Abstracts

INTRODUCTION

The Brazilian Governmental Program Farmácia Popular Rede Própria was implemented to ensure access to low-cost medications that are considered essential for health for Brazilian citizens (Brasil, 2003BRASIL. Presidência da Republica. Casa Civil. Subchefia para Assuntos Jurídicos. Medida Provisória n.154, 23 de dezembro de 2003. Autoriza a Fundação Oswaldo Cruz - Fiocruz a disponibilizar medicamentos, mediante ressarcimento, e dá outras providências. Available at: http://www.planalto.gov.br/ccivil_03/MPV/Antigas_2003/154.htm. Acessed on: May 2012.
http://www.planalto.gov.br/ccivil_03/MPV... ). Some medications are manufactured and distributed through this nationwide chain. The Farmácia Popular Rede Própria is managed by Fundação Oswaldo Cruz (FIOCRUZ). The list of available medications is defined by the Ministry of Health based on epidemiological studies of the Brazilian population (Brasil, 2004). The drugs analyzed herein are all from the Farmácia Popular Rede Própria, which is hereafter referred to as FPRP.

Drug formulations provided by the FPRP are typically solid, which is consistent with the findings of a survey published in 2010 that revealed that over 80% of all medications are commercialized as tablets (Thayer, 2010THAYER, A.M. Finding solutions: custom manufacturers take on drug solubility issues to help pharmaceutical firms move products through development. Chem. Eng. News, v.88, n.22, p.13-18, 2010.). This predominance of solid drug formulations reflects the greater chemical stability of solid state compared with liquid state formulations (Nunn et al., 2005THAYER, A.M. Finding solutions: custom manufacturers take on drug solubility issues to help pharmaceutical firms move products through development. Chem. Eng. News, v.88, n.22, p.13-18, 2010.; Lee et al., 2011LEE, A.Y.; ERDEMIR, D.; MYERSON, A.S. Crystal polymorphism in chemical process development. Annu. Rev. Chem. Biomol. Eng., v.2, p.259-280, 2011.). Moreover, the development, manufacture, transportation, storage and supply of solid state formulations are simpler and less expensive in comparison to liquid state formulations (Nunn et al., 2005THAYER, A.M. Finding solutions: custom manufacturers take on drug solubility issues to help pharmaceutical firms move products through development. Chem. Eng. News, v.88, n.22, p.13-18, 2010.). However, solid state formulations also present challenges, such as polymorphism (Lee et al., 2011LEE, A.Y.; ERDEMIR, D.; MYERSON, A.S. Crystal polymorphism in chemical process development. Annu. Rev. Chem. Biomol. Eng., v.2, p.259-280, 2011.). This review focuses on the current knowledge of polymorphism in solid pharmaceuticals and the potential risk to the quality of drug products provided by the FPRP.

POLYMORPHISM

Definition and General Considerations

Polymorphism occurs when a solid compound exists in two or more crystal forms. Polymorphs are compounds with an identical chemical composition in which the molecules are arranged in at least two different ways in the crystalline state (Bilton et al., 1999BILTON, C.; HOWARD, J.A.K.; MADHAVI, N.N.L.; NANGIA, A.; DESIRAJU, G.R.; ALLEN, F.H.; CHICK, C.W. When is a polymorph not a polymorph? Helical trimeric O-H O synthons in trans-1,4-diethynylcyclohexane-1,4-diol. Chem. Commun., v.17, p.1675-1676, 1999.; Karpinski, 2006KARPINSKI, P.H. Polymorphism of active pharmaceutical ingredients. Chem. Eng. Technol., v.29, n.2, p.233-237, 2006.; Desiraju, 2008DESIRAJU, G.R. Polymorphism: the same and not quite the same. Cryst. Growth Des., v.8, n.1, p.3-5, 2008.; Purohit et al., 2009PUROHIT, R.; VENUGOPALAN, P. Polymorphism: an overview. Resonance, v.14, n.9, p.882-893, 2009.). In pharmaceutical science, however, the term is used to designate several solid state forms of drugs and excipients, including amorphous forms, solvates, hydrates, salts and co-crystals (Aaltonen et al., 2009AALTONEN, J.; ALLESØ, M.; MIRZA, S.; KORADIA, V.; GORDON, K.C.; RANTANEN, J. Solid form screening – a review. Eur. J. Pharm. Biopharm., v.71, n.1, p.23-37, 2009.).

The amorphous form does not possess a defined order in its arrangement. Although the amorphous form is the most soluble form, it exhibits the lowest stability (Haisa et al., 1974HAISA, M.; KASHINO, S.; MAEDA, H. The orthorhombic form of p-hydroxyacetanilide. Acta Crystallogr., Sect. B: Struct. Crystallogr. Cryst. Chem., v.30, n.10, p.2510-2512, 1974.; Lowes et al., 1987LOWES, M.M.; CAIRA, M.R.; LÖTTER, A.P.; VAN DER WATT, J.G. Physicochemical properties and X-ray structural studies of the trigonal polymorph of carbamazepine. J. Pharm. Sci., v.76, n.9, p.744-752, 1987.; Chieng et al., 2009CHIENG, N.; AALTONEN, J.; SAVILLE, D.; RADES, T. Physical characterization and stability of amorphous indomethacin and ranitidine hydrochloride binary systems prepared by mechanical activation. Eur. J. Pharm. Biopharm., v.71, n.1, p.47-54, 2009.).

In amorphous and crystalline forms, a solid drug may be anhydrous or a solvate/hydrate. When a solid form contains a solvent, it is known as a solvate. When the solvent is water, it is termed a hydrate (European Pharmapoeia, 2008EUROPEAN Pharmapoeia. 6.ed. Strasbourg: Council of Europe, 2008. v.1, p.649.).

Due to the frequent presence of water in the environment and its use in solvent blendings during the crystallization process, the formation of hydrated drugs is common. Because the water molecule is small and able to form hydrogen bonds, it is easily incorporated into the crystalline lattice of drugs both occupying spaces and stabilizing the structure (Gillon et al., 2003GILLON, A.L.; FEEDER, N.; DAVEY, R.J.; STOREY, R.; Hydration in molecular crystals - a Cambridge structural database analysis. Cryst. Growth Des., v.3, n.5, p.663-673, 2003.).

A survey performed in 1999 on drugs described in the European Pharmacopoeia revealed that one-third of the 808 products listed therein could form hydrates (Griesser, 2006GRIESSER, U.J. The importance of solvates. In: HILFIKER, R. (Ed.). Polymorphism in pharmaceutical industry. Weinheim: Wiley –VCH, 2006. cap.8, p.211-230.). In Brazil, drugs commercialized as hydrates include the following: amoxicillin trihydrate, ampicillin trihydrate, cephalexin monohydrate, sodium dipyrone monohydrate, lidocaine hydrochloride monohydrate, meropenem trihydrate, methyldopa sesquihydrate, pantoprazole sesquihydrate, morphine sulfate pentahydrate, and dexamethasone acetate monohydrate (Farmacopeia Brasileira, 2010FARMACOPEIA Brasileira. 5.ed. Brasília: Agência Nacional de Vigilância Sanitária, 2010. v.2, 904 p.).

