Добірка наукової літератури з теми "Stoichiometric cocrystal"

A synthetic strategy is described for the co-crystallization of four- and five-component molecular crystals, based on the fact that if any particular chemical constituent of a lower cocrystal is found in two different structural environments, these differences may be exploited to increase the number of components in the solid. 2-Methylresorcinol and tetramethylpyrazine are basic template molecules that allow for further supramolecular homologation. Ten stoichiometric quaternary cocrystals and one quintinary cocrystal with some solid solution character are reported. Cocrystals that do not lend themselves to such homologation are termed synthetic dead ends.

The anti-cancer steroidal drug exemestane presents significantly different behavior in cocrystallization with arenes compared with the previously explored steroid progesterone. Mechanochemical and solution-based cocrystallization of exemestane with hydroxy derivatives of phenanthrene and pyrene leads to the formation of cocrystals exhibiting clear O–H···O type arene-steroid hydrogen bonds. So far, exemestane and 1-hydroxypyrene have been observed to form only one type of cocrystal, with the 1:1 stoichiometric ratio of the two components. However, there are two stoichiometric variations of the cocrystal of 9-hydroxyphenanthrene and exemestane, with the arene:steroid stoichiometric ratio of either 1:1 or 1:2. Importantly, although cocrystallization of progesterone with the same arene cocrystal formers was previously reported to take place regioselectively through α···π contacts between the α-face of the steroid and the π-electron surface of the arene, the herein explored cocrystals of exemestane reveal α···π and β···π contacts, as well as sidewise interactions involving the arene π-system and different edges of the steroid molecule. The loss of regioselectivity for the steroid α-face in cocrystallization with the two monohydroxylated arenes is tentatively explained by the highly positive electrostatic surface potential of the steroid β-face and a diminished number of C–H groups on the α-face of exemestane compared with progesterone.

In this present research, an attempt has been made to address the influence of drug-coformer stoichiometric ratio on cocrystal design and its impact on improvement of solubility and dissolution, as well as bioavailability of poorly soluble telmisartan. The chemistry behind cocrystallization and the optimization of drug-coformer molar ratio were explored by the molecular docking approach, and theoretical were implemented practically to solve the solubility as well as bioavailability related issues of telmisartan. A new multicomponent solid form, i.e., cocrystal, was fabricated using different molar ratios of telmisartan and maleic acid, and characterized by SEM, DSC and XRD studies. The molecular docking study suggested that specific molar ratios of drug-coformer can successfully cluster with each other and form a specific geometry with favourable energy conformation to form cocrystals. Synthesized telmisartan-maleic acid cocrystals showed remarkable improvement in solubility and dissolution of telmisartan by 9.08-fold and 3.11-fold, respectively. A SEM study revealed the formation of cocrystals of telmisartan when treated with maleic acid. DSC and XRD studies also confirmed the conversion of crystalline telmisartan into its cocrystal state upon treating with maleic acid. Preclinical investigation revealed significant improvement in the efficacy of optimized cocrystals in terms of plasma drug concentration, indicating enhanced bioavailability through improved solubility as well as dissolution of telmisartan cocrystals. The present research concluded that molecular docking is an important path in selecting an appropriate stoichiometric ratio of telmisartan: maleic acid to form cocrystals and improve the solubility, dissolution, and bioavailability of poorly soluble telmisartan.

A synthetic strategy for the formation of stoichiometric quaternary and nonstoichiometric quinary solids is outlined. A series of 2-nitroresorcinol-based quaternary cocrystals were developed from binary precursors in two conceptual stages. In the first stage, ternary solids are synthesized based on the structural inequivalence at two recognition sites in the binary. In the second stage, the ternary is homologated into a stoichiometric quaternary based on the same concept. Any cocrystal without an inequivalence becomes a synthetic dead end. The combinatorial approach involves lower cocrystal systems with different structural environments and preferred synthon selection from a synthon library in solution. Such are the stepping stones for the isolation of higher cocrystals. In addition, a quaternary cocrystal of 4,6-dichlororesorcinol is described wherein an unusual synthon is observed with two resorcinol molecules in a closed loop with two different ditopic bases. The concept of the virtual synthon in binaries with respect to isolated ternaries is validated for the 4,6-dichlororesorcinol system. It is possible that only some binary systems are amenable to homologation into higher cocrystals. The reasons for this could have to do with the existence of preferred synthon modules, in other words, the critical components of the putative higher assembly that cannot be altered. Addition of the third and fourth component might be more flexible, and the choices of these components, possible from a larger pool of chemically related molecules.

