Attrition Induced Deracemisation of 2-Fluorophenylglycine

Section: Introductionmentioning

confidence: 99%

Particle Breakage Kinetics and Mechanisms in Attrition-Enhanced Deracemization

Xiouras

Fytopoulos

Horst

et al. 2018

“…Viedma ripening was first demonstrated for sodium chlorate, an intrinsically achiral compound that crystallizes as conglomerate crystals, but has since then been modified to work also for intrinsically chiral compounds e.g. amino acids [4][5][6][7] and pharmaceuticals [8][9][10] that crystallize as conglomerate crystals by incorporating a fast racemization reaction. The outcome of the deracemization process depends on the initial conditions 11,12 : mass or crystal size distribution (CSD) imbalance between the enantiomers 1,[13][14][15] , presence of chiral impurities 16 or additives [17][18][19] or circularly polarized light 20 .…”

Section: Introductionmentioning

confidence: 99%

Coupling Viedma Ripening with Racemic Crystal Transformations: Mechanism of Deracemization

Xiouras

Horst

Gerven

et al. 2017

It has been recently observed that coupling Viedma ripening with a seeded in-situ metastable racemic crystal to conglomerate transformation leads to accelerated and complete deracemization: crystal transformation-enhanced deracemization. By means of a simple kinetic model, we show that the mechanistic pathway of this new process depends profoundly on the interplay between the crystal transformation and racemization processes, which in turn influence the nucleation process of the counter enantiomer. If the nucleation of the counter enantiomer is suppressed (e.g. by sufficiently fast racemization, low amount of racemic compound or gradual feed, low relative solubility between racemic compound and conglomerate), deracemization proceeds via a second order asymmetric transformation (SOAT) and is limited primarily by the dissolution rate of the racemic crystals and the growth rate of the preferred enantiomer crystals. Breakage and agglomeration accelerate the process, but contrary to conventional Viedma ripening, they are not essential ingredients to explain the observed enantiomeric enrichment. If the nucleation process of the counter enantiomer is not sufficiently suppressed, deracemization is initially controlled by the dissolution rate of the racemic crystals, but Viedma ripening is subsequently required to convert the conglomerate crystals of the counter enantiomer formed by nucleation, resulting in slower deracemization kinetics. In both cases, the combined process leads to faster deracemization kinetics compared to conventional Viedma ripening, while it autocorrects for the main disadvantage of SOAT, i.e. the accidental nucleation of the counter enantiomer. In addition, crystal transformation-enhanced deracemization extends the range of applicability of solid-state deracemization processes to compounds that form metastable racemic crystals. interplay between the crystal transformation and racemization processes, which in turn influence the nucleation process of the counter enantiomer. If the nucleation of the counter enantiomer is 3 suppressed (e.g. by sufficiently fast racemization, low amount of racemic compound or gradual feed, low relative solubility between racemic compound and conglomerate), deracemization proceeds via a second order asymmetric transformation (SOAT) and is limited primarily by the dissolution rate of the racemic crystals and the growth rate of the preferred enantiomer crystals.Breakage and agglomeration accelerate the process, but contrary to conventional Viedma ripening, they are not essential ingredients to explain the observed enantiomeric enrichment. If the nucleation process of the counter enantiomer is not sufficiently suppressed, deracemization is initially controlled by the dissolution rate of the racemic crystals, but Viedma ripening is subsequently required to convert the conglomerate crystals of the counter enantiomer formed by nucleation, resulting in slower deracemization kinetics. In both cases, the combined process leads to faster deracemization kinetics compared ...

“…6,14,15 Because in these cases the ee was determined in the end, it is unclear to what extent secondary nucleation and Viedma ripening were involved.…”

Section: ■ Introductionmentioning

confidence: 99%

Deracemization Controlled by Reaction-Induced Nucleation: Viedma Ripening as a Safety Catch for Total Spontaneous Resolution

Steendam¹,

Benthem²,

Huijs³

et al. 2015

Viedma ripening was recently applied to a reaction enabling the conversion of achiral reactants in solution into enantiopure product crystals. Here we show that the configuration of the final product and the rate of deracemization are highly dependent on the initial crystal nucleation process or, if applied, seed crystals. Depending on the nucleation process, the transformation proceeds through total spontaneous resolution or Viedma ripening. Swift solid state deracemization can also be achieved using heating−cooling cycles as an alternative to Viedma ripening, provided that crystal nucleation results in a sufficiently high initial enantiomeric excess to trigger the deracemization process.