In addition to molecular crystals, drug anhydrates or solvates/hydrates, co-crystals, and salts also occur. Co-crystals are drug solids defined as multicomponent molecular crystals in which at least one of the compounds is an active pharmaceutical ingredient (API) (Bond, 2007BOND, A.D. What is a co-crystal? Cryst. Eng. Comm., v.9, n.9, p.833-834, 2007.; Schultheiss et al., 2009). Salts are considered different from co-crystals provided that they are crystals formed by ionic multicomponents (Mohamed et al., 2009MOHAMED, S.; TOCHER, D.A.; VICKERS, M.; KARAMERTZANIS, P.G. Salt or cocrystal? a new series of crystal structures formed from simple pyridines and carboxylic acids. Cryst. Growth Des., v.9, n.6, p.2881-2889, 2009.). The FDA has recently published a Regulatory Classification of Pharmaceutical Co-Crystals (FDA, 2013) in which co-crystal is defined as “Crystalline materials composed of two or more molecules within the same crystal lattice” and polymorphs as “Different crystalline forms of the same drug substance. This may include solvation or hydration products (also known as pseudopolymorphs) and amorphous forms”.

However, the definitions for these solid forms are matters of debate among the scientific community, regulatory agencies, and industrial groups, without a clear consensus (Schultheiss et al., 2009; Aitipamula et al., 2012AITIPAMULA, S.; BANERJEE, R.; BANSAL, A.K.; BIRADHA, K.; CHENEY, M.L.; CHOUDHURY, A.R.; DESIRAJU, G.R.; DIKUNDWAR, A.G.; DUBEY, R.; DUGGIRALA, N.; GHOGALE, P.P.; GHOSH, S.; GOSWAMI, P.K.; GOUD, N.R.; JETTI, R.K.R.; KARPINSKI, P.; KAUSHIK, P.; KUMAR, D.; KUMAR, V.; MOULTON, B.; MUKHERJEE, A.; MUKHERJEE, G.; MYERSON, A.S.; PURI, V.; RAMANAN, A.; RAJAMANNAR, T.; REDDY, C.M.; RODRIGUEZ-HORNEDO, N.; ROGERS, R.D.; ROW, T.N.G.; SANPHUI, P.; SHAN, N. SHETE, G.; SINGH, A.; SUN, C.C.; SWIFT, J.A.; THAIMATTAM, R.; THAKUR, T.S.; THAPER, R.K.; THOMAS, S.P.; TOTHADI, S.; VANGALA, V.R.; VARIANKAVAL, N.; VISHWESHWAR, P.; WEYNA, D.R.; ZAWOROTKO, M.J. Polymorphs, salts, and cocrystals: what’s in a name? Cryst. Growth Des., v.12, n.5, p.2147-52, 2012.).

Moreover, a nomenclature for polymorphs has not been established. Generally, different polymorphic forms of identical molecules are denoted by numerical (Carstensen, 2001CARSTENSEN, J.T. One-component systems. In: ______. Advanced pharmaceutical solids. New York: Marcel Dekker, 2001. p.1-11. (Drugs and the pharmaceutical sciences; v.110).) or alphabetical sequences; they can also be differentiated by means of hydration or solvation levels. In general, polymorphs are designated by the chronological order in which they have been reported (Carstensen, 2001CARSTENSEN, J.T. One-component systems. In: ______. Advanced pharmaceutical solids. New York: Marcel Dekker, 2001. p.1-11. (Drugs and the pharmaceutical sciences; v.110).).

The occurrence of polymorphism and its effects on solid products are attributed to existing intermolecular bonds. These noncovalent bonds, such as hydrogen bonds and van der Waals, π-π, and electrostatic interactions, determine the arrangement of the molecules in a crystal (Desiraju, 1995DESIRAJU, G.R. Supramolecular synthons in crystal engineering — a new organic synthesis. Angew. Chem., Int. Ed. Engl., v.34, n.21, p.2311-2327, 1995., 2001DESIRAJU, G.R. Chemistry beyond the molecule. Nature, v.412, n.6845, p.397-400, 2001.; Moulton et al., 2001MOULTON, B.; ZAWOROTKO, M.J. From molecules to crystal engineering: supramolecular isomerism and polymorphism in network solids. Chem. Rev., v.101, n.33, p.1629-1658, 2001.; Purohit et al., 2009PUROHIT, R.; VENUGOPALAN, P. Polymorphism: an overview. Resonance, v.14, n.9, p.882-893, 2009.). API molecules are produced by atoms connected by covalent bonds, whereas crystals consist of molecules arranged through intermolecular interactions. The differences in these interactions can lead to distinct polymorphic forms and vice-versa (Blagden et al., 2007BLAGDEN, N.; DE MATAS, M.; GAVAN, P.T.; YORK, P. Crystal engineering of active pharmaceutical ingredients to improve solubility and dissolution rates. Adv. Drug Delivery Rev., v.59, n.7, p.617-630, 2007.).

Any variation in the intermolecular arrangement of solid materials will alter the physical and chemical properties because these characteristics are intrinsically determined by its crystalline form, with the possibility of affecting bioavailability and stability (Byrn et al., 1999BYRN, S.R.; PFEIFFER, R.R.; STOWELL, J.G. Solid-state chemistry of drugs. 2.ed. West Lafayette: SSCI, 1999. 574 p.; ICH Q6A, 1999ICH. Q6A: Test procedures and acceptance criteria for new drug substances and new drug products: chemical substances. Genebra: ICH, 1999. Available at: http://www.ich.org/products/guidelines/quality/article/qualityguidelines.html. Acsessed on: July 2012.
http://www.ich.org/products/guidelines/q... ; Bauer et al., 2001BAUER, J.; SPANTON, S.; HENRY, R.; QUICK, J.; DZIKI, W.; PORTER, W.; MORRIS, J. Ritonavir: an extraordinary example of conformational polymorphism. Pharm. Res., v.18, n.6, p.859-866, 2001.; Erk et al., 2004ERK, P.; HENGELSBERG, H.; HADDOW, M.F.; GELDER, R.V. The innovative momentum of crystal engineering. Cryst. Eng. Comm., v.6, p.474-483, 2004.; Lee et al., 2011LEE, A.Y.; ERDEMIR, D.; MYERSON, A.S. Crystal polymorphism in chemical process development. Annu. Rev. Chem. Biomol. Eng., v.2, p.259-280, 2011.).

According to Lee et al., 2011LANG, M.; KAMPF, J.W.; MATZGER, A.J. Form IV of carbamazepine. J. Pharm. Sci., v.91, n.4, p.1186-1190, 2002., the properties that vary as a consequence of the polymorphic form of the active pharmaceutical ingredient are the following: a) chemical: chemical reactivity and photochemical reactivity; b) kinetic: the rate of dissolution and stability; c) mechanical: compactability, hardness, powder flow, and friability; d) physical: conductivity, density, hygroscopicity, and particle morphology; e) surface: interfacial tension, surface area, and surface free energy; and f) thermodynamic: chemical potential, free energy, and solubility; enthalpy and entropy; heat capacity; melting and sublimation; and vapor pressure.

Challenges for the Pharmaceutical Industry

One of the first reports concerning the influence of polymorphism on drugs dates back to 1967 (Aguiar et al., 1967AGUIAR, J.A.; KRC JR, J.; KINKEL, A.W.; SAMYN, J.C. Effect of polymorphism on the absorption of chloramphenicol from chloramphenicol palmitate. J. Pharm. Sci., v.56, n.7, p.847-853, 1967.). In this study, the bioavailability of chloramphenicol palmitate in suspension was evaluated in humans, and it was concluded that the distinct A and B polymorphic forms exhibited not only different dissolution rates but also differences in serum levels. Form A, which is more stable, did not exhibit adequate bioavailability, whereas form B, which is metastable, exhibited greater bioavailability (Aguiar et al., 1967AGUIAR, J.A.; KRC JR, J.; KINKEL, A.W.; SAMYN, J.C. Effect of polymorphism on the absorption of chloramphenicol from chloramphenicol palmitate. J. Pharm. Sci., v.56, n.7, p.847-853, 1967.).