Background and Objective: The top approach to deliver poorly soluble drugs is the use of a highly soluble form. The present study was conducted to enhance the solubility and dissolution of a poorly aqueous soluble drug nevirapine via a pharmaceutical cocrystal. Another objective of the study was to check the potential of the nevirapine cocrystal in the dosage form. Methods: A neat and liquid assisted grinding method was employed to prepare nevirapine cocrystals in a 1:1 and 1:2 stoichiometric ratio of drug:coformer by screening various coformers. The prepared cocrystals were preliminary investigated for melting point and saturation solubility. The selected cocrystal was further confirmed by Infrared Spectroscopy (IR), Differential Scanning Calorimetry (DSC), and Xray Powder Diffraction (XRPD). Further, the cocrystal was subjected to in vitro dissolution study and formulation development. Results: The cocrystal of Nevirapine (NVP) with Para-Amino Benzoic Acid (PABA) coformer prepared by neat grinding in 1:2 ratio exhibited greater solubility. The shifts in IR absorption bands, alterations in DSC thermogram, and distinct XRPD pattern showed the formation of the NVP-PABA cocrystal. Dissolution of NVP-PABA cocrystal enhanced by 38% in 0.1N HCl. Immediate release tablets of NVP-PABA cocrystal exhibited better drug release and less disintegration time. Conclusion: A remarkable increase in the solubility and dissolution of NVP was obtained through the cocrystal with PABA. The cocrystal also showed great potential in the dosage form which may provide future direction for other drugs.

Most of the Active Pharmaceutical Ingredients (APIs) are typically formulated and administered to patients in oral solid dosage forms due to ease of administration, patient compliance and cost effectiveness. Poor water solubility, low permeability and low bioavailability of APIs are major hurdles in development of oral solid dosage forms. In recent years, cocrystal development has evolved as a feasible approach for enhancing the solubility and bioavailability of poorly soluble drugs. Crystal engineering strategies have been asserted to enhance the likelihood of discovering new solid forms of an API. A pharmaceutical cocrystal is made up of two basic components, an API and a harmless material known as a coformer in stoichiometric ratio. Cocrystallization of an API with a pharmaceutically acceptable coformer can improve the physical characteristics of the API, such as solubility, hygroscopicity, and compaction behavior, without affecting the API's pharmacological efficacy. This review article offers a comprehensive overview of pharmaceutical cocrystals, their physiochemical characteristics, and methods of preparation, with an emphasis on cocrystal screening and cocrystal characterization. The review also included recent FDA and EMA guidance on pharmaceutical cocrystals as well as an outline of multidrug cocrystals. Keywords: Pharmaceutical co-crystals, crystal engineering, coformers, supramolecular synthons, Solubility

The objective of this study was to improve the solubility of poorly water-soluble drugs by pharmaceutical cocrystal engineering techniques and select the best pharmaceutical forms with high solubility and solubilized formulations for progress from the early discovery stage toward the clinical stage. Several pharmaceutical cocrystals of TAK-020, a Bruton tyrosine kinase inhibitor, were newly discovered in the screening based on the solid grinding method and the slurry method, considering thermodynamic factors that dominate cocrystal formation. TAK-020/gentisic acid cocrystal (TAK-020/GA CC) was selected based on a physicochemical property of enhanced dissolution rate. TAK-020/GA CC was proven to be a reliable cocrystal formation with a definitive stoichiometric ratio by a variety of analytical techniques—pKa calculation, solid-state nuclear magnetic resonance, and single X-ray structure analysis from the view of regulation. Furthermore, its absorption was remarkable and beyond those achieved in currently existing solubilized formulation techniques, such as nanocrystal, amorphous solid dispersion, and lipid-based formulation, in dog pharmacokinetic studies. TAK-020/GA CC was the best drug form, which might lead to good pharmacological effects with regard to enhanced absorption and development by physicochemical characterization. Through the trials of solid-state optimization from early drug discovery to pharmaceutical drug development, the cocrystals can be an effective option for achieving solubilization applicable in the pharmaceutical industry.

