Population-Based Mathematical Model of Solid-State Deracemization via Temperature Cycles

Bodák, Brigitta; Maggioni, Giovanni Maria; Mazzotti, Marco

doi:10.1021/acs.cgd.8b01292

Cited by 36 publications

(73 citation statements)

References 35 publications

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“…Several groups have studied the behaviour of the process of temperature-cycling-induced deracemization, either experimentally or computationally via the use of population balance equations. While earlier experimental studies relied on simple first-order kinetics expressions to describe the progress and the time-evolution of the enantiomeric excess [8], later more detailed models using population balance equations have been developed [10][11][12][13]. In the context of this work, we were looking for a simple way to quantify the efficiency of the deracemization process depending on the process settings of individual trials and relate it to the number of cycles performed.…”

Section: Evaluation Of Resultsmentioning

confidence: 99%

“…Existing literature addressing deracemization reveals no general agreement on the impact of various factors governing the shape of ee profiles during temperature cycling. While some results show an inflection point in the progress of ee with the number of temperature cycles [6,10,25,26], others show an exponential character throughout the evolution of the enantiomeric excess [8,9,21].…”

Section: Effect Of Initial Enantiomeric Excess Ee(0)and Particle Sizementioning

confidence: 99%

“…In contrast to Viedma ripening, where particle agglomeration and breakage are essential phenomena for driving the process, for temperature cycling the key factor is sizedependent solubility [6,10]: Following the Gibbs-Thomson equation the solubility of a certain particle is proportional (but not necessarily equal) to the bulk solubility of the substance (accessible via standard solubility measurements) [27]. The proportionality factor is a function of the particle size (as well as of the interfacial tension and the temperature).…”

Section: Effect Of Initial Enantiomeric Excess Ee(0)and Particle Sizementioning

confidence: 99%

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Complete chiral resolution in a continuous flow crystallizer with recycle stream

2021

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Repeated temperature cycling of crystals from a conglomerate forming chiral substance suspended in their saturated solution has shown to be effective in converting a mixture of both enantiomers into an enantiomerically pure state. While by now a large number of different setups has been demonstrated, here we show for the first time how a continuous flow temperature cycler with recycle stream is capable of establishing enantiopurity while converting a racemic starting suspension. By capturing the most significant parameters influencing the process kinetics a competitive productivity could be achieved. We show, that fast crystal dissolution at high undersaturations and fast crystal growth at high supersaturations are speeding up the process as long as nucleation can be kept to a minimum or avoided at all. Temperature cycling has shown to result in a shift towards larger sizes for the particle size distribution of the crystals suspended, which is detrimental to the present process governed by size-dependent solubility. By implementing an ultrasound unit recycled material was comminuted, resulting in nearly stable deracemization rates. Graphical abstract

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Section: Evaluation Of Resultsmentioning

confidence: 99%

Section: Effect Of Initial Enantiomeric Excess Ee(0)and Particle Sizementioning

confidence: 99%

Section: Effect Of Initial Enantiomeric Excess Ee(0)and Particle Sizementioning

confidence: 99%

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Complete chiral resolution in a continuous flow crystallizer with recycle stream

2021

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“…Iggland and Mazzotti 22 for the isothermal case and Bodàk et al 28 for the polythermal case, the relevant population balance equations can be written as…”

Section: Population Balance Equations and Mass Balancesmentioning

confidence: 99%

Designing Isothermal Batch Deracemization Processes with Optimal Productivity: 1. Parametric Analysis Using a Population Balance Equation Model

Vetter¹

2020

Crystal Growth & Design

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Isothermal batch deracemization (Viedma ripening) is an attractive process variant to separate conglomerate forming enantiomers. These processes rely on a complex interplay between a racemization reaction in the liquid phase and crystal growth/dissolution, agglomeration and breakage in the solid phase. While reports in the literature have explored using a parametric sensitivity analysis carried out on a process model based on dimensionless population balance equations. The general trends identified from the parametric analysis highlight that processes with maximum productivity should be carried out at i) high breakage intensities, ii) low agglomeration intensities, and iii) high suspension densities. The initial enantiomeric excess necessary to reach maximum productivity varies strongly with the kinetics of the different phenomena involved and falls within a wide range of 25-80%.

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“…The observed increase in chiral enrichment in the solid phase has been ascribed to a difference in growth rate dispersion between the two enantiomeric crystal size distributions or to a crystal growth mechanism that involves (partial) incorporation of small chiral clusters into crystals of the same chirality . A recent publication that simulates TCID by using a population balance model claims that growth, dissolution, and racemization processes alone can explain deracemization without the need for breakage or agglomeration, as long as both temperature and size dependence of solubility (through the Gibbs–Thomson equation) are taken into account . Indeed, alternative mechanisms to conventional crystal growth following McCabe's Δ L law have been sought to explain deracemization, which, because it features equal growth/dissolution kinetics for the different chiral populations, would lead to no changes in enantiomeric enrichment during temperature cycling even in the presence of fast racemization .…”

Section: Introductionmentioning

confidence: 99%

On the Effect of Secondary Nucleation on Deracemization through Temperature Cycles

Cameli

Horst

Steendam³

et al. 2020

Chemistry A European J

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Herein, the pivotal role of secondaryn ucleation in ac rystallization-enhanced deracemization process is reported. During this process, complete and rapid deracemization of chiral conglomerate crystalso fa ni soindolinone is attained through fast microwave-assistedt emperature cycling. Ap arametric study of the main factorst hat affect the occurrence of secondary nucleation in this process, namely agitation rate, suspension density,a nd solutes upersaturation, confirmst hat an enhanced stereoselective secondary nucleation rate maximizest he deracemizationr ate. Analysis of the systemd uring as ingle temperature cycle showed that, although stereoselective particlep roduction during the crystallization stage leadstoenantiomeric enrichment, undesired kinetic dissolution of smaller particleso ft he preferred enantiomero ccurs during the dissolution step. Therefore, secondary nucleationi sc rucial for the enhancemento fd eracemization through temperature cycles and as such should be considered in further design and optimization of this process, as well as in other temperature cyclingp rocesses commonly applied in particle engineering.

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Population-Based Mathematical Model of Solid-State Deracemization via Temperature Cycles

Cited by 36 publications

References 35 publications

Complete chiral resolution in a continuous flow crystallizer with recycle stream

Complete chiral resolution in a continuous flow crystallizer with recycle stream

Designing Isothermal Batch Deracemization Processes with Optimal Productivity: 1. Parametric Analysis Using a Population Balance Equation Model

On the Effect of Secondary Nucleation on Deracemization through Temperature Cycles

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