Glass Transition Temperature of Glucose, Sucrose, and Trehalose:  An Experimental and in Silico Study

Simperler, Alexandra; Kornherr, Andreas; Chopra, Reenu; Bonnet, Pierre; Jones, William; Motherwell, W. D. S.; Zifferer, Gerhard

doi:10.1021/jp063134t

Cited by 148 publications

(113 citation statements)

References 38 publications

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“…In this experiment, D mono D 50 nm, D c D 60.9 nm § 2.5 nm observed at T »70 C, D uc D 65.7 nm § 0.5 nm observed at T < 50 C, and transition diameters corresponding to partially coalesced particles are observed between 50 C and 70 C. The relaxation temperature (T r ) was measured as 63.7 C § 4.4 C. This temperature is higher than the 60 C glass transition temperature (T g ) of amorphous sucrose estimated from differential scanning calorimetry data (Simperler et al 2006), as would be expected for a less viscous particle. However, the observed difference is within measurement uncertainties in either measurement.…”

Section: Cooling Cycle (Rh) Experimentsmentioning

confidence: 71%

Coalescence-based assessment of aerosol phase state using dimers prepared through a dual-differential mobility analyzer technique

Rothfuss

Petters

2016

Aerosol Science and Technology

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Viscosity of atmospheric aerosol spans at least 15 orders of magnitude, from thin liquids to glassy solids, with possible concomitant impact on multiple processes of meteorological and/or climatological concern. Recently there has been interest in aerosol phase assessment techniques based upon dimer coalescence. Theoretical treatment suggests discernible reductions in dimer diameter begin when viscosity »10 8 Pa¢s and the dimer is spherical at »10 5 Pa¢s for submicron particles, or the middle range of the semisolid regime. A method using nanoparticle dimers synthesized by utilizing differential mobility analyzers of opposite polarity to produce monomers of opposite charge that subsequently undergo electrostatically mediated coagulation has been developed and is detailed in this work. This method was used to assess the aerosol phase state of several atmospherically relevant organic species and inorganic salts at relative humidity (RH) values ranging between 10% and 100%. Ammonium sulfate, monosodium a-ketoglutaric acid, sodium chloride, and sucrose all displayed RH-dependent phase state. These observed viscous transitions occurred at RH values less than existing deliquescence RH data, a result consistent with existing literature reports of RH-induced structural rearrangements. Fully coalesced and fully uncoalesced diameters could be fitted to single values, indicating that the presented technique is absolute. The method was also used to assess the phase state of dry sucrose aerosol at temperatures between 20 C and 70 C. A phase transition was noted at 63.7 C § 4.4 C, near the glass transition temperature, suggesting the presented method may also be useful for probing phase responses to temperature perturbations.

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Section: Cooling Cycle (Rh) Experimentsmentioning

confidence: 71%

Coalescence-based assessment of aerosol phase state using dimers prepared through a dual-differential mobility analyzer technique

Rothfuss

Petters

2016

Aerosol Science and Technology

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“…The same criteria to determine T g , but using NPTMD was reported for maltodecaose (w 2 = 0.84-0.99) aqueous solutions [148]; glucose and isomaltodecaose (in the pure form and hydrated with one molecule of water) [149]; pure cellulose [150]; pure myo-and neo-inositol [151]; pure glucose, sucrose, and trehalose [152]; trehalose (w 2 = 0.95-1.00) aqueous mixtures [153]; and glycerol [154]. Figure 7 shows the experimental and calculated T g of concentrated aqueous trehalose solutions as a function of concentration on the very concentrated region (w 2 > 0.92) where MD simulations are available.…”

Section: Molecular Dynamics Simulations Of the Glass Transitionmentioning

confidence: 99%

“…The coarse grain model for carbohydrates (denoted M3B), applied by Molinero et al [156] for glucose, represents each glucose monomer by three beads while describing the water molecule as a single particle. The M3B model includes no charges or hydrogen-bonding terms, predicted by NPTMD ( ) [153], compared to experimental data ( ) [7,92,123,126], ( ○ ) [152].…”

Section: Molecular Dynamics Simulations Of the Glass Transitionmentioning

confidence: 99%

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Empirical and theoretical models of equilibrium and non-equilibrium transition temperatures of supplemented phase diagrams in aqueous systems (IUPAC Technical Report)

Corti

Angell

Auffret

et al. 2010

Pure and Applied Chemistry

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This paper describes the main thermodynamic concepts related to the construction of supplemented phase (or state) diagrams (SPDs) for aqueous solutions containing vitrifying agents used in the cryo-and dehydro-preservation of natural (foods, seeds, etc.) and synthetic (pharmaceuticals) products. It also reviews the empirical and theoretical equations employed to predict equilibrium transitions (ice freezing, solute solubility) and non-equilibrium transitions (glass transition and the extrapolated freezing curve). The comparison with experimental results is restricted to carbohydrate aqueous solutions, because these are the most widely used cryoprotectant agents. The paper identifies the best standard procedure to determine the glass transition curve over the entire water-content scale, and how to determine the temperature and concentration of the maximally freeze-concentrated solution.

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“…To date, a number of molecular mechanics (MM)-based molecular dynamics (MD) simulation studies [9][10][11][12] have been performed to study various molecules (e.g. dissolution of the molecules from the crystal surface) 13 or to identify drug-polymer miscibility in solid dispersions [14][15][16][17][18] . Recently, we 19 reported the use of quantum mechanical (QM) calculations with commercially available software (Gaussian 09) to characterise possible drug/polymer interactions.…”

Section: Introductionmentioning

confidence: 99%

Molecular Modeling as a Predictive Tool for the Development of Solid Dispersions

et al. 2015

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In this study molecular modelling is introduced as a novel approach for the development of pharmaceutical solid dispersions. A computational model based on quantum mechanical (QM) calculations was used to predict the miscibility of various drugs in various polymers by predicting the binding strength between the drug and dimeric form of the polymer. The drug/polymer miscibility was also estimated by using traditional approaches such as Van Krevelen/Hoftyzer and Bagley solubility parameters or Flory Huggins interaction parameter in comparison to the molecular modelling approach.The molecular modelling studies predicted successfully the drug-polymer binding energies and the preferable site of interaction between the functional groups. The drug-polymer miscibility and the physical state of bulk materials, physical mixtures and solid dispersions were determined by thermal analysis (DSC/MTDSC) and X-ray diffraction. The produced solid dispersions were analysed by X-ray photoelectron spectroscopy (XPS), which confirmed not only the exact type of the intermolecular interactions between the drugpolymer functional groups but also the binding strength by estimating the N-coefficientvalues. The findings demonstrate that QM-based molecular modelling is a powerful tool to predict the strength and type of intermolecular interactions in a range of drug/polymeric systems for the development of solid dispersions.

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Glass Transition Temperature of Glucose, Sucrose, and Trehalose: An Experimental and in Silico Study

Cited by 148 publications

References 38 publications

Coalescence-based assessment of aerosol phase state using dimers prepared through a dual-differential mobility analyzer technique

Coalescence-based assessment of aerosol phase state using dimers prepared through a dual-differential mobility analyzer technique

Empirical and theoretical models of equilibrium and non-equilibrium transition temperatures of supplemented phase diagrams in aqueous systems (IUPAC Technical Report)

Molecular Modeling as a Predictive Tool for the Development of Solid Dispersions

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