Thermophysical properties of pharmaceutically compatible buffers at sub-zero temperatures: Implications for freeze-drying

Thermophysical properties of pharmaceutically compatible buffers at sub-zero temperatures: Implications for freeze-drying

To evaluate crystallization behavior and collapse temperature (Tg') of buffers in the frozen state, in view of its importance in the development of lyophilized formulations. Sodium tartrate, sodium malate, potassium citrate, and sodium citrate buffers were prepared with a pH range within their...

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Bibliographic Details
Published in:Pharmaceutical research Vol. 19; no. 2; pp. 195 - 201
Main Authors: SHALAEV, Evgenyi Y, JOHNSON-ELTON, Tiffany D, LIUQUAN CHANG, PIKAL, Michael J
Format: Journal Article
Language:English
Published: New York, NY Springer 01-02-2002
Springer Nature B.V
Subjects:
Acids
Aluminum
Biological and medical sciences
Buffers
Calorimetry, Differential Scanning
Caustic soda
Chemical Phenomena
Chemistry, Physical
Citrates
Crystallization
Experiments
Freeze Drying
General pharmacology
Hydrogen-Ion Concentration
Indicators and Reagents
Medical sciences
Pharmaceutical technology. Pharmaceutical industry
Pharmaceuticals
Pharmacology. Drug treatments
Potassium
Sodium
Temperature
Freeze drying
Temperature
Pharmaceutical technology
Crystallization
Citrate
Buffer solution
Freezing
Tartrate
Heating
pH
Malic acid
Aqueous solution
Thermophysical properties
Physicochemical properties
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Summary:To evaluate crystallization behavior and collapse temperature (Tg') of buffers in the frozen state, in view of its importance in the development of lyophilized formulations. Sodium tartrate, sodium malate, potassium citrate, and sodium citrate buffers were prepared with a pH range within their individual buffering capacities. Crystallization and the Tg' were detected during heating of the frozen solutions using standard DSC and modulated DSC. Citrate and malate did not exhibit crystallization, while succinate and tartrate crystallized during heating of the frozen solutions. The citrate buffer had a higher Tg' than malate and tartrate buffers at the same pH. Tg' vs. pH graphs for citrate and malate buffers studied had a similar shape, with a maximum in Tg' at pH ranging from 3 to 4. The Tg' maximum was explained as a result of a competition between two opposing trends: an increase in the viscosity of the amorphous phase because of an increase in electrostatic interaction, and a decrease in the Tg' because of an increase in a water concentration of the freeze-concentrated solution. Citrate buffer was identified as the preferred buffer for lyophilized pharmaceuticals because of its higher Tg' and a lower crystallization tendency.
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ISSN:0724-8741
1573-904X
DOI:10.1023/A:1014229001433