Although the effects of polymorphism on drugs have been known since the 1960s, it was only until the case of Norvir^® (ritonavir), which is used for the control of acquired immunodeficiency syndrome (AIDS), that highlighted polymorphism as a serious concern for the pharmaceutical industry (Aaltonen et al., 2009AALTONEN, J.; ALLESØ, M.; MIRZA, S.; KORADIA, V.; GORDON, K.C.; RANTANEN, J. Solid form screening – a review. Eur. J. Pharm. Biopharm., v.71, n.1, p.23-37, 2009.). During the development of Norvir^®, only a single polymorphic form was identified. In 1998, several lots of capsules did not pass the dissolution test due to the appearance of a new polymorphic form (denoted form II) that had formed during the manufacturing process, which was more stable and not very soluble (Chemburkar et al., 2000CHEMBURKAR, S.R.; BAUER, J.; DEMING, K.; SPIWEK, H.; PATEL, K.; MORRIS, J.; HENRY, R.; SPANTON, S.; DZIKI, W.; PORTER, W.; QUICK, J.; BAUER, P.; DONAUBAUER, J.; NARAYANAN, B.A.; SOLDANI, M.; RILEY, D.; MCFARLAND, K. Dealing with the impact of ritonavir polymorphs on the late stages of bulk drug process development. Org. Process Res. Dev., v.4, n.5, p.413-417, 2000.; Bauer et al., 2001BAUER, J.; SPANTON, S.; HENRY, R.; QUICK, J.; DZIKI, W.; PORTER, W.; MORRIS, J. Ritonavir: an extraordinary example of conformational polymorphism. Pharm. Res., v.18, n.6, p.859-866, 2001.). Thus, the medication was removed from the market due to the inability to manufacture the desired polymorphic form (form I) (Lee et al.., 2011LEE, A.Y.; ERDEMIR, D.; MYERSON, A.S. Crystal polymorphism in chemical process development. Annu. Rev. Chem. Biomol. Eng., v.2, p.259-280, 2011.) To resolve this issue, Abbott Laboratories was required to spend hundreds of millions of dollars with an estimated loss of US$250m in sales in 1998 alone (Goldbek et al., 2011GOLDBEK, G.; PIDCOK, E.; GROOM, C. Solid form informatics for pharmaceuticals and agrochemicals: knowledge-based substance development and risk assessment. Cambridge Crystallographic Data Centre, p.1-8, 2011. Available at: http://www.ccdc.cam.ac.uk/Lists/ResourceFileList/Solid%20Form%20Informatics%20.pdf. Accessed on: Oct. 2013.
http://www.ccdc.cam.ac.uk/Lists/Resource... ).

The reformulation of Norvir^® using the more stable form required approximately one year, in which patients were deprived of this important medication (Peterson et al., 2006PETERSON, M.L.; HICKEY, M.B.; ZAWOROTKO, M.J.; ALMARSSON, Ö. Expanding the scope of crystal form evaluation in pharmaceutical science. J. Pharm. Pharm. Sci., v.9, n.3, p.317-326, 2006.). The impact on the standard of living of these patients caused by drug polymorphism highlights the serious consequences of drug polymorphism as a public health concern.

A similar situation occurred with rotigotine. Originally licensed as a polymorphism-free API, Schwarz Pharma commercialized rotigotine in 2006 as a transdermal medication to treat the signs and symptoms of Parkinson’s disease (Goldbek et al., 2011GOLDBEK, G.; PIDCOK, E.; GROOM, C. Solid form informatics for pharmaceuticals and agrochemicals: knowledge-based substance development and risk assessment. Cambridge Crystallographic Data Centre, p.1-8, 2011. Available at: http://www.ccdc.cam.ac.uk/Lists/ResourceFileList/Solid%20Form%20Informatics%20.pdf. Accessed on: Oct. 2013.
http://www.ccdc.cam.ac.uk/Lists/Resource... ). Nevertheless, in 2008, rotigotine (Neupro^®) was removed from the market due to the transformation into a less soluble polymorphic substance that had crystallized and was not absorbed by the skin (Goldbek et al., 2011GOLDBEK, G.; PIDCOK, E.; GROOM, C. Solid form informatics for pharmaceuticals and agrochemicals: knowledge-based substance development and risk assessment. Cambridge Crystallographic Data Centre, p.1-8, 2011. Available at: http://www.ccdc.cam.ac.uk/Lists/ResourceFileList/Solid%20Form%20Informatics%20.pdf. Accessed on: Oct. 2013.
http://www.ccdc.cam.ac.uk/Lists/Resource... ; FDA, 2008).

Due to its strategic importance for public health, medications available in the ‘FPRP’ program (Brasil, 2012) were selected for this study to perform a bibliographic survey on the occurrence of polymorphism, its possible influence on the physicochemical properties of the API and, consequently, on the final quality of the pharmaceutical formulations.

Bioequivalence and Bioavailability

To reach an expected therapeutic aim, it is imperative that pharmaceuticals exist at the expected concentration. Considering solid formulations, the medications must release the appropriate amount of API at a suitable rate for the desired therapeutic effect and be bioequivalent to the reference product. Moreover, these formulations must exhibit physicochemical stability within their shelf life (Aulton, 2005AULTON, M.E. Delineamento de formas farmacêuticas. 2.ed. Rio de Janeiro: Artmed. 2005. 678 p.).

The Biopharmaceutical Classification System (BCS) may provide useful information to develop strategies to control polymorphism because the solubility, dissolution, and permeability of an API are determinants of its bioavailability. According to the BCS, drugs are subdivided into the following four categories: I, high solubility and high permeability; II, low solubility and high permeability; III, high solubility and low permeability; and IV, low solubility and low permeability. A drug is considered to have high solubility when its highest recommended dose is soluble in 250 mL of aqueous medium in a pH range of 1-7.5 (Amidon et al., 1995AMIDON, G.L.; LENNERNÄS, H.; SHAH, V.P.; CRISON, J.R. A theoretical basis for a biopharmaceutic drug classification: the correlation of in vitro drug product dissolution and in vivo bioavailability. Pharm. Res., v.12, n.3, p.413-420, 1995.).

Considering that polymorphic forms of an API can exhibit different solubility levels, choosing the incorrect polymorphic form or the occurrence of a phase transition during the manufacture and storage may affect the bioavailability and, consequently, the efficacy and safety, particularly for drugs for which dissolution is the absorption-limiting factor (classes II and IV) (FDA, 2007FDA. U.S. Food and Drug Administration. Guidance for Industry - ANDAs: Pharmaceutical Solid Polymorphism Chemistry, Manufacturing, and Controls Information, 2007. Available at: http://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Guidances/ucm072866.pdf. Accessed on: Apr. 2012.
http://www.fda.gov/downloads/Drugs/Guida... ; Llinàs et al.,2008LLINÀS, A.; GOODMAN, J.M. Polymorph control: past, present and future. Drug Disc. Today, v.13, n.5/6, p.198-210, 2008.).

