Structural Properties, Order–Disorder Phenomena, and Phase Stability of Orotic Acid Crystal Forms

Braun, Doris E.; Nartowski, Karol P.; Khimyak, Yaroslav Z.; Morris, Kenneth R.; Byrn, Stephen R.; Griesser, Ulrich J.

doi:10.1021/acs.molpharmaceut.5b00856

Cited by 38 publications

(46 citation statements)

References 83 publications

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“…A strong diffraction peak is observed at 2q ¼ 28.8 for both of the two samples, which corresponds to the stacking reection of layer structures. 45 In contrast to OA-m, a broadened diffraction peak appears at 2q around 20…”

Section: Nucleation Analysismentioning

confidence: 97%

“…In fact, there are two commercially available types for orotic acid, that is, anhydrous and monohydrated forms, which possess different structural features and properties, 45 and may result in discrepant nucleation ability on polymer crystallization. However, previous studies are mainly focused on the nucleation effects of monohydrated form.…”

Section: -44mentioning

confidence: 99%

“…Notably, this literature has also pointed out that OA-m loses the bound water and dissociates into OA-a when it is heated above 135 C under normal or hermetically sealed high-pressure atmospheric conditions. 45 In addition, it has been reported that an endothermic peak, which is attributed to the evaporation of the water associated with OA-m, appears at 144 C before the melting peak of poly(hydroxybutyrate-co-hydroxyvalerate) (PHBV) at 171 C in the rst heating DSC curve of PHBV solvent-cast lm containing 5 wt% OA-m. 44 In this work, considering the blended samples were prepared in the temperature range of 170-190 C for 6 min, it is reasonable to conclude that OA-m is transformed into OA-a during the melt extrusion processes, and nally, OAa acts as the true nucleating agent in PLLA/OA-m blends. Fig.…”

Section: Nucleation Analysismentioning

confidence: 99%

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Insight into the role of bound water of a nucleating agent in polymer nucleation: a comparative study of anhydrous and monohydrated orotic acid on crystallization of poly(l-lactic acid)

et al. 2017

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To gain an insight into the role of bound water of a nucleating agent in polymer nucleation, a biobased nucleating agent, orotic acid (OA), was selected as a model to investigate the effects on crystallization of poly(L-lactic acid) (PLLA). In such a context, two commercially available types of OA in anhydrous (OA-a) and monohydrated (OA-m) forms were melt mixed with PLLA, and their nucleation effectiveness on nonisothermal and isothermal melt crystallization of PLLA was comparatively studied. Results indicate that both forms of OA can significantly improve nonisothermal crystallization temperature and degree of crystallinity, overall isothermal crystallization rate, as well as nucleation density of PLLA. Interestingly, OA-a shows more prominent nucleation efficiency than OA-m. That is, the bound water of OA-m and its dehydration transition play a negative role in nucleation effects on PLLA crystallization. It is attributed to the deteriorated dispersion and the reduced active concentration of dehydration-transformed OA-a in PLLA/OA-m blends, as compared with pristine OA-a in PLLA/OA-a blends. Furthermore, an epitaxial mechanism is proposed to explain the nucleation phenomenon of PLLA/OA blends.

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Section: Nucleation Analysismentioning

confidence: 97%

Section: -44mentioning

confidence: 99%

Section: Nucleation Analysismentioning

confidence: 99%

See 1 more Smart Citation

Insight into the role of bound water of a nucleating agent in polymer nucleation: a comparative study of anhydrous and monohydrated orotic acid on crystallization of poly(l-lactic acid)

et al. 2017

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“…In general, the 1 H isotropic shifts are regarded as more sensitive to structural changes. There are two structures that are close to fulfilling these requirements, namely, one 2.5-hydrate (16) and one dihydrate (11), which are both obtained by manual modification of the 4.5-hydrate structure. However, appropriate weights should be assigned to all of these features.…”

Section: General Remarks On the Computationsmentioning

confidence: 99%

Computational and experimental study of reversible hydration/dehydration processes in molecular crystals of natural products – a case of catechin

