Effects of Solvents on Polymorphism and Shape of Mefenamic Acid Crystals

Mudalip, Siti Kholijah Abdul; Bakar, Mohd Rushdi Abu; Jamal, Parveen; Adam, Fatmawati; Man, Rohaida Che; Sulaiman, Siti Zubaidah; Arshad, Zatul Iffah Mohd; Shaarani, Shalyda Md

doi:10.1051/matecconf/201815002004

Cited by 10 publications

(6 citation statements)

References 19 publications

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“…Two endothermic peaks were observed in the DSC curve of MFA crystals, one near 164 °C and the other near 229 °C. MFA is known to have crystal polymorphism [ 9 ], and it has been reported that the endothermic peak near 171 °C is the temperature at which Form I crystals transition to Form II crystals, and the peak near 231 °C is the endothermic peak due to thermal decomposition of Form II crystals [ 10 ]. In this study, peaks were observed near 164 °C and 229 °C, suggesting that the MFA used in this study is a Form I crystal ( Figure 3 ).…”

Section: Resultsmentioning

confidence: 99%

Microparticulated Mefenamic Acid with High Dispersion Stability for Pediatric Dosage Form

et al. 2022

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Mefenamic acid (MFA), a water-insoluble drug, is used as a suspension in the medical field, but it requires shaking before using to disperse MFA content in the suspension. In previous studies, trials to prepare MFA suspension with high dispersion stability by atomizing MFA by the wet-milling method. However, HPC is used for atomizing MFA. Therefore, the optimum concentration and molecular weight for atomizing MFA have not been investigated. In this study, we investigated the optimum molecular weight and concentration of HPC for the micronization of MFA. As a result, MFA particles became fine particles by adding SDS, and the particle size was also smaller than that of HPC alone. In addition, the suspension with the highest dispersion stability can be obtained when a mixed solution of 1.0% HPC-SL and 0.12% SDS aqueous solution is used. Therefore, this study considers that the addition of SDS and 1.0% HPC-SL aqueous solution are optimal for improving the dispersion stability of the MFA suspension.

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Section: Resultsmentioning

confidence: 99%

Microparticulated Mefenamic Acid with High Dispersion Stability for Pediatric Dosage Form

et al. 2022

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“…For a long time, only two polymorphic forms of MA were known. 5 − 7 These polymorphs can be obtained from different solvents, 8 , 9 and their solubility and dissolution rate were studied thoroughly. 10 − 12 Both polymorphic structures were characterized by different physicochemical methods, 13 − 17 and the thermal conversion of mefenamic acid from its polymorphic form I to polymorphic form II was revealed and studied by IR spectroscopy.…”

Section: Introductionmentioning

confidence: 99%

“…For a long time, only two polymorphic forms of MA were known. − These polymorphs can be obtained from different solvents, , and their solubility and dissolution rate were studied thoroughly. − Both polymorphic structures were characterized by different physicochemical methods, − and the thermal conversion of mefenamic acid from its polymorphic form I to polymorphic form II was revealed and studied by IR spectroscopy . However, the polymorphic form I of mefenamic acid proved to be more stable than form II under ambient conditions, which causes a slow transformation of polymorph II to polymorph I . , The mechanism of this thermally dependent reversible polymorphic transition remains unclear due to the fact that the mefenamic acid molecule is disordered in the polymorphic form II .…”