When the occurrence of two or more solid forms of an API, including polymorphs, is identified during the development of a drug, the chosen form is typically the most stable (Shingal et al., 2004TAWASHI, R. Aspirin: dissolution rates of two polymorphics forms. Science, v.160, n.3823, p.76, 1968.; Von Raumer, Dannappel, Hilfiker, 2012VON RAUMER, M.; DANNAPPEL, J.; HILFIKER, R. Polymorphism, salts, and crystallization. The relevance of solid-state development. Chim. Oggi, v. 24, n. 1, p. 41-44, 2006.). In addition to being easily controllable, the more stable polymorphic form also complies with requirements described in the Q6A Guide of the International Commission on Harmonization (ICH) for solid form selection (Grant et al., 2004GRANT, D.J.W.; BYRN, S.R. A timely re-examination on drug polymorphism in pharmaceutical development and regulation. Adv. Drug Delivery Rev., v.56, n.3, p.237-239, 2004.).

KNOWN CRYSTAL FORMS OF APIS PROVIDED BY THE FPRP

Table I summarizes the different APIs distributed by the FPRP as solid pharmaceutical formulations, for which the therapeutic class and relevant information on polymorphism are also included. Despite 79 of 113 (69.9%) solid formulations from the FPRP, the number of different solid APIs is 65. This difference is due to the availability of more than one dosage for an identical API. Table I also includes the BCS class, known crystal structures and correct polymorph reported in the literature that is present in the medication for each API.

The Cambridge Structural Database (CSD, 2011CSD. Cambridge Crystallographic Data Centre. version 5.33 of November 2011 with February 2012 and May 2012 updates. Available at: http://www.ccdc.cam.ac.uk/. Accessed on: May 2012.
http://www.ccdc.cam.ac.uk/... ) and Inorganic Crystal Structure Database (ICSD, 2002) was used to analyze crystalline structures by entering the compound name, molecular form, and chemical structure. Information on patents and indexed journals in the electronic databases SciFinder^© (2012) and Web of Science^© (2012) were also collected. Compound structures were included as single component forms, hydrates, salts, and solvates with pharmaceutical application. Biopharmaceutical classification was obtained at the Therapeutic System Research Laboratories, which is managed by Amidon et al., 2012 (TSRL inc 2012TSRL inc. Therapeutic System Research Laboratories. BCS (Biopharmaceutics Classification System).Avaiable at: http://69.20.123.154/services/bcs/search.cfm. Acessed on: 16 Jul. 2012.
http://69.20.123.154/services/bcs/search... ). Furthermore, a search was performed using the aforementioned electronic databases by combining the terms “name of the compound in English” and “polymorph” in the free search of databases. Articles that discussed solid state chemical polymorphism were included; articles that discussed other types of polymorphism were excluded.

Table I indicates that phenobarbital and alendronate sodium are the APIs with the most reported polymorphic crystal structures (11 forms each) followed by cephalexin (8 forms) and acetaminophen/carbamazepine/acyclovir (6 forms each). A total of 168 crystal structures were found for the 65 APIs listed in Table I, which resulted in a mean value of 2.67 polymorphs per API. Figure 1a illustrates that 42 (65%) of the 65 APIs exhibit two or more polymorphs of known crystal structure. Only 21 (32%) APIs do not exhibit more than one reported crystal form. However, it is important to emphasize that in this review, only polymorphs deposited in the CSD^© and ICSD^© or in articles indexed in SciFinder^© and Web of Science^© were considered. The revision work also indicates that no crystal structure is known for 2 (3%) APIs listed in Table 1. For some APIs, the thermodynamically stable form (or preconized polymorphic form) is reported in the literature. This result is also summarized in Table I and is illustrated in Figure 1b. Noteworthy is the number of APIs (24, 37%) without studies indicating the correct crystal form, of which 13 (54%) have two or more known polymorphic crystal structures.

Figures 1c and 1d show the BCS classification of the 65 solid APIs available at the FPRP, illustrating that 31 (48%) possess low solubility (classes II and IV). Figure 2 shows the number of APIs with “unknown”, “only one”, and “two or more” crystal structures per BCS class. For 21 (68%) of the 31 class II and IV APIs (low solubility), two or more crystal structures have been reported. For 17 (68%) of the 25 class I and III APIs (high solubility), two or more polymorphic structures have been reported.

Despite 41 (63%) APIs (Table 1) with more than one reported crystal structure, as previously mentioned, there are studies concerning the influence of polymorphism on drug performance for only 22 (14.3%). Problems related to either the efficacy or the manufacture caused by polymorphism have been reported, i.e., for mebendazole, carbamazepine, estradiol, and acetaminophen.

Albendazole and Mebendazole

The antiparasitic albendazole and mebendazole are among the low solubility drugs with reported polymorphism. Albendazole is commercialized in form I (metastable), which is the most soluble form. Both forms I and II are stable under storage conditions; however, much care is required to control the form because of the possibility of undesirable polymorphic phase conversion in this API (Pranzo et al., 2010PRANZO, M.B.; CRUICKSHANK, D.; CORUZZI, M.; CAIRA, M.R.; BETTINI, R. Enantiotropically related albendazole polymorphs. J. Pharm. Sci., v.99, n.9, p.3731-3742, 2010.).

Mebendazole exhibits polymorphic forms A, B, and C, which differ in their biopharmaceutical and physicochemical properties. Polymorph C is the pharmaceutically preferred form due to its adequate aqueous solubility (Rodriguez et al., 1987RODRIGUEZ-CAABEIRO, F.; CRIADO-FORNELIO, A.; JIMENEZ- GONZALEZ, A.; GUZMAN, L.; IGUAL, A.; PÉREZ, A.; PUJOL, M. Experimental chemotherapy and toxicity in mice of three mebendazole polymorphic forms. Chemotherapy, v.33, n.4, p.266-271, 1987.; Charoenlarp et al., 1993CHAROENLARP, P.; WAIKAGUL, J.; MUENNOO, C.; SRINOPHAKUN, S.; KITAYAPORN, D. Efficacy of single-dose mebendazole, polymorphic forms A and C, in the treatment of hookworm and Thichuris infections. Southeast Asian J. Trop. Med. Public Health, v.24, n.4, p.712-716, 1993.). Form A is the most stable, less soluble form that is considered therapeutically ineffective (Rodriguez et al., 1987RODRIGUEZ-CAABEIRO, F.; CRIADO-FORNELIO, A.; JIMENEZ- GONZALEZ, A.; GUZMAN, L.; IGUAL, A.; PÉREZ, A.; PUJOL, M. Experimental chemotherapy and toxicity in mice of three mebendazole polymorphic forms. Chemotherapy, v.33, n.4, p.266-271, 1987.). In a clinical study with 958 children, the efficacy of polymorph A did not differ from the placebo (Charoenlarp et al., 1993CHAROENLARP, P.; WAIKAGUL, J.; MUENNOO, C.; SRINOPHAKUN, S.; KITAYAPORN, D. Efficacy of single-dose mebendazole, polymorphic forms A and C, in the treatment of hookworm and Thichuris infections. Southeast Asian J. Trop. Med. Public Health, v.24, n.4, p.712-716, 1993.). Costa et al. (1991) have shown that polymorph B is more soluble than polymorph C. Therefore, polymorph B should be avoided or a strategy to ensure the proper dosage must be developed to enable the drug to exert the desired effect. Form C, thus, recommended for oral use, is metastable and, in solution, may crystallize as the more stable form A (Rodriguez et al., 1987RODRIGUEZ-CAABEIRO, F.; CRIADO-FORNELIO, A.; JIMENEZ- GONZALEZ, A.; GUZMAN, L.; IGUAL, A.; PÉREZ, A.; PUJOL, M. Experimental chemotherapy and toxicity in mice of three mebendazole polymorphic forms. Chemotherapy, v.33, n.4, p.266-271, 1987.; Agatonovic-Kustrin et al., 2008AGATONOVIC-KUSTRIN, S.; WU, V.; RADES, T.; SAVILLE, D.; TUCKER, I.G. Powder diffractometric assay of two polymorphic forms of ranitidine hydrochloride. Int. J. Pharm., v.184, n.1, p.107-114, 1999.). Moreover, regarding stability, the presence of small quantities of form A in tablets results in a rapid increase of transformation into other polymorphic forms. Four analyzed trademark drugs presented traces of form A, and, in most of them, the shelf life was reduced to less than a month. These products also failed to comply with the acceptance criteria of the United States Pharmacopoeia (USP) and the Food and Drug Administration (FDA) in dissolution assays (Brits et al., 2010BRITS, M.; LIEBENBERG, W.; DE VILLIERS, M.M. Characterization of polymorph transformations that decrease the stability of tablets containing the WHO essential drug mebendazole. J. Pharm. Sci., v.99, n.3, p.1138-1151, 2010.). Therefore, the anthelmintic efficacy of mebendazole is highly dependent on the polymorphism (Martins et al., 2009MARTINS, F.T.; NEVES, P.P.; ELLENA, J.; CAMÍ, G.E.; BRUSAU, E.V.; NARDA, G.E. Intermolecular contacts influencing the conformational and geometric features of the pharmaceutically preferred mebendazole polymorph C. J. Pharm. Sci., v.98, n.7, p.2336-2344, 2009.).

