Lidocaine/l-Menthol Binary System: Cocrystallization versus Solid-State Immiscibility | Zendy

Yohann Corvis | Zendy; Philippe Négrier | Zendy; Mathieu Lazerges | Zendy; Stéphane Massip | Zendy; JeanMichel Léger | Zendy; Philippe Espeau | Zendy

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Lidocaine/l-Menthol Binary System: Cocrystallization versus Solid-State Immiscibility

Author(s) -

Yohann Corvis,

Philippe Négrier,

Mathieu Lazerges,

Stéphane Massip,

JeanMichel Léger,

Philippe Espeau

Publication year - 2010

Publication title -

the journal of physical chemistry b

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.864

H-Index - 392

eISSN - 1520-6106

pISSN - 1520-5207

DOI - 10.1021/jp101303j

Subject(s) - cocrystal , differential scanning calorimetry , lidocaine , menthol , phase diagram , stoichiometry , chemistry , binary system , phase (matter) , thermodynamics , materials science , binary number , organic chemistry , molecule , mathematics , anesthesia , physics , medicine , hydrogen bond , arithmetic

We present the synthesis, structure determination, and thermodynamic properties of a never reported cocrystal prepared with lidocaine and L-menthol. The temperature-composition phase diagram of the lidocaine/L-menthol binary system was achieved using differential scanning calorimetry and X-ray diffraction experiments. The present study demonstrates that the only way to perform a phase equilibrium survey of the lidocaine/L-menthol system is to prepare the binary mixtures from the cocrystal, an equimolar stoichiometric compound of L-menthol and lidocaine. We describe a process that is crucial to elaborate pharmaceutical agents that remain in their thermodynamical stable state throughout their preparation, manufacture, and storage for effective use.

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