Section: Introductionmentioning

confidence: 99%

Quantum Chemical Study on Mefenamic Acid Polymorphic Forms

et al. 2022

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Three polymorphic structures of mefenamic acid, which is a very popular drug, have been studied using quantum chemical methods. It has been shown that the centrosymmetric dimer formed due to two O–H···O hydrogen bonds is a complex building unit in all of the polymorphic structures under study. On the basis of an analysis of the pairwise interaction energies between molecules, the polymorphic forms I and II are classified as columnar-layered while the polymorphic form III has a columnar structure. The stabilities of the three polymorphic forms of mefenamic acid under ambient conditions ( I > II > III ) correlate with the degree of anisotropy of the interaction energies between columns (primary basic structural motifs) formed due to stacking interactions. The shear deformation modeling of strongly bound layers in all of the polymorphic structures has not revealed any possibility for deformation of the crystal structure. The construction of the shift energy profiles and calculation of the energy barriers for the displacement along the (100) crystallographic plane in the [100], [010], and [011] crystallographic directions make it possible to explain the experimental data obtained for commercially available polymorphic structure I in a diamond anvil cell. The absence of any local minimum near the starting point on the shift energy profile and the extremely high energy barrier can be considered as criteria for the impossibility of a crystal structure deformation under pressure.

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“…A variety of crystal shapes have been reported from prior experimental studies for mefenamic acid, ranging from plate-like to needle-like crystals [32][33][34]. Plates or elongated crystals of mefenamic acid were observed when crystallised from tetrahydrofuran [33], ethanol [35], ethyl acetate [30,33], dimethylacetamide (DMA) [30,34], and isopropanol [35], while needle-like crystals were often observed when mefenamic acid was crystallised from acetone [34,35]. However, many studies of the crystallisation of mefenamic acid have yielded different results for crystal shape despite using the same crystallisation solvent.…”

Section: Introductionmentioning

confidence: 99%

“…However, many studies of the crystallisation of mefenamic acid have yielded different results for crystal shape despite using the same crystallisation solvent. For example, the crystallisation of mefenamic acid from ethyl acetate carried out by Mudalip et al produced needle-like crystals [34], while the SEM pictures of mefenamic acid crystallised from ethyl acetate showed plate-like crystals in the study of Panchagnula et al [33] The latter study has also shown that the shape of mefenamic acid crystal grown from tetrahydrofuran and ethyl acetate changed as supersaturation levels changed [33]. Here, we've focused on polyhedral and needle crystal with a broad interpretation of polyhedral classification for the practical implications for downstream pharmaceutical manufacturing processes as needle-shaped crystals are more likely to cause issues during manufacturing than crystal shapes with aspect ratios closer to 1, and so are generally undesirable.…”

Section: Introductionmentioning

confidence: 99%

Prediction of Mefenamic Acid Crystal Shape by Random Forest Classification

et al. 2022

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Objective Particle shape can have a significant impact on the bulk properties of materials. This study describes the development and application of machine-learning models to predict the crystal shape of mefenamic acid recrystallized from organic solvents. Methods Crystals were grown in 30 different solvents to establish a dataset comprising solvent molecular descriptors, process conditions and crystal shape. Random forest classification models were trained on this data and assessed for prediction accuracy. Results The highest prediction accuracy of crystal shape was 93.5% assessed by fourfold cross-validation. When solvents were sequentially excluded from the training data, 32 out of 84 models predicted the shape of mefenamic acid crystals for the excluded solvent with 100% accuracy and a further 21 models had prediction accuracies from 50–100%. Reducing the feature set to only solvent physical property descriptors and supersaturations resulted in higher overall prediction accuracies than the models trained using all available or another selected subset of molecular descriptors. For the 8 solvents on which the models performed poorly (< 50% accuracy), further characterisation of crystals grown in these solvents resulted in the discovery of a new mefenamic acid solvate whereas all other crystals were the previously known form I. Conclusions Random forest classification models using solvent physical property descriptors can reliably predict crystal morphologies for mefenamic acid crystals grown in 20 out of the 28 solvents included in this work. Poor prediction accuracies for the remaining 8 solvents indicate that further factors will be required in the feature set to provide a more generalized predictive morphology model.

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Effects of Solvents on Polymorphism and Shape of Mefenamic Acid Crystals

Cited by 10 publications

References 19 publications

Microparticulated Mefenamic Acid with High Dispersion Stability for Pediatric Dosage Form

Microparticulated Mefenamic Acid with High Dispersion Stability for Pediatric Dosage Form

Quantum Chemical Study on Mefenamic Acid Polymorphic Forms

Prediction of Mefenamic Acid Crystal Shape by Random Forest Classification

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