Quality control routine tests that may distinguish among polymorphic forms include the dissolution assay, IR spectroscopy, thermogravimetric analyses, and primarily powder X-ray diffraction measurements (Liebenberg et al., 1998LIEBENBERG, W.; DEKKER, T.G.; LÖTTER, A.P.; VILLIERS, M.M. Identification of the mebendazole polymorphic form present in raw materials and tablets available in South Africa. Drug Dev. Ind. Pharm., v.24, n.5, p.485-488, 1998.). Nevertheless, it was observed that the mebendazole dissolution assay described in USP 25 did not distinguish among the three polymorphic forms. The recommended dissolution medium was 0.1 M hydrochloride acid containing sodium lauryl sulfate (SLS). The solubility difference among the polymorphs had been masked with the inclusion of the surfactant, and the removal of SLS from the dissolution medium resolved the polymorphic forms (Swanepoel et al., 2003SWANEPOEL, E.; LIEBENBERG, W.; DE VILLIERS, M.M. Quality evaluation of generic drugs by dissolution test: changing the USP dissolution medium to distinguish between active and non-active mebendazole polymorphs. Eur. J. Pharm. Biopharm., v.55, n.3, p.345-349, 2003.).

Despite this example, the USP 34 (2011) continues to recommend a dissolution medium that contains SLS. Therefore, much attention should be directed at quality control methods that are able to discriminate between polymorphic forms and that the polymorphic form present in the medication is the recommended form. In this respect, characterization using powder X-ray diffraction is very useful.

In 2005, an analysis of the raw materials and drug products containing mebendazole in the Brazilian market revealed the following alarming results: the expected form C was not found in any analyzed raw material, USP reference standard included. From the 10 analyzed medications, five contained polymorph A, three contained polymorph C, and two contained a mixture of polymorphs B and C, with B as the majority. At the time the study was published, the mebendazole reference brand (manufactured by Abbott Laboratories) was altered. Polymorph C was not detected in this new reference medication, which also contained different polymorphs in different lots (Froehlich et al., 2005FROEHLICH, P.E.; GASPAROTTO, F.S. Mebendazol: identificação das formas polimórficas em diferentes matérias-primas e medicamentos (referência e genéricos) disponíveis no mercado nacional. Rev. Cienc. Farm. Basica Apl., v.26, n.3, p.205-210, 2005.).

Furosemide

Another low solubility drug that exhibits problems related to the dissolution assay in official compendia is the diuretic furosemide. When the solubilities of furosemide polymorphs are compared, the metastable form II is found to be the most soluble (Matsuda et al., 1990MATSUDA, Y.; TATSUMI, E. Physicochemical characterization of furosemide modifications. Int. J. Pharm., v.60, n.1, p.11-26, 1990.). This API has been observed to undergo photolytic degradation from which the metastable forms suffer more than the thermodynamically stable form I (Matsuda et al., 1990MATSUDA, Y.; TATSUMI, E. Physicochemical characterization of furosemide modifications. Int. J. Pharm., v.60, n.1, p.11-26, 1990.; Villiers et al.1992VILLIERS, M.M.; WATT, J.G.; LÖTTER, A.P. Kinetic study of the solid-state photolytic degradation of two polymorphic forms of furosemide. Int. J. Pharm., v.88, n.1/3, p.275-283, 1992.). To differentiate furosemide polymorphic forms in pharmaceutical formulations, several dissolution mediums were tested, which resulted in a recommended medium at pH 2.2 due to its ability to differentiate the commercialized form (form I) from the other forms (II and III) (Maggio et al., 2009MAGGIO, R.M.; CASTELLANO, P.M.; KAUFMAN, T.S. PCA-CR analysis of dissolution profiles: a chemometric approach to probe the polymorphic form of the active pharmaceutical ingredient in a drug product. Int. J. Pharm., v.378, n.1, p.187-193, 2009.).

Considering the diuretic furosemide as an example, the in vitro dissolution assay is an excellent tool to differentiate polymorphic forms and identify polymorphic phase transitions. Provided the test anticipates bioavailability and physical stability, it can evaluate the quality of a medication (Yu et al., 2003YU, L.X.; FURNESS, M.S.; RAW, A.; OUTLAW, K.P.W.; NASHED, N.E.; RAMOS, E.; MILLER, S.P.F.; ADAMS, R.C..;FANG, F.; PATEL, M.R.; HOLCOMBE, O.F.; CHIU, Y-Y.; HUSSAIN, A.S. Scientific considerations of pharmaceutical solid polymorphism in abbreviated new drug applications. Pharm. Res., v.20, n.4, p.531-536, 2003.; Raw et al., 2004RAW, A.S.; FURNESS, M.S.; GILL, D.S.; ADAMS, R.C.; HOLCOMBE JR., F.O.; YU, L.X. Regulatory considerations of pharmaceutical solid polymorphism in Abbreviate New Drug Applications (ANDAs). Adv. Drug Delivery Rev., v.56, n.3, p.397-414, 2004.).

Therefore, methods that are described in official compendia must be carefully considered because, as observed with mebendazole, the recommended dissolution test for furosemide does not discriminate among forms (United States Pharmacopeia, 2011UNITED States Pharmacopeia USP34; National Formulary NF29. Rockville: United States Pharmacopeial Convention, 2011. v.2-3.). Thus, the development of methods that are able to differentiate polymorphic forms is essential for the quality control of medications, particularly for low solubility drugs (Bonfilio et al., 2012BONFILIO, R.; PIRES, S.A.; FERREIRA, L.M.B.; ALMEIDA, A.E.; DORIGUETTO, A.C.; ARAÚJO, M.B.; HÉRIDA, R.N.S. A discriminating dissolution method for glimepiride polymorphs. J. Pharm. Sci., v.101, n.2, p.794-804, 2012.).

