of total methoxyflavones. This result suggested that d-limonene play a role as skin permeation enhancer. Organogel consisting of poloxamer 407 and lecithin also increased the skin permeation of KP extract. In conclusion, PLO-L could be a potential transdermal delivery system for KP extract