Hydrates and Solid-State Reactivity: A Survey of β-Lactam Antibiotics

Crystalline hydrates of hydrolytically susceptible pharmaceuticals are commonly encountered, and are particularly prevalent in the β-lactam class of antibiotics. In order to rationalize how the apparent chemical incompatibility between water and β-lactams is reduced through crystallization, a review...

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Bibliographic Details
Published in:Journal of pharmaceutical sciences 2007-05, Vol.96 (5), p.1090-1099
Main Authors: Hickey, Magali B., Peterson, Matthew L., Manas, Eric S., Alvarez, Juan, Haeffner, Fredrik, Almarsson, Örn
Format: Article
Language:English
Subjects:
amorphous
Anti-Bacterial Agents - chemistry
antibiotic
beta-Lactams - chemistry
Biological and medical sciences
Cefadroxil - chemistry
chemical stability
Chemistry, Pharmaceutical
Computer Simulation
crystallinity
Crystallization
Databases, Factual
Drug Stability
General pharmacology
hydrates
Hydrogen Bonding
Hydrolysis
Medical sciences
Models, Molecular
Molecular Conformation
Molecular Structure
Pharmaceutical technology. Pharmaceutical industry
Pharmacology. Drug treatments
solid-state
Structure-Activity Relationship
Temperature
Time Factors
Water - chemistry
β-lactam
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Summary:Crystalline hydrates of hydrolytically susceptible pharmaceuticals are commonly encountered, and are particularly prevalent in the β-lactam class of antibiotics. In order to rationalize how the apparent chemical incompatibility between water and β-lactams is reduced through crystallization, a review of the published literature and available structural information on the solid state stability was undertaken. A search in the CSD yielded a total of 32 crystal structures of water-containing β-lactams which were examined and classified in terms of hydrogen-bonded networks. In most cases the waters of hydration in the single crystal structures were found to fulfill structural roles and were not sufficiently close in proximity to react with the β-lactam ring. Published data for the solid-state of several hydrates were also considered. In general, the stability data indicate high thermal stability for the crystalline hydrates. Moreover, even when water molecules are in appropriate proximity and orientation with respect to the β-lactam moiety for a reaction to occur, the crystalline solids remain stable. The use of the crystal structure information along with computational modeling suggests that a combination of proximal relationships, steric and mechanistic arguments can explain the observed solid-state stability of crystalline β-lactam hydrates.
ISSN:0022-3549
1520-6017
DOI:10.1002/jps.20919