Fluconazole

Fluconazole confirms the high frequency of hydrate occurrence in APIs. Fluconazole exists as a mixture of forms I and II and fluconazole monohydrate (Park et al., 2007PARK, H.J.; KIM, M.; KIM, J.; CHO, W.; PARK, J.; CHA, K.; YOUNG-SHIN, K.; SUNG-JOO, H. Solid-state carbon NMR characterization and investigation of intrinsic dissolution behavior of fluconazole polymorphs, anhydrate forms I and II. Chem. Pharm. Bull., v.58, n.9, p.1243-1247, 2010.). The solubility order among the polymorphs of this API is II (metastable) > I > monohydrate (Park et al., 2010PARK, H.J.; KIM, M.; KIM, J.; CHO, W.; PARK, J.; CHA, K.; YOUNG-SHIN, K.; SUNG-JOO, H. Solid-state carbon NMR characterization and investigation of intrinsic dissolution behavior of fluconazole polymorphs, anhydrate forms I and II. Chem. Pharm. Bull., v.58, n.9, p.1243-1247, 2010.), and forms I and II convert into the monohydrate when dissolved in water (Park et al., 2010PARK, H.J.; KIM, M.; KIM, J.; CHO, W.; PARK, J.; CHA, K.; YOUNG-SHIN, K.; SUNG-JOO, H. Solid-state carbon NMR characterization and investigation of intrinsic dissolution behavior of fluconazole polymorphs, anhydrate forms I and II. Chem. Pharm. Bull., v.58, n.9, p.1243-1247, 2010.). Polymorph II has been found to absorb humidity and form the monohydrate phase from both the environment and the excipient during either the storage phase or the manufacturing phase (Chandavarkar, Jindai, Kulkarni, 2011CHANDAVARKAR, N.M.; JINDAI, K.C.; KULKARNI, S.S. Stabilized fluconazole polymorph III formulation. WO 2011/101862, Aug. 24, 2011. 26 p.).

Acyclovir

The acyclovir in pharmaceutical formulations is present as a hydrate (polymorph V) (Kristl et al., 1996KRISTL, A.; SRČIČ, S.; VREČER, F.; ŠUŠTAR, B.; VOJNOVIC, D. Polymorphism and pseudopolymorphism: influencing the dissolution properties of the guanine derivative acyclovir. Int. J. Pharm., v.139, n.1/2, p.231-235, 1996.; Lutker et al., 2011LUTKER, K.M.; QUINONES, R.; XU, J.; RAMAMOORTHY, A.; MATZGER, A.J. Polymorphs and hydrates of acyclovir. J. Pharm. Sci., v.100, n.3, p.949-963, 2011.). Unexpectedly, the hydrated form of acyclovir solubilizes more rapidly than the anhydrous form (Kristl et al., 1996KRISTL, A.; SRČIČ, S.; VREČER, F.; ŠUŠTAR, B.; VOJNOVIC, D. Polymorphism and pseudopolymorphism: influencing the dissolution properties of the guanine derivative acyclovir. Int. J. Pharm., v.139, n.1/2, p.231-235, 1996.; Stephenson et al., 1997STEPHENSON, G.A.; STOWELL, J.G.; TOMA, P.H.; PFEIFFER, R.R.; BYRN, S.R. Solid-state investigations of Erythromycin A dihydrate: structure, NMR spectroscopy, and Hygroscopicity. J. Pharm. Sci., v.86, n.11, p.1239-1244, 1997.), which is explained by the high thermodynamic stability and low hygroscopicity of the anhydrous form (Kristl et al., 1996KRISTL, A.; SRČIČ, S.; VREČER, F.; ŠUŠTAR, B.; VOJNOVIC, D. Polymorphism and pseudopolymorphism: influencing the dissolution properties of the guanine derivative acyclovir. Int. J. Pharm., v.139, n.1/2, p.231-235, 1996.).

Cephalexin, Erythromycin, Ciprofloxacin, Sulfamethoxazole, and Digoxin

A tendency to form hydrates is also observed in the antibiotics cephalexin, erythromycin, ciprofloxacin, and sulfamethoxazole. In pharmaceutical preparations, monohydrated cephalexin is the predominant polymorphic form (Aguiar et al., 2011AGUIAR, D.L.M.; SAN GIL, R.A.S.; BORRE, L.B.; MARQUES, M.R.C.; GEMAL, A.L. Evaluation of polymorphs in cephalexin medicines by 13C solid state NMR. Int. J. Pharm. Pharm. Sci., v.3, n.3, p.293-298, 2011.). Cephalexin is also found in the dihydrated form, which, at room temperature, rapidly loses one molecule of water to form the monohydrated cephalexin (Kennedy et al., 2003KENNEDY, A.R.; OKOTH, M.O.; SHEEN, D.B.; SHERWOOD, J.N.; TEAT, S.J.; VRCELJ, R.M. Cephalexin: a channel hydrate. Acta Crystallogr., Sect. C: Cryst. Struct. Commun., v.59, n.11, p.650-652, 2003.). A similar phenomenon occurs with erythromycin, which is commercialized in its more stable and less soluble dihydrated form. This API loses its water molecules at relatively low temperature (71 °C) (Fukumor et al., 1983FUKUMORI, Y.; FUKUDA, T.; YAMAMOTO, Y.; SHIGITANI, Y.; HANYU, Y.; TAKEUCHI, Y.; SATO, N. Physical characterization of erythromycin dehydrate, anhydrate and amorphous solid and their dissolution properties. Chem. Pharm. Bull., v.31, n.11, p.4029-4039, 1983.).

As for ciprofloxacin, the exposure of form I (anhydrous) to a relative humidity higher than 90% leads to the appearance of form II (hydrate), which is observed when an aqueous suspension of form I is prepared (Mafra et al., 2012MAFRA, L.; SANTOS, S.M.; SIEGEL, R; ALVES, I.; PAZ, F.A.A.; DUDENKO, D.; SPIESS, H.W. Packing interactions in hydrated and anhydrous forms of the antibiotic ciprofloxacin: a solid-state NMR, X-RAY diffraction, and computer simulation study. J. Am. Chem. Soc., v.134, n.1, p.71-74, 2012.).

For sulfamethoxazole, form II converts to the hemihydrate (form III) more rapidly than form I. In the solubility assay, a phase transition was not observed for form II, whereas form I converted to the hemihydrate under identical conditions (Fioritto et al., 2007FIORITTO, A.F.; BHATTACHAR, S.N.; WESLEY, J.A. Solubility measurement of polymorphic compounds via the pH-metric titration technique. Int. J. Pharm., v.330, n.1/2, p.105-113, 2007.).

Micronization with supercritical antisolvent has led to an increase in the sulfamethoxazole dissolution rate and has caused the phase transition of polymorph I to II, with a solubility ratio of 1.2 (Pudipeddi et al., 2005PUDIPEDDI, M.; SERAJUDDIN, A.T.M. Trends in solubility of polymorphs. J. Pharm. Sci., v.94, n.5, p.929-939, 2005.; Chang et al., 2008CHANG, Y.P.; TANG, M.; CHEN, Y.P. Micronization of sulfamethoxazole using the supercritical anti-solvent process. J. Mater. Sci., v.43, n.7, p.2328-2335, 2008.).

