Effect of Cations and Anions on Glass Transition Temperatures in Excipient Solutions

Nesarikar, Vishwas V.; Nassar, Munir N.

doi:10.1080/10837450701212826

Cited by 15 publications

(9 citation statements)

References 4 publications

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“…The thermal event taking place at − 35 °C, detected for our 10% sucrose solution, may instead be related to the onset of ice dissolution as suggested by Ablett et al 37 A step change could not be observed for the other polymers, which can be explained by the fact that cellulose‐based polymers are strong glass formers, hence having a too small change in heat capacity over the glass transition to be detectable by DSC 39, 40. The addition of the salt was found to decrease the T g ′ of Ficoll by about 9 °C, an effect of that the presence of NaCl increases the amount of water withheld in the freeze concentrate during ice formation 41, 42. In the case of HEC and HPMC an endothermic peak with an onset of − 28 °C and − 27 °C, respectively, appeared when NaCl was included in the formulations, interpreted as the onset of a eutectic melting of NaCl and ice (see Discussion).…”

Section: Resultsmentioning

confidence: 97%

“…A prerequisite for the eutectic melting behaviour is that the components (NaCl and water) are phase separated in the frozen state. NaCl is known to form complexes with the hydroxyl groups of carbohydrates 41, 53. The NaCl to hydroxyl molar ratio in the dry formulations was 1:11, 1:6 and 1:1 for the Ficoll‐, PVA‐ and HEC‐based formulations, respectively, explaining why no or a smaller fraction of crystallised NaCl was detected in the Ficoll and PVA samples.…”

Section: Discussionmentioning

confidence: 99%

“…Hence, to accurately compare the survival of cells formulated in the different sucrose and polymer solutions we aimed at keeping the initial osmolality of the different formulations equal by including 150 mmol L −1 of NaCl in all polymer solutions. It is, however, important to appreciate the effect that inclusion of electrolytes such as NaCl have on the T g ′ of the freeze concentrate41, 42 and if needed adjust the freeze‐drying protocol accordingly. Due to high viscosities the amount of polymer in the HEC, HPMC and PVA formulations was lower than in the Ficoll solution.…”

Section: Discussionmentioning

confidence: 99%

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Impact of matrix properties on the survival of freeze‐dried bacteria

et al. 2011

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Section: Resultsmentioning

confidence: 97%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Impact of matrix properties on the survival of freeze‐dried bacteria

et al. 2011

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“…90 Additionally, the presence of salts decreases the T g ' even further. 60,112 On the other hand, a special mechanism where the water behaves like an antiplasticizing agent is also known. 113…”

Section: ■ Discussionmentioning

confidence: 99%

Using Excimeric Fluorescence to Study How the Cooling Rate Determines the Behavior of Naphthalenes in Freeze-Concentrated Solutions: Vitrification and Crystallization

et al. 2020

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We utilized fluorescence spectroscopy to learn about the molecular arrangement of naphthalene (Np) and 1-methylnaphthalene (MeNp) in frozen aqueous solutions. The freezing induces pronounced compound aggregation in the freeze-concentrated solution (FCS) in between the ice grains. The fluorescence spectroscopy revealed prevalent formation of a vitrified solution and minor crystallization of aromatic compounds. The FCS is shown as a specific environment, differing significantly from not only the pure compounds but also the ice surfaces. The results indicate marked disparity between the behavior of the Np and the MeNp; the cooling rate has a major impact on the former but not on the latter. The spectrum of the Np solution frozen at a faster cooling rate (ca 20 K/min) exhibited a temperature-dependent spectral behavior, whereas the spectrum of the solution frozen at a slower rate (ca 2 K/min) did not alter before melting. We interpret the observation through considering the varied composition of the FCS: Fast freezing leads to a higher water content expressed by the plasticizing effect, allowing molecular rearrangement, while slow cooling produces a more concentrated and drier environment. The experiments were conceived as generalizable for environmentally relevant pollutants and human-made freezing.

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“…No crystalline material was detected in the Ficoll based formulation. NaCl can form complexes with the hydroxyl moieties in carbohydrates 9,10 . In Ficoll and HEC-based formulations the NaCl to hydroxyl moiety molar ratio was 1:11 and 1:1, respectively, explaining why no crystallization was detected in the Ficoll-based formulation.…”

Section: Discussionmentioning

confidence: 99%

Formulations for Freeze-drying of Bacteria and Their Influence on Cell Survival

Wessman

Håkansson

Leifer

et al. 2013

JoVE

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Cellular water can be removed to reversibly inactivate microorganisms to facilitate storage. One such method of removal is freeze-drying, which is considered a gentle dehydration method. To facilitate cell survival during drying, the cells are often formulated beforehand. The formulation forms a matrix that embeds the cells and protects them from various harmful stresses imposed on the cells during freezing and drying. We present here a general method to evaluate the survival rate of cells after freeze-drying and we illustrate it by comparing the results obtained with four different formulations: the disaccharide sucrose, the sucrose derived polymer Ficoll PM400, and the respective polysaccharides hydroxyethyl cellulose (HEC) and hydroxypropyl methyl cellulose (HPMC), on two strains of bacteria, P. putida KT2440 and A. chlorophenolicus A6. In this work we illustrate how to prepare formulations for freeze-drying and how to investigate the mechanisms of cell survival after rehydration by characterizing the formulation using of differential scanning calorimetry (DSC), surface tension measurements, X-ray analysis, and electron microscopy and relating those data to survival rates. The polymers were chosen to get a monomeric structure of the respective polysaccharide resembling sucrose to a varying degrees. Using this method setup we showed that polymers can support cell survival as effectively as disaccharides if certain physical properties of the formulation are controlled 1 . Video LinkThe video component of this article can be found at http://www.jove.com/video/4058/ Protocol 1. Cultivation and harvest of P. putida 1. Prepare a starter culture of Pseudomonas putida by inoculating 100 ml of tryptic soy broth (TSB) with a colony of P. putida cells cultured on agar supplemented with tryptic soy broth (TSA). Keep the culture at 30 °C on a shaking board set at 130 rpm. 2. After 7 hr transfer an aliquot from the starter culture equivalent to 1/10 of the final volume of the main culture to fresh TSB-medium. Keep the cells at 30 °C on a shaking board at 130 rpm for 16 hr. 3. After 16 hr of growth the cells are harvested by spinning the cell culture at 1,500 x g for 20 min at RT. Decant the supernatant and wash the cells by re-suspending the cell pellet is in a NaCl-solution that is isotonic to the growth medium. In this case a 150 mM NaCl solution was used. The cells are then centrifuged once more and the supernatant is decanted before resuspending the cells in the formulation medium, see step 3.2. Cultivation of other species1. To adapt the protocol to other bacterial species the cultivation and harvest procedures should be changed according to the requirements of that species. To avoid osmotic shock when handling the cells during harvest and the washing step(s), the osmolality of the solutions needs to match that of the growth medium at harvest. Formulation of cells1. Prepare the formulation solutions by weighing out the respective matrix components and dissolve them in water. To achieve isotonic conditions, eit...

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Effect of Cations and Anions on Glass Transition Temperatures in Excipient Solutions

Cited by 15 publications

References 4 publications

Impact of matrix properties on the survival of freeze‐dried bacteria

Impact of matrix properties on the survival of freeze‐dried bacteria

Using Excimeric Fluorescence to Study How the Cooling Rate Determines the Behavior of Naphthalenes in Freeze-Concentrated Solutions: Vitrification and Crystallization

Formulations for Freeze-drying of Bacteria and Their Influence on Cell Survival

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