The Pressure-Temperature Phase Diagram of Metacetamol and Its Comparison to the Phase Diagram of Paracetamol

Understanding the polymorphic behavior of active pharmaceutical ingredients is important for formulation purposes and regulatory reasons. Metacetamol is an isomer of paracetamol and it similarly exhibits polymorphism. In the present article, it has been found that one of the polymorphs of metacetamo...

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Veröffentlicht in:	Journal of pharmaceutical sciences 2017-06, Vol.106 (6), p.1538-1544
Hauptverfasser:	Barrio, Maria, Huguet, Judit, Rietveld, Ivo B., Robert, Benoît, Céolin, René, Tamarit, Josep-Lluis
Format:	Artikel
Sprache:	eng
Schlagworte:	Acetaminophen - chemistry Analgesics, Non-Narcotic - chemistry Analytical chemistry Calorimetria Calorimetry Chemical Sciences Cristallography crystal polymorphism Crystallization Drug Stability Enginyeria biomèdica Estat sòlid Isomerism Life Sciences Material chemistry Medication or physical chemistry Pharmaceutical sciences phase behavior Phase Transition physical characterization physical stability Pressure solid state Solid state chemistry Temperature Termodinàmica Theoretical and thermal expansion Thermodynamics topological phase diagram Àrees temàtiques de la UPC
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creator	Barrio, Maria Huguet, Judit Rietveld, Ivo B. Robert, Benoît Céolin, René Tamarit, Josep-Lluis
description	Understanding the polymorphic behavior of active pharmaceutical ingredients is important for formulation purposes and regulatory reasons. Metacetamol is an isomer of paracetamol and it similarly exhibits polymorphism. In the present article, it has been found that one of the polymorphs of metacetamol is only stable under increased pressure, which has led to the conclusion that metacetamol like paracetamol is a monotropic system under ordinary (= laboratory) conditions and that it becomes enantiotropic under pressure with the I-II-L triple point coordinates for metacetamol TI-II-L = 535 ± 10 K and PI-II-L = 692 ± 70 MPa. However, whereas for paracetamol the enantiotropy under pressure can be foreseen, because the metastable polymorph is denser, in the case of metacetamol this is not possible, as the metastable polymorph is less dense than the stable one. The existence of the stability domain for the less dense polymorph of metacetamol can only be demonstrated by the construction of the topological phase diagram as presented in this article. It is a delicate interplay between the specific volume differences and the enthalpy differences causing the stability domain of the less dense polymorph to be sandwiched between the denser polymorph and the liquid. Metacetamol shares this behavior with bicalutamide and fluoxetine nitrate.
doi_str_mv	10.1016/j.xphs.2017.02.003
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Metacetamol is an isomer of paracetamol and it similarly exhibits polymorphism. In the present article, it has been found that one of the polymorphs of metacetamol is only stable under increased pressure, which has led to the conclusion that metacetamol like paracetamol is a monotropic system under ordinary (= laboratory) conditions and that it becomes enantiotropic under pressure with the I-II-L triple point coordinates for metacetamol TI-II-L = 535 ± 10 K and PI-II-L = 692 ± 70 MPa. However, whereas for paracetamol the enantiotropy under pressure can be foreseen, because the metastable polymorph is denser, in the case of metacetamol this is not possible, as the metastable polymorph is less dense than the stable one. The existence of the stability domain for the less dense polymorph of metacetamol can only be demonstrated by the construction of the topological phase diagram as presented in this article. It is a delicate interplay between the specific volume differences and the enthalpy differences causing the stability domain of the less dense polymorph to be sandwiched between the denser polymorph and the liquid. 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Metacetamol is an isomer of paracetamol and it similarly exhibits polymorphism. In the present article, it has been found that one of the polymorphs of metacetamol is only stable under increased pressure, which has led to the conclusion that metacetamol like paracetamol is a monotropic system under ordinary (= laboratory) conditions and that it becomes enantiotropic under pressure with the I-II-L triple point coordinates for metacetamol TI-II-L = 535 ± 10 K and PI-II-L = 692 ± 70 MPa. However, whereas for paracetamol the enantiotropy under pressure can be foreseen, because the metastable polymorph is denser, in the case of metacetamol this is not possible, as the metastable polymorph is less dense than the stable one. The existence of the stability domain for the less dense polymorph of metacetamol can only be demonstrated by the construction of the topological phase diagram as presented in this article. It is a delicate interplay between the specific volume differences and the enthalpy differences causing the stability domain of the less dense polymorph to be sandwiched between the denser polymorph and the liquid. 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subjects	Acetaminophen - chemistry Analgesics, Non-Narcotic - chemistry Analytical chemistry Calorimetria Calorimetry Chemical Sciences Cristallography crystal polymorphism Crystallization Drug Stability Enginyeria biomèdica Estat sòlid Isomerism Life Sciences Material chemistry Medication or physical chemistry Pharmaceutical sciences phase behavior Phase Transition physical characterization physical stability Pressure solid state Solid state chemistry Temperature Termodinàmica Theoretical and thermal expansion Thermodynamics topological phase diagram Àrees temàtiques de la UPC
title	The Pressure-Temperature Phase Diagram of Metacetamol and Its Comparison to the Phase Diagram of Paracetamol
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