Studies revealed that for digoxin, the grinding process leads to amorphization (Florence et al., 1976FLORENCE, A.T.; SALOLE, E.G. Changes in crystallinity and solubility on comminution of digoxin and observations on spironolactone and estradiol. J. Pharm. Pharmacol., v.28, n.8, p.637-642, 1976.). Storage of the amorphous form at room temperature results in a reduction in solubility (Chiou et al., 1979CHIOU, W.L.; KYLE, L.E. Differential thermal, solubility, and ageing studies on various sources of digoxin and digitoxin powder: biopharmaceutical implications. J. Pharm. Sci., v.68, n.10, p.1224-1229, 1979.), which is a great concern considering that this antiarrhythmic has a narrow therapeutic window. Thermal stress of digoxin also results in polymorphic phase transitions (Eberhard et al., 1983EBERHARD, N.; BERND, D. Occurrence of paracrystalline forms of digoxin. Acta Pharm. Technol., v.29, n.1, p.1-8, 1983.).

Carbamazepine

The impact of polymorphism has been extensively studied on the anticonvulsant carbamazepine, highlighting its impact on product quality. In 1988, a clinical failure was reported for Tegretol^® tablets (carbamazepine), likely due to the polymorphic phase transition from the anhydrous to the dihydrate form (Lee et al., 2011LEE, A.Y.; ERDEMIR, D.; MYERSON, A.S. Crystal polymorphism in chemical process development. Annu. Rev. Chem. Biomol. Eng., v.2, p.259-280, 2011.). Moreover, there are several reports of variability in the dissolution profile of commercially available carbamazepine tablets (Davidson, 1994DAVIDSON, A.G.A. Multinational survey of the quality of carbamazepine tablets. Drug Dev. Ind. Pharm., v.21, n.19, p.2167-2186, 1995.; Meyer et al., 1992MEYER, M.C.; STRAUGHN, A.B.; JARVI, E.J.; WOOD, G.C.; PELSOR, F.R.; SHAH, V.P. The bioinequivalence of carbamazepine tablets with a history of clinical failures. Pharm. Res., v.9, n.12, p.1612-1616, 1992., 1998MEYER, M.C.; STAUGHN, A.B.; MHATRE, R.M.; SHAH, V.P.; WILLIAMS, R.L.; LESKO, L.J. The relative bioavailability and in vivo–in vitro correlations for four marketed carbamazepine tablets. Pharm. Res., v.15, n.11, p.1787-1791, 1998.; Al-Zein et al., 1999AL-ZEIN, H.; RIAD, L.E.; ABD-ELBARY, A. Effect of packaging and storage on the stability of carbamazepine tablets. Drug Dev. Ind. Pharm., v.25, n.2, p.223-227, 1999.; Lake et al., 1999LEE, A.Y.; ERDEMIR, D.; MYERSON, A.S. Crystal polymorphism in chemical process development. Annu. Rev. Chem. Biomol. Eng., v.2, p.259-280, 2011.; Mittapalli et al., 2008MITTAPALLI, P.K.; SURESH, B.; HUSSAINI, S.S.Q.; RAO, Y.M.; APTE, S. Comparative in vitro study of six carbamazepine products. AAPS Pharm. Sci. Tech., v.9, n.2, p.357-365, 2008.).

Carbamazepine is one of the few APIs for which the recommended polymorphic form is described in official compendia. Although such compendia determine form III for medical preparations, they do not define limits for the other forms (European Pharmacopeia, 2008EUROPEAN Pharmapoeia. 6.ed. Strasbourg: Council of Europe, 2008. v.1, p.649.; British Pharmacopeia, 2009BRITISH Pharmacopoeia. 6.ed. London: Stationery Office, 2009. v.4, p.A146.; United States Pharmacopeia, 2011UNITED States Pharmacopeia USP34; National Formulary NF29. Rockville: United States Pharmacopeial Convention, 2011. v.2-3.), and the manufacture of this API does not always result in pure crystalline phases (Rustichelli et al., 2000RUSTICHELLI, C.; GAMBERINI, G.; FERIOLI, V.; GAMBERINI, SCHULTHEISS, N.; NEWMAN, A. Pharmaceutical cocrystals and their physicochemical properties. Cryst. Growth Des., v.9, n.6, p.2950-2967, 2009.; Lang et al., 2002LANG, M.; KAMPF, J.W.; MATZGER, A.J. Form IV of carbamazepine. J. Pharm. Sci., v.91, n.4, p.1186-1190, 2002.; Grzesiak et al., 2003GRZESIAK, A.; LANG, M.; KIM, K.; MATZGER, A. Comparison of the four anhydrous polymorphs of carbamazepine and the crystal structure of form I. J. Pharm. Sci., v.92, n.11, p.2260-2271, 2003.; Quist et al., 2008QUIST, F.; MOONEY, J.; KAKKAR, A.K. Self-assembled monolayers: solidification of carbamazepina in form II at an interface. Colloids Surf., B, v.62, n.2, p.319-323, 2008.; Javadzadeh et al., 2009JAVADZADEH, Y.; MOHAMMADI, A.; KHOEI, N.S.; NOKH, A. Improvement of physicomechanical properties of carbamazepine by recrystallization at different pH values. Acta Pharm., v.59, n.2, p.187-197, 2009.; Diao et al., 2012DIAO, Y.; WHALEY, K.E.; HELGESON, M.E.; WOLDEYES, M.A.; DOYLE, P.S.; MYERSON, A.S.; HATTON, T.A.; TROUT, L.B. Gel-induced selective crystallization of polymorphs. J. Am. Chem. Soc., v.134, n.1, p.673-684, 2012.; Wang et al., 2012WANG, M.; RUTLEDGE, G.C.; MYERSON, A.S.; TROUT, B.L. Production and characterization of carbamazepine nanocrystals by electrospraying for continuous pharmaceutical manufacturing. J. Pharm. Sci., v.10, n.3, p.1178-1188, 2012.), which emphasizes the need to develop methods to quantify the contamination of form III with other polymorphic forms (Kipouros et al., 2005KIPOUROS, K.; KACHRIMANIS, K.; NIKOLAKAKIS, I.; MALAMATARIS, S. Quantitative analysis of less soluble form IV in commercial carbamazepine (form III) by diffuse reflectance fourier transform spectroscopy (DRIFTS) and lazy learning algorithm. Anal. Chim. Acta, v.550, n.1/2, p.191-198, 2005.).

A mixture of polymorphic forms has been observed in commercial samples of carbamazepine raw material (Šehić et al., 2010ŠEHIĆ, S.; BETZA, G.; HADŽIDEDIĆ, Š.; EL-ARINI, S.K.; LEUENBERGER, H. Investigation of intrinsic dissolution behavior of different carbamazepine samples. Int. J. Pharm., v.386, n.1-2, p.77-90, 2010.; Flicker et al., 2011FLICKER, F.; EBERLE, V.A.; BETZ, G. Variability in commercial carbamazepine samples – impact on drug release. Int. J. Pharm., v.410, n.1/2, p.99-106, 2011.). As expected, these polymorphs exhibit different dissolution rates. Form III converts to carbamazepine dihydrate (a less soluble form) more rapidly than form I, which critically affects the solubility and bioavailability of pharmaceutical preparations (Kobayashi et al., 2000KOBAYASHI, Y.; ITO, S.; ITAI, S.; YAMAMOTO, K. Physicochemical properties and bioavailability of carbamazepine polymorphs and dehydrate. Int. J. Pharm., v.193, n.2, p.137-146, 2000.).

