Separation of Enantiomers by Continuous Preferential Crystallization: Experimental Realization Using a Coupled Crystallizer Configuration

Chaaban, Joussef Hussein; Dam‐Johansen, Kim; Skovby, Tommy; Kiil, Søren

doi:10.1021/op400087g

Cited by 22 publications

(41 citation statements)

References 35 publications

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“…The presence of the counter enantiomer can also cause undesired side effects in patients such as in the case of thalidomide . In this tragic case, the (S)‐enantiomer of thalidomide was a potent teratogen, whereas the (R)‐enantiomer was prescribed to alleviate morning sickness for pregnant women . The unmonitored administration of the drug resulted in physical birth defects due to the drugs rapid enantioconversion under physiological conditions .…”

Section: Introductionmentioning

confidence: 99%

Diastereomeric salt crystallization of chiral moleculesvia sequential coupled‐Batch operation

et al. 2018

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A novel process, sequential coupled‐batch diastereomeric crystallization is presented for the resolution of racemic mixtures. This strategy utilized a preferential crystallization of diastereomeric salt followed by sequential coupled diastereomeric salt resolution of racemic ibuprofen with the resolving agent (S)‐lysine utilizing a novel small scale pneumatic liquid exchange design to couple two batch crystallizers. Results were compared to conventional sequential resolution via seeded isothermal batch crystallization. Diastereomeric salt resolution was developed using the ternary phase diagram of the isolated (R)‐ibuprofen‐(S)‐lysine and (S)‐ibuprofen‐(S)‐lysine salts and optimized empirically with the aid of process analytical technology. Sequential coupled‐batch crystallization was found to be capable of increasing the yield of both salts while maintaining purity. This gave an increase in both the productivity and yield (20.5% for (S)‐ibuprofen‐(S)‐lysine) compared to the equivalent sequential batch (17.7% for (S)‐ibuprofen‐(S)‐lysine) crystallization methodology. Single crystals of the (S)‐ibuprofen‐(S)‐lysine were isolated, and its single crystal structure determined. © 2018 American Institute of Chemical Engineers AIChE J, 65: 604–616, 2019

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Section: Introductionmentioning

confidence: 99%

Diastereomeric salt crystallization of chiral moleculesvia sequential coupled‐Batch operation

et al. 2018

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“…However, Qamar et al still used continuous or periodic seeding to accomplish their separation performance (in the case of Qamar et al seed crystals for both enantiomers were needed). An experimental implementation of a similar process was presented by Chaaban et al, who, however, only treated the liquid phase in a continuous fashion and needed to restart their process with fresh seeds after some time. Furthermore, the yield obtained from all three processes was rather low.…”

Section: The Flow Sheet and Its Rationalementioning

confidence: 99%

Separation of conglomerate forming enantiomers using a novel continuous preferential crystallization process

2015

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in Wiley Online Library (wileyonlinelibrary.com) Providing enantiomerically pure products is of key importance in the fine chemicals, food, and pharmaceutical industries. A continuous preferential crystallization process is presented that allows the separation of conglomerate forming enantiomers in a stable, robust, and flexible way. This is achieved by coupling two continuous crystallizers by exchanging their clear liquid phases. Each crystallizer is connected to a suspension mill responsible for in situ seed generation through particle breakage. The dynamic and steady-state behavior of this process is extensively analyzed for racemic feed streams through process simulations, and parameter regions, which yield pure enantiomers in both crystallizers, are identified. For enriched feed streams, it is further shown when this novel flow sheet is capable of outperforming an ideal batch process in terms of solvent consumption per unit mass of desired enantiopure product produced.

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“…The correct chemical (e.g., enantiomer 103 ) and solid forms are selected before deciding on seed crystal size and loading, as described in step 1 of section 2. Most in situ seed generation methods can be applied off line.…”

Section: Seed Generationmentioning

confidence: 99%

Designs of continuous-flow pharmaceutical crystallizers: developments and practice

2019

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Separation of Enantiomers by Continuous Preferential Crystallization: Experimental Realization Using a Coupled Crystallizer Configuration

Cited by 22 publications

References 35 publications

Diastereomeric salt crystallization of chiral moleculesvia sequential coupled‐Batch operation

Diastereomeric salt crystallization of chiral moleculesvia sequential coupled‐Batch operation

Separation of conglomerate forming enantiomers using a novel continuous preferential crystallization process

Designs of continuous-flow pharmaceutical crystallizers: developments and practice

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