Cocrystals have gained attention in the pharmaceutical industry due to their ability to improve solubility, stability, in vitro dissolution rate, and bioavailability of poorly soluble drugs. Conceptually, cocrystals are multicomponent solids that contain two or more neutral molecules in stoichiometric amounts within the same crystal lattice. There are several techniques for obtaining cocrystals described in the literature; however, the focus of this article is the Reaction Crystallization Method (RCM). This method is based on the generation of a supersaturated solution with respect to the cocrystal, while this same solution is saturated or unsaturated with respect to the components of the cocrystal individually. The advantages of the RCM compared with other cocrystallization techniques include the ability to form cocrystals without crystallization of individual components, applicability to the development of in situ techniques for the screening of high quality cocrystals, possibility of large-scale production, and lower cost in both time and materials. An increasing number of scientific studies have demonstrated the use of RCM to synthesize cocrystals, mainly for drugs belonging to class II of the Biopharmaceutics Classification System. The promising results obtained by RCM have demonstrated the applicability of the method for obtaining pharmaceutical cocrystals that improve the biopharmaceutical characteristics of drugs.

Cocrystal is one form of modification in increasing the solubility of meloxicam which is included in Biopharmaceutics Classifications System (BCS) II. Cocrystal is a multicomponent system with a stoichiometric ratio between the active ingredient and the coformer which are bound in the crystals lattice to form hydrogen bonds. Design of new drugs can be done through an in silico program to optimize the parent compound before the synthesis of derivative compounds. This study aims to predict which coformers are most stable in the formation of crystals. Cocrystal formation is done by drawing a two-dimensional structure from meloxicam and coformer using ChemBioDraw Professional 16.0 software from CambridgeSoft®. The prediction will result in the amount of bond energy formed between meloxicam with coformer. The smaller the bond energy, the more stable the meaning of the bond. The smaller the bond energy formed, the more stable the bond is. Stable bonds have a high probability of forming cocrystals meloxicam. Hydrogen bonds occur between hydrogen atoms and other atoms that have high electronegativities such as O and N atoms which have lone pairs of electrons. This electronegativity difference makes H atoms tightly bound to O and N atoms so that the hydrogen bonds in the meloxicam cocrystal are tightly bound and stable. From the results of the study showed that the most stable coformer can form cocrystals with a small bond energy that can produce bonds with meloxicam, namely urea.

A cocrystal of the antihypertensive drug chlorthalidone (CTD) with caffeine (CAF) was obtained (CTD-CAF) by the slurry method, for which a 2:1 stoichiometric ratio was found by powder and single-crystal X-ray diffraction analysis. Cocrystal CTD-CAF showed a supramolecular organization in which CAF molecules are embedded in channels of a 3D network of CTD molecules. The advantage of the cocrystal in comparison to CTD is reflected in a threefold solubility increase and in the dose/solubility ratios, which diminished from near-unit values for D0D to 0.29 for D0CC. Furthermore, dissolution experiments under non-sink conditions showed improved performance of CTD-CAF compared with pure CTD. Subsequent studies showed that CTD-CAF cocrystals transform to CTD form I where CTD precipitation inhibition could be achieved in the presence of pre-dissolved polymer HPMC 80–120 cPs, maintaining supersaturation drug concentrations for at least 180 min. Finally, dissolution experiments under sink conditions unveiled that the CTD-CAF cocrystal induced, in pH-independent manner, faster and more complete CTD dissolution when compared to commercial tablets of CTD. Due to the stability and dissolution behavior of the novel CTD-CAF cocrystal, it could be used to develop solid dosage forms using a lower CTD dose to obtain the same therapeutic response and fewer adverse effects.

The thesis entitled “Structure-function control in organic co-crystals/salts via studies on polymorphism, phase transitions and stoichiometric variants” consists of five chapters. The main emphasis of the thesis is on two aspects, one to characterize co-crystal polymorphism in terms of propensity of intermolecular interactions to form co-crystals/salts or eutectics. The other aspect is to explore the feasibility of using such co-crystals/salts to exhibit properties like proton conduction, dielectric and ferroelectric behaviour. Gallic acid and its analogues possess functionalities to provide extensive hydrogen bonding capabilities and are chosen as the main component while the coformers are carefully selected such that they either accept or reject the hydrogen bonding offered. Such co-crystallization experiments therefore provide an opportunity to unravel the intricate details of the formation of crystalline polymorphs and/or eutectics at the molecular level. Further these co-crystal systems have been exploited to evaluate proton conductivity, dielectric and ferroelectric features since the focus is also on the design aspect of functional materials. In the context of identifying and utilizing Crystal Engineering tools, the discussions in the following chapters address not only the structural details but identify the required patterns and motifs to enable the design of multi-component co-crystals/salts and eutectics. In particular, the presence/absence of lattice water in gallic acid has been evaluated in terms of importing the required physical property to the system. Chapter 1 discusses the structural features of tetramorphic anhydrous co-crystals (1:1; which are synthon polymorphs) generated from a methanolic solution of gallic acid monohydrate and acetamide, all of which convert to a stable form on complete drying. The pathway to the stable form (1:3 co-crystal) is explained based on the variability in the hydrogen bonding patterns followed by lattice energy calculations. Chapter 2A studies the presence/absence and geometric disposition of hydroxyl functionality on hydroxybenzoic acids to drive the formation of co-crystal/eutectic in imide-carboxylic acid combinations. In Chapter 2B the crystal form diversity of gallic acid-succinimide co-crystals are evaluated with major implications towards the design and control of targeted multi-component crystal forms. The co-crystal obtained in this study shows a rare phenomenon of concomitant solvation besides concomitant polymorphism and thus making it difficult to obtain a phase-pure crystal form in bulk quantity. This issue has been resolved and formation of desired target solid form is demonstrated. Thus, this study addresses the nemesis issues of co-crystallization with implications in comprehending the kinetics and thermodynamics of the phenomenon in the goal of making desired materials. Chapter 3 focuses on the systematic co-crystallization of hydroxybenzoic acids with hexamine using liquid assisted grinding (LAG) which show facile solid state interconversion among different stoichiometric variants. The reversible interconversion brought about by varying both the acid and base components in tandem is shown to be a consequence of hydrogen bonded synthon modularity present in the crystal structures analyzed in this context. In Chapter 4A, the rationale for the proton conduction in hydrated/anhydrous salt/co-crystal of gallic acid - isoniazid is provided in terms of the structural characteristics and the conduction pathway is identified to follow Grotthuss like mechanism which is supplemented by theoretical calculations. Chapter 4B describes an extensive examination of the hydrated salt of gallic acid-isoniazid which unravels the irreversible nature of the dielectric property upon dehydration and suggests that the “ferroelectric like” behaviour is indeed not authenticated. This chapter brings out the significance role of lattice water in controlling the resulting physical property (dielectric/ferroelectric in this case). Chapter 5 describes the structural features of two hydrated quaternary salts of hydroxybenzoic acids-isoniazid-sulfuric acid and the phase transitions at both low and high temperatures are shown to be reversible. Single Crystal to Single Crystal (SCSC) in situ measurement corroborated by thermal and in situ Powder X-ray Diffraction studies proves the claim. Further, the properties exhibited by these materials are also governed by lattice water content.