Computational and Experimental Insights in Design and Development of Aceclofenac Co-Crystals

Mehta, C.H.; Srinivas, P.P.; Anusha, S.B.; Mahany, K.B.F.; Koteshwara, K.B.; Nayak, U.Y.

doi:10.52711/0974-360X.2022.00622

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Computational and Experimental Insights in Design and Development of Aceclofenac Co-Crystals
Citation	Mehta CH, Srinivas PP, Anusha SB, Mahany KBF, Koteshwara KB, Nayak UY. Research Journal of Pharmacy and Technology 2022; 15(8): 3709-3716.
Copyright	(Copyright © 2022)
DOI	10.52711/0974-360X.2022.00622
PMID	unavailable
Abstract	The present study is aimed at the design and development of aceclofenac co-crystals. Co-crystallization is one of the important techniques which helps to enhance the aqueous solubility of drugs by modifying the crystal structure using incorporation of the co-former into the formulation.. In the present study, supramolecular synthon approach and computational grid scan methods were used for the co-former selection. The different co-formers such as oxalic acid (OA), succinic acid (SA), maleic acid (MA), and benzoic acid (BA) were used. Aceclofenac (ACF) co-crystals were prepared by solvent evaporation and dry grinding method. Based on the computational results and experimental saturation solubility studies, maleic acid was considered as the suitable co-former for the preparation. The solid-state characterization showed partial conversion of ACF crystallinity to the amorphization as evident from the decrease in peak intensity and the number of peaks. The co-crystals showed increased aqueous solubility of ACF and higher drug release in basic pH. All the characterization parameters proved the co-crystal formation and the in vitro release studies showed that the solubility enhancement of the ACF by preparing ACF-MA co-crystals. Thus, it can be concluded that co-crystallization is one of the novel method for improving the bioavailability of aceclofenac. © RJPT All right reserved. Language: en
Keywords	suicide; X ray diffraction; nonsteroid antiinflammatory agent; oxalic acid; drug formulation; crystal structure; hydrogen bond; drug bioavailability; crystallization; Article; binding affinity; drug dosage form; drug stability; infrared spectroscopy; drug solubility; bioavailability; molecular docking; evaporation; atomic force microscopy; aceclofenac; Aceclofenac; benzoic acid; Co-crystals; Computational grid scan calculations; Dry grinding technique; excipient compatibility; grinding; maleic acid; Solvent evaporation method; succinic acid; Supramolecular synthon approach