Maryam Karimi-Jafari scite author profile

Originally discovered almost a century ago, cocrystals continue to gain interest in the modern day due to their ability to modify the physical properties of solid-state materials, particularly pharmaceuticals. Intensification of cocrystal research efforts has been accompanied by an expansion of the potential applications where cocrystals can offer a benefit. Where once solubility manipulation was seen as the primary driver for cocrystal formation, cocrystals have recently been shown to provide attractive options for taste masking, mechanical property improvement, and intellectual property generation and extension. Cocrystals are becoming a commercial reality with a number of cocrystal products currently on the market and more following in registration and clinical trial phases. Increased commercialization of cocrystals has in turn necessitated additional research on methods to make cocrystals, with particular emphasis placed on emerging technologies that can offer environmentally attractive and efficient options. Methods of producing cocrystals and of harnessing the bespoke physical property adjustment provided by cocrystals are reviewed in this article, with a particular focus on emerging trends in these areas.

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In-line Raman spectroscopy and chemometrics for monitoring cocrystallisation using hot melt extrusion

Karimi-Jafari

Albadarin

Croker

et al. 2021

International Journal of Pharmaceutics

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Impact of polymeric excipient on cocrystal formation via hot-melt extrusion and subsequent downstream processing

Karimi-Jafari

Ziaee

Iqbal

et al. 2019

International Journal of Pharmaceutics

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Formation of Ciprofloxacin–Isonicotinic Acid Cocrystal Using Mechanochemical Synthesis Routes—An Investigation into Critical Process Parameters

et al. 2022

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The mechanochemical synthesis of cocrystals has been introduced as a promising approach of formulating poorly water-soluble active pharmaceutical ingredients (APIs). In this study, hot-melt extrusion (HME) as a continuous process and grinding and ball milling as batch processes were employed to explore the feasibility of cocrystallization. Ciprofloxacin (CIP) and isonicotinic acid (INCA) were selected as the model API and coformer. CIP–INCA cocrystal was produced in all techniques. It was revealed that higher cocrystal content could be achieved at longer durations of grinding and ball milling. However, milling for more than 10 min led to increased co-amorphous content instead of cocrystal. A design of experiment (DoE) approach was used for deciphering the complex correlation of screw configuration, screw speed, and temperature as HME process parameters and their respective effect on final relative cocrystal yield. Statistical analysis showed that screw configuration, temperature, and their interaction were the most critical factors affecting cocrystallization. Interestingly, screw speed had minimal impact on the relative cocrystallization yield. Cocrystallization led to increased dissolution rate of CIP in phosphate buffer up to 2.5-fold. Overall, this study shed a light on the potential of mechanochemical synthesis techniques with special focus on HME as a continuous process for producing cocrystals.

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3.22 Spark Plasma Sintering of Lead-Free Ferroelectric Ceramic Layers

Karimi-Jafari

Kowal

ul-Haq

et al. 2017

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