When pure form III samples are compared, the effect of particle size on the dissolution rate is counterintuitive, i.e., a larger amount of small-sized particles results in a slower carbamazepine dissolution rate, which occurs because the narrow shape of these particles enables the conversion to the dehydrate (Flicker et al., 2011FLICKER, F.; EBERLE, V.A.; BETZ, G. Variability in commercial carbamazepine samples – impact on drug release. Int. J. Pharm., v.410, n.1/2, p.99-106, 2011.). Micronization of carbamazepine by expansion in supercritical solution appears to increase the solubility of the drug, although this process may lead to a phase transition (Bolten et al., 2012BOLTEN, D.; TÜRK, M. Micronisation of carbamazepine through rapid expansion of supercritical solution (RESS). J. Supercrit. Fluids, v.62, p.32-40, 2012.).

Phenobarbital

Six of the polymorphic forms of another anticonvulsant, phenobarbital (A, B, C (monohydrate), D (dioxane solvate), E (hemihydrate) and F), were evaluated. The order of the dissolution rate among the forms is F > B > E > C > A > D, and the order of the hardness among the tablets containing them is D > A > C > E > B = F (Otsuka et al., 1994OTSUKA, M.; ONOE, M.; MATSUDA, Y. Physicochemical characterization of phenobarbital polymorphs and their pharmaceutical properties. Drug Dev. Ind. Pharm., v.20, n.8, p.1453-1470, 1994.).

Under isothermal conditions (45 °C), phenobarbital stability was as follows: A, B, and F forms were stable at 0 and 75% relative humidity, whereas C, D, and E forms underwent transformation during storage, with the transformation rate of form D as the fastest (Otsuka et al., 1993OHISHI, H.; IN, Y.; ISHIDA, T; INOUE, M.; SATO, F.; OKITSU M.; OHNO, T. Structure of methoxy-2-{(4-methoxy-3,5-dimethyl-2-pyridinylmethyl)sulfinyl}-1H-benzimidazole (omeprazole). Acta Crystallogr., Sect. C: Cryst. Struct. Commun., v.45, n.12, p.1921-1923, 1989.).

Acetylsalicylic Acid

The possibility of the occurrence of polymorphism in acetylsalicylic acid (ASA) antiinflammatory and analgesic products has been investigated since the 1960s (Tawashi, 1968TAWASHI, R. Aspirin: dissolution rates of two polymorphics forms. Science, v.160, n.3823, p.76, 1968.). It was only in 2005 that polymorphism was verified in this API, in which it was found that form II (metastable) coexists with form I (Vishweshwar et al., 2005VISHWESHWAR, P.; MCMAHON, J.A.; OLIVEIRA, M.; PETERSON, M.L.; ZAWOROTKO, M.J. The predictably elusive form II of aspirin. J. Am. Chem. Soc., v.127, n.48, p.16802-1603, 2005.). Subsequently, form II was isolated, and its conversion into form I occurs at room temperature, which is accelerated by mechanical grinding (Varughese et al., 2011VARUGHESE, S.; KIRAN, M.S.R.N.; SOLANKO, K.A.; BOND, A.D.; RAMAMURTY, U.; DESIRAJU, G.R. Interaction anisotropy and shear instability of aspirin polymorphs established by nanoindentation. Chem. Sci., v.2, n.11, p.2236-2242, 2011.).

Acetaminophen

Acetaminophen, which is another analgesic and antithermic drug, is an example of manufacturing problems associated with polymorphism (Snider et al., 2004SNIDER, D.A.; ADDICKS, W.; OWENS, W. Polymorphism in generic drug product development. Adv. Drug Delivery Rev., v.56, n.3, p.391-395, 2004.). Form II (metastable), in contrast to form I (stable), can be used in the manufacture of tablets, which is advantageous because the process is simpler and less expensive (Di et al., 1996DI MARTINO, P.; GUYOT-HERMANN, A.M.; CONFLANT, P.; DRACHE, M.; GUYOT, J.C. A new pure paracetamol for direct compression: the orthorhombic form. Int. J. Pharm., v.128, n.1/2, p.1-8, 1996.; Nichols et al., 1998NICHOLS, G.; FRAMPTON, C.S. Physicochemical characterization of the orthorhombic polymorph of paracetamol crystallized from solution. J. Pharm. Sci., v.87, n.6, p.684-693, 1998.). To manufacture medications containing form I, commercially available agglutinant excipients are required, which increases the cost (Di et al., 1997DI MARTINO, P.; CONFLANT, P.; DRACHE, M.; HUVENNE, J.P.; GUYOT-HERMANN, A.M. Preparation and physical characterization of forms II and III of paracetamol. J. Therm. Anal., v.48, n.3, p.447-458, 1997.; Nichols et al., 1998NICHOLS, G.; FRAMPTON, C.S. Physicochemical characterization of the orthorhombic polymorph of paracetamol crystallized from solution. J. Pharm. Sci., v.87, n.6, p.684-693, 1998.). Because the dissolution rate is similar for both form II and commercialized form I tablets, a possible transformation does not lead to problems with bioavailability (Di et al., 1996DI MARTINO, P.; CONFLANT, P.; DRACHE, M.; HUVENNE, J.P.; GUYOT-HERMANN, A.M. Preparation and physical characterization of forms II and III of paracetamol. J. Therm. Anal., v.48, n.3, p.447-458, 1997.).

Verapamil Hydrochloride, Enalapril, Losartan, and Propranolol

For antihypertensive drugs that contain verapamil hydrochloride, studies were performed at temperatures varying from 25 °C to 750 °C using several analytical techniques, and it was found that this API did not exhibit polymorphic forms at the evaluated conditions (Yoshida et al., 2010YOSHIDA, M.I.; GOMES, E.C.L.; SOARES, C.D.V.; CUNHA, A.F.; OLIVEIRA, M.A. Thermal analysis applied to Verapamil hydrochloride characterization in pharmaceutical formulations. Molecules, v.15, n.4, p.2439-2452, 2010.).

In the studies on enalapril, form II was observed to be much less stable than form I in tablets containing an identical amount of sodium hydrogen carbonate (Eyjolfsson, 2002EYJOLFSSON, R. Enalapril maleate polymorphs: instability of form II in a tablet formulation. Pharmazie, v.57, n.5, p.347-348, 2002.). The increased ratio of sodium hydrogen carbonate in the tablet containing form II and the presence of desiccant in the blister packaging significantly decreased its degradation (Eyjolfsson, 2003EYJOLFSSON, R. Enalapril maleate form II: stabilization in a tablet formulation. Pharmazie, v.58, n.5, p.357, 2003.).

Losartan antihypertensive form I is thermodynamically more stable and less soluble than form II at room temperature, and form II may convert to form I during storage (Wu et al., 1993WU, C.; BENET, L.Z. Predicting drug disposition via application of BCS: transport/absorption/elimination interplay and development of a biopharmaceutics drug disposition classification system. Pharm. Res., v.22, n.1, p.11-23, 2005.; Crocker et al., 1997CROCKER, L.S.; MCCAULEY, J.A. Solubilities of losartan polymorphs. Pharmazie, v.52, n.1, p.72, 1997.).

Both forms I and II of another antihypertensive, propranolol, are stable at room temperature even after grinding and compression. Polymorph I (metastable) is 34% more soluble than form II (commercially available) (Bartolomei et al., 1999BARTOLOMEI, M.; BERTOCCHI, P.; RAMUSINO, M.C.; SANTUCCI, N.; VALