Pharmaceutical Co-crystal of Antiviral Agent Efavirenz with Nicotinamide for the Enhancement of Solubility, Physicochemical Stability, and Oral Bioavailability

Cocrystallization of amantadine hydrochloride with nutrient: Insights into directed self- assembly and optimized biopharmaceutical character by integrating theory and experiment

In order to make full use of the advantages of phenolic acid nutraceutical p-coumaric acid (COA) in cocrystallizing with antiviral medication amantadine hydrochloride (ADH), further get innovative insights into assembling ADH-nutraceutical cocrystal and optimizing biopharmaceutical characters of ADH by combining experiment with theory, a novel cocrystal, ADH-COA, is prepared and structurally characterized. Single-crystal X-ray diffraction confirms that the cocrystal consists of COA and ADH molecules in a 1:2 ratio, building a three-dimensional supramolecular network strengthened by charge-assisted hydrogen bonds and tightly packed patterns, which is distinguished by two distinct conformations H-1 and H-2 arising from neutral COA molecules with different counter-ions of ADH within the lattice. These features endow the cocrystal with promoting charge dispersion and polarity reduction, resulting in 37.11 ∼ 41.39 % solubility reduction under different pH conditions versus raw ADH, contributing to mitigating side effects associated with excessive solubility of ADH. Such change of in vitro property, in turn, optimizes in vivo pharmacokinetics, showcasing the lengthened half-life and enhanced 1.45-fold bioavailability. Emphatically, these experimental findings are corroborated by DFT-based theoretical models, demonstrating some positive correlations between macroscopic properties and microstructures of the cocrystal. Thereby, the dual-optimization of in vivo/vitro properties of ADH allows to be fulfilled through the cocrystallization-driven strategy.

Revolutionizing Antiviral Therapeutics: Unveiling Innovative Approaches for Enhanced Drug Efficacy

Since the beginning of the coronavirus pandemic in late 2019, viral infections have become one of the top three causes of mortality worldwide. Immunization and the use of immunomodulatory drugs are effective ways to prevent and treat viral infections. However, the primary therapy for managing viral infections remains antiviral and antiretroviral medication. Unfortunately, these drugs are often limited by physicochemical constraints such as low target selectivity and poor aqueous solubility. Although several modifications have been made to enhance the physicochemical characteristics and efficacy of these drugs, there are few published studies that summarize and compare these modifications. Our review systematically synthesized and discussed antiviral drug modification reports from publications indexed in Scopus, PubMed, and Google Scholar databases. We examined various approaches that were investigated to address physicochemical issues and increase activity, including liposomes, cocrystals, solid dispersions, salt modifications, and nanoparticle drug delivery systems. We were impressed by how well each strategy addressed physicochemical issues and improved antiviral activity. In conclusion, these modifications represent a promising way to improve the physicochemical characteristics, functionality, and effectiveness of antivirals in clinical therapy.

Advancing Drug Delivery Paradigms: Polyvinyl Pyrolidone (PVP)-Based Amorphous Solid Dispersion for Enhanced Physicochemical Properties and Therapeutic Efficacy

BACKGROUND

The current challenge in drug development lies in addressing the physicochemical issues that lead to low drug effectiveness. Solubility, a crucial physicochemical parameter, greatly influences various biopharmaceutical aspects of a drug, including dissolution rate, absorption, and bioavailability. Amorphous solid dispersion (ASD) has emerged as a widely explored approach to enhance drug solubility.

OBJECTIVE

The objective of this review is to discuss and summarize the development of polyvinylpyrrolidone (PVP)-based amorphous solid dispersion in improving the physicochemical properties of drugs, with a focus on the use of PVP as a novel approach.

METHODOLOGY

This review was conducted by examining relevant journals obtained from databases such as Scopus, PubMed, and Google Scholar, since 2018. The inclusion and exclusion criteria were applied to select suitable articles.

RESULTS

This study demonstrated the versatility and efficacy of PVP in enhancing the solubility and bioavailability of poorly soluble drugs. Diverse preparation methods, including solvent evaporation, melt quenching, electrospinning, coprecipitation, and ball milling are discussed for the production of ASDs with tailored characteristics.

CONCLUSION

PVP-based ASDs could offer significant advantages in the formulation strategies, stability, and performance of poorly soluble drugs to enhance their overall bioavailability. The diverse methodologies and findings presented in this review will pave the way for further advancements in the development of effective and tailored amorphous solid dispersions.