Investigation of the Capacity of Low Glass Transition Temperature Excipients to Minimize Amorphization of Sulfadimidine on Comilling

Curtin, Vincent; Amharar, Youness; Hu, Yun; Erxleben, Andrea; McArdle, Patrick; Caron, Vincent; Tajber, Lidia; Corrigan, Owen I.; Healy, Anne Marie

doi:10.1021/mp300529a

Cited by 26 publications

(19 citation statements)

References 45 publications

(88 reference statements)

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“…Co-milling and freeze drying with hydrophilic polymers were used to form amorphous glass solutions and hot-melt extrusion of drugs using mixtures of low-melting polymers and surfactants were also employed for co-amorphization (Zhang et al, 2014). Some di and tricarboxylic acids have the ability to adjust the glass transition temperature of the composite solid dispersion by the antiplasticizing effects thus protecting the amorphous state of the resulting dispersion (Curtin et al, 2012). In this study, solvent evaporation under vacuum was used for the preparation of solid dispersions of OL and poly carboxylic acids followed by incorporation of successful co-amorphous dispersions into different film formulations, followed by incorporation in different film formulations.…”

Section: Introductionmentioning

confidence: 99%

In vitro/in vivo evaluation of an optimized fast dissolving oral film containing olanzapine co-amorphous dispersion with selected carboxylic acids

et al. 2016

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Improvement of water solubility, dissolution rate, oral bioavailability, and reduction of first pass metabolism of OL (OL), were the aims of this research. Co-amorphization of OL carboxylic acid dispersions at various molar ratios was carried out using rapid solvent evaporation. Characterization of the dispersions was performed using differential scanning calorimetry (DSC), Fourier transform infrared spectrometry (FTIR), X-ray diffractometry (XRD), and scanning electron microscopy (SEM). Dispersions with highest equilibrium solubility were formulated as fast dissolving oral films. Modeling and optimization of film formation were undertaken using artificial neural networks (ANNs). The results indicated co-amorphization of OL-ascorbic acid through H-bonding. The co-amorphous dispersions at 1:2 molar ratio showed more than 600-fold increase in solubility of OL. The model optimized fast dissolving film prepared from the dispersion was physically and chemically stable, demonstrated short disintegration time (8.5 s), fast dissolution (97% in 10 min) and optimum tensile strength (4.9 N/cm 2 ). The results of in vivo data indicated high bioavailability (144 ng h/mL) and maximum plasma concentration (14.2 ng/mL) compared with the marketed references. Therefore, the optimized co-amorphous OL-ascorbic acid fast dissolving film could be a valuable solution for enhancing the physicochemical and pharmacokinetic properties of OL.

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Section: Introductionmentioning

confidence: 99%

In vitro/in vivo evaluation of an optimized fast dissolving oral film containing olanzapine co-amorphous dispersion with selected carboxylic acids

et al. 2016

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“…Particle engineering and solid form modification of APIs and functional excipients can occur during spray drying [66,67], crystallization [68], milling [69,70], wet extrusion, wet granulation and hot melt extrusion [71]. Multiparticulate systems and tablet dosage forms can be coated by functional excipients to modify drug release [72], to avoid chemical degradation [73] and to reduce irritation of parts of the gastrointestinal tract [74].…”

Section: Phase Transformation Of Hydrates and Solvatesmentioning

confidence: 99%

Pharmaceutical solvates, hydrates and amorphous forms: A special emphasis on cocrystals

Healy

Worku

Kumar

et al. 2017

Advanced Drug Delivery Reviews

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a b s t r a c t a r t i c l e i n f oActive pharmaceutical ingredients (APIs) may exist in various solid forms, which can lead to differences in the intermolecular interactions, affecting the internal energy and enthalpy, and the degree of disorder, affecting the entropy. Differences in solid forms often lead to differences in thermodynamic parameters and physicochemical properties for example solubility, dissolution rate, stability and mechanical properties of APIs and excipients. Hence, solid forms of APIs play a vital role in drug discovery and development in the context of optimization of bioavailability, filing intellectual property rights and developing suitable manufacturing methods. In this review, the fundamental characteristics and trends observed for pharmaceutical hydrates, solvates and amorphous forms are presented, with special emphasis, due to their relative abundance, on pharmaceutical hydrates with single and two-component (i.e. cocrystal) host molecules.

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“…Without an obvious sign of recrystallization, the diacids with relatively low T g s, i.e., MAE (4.6 • C) and MAL (−20 • C), on the other hand, resulted in Class III GFA behavior [16,40]. It has been shown that for co-milling and spray-drying, which are also major sources of inducing amorphization, high T g excipients confer functional advantages for stabilizing the amorphous drugs [41][42][43][44][45]. However, the opposite trend was observed in our study, i.e., the crystallization tendency was positively correlated with the T g of the coformer (Figure 2).…”

Section: Role Of C4 Diacid Coformers In Altering the Glass-forming Abmentioning

confidence: 99%

Effects of the Glass-Forming Ability and Annealing Conditions on Cocrystallization Behaviors via Rapid Solvent Removal: A Case Study of Voriconazole

et al. 2020

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The kinetic entrapment of molecules in an amorphous phase is a common obstacle to cocrystal screening using rapid solvent removal, especially for drugs with a moderate or high glass-forming ability (GFA). The aim of this study was to elucidate the effects of the coformer’s GFA and annealing conditions on the nature of amorphous phase transformation to the cocrystal counterpart. Attempts were made to cocrystallize voriconazole (VRC) with four structural analogues, namely fumaric acid (FUM), tartaric acid (TAR), malic acid (MAL), and maleic acid (MAE). The overall GFA of VRC binary systems increased with decreasing glass transition temperatures (Tgs) of these diacids, which appeared as a critical parameter for predicting the cocrystallization propensity such that a high-Tg coformer is more desirable. A new 1:1 VRC-TAR cocrystal was successfully produced via a supercooled-mediated re-cocrystallization process, and characterized by PXRD, DSC, and FTIR. The cocrystal purity against the annealing temperature displayed a bell-shaped curve, with a threshold at 40 °C. The isothermal phase purity improved with annealing and adhered to the Kolmogorov–Johnson–Mehl–Avrami kinetics. The superior dissolution behavior of the VRC-TAR cocrystal could minimize VRC precipitation upon gastric emptying. This study offers a simple but useful guide for efficient cocrystal screening based on the Tg of structurally similar coformers, annealing temperature, and time.

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Investigation of the Capacity of Low Glass Transition Temperature Excipients to Minimize Amorphization of Sulfadimidine on Comilling

Cited by 26 publications

References 45 publications

In vitro/in vivo evaluation of an optimized fast dissolving oral film containing olanzapine co-amorphous dispersion with selected carboxylic acids

In vitro/in vivo evaluation of an optimized fast dissolving oral film containing olanzapine co-amorphous dispersion with selected carboxylic acids

Pharmaceutical solvates, hydrates and amorphous forms: A special emphasis on cocrystals

Effects of the Glass-Forming Ability and Annealing Conditions on Cocrystallization Behaviors via Rapid Solvent Removal: A Case Study of Voriconazole

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