Characterization of solvent induced crystalline and amorphous homoharringtonine

Kim, Byung-Sik; Kim, Jin-Hyun

doi:10.1007/s11814-009-0181-z

Cited by 6 publications

(4 citation statements)

References 17 publications

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“…This result agrees with that for nevirapine, an API with a very low solubility in water; the higher the polarity index of the solvent, the higher the degree of crystallinity [27]. Since crystal shape may vary according to the evaporation rate of a solvent [28], the effect of this parameter was examined using acetonitrile at different temperatures (30,40, and 50 o C), which can affect the evaporation rate. Almost no change in the degree of crystallinity due to differences in evaporation rate was evident in the XRD pattern (data not shown).…”

Section: Analysis Of the Characteristics Of Crystalline Paclitaxelsupporting

confidence: 75%

“…To determine the effect of the evaporation rate on paclitaxel crystal shape, solvent evaporation was conducted with acetonitrile at different temperatures (30,40, and 50 o C). The sample was evaporated in a vacuum dryer for 24 h at each temperature, then analyzed by XRD.…”

Section: Analysis Of Effect Of Evaporation Ratementioning

confidence: 99%

“…This phenomenon appears to be associated with the degree of supersaturation of paclitaxel in the organic solvent used in the solvent evaporation process. For APIs, smaller final products have higher utilization value because small size is advantageous in terms of removal of residual solvent and solubility [29,30].…”

Section: Analysis Of the Characteristics Of Amorphous Paclitaxelmentioning

confidence: 99%

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Establishment of a solvent map for formation of crystalline and amorphous paclitaxel by solvent evaporation process

Yoon

Kim

2011

Korean J. Chem. Eng.

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This study intended to establish a solvent map for formation of crystalline and amorphous paclitaxel by a solvent evaporation process. Crystalline paclitaxel was produced by evaporation with polar solvents (acetone, acetonitrile, ethanol, isobutyl alcohol, methanol, methyl ethyl ketone, and n-butyl alcohol) having a polarity index above 4.00. On the other hand, amorphous paclitaxel was produced by evaporation with non-polar solvents (methylene chloride, n-butyl chloride, and toluene) having a polarity index of about 4.00 or lower. The formation of paclitaxel was very closely associated with the polarity index of the organic solvent used in the solvent evaporation process. In the case of crystalline paclitaxel, the higher the polarity index and the lower the viscosity of the organic solvent (n-butyl alcohol, methyl ethyl ketone, and acetonitrile), the higher the degree of crystallinity. In the case of amorphous paclitaxel, the shape and size of particles varied according to the solvent (methylene chloride, n-butyl chloride, and toluene) used in the solvent evaporation process.

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Section: Analysis Of the Characteristics Of Crystalline Paclitaxelsupporting

confidence: 75%

Section: Analysis Of Effect Of Evaporation Ratementioning

confidence: 99%

Section: Analysis Of the Characteristics Of Amorphous Paclitaxelmentioning

confidence: 99%

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Establishment of a solvent map for formation of crystalline and amorphous paclitaxel by solvent evaporation process

Yoon

Kim

2011

Korean J. Chem. Eng.

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“…It measures the onset relative humidity for a glass transition and crystallization processes in amorphous or partially amorphous materials, a useful parameter describing stability of solid-state forms. [12] Despite a number of theoretical studies on evaporation in spray-drying very little experimental data has been published on the residual solvent levels in spray-dried APIs [9,16] and this aspect of the process requires additional attention. This report therefore aim to investigate the solid-state physicochemical transformations of two model hydrophilic compounds, chlorothiazide sodium (CTZNa) [17] and potassium (CTZK), [18] on spray-drying and their subsequent characteri-sation in terms of residual solvent content and physical stability.…”

Section: Introductionmentioning

confidence: 99%

Impact of process variables on the micromeritic and physicochemical properties of spray-dried microparticles – Part II. Physicochemical characterisation of spray-dried materials

Paluch

Tajber

Amaro

et al. 2012

Journal of Pharmacy and Pharmacology

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In this work we investigated the residual organic solvent content and physicochemical properties of spray dried chlorothiazide sodium (CTZNa) and potassium (CTZK) salts. The powders were characterised by thermal, X-ray diffraction, infrared and dynamic vapour sorption (DVS) analyses. Solvent levels were investigated by Karl-Fischer titration and gas chromatography.Spray drying from water, methanol (MeOH) and mixes of methanol and butyl acetate (BA) resulted in amorphous microparticles. The glass transition temperatures of CTZNa and CTZK were ~192 ˚C and ~159 ˚C respectively. These materials retained their amorphous nature when stored at 25 °C in dry conditions for at least 6 months with no chemical decomposition observed. DVS determined critical relative humidity of recrystallisation of CTZNa and CTZK to be 57% RH and 58% RH, respectively.Inlet temperature dependant oxidation of MeOH to formaldehyde was observed; the formaldehyde was seen to deposit within the amorphous matrix of spray dried product. Spray drying in the open blowing mode coupled with secondary drying resulted in a three-fold reduction in residual BA (below pharmacopoeial permitted daily exposure limit) compared to spray drying in the closed mode. Experiments showed recirculation of recovered drying gas increases the risk of deposition of residual solvents in the spray dried product.

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