2016

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When employing a complementary approach that joins theoretical (crystal structure prediction, CSP, gauge-including projector-augmented wave density functional theory, GIPAW DFT) and experimental (solid-state nuclear magnetic resonance, SSNMR) techniques, we prove that detectable changes in the water content in a crystal lattice can be monitored as a continuous or quantum process by using border values of the measurable number of water molecules in the crystal, depending on the observation probe.In the case of a 13 C nucleus, which "feels" the presence of water in its nearest neighbourhood, the subtle changes in the structure of the water channel during the dehydration/rehydration process are not reflected until the water loss exceeds a certain number of molecules. Here, the dehydration of (+)-catechin 4.5-hydrate with a loss of ca. 1-1.5 and 2-2.5H 2 O molecules leads to microcrystalline form II (partially dehydrated) or amorphous form III, respectively. The CSP calculations for the partially dehydrated (+)-catechin (form II), as verified by experimental 1 H and 13 C shieldings, resulted in two similar probable crystal structures, which have 2 and 2.5 water molecules in the unit cell. CrystEngCommThis journal is † Electronic supplementary information (ESI) available: 1 H-13 C FSLG HETCOR spectra of forms I and II, 13 C CPMAS NMR spectra of form I and II with different water content, DFT calculations of (+)-catechin CSTs for structures with variable C3-C2-C11-C16 dihedral angle, hydrogen bonding network for each of 26 structures obtained in the prediction of the partially dehydrated catechin crystals and the description of the energy share estimation of each water molecule. See

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“…A complicating factor in the search for commercially viable solid phases is that the stable forms of a material can change based on external factors such as temperature [18,46,[92][93][94][95][96][97][98][99][100][101][102][103], pressure [76][77][78][79][80][81] and humidity [47,82,83,200]. A complete experimental mapping of all possible solid forms for a given material would therefore require screening at every condition the material will encounter.…”

Section: Introductionmentioning

confidence: 99%

Capturing the Role of Temperature and Entropy in Crystal Polymorphs Through Molecular Simulations

Dybeck

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AcknowledgementsI would like to acknowledge the guidance and support provided by my advisor MichaelShirts. I would also like to thank Levi Naden, Natalie Schieber, Nate Abraham and the entire Shirts group for their help and technical support during my research. I also would like to acknowledge the UVA high performance computing team for the computational resources necessary to complete this work. Finally, I would like to acknowledge the endless love and support that my friends and family provided me during this challenging Ph.D. journey.iii AbstractThe presence of multiple stable crystal structures in solid organic materials can limit their commercial viability when two or more observable polymorphs exhibit markedly different physical properties. Unintended restructuring events have hindered pharmaceutical solid form development in numerous therapeutic candidates and have led to costly market recalls.Conversely, intentional synthesis of a metastable form has led to significantly more favorable performance in numerous materials.Current computational methods for predicting polymorphic behavior evaluate candidate crystal structures based on the minimized lattice energy. However, these static lattice energybased approaches generate far more lattice energy minima than there are experimentally observed structures. Thermal motion of the crystals under working conditions has the potential to explain why many of these lattice minima are not observed experimentally. Lattice minima that are identified from a static crystal structure prediction can ultimately be unstable at experimental conditions through either temperature-mediated stability reranking, kinetic interconversion of multiple minima, or inaccuracies of the energy function in producing the real crystal ensemble.In this work, we explore the role of thermal motion in eliminating candidate crystal structures using fully atomistic molecular dynamics simulations. Enthalpically favorable structures with low entropy will become unfavorable at high temperatures through temperaturemediated stability reranking. Our simulations correctly identify the high temperature solid form as having a larger entropy than the low temperature form in twelve small molecule organic systems with known temperature-mediated transformations. The estimated entropy differences in the classical point-charge potential are significantly closer to experimental measurements than estimated enthalpy differences. This result suggests that entropy difference estimates are less sensitive to the complexity of the simulation potential than the corresponding enthalpy estimates. We additionally find that a cheaper harmonic approximation provides a sufficient estimate of entropic contributions in small rigid molecules. However, entropies with iv the harmonic approximation diverge from molecular dynamics-derived entropies in systems with multiple rotatable degrees of freedom or dynamically disordered crystalline structures.We additionally probe the sensitivity of the stability estimates to the energy function ...

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Structural Properties, Order–Disorder Phenomena, and Phase Stability of Orotic Acid Crystal Forms

Cited by 38 publications

References 83 publications

Insight into the role of bound water of a nucleating agent in polymer nucleation: a comparative study of anhydrous and monohydrated orotic acid on crystallization of poly(l-lactic acid)

Insight into the role of bound water of a nucleating agent in polymer nucleation: a comparative study of anhydrous and monohydrated orotic acid on crystallization of poly(l-lactic acid)

Computational and experimental study of reversible hydration/dehydration processes in molecular crystals of natural products – a case of catechin

Capturing the Role of Temperature and Entropy in Crystal Polymorphs Through Molecular Simulations

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