Assessment of in Vivo Performance of Lipid-Based Formulations: Correlation between in Vitro Drug Release Profiles and in Vivo Absorption Rate Profiles.

The purpose of this study was to assess the in vivo absorption enhancement effects of lipid-based formulations (LBFs) through in vitro release studies. The type IIIA-MC (medium-chain) and type IIIA-LC (long-chain) formulations containing a Biopharmaceutics Classification System (BCS) Class II drug (dipyridamole or ketoconazole) were used as model LBFs. The type IIIA-MC formulation, but not the type IIIA-LC formulation, showed a higher initial absorption rate than the control suspension for both model drugs in rats. An in vitro side-by-side chamber system coupled with a lipid digestion model was used to measure free drugs, available for intestinal absorption, that are released from a model LBF. The profiles of free drug concentration on the donor side were determined by calculating the ratio of permeation rate (LBF/suspension) at every sampling interval. The in vitro free drug concentration was immediately supersaturated when the digestion of type IIIA-MC formulation was initiated for both drugs, which would cause the initially high absorption rate in rats. In contrast, the free concentration of the type IIIA-LC formulation became lower than the equilibrium solubility over time for both drugs. Overall, the profiles of in vitro free concentrations were consistent with those of in vivo absorption rates for both drugs and all LBFs. These findings would help predict the in vivo performance and establish an in vitro-in vivo correlation (IVIVC) of LBFs.

Development of a Novel Gastric Process Simulation Model: The Successful Assessment of Bioequivalence and Bioinequivalence of a Biopharmaceutics Classification System Class II Weak Acid Drug.

Bioequivalence has been assessed using in vitro dissolution testing, such as in vivo predictive dissolution methodology. However, the assessment of bioequivalence should be performed carefully, considering the effect of the in vivo environment and according to the properties of the drug. The gastric emptying process is a key factor for the assessment of biopharmaceutics classification system class II (BCS class IIa) drugs with acidic properties since they cannot dissolve in the acidic stomach, but do dissolve in the small intestine (SI). The disintegration of a tablet in the stomach affects the distribution/dissolution in the SI due to the difference in the gastric emptying step, which in turn is a result of the varying formulation of the drugs. In this study, we used the reported dynamic pH change method and a novel gastric process simulation (GPS) model, which can compare the gastric emptying of particular-sized drug particles. The in vitro results were compared to clinical data using bioequivalent and bioinequivalent products of candesartan cilexetil. It was revealed that the dynamic pH change method was inappropriate, whereas the amount of filtered drug in GPS studies with 20 and 50 µm pore size filters could reflect the clinical results of all products. The evaluation of the gastric emptying process of drug particles less than 50 µm enabled us to assess the bioequivalence because they probably caused the difference in the distribution in the SI. This study demonstrated the utility of the GPS model for the assessment of bioequivalence of BCS class IIa drugs.

[Effect of physicochemical properties on the pharmacokinetic parameters of the new representative of benzothiazinones antituberculosis drug macozinonе].

INTRODUCTION: Tuberculosis (TB) is one of the top ten causes of death worldwide. Improvement of the treatment options via development of new drugs and treatment regimens that would be more convenient for patients is one of key options of improving the effecacy of the TB prevention and careis. Since the creation of new treatment regimens by minimizing the number of the drugs used and reducing the duration of treatment is the most promising and correct direction, macozinone, a new candidate of the benzothiazinone series, can become the basis for development of new chemotherapy regimens for drug-resistant forms of TB including the combination of macozinone with the most effective modern anti-TB drugs. AIM: Comparative evaluation of the pharmacokinetic properties of macozinone capsules 80 mg and the new dosage form a dispersible tablet for preparation of oral solution. MATERIALS AND METHODS: Solubility of the substance macozinone in biorelevant media in vitro, permeability of macozinone in the test Caco-2 in vitro, as well as pharmacokinetics of macozinone in dogs in vivo were evaluated. RESULTS: The solubility assessment in biorelevant media showed that the average limit of macozinone substance dissolution in the pH 5.0 acetate buffer solution was from 6 to 9 mg/l, in FaSSIF medium (fasted) from 2.5 to 4 mg/l, and in FeSSIF medium (after meals) from 16.8 to 29 mg/l. It is established that the cell permeability of the pharmaceutical substance macozinone in the CACO-2 test system is on average 2.510-6cm/s in the forward direction from the apical to basolateral cell membrane, and 1.510-6cm/s in the reverse direction, which corresponds to low permeability. The main pharmacokinetic parameters of macozinone dispersable tablets 160 mg, after dosing with food and on an empty stomach, as well as capsules 80 mg, when administered on an empty stomach in vivo studies in dogs are presented. DISCUSSION: The specific physicochemical properties of macozinone, the problems of developing the new dosage form, as well as ways of solving some of them are presented. CONCLUSION: In the process of new dosage forms development, the existing chemical properties of the macozinone substance should be considered. One of the promising ways of increasing bioavailability and, consiquently, efficacy is development a fundamentally new drug form with modified release within the absorption window.

Designing of Stable Co-crystals of Zoledronic Acid Using Suitable Coformers.

In this present study a new co-crystals of zoledronic acid with DL-tartaric acid and nicotinamide has been developed with improved solubility. Zoledronic acid is a class III drug with poor oral bioavailability due to its poor permeability and low aqueous solubility; hence an attempt has been made to improve its solubility by co-crystallization technology. Pharmaceutical cocrystals are multi-component crystals with a stoichiometric ratio of active pharmaceutical ingredients (APIs) and cocrystal coformers (CCFs) that are assembled by noncovalent interactions such as hydrogen bonds, π-π packing, and Vander Waals forces. In this study the coformers selected were DL-tartaric acid and nicotinamide based on ease of hydrogen bond formation. The co-crystal of zoledronic acid with DL-tartaric acid were prepared in three ratios (1 : 1, 1 : 2 and 2 : 1) by slow solvent evaporation method and with nicotinamide in 1 : 1 ratio by dry grinding method. The formation of co-crystal was confirmed by powder X-ray diffractometry (PXRD), differential scanning calorimetry (DSC) and Fourier transform (FT)IR. The dynamic solubility of co-crystals with DL-tartaric acid in the ratios 1 : 1, 1 : 2 and 2 : 1 increased by fold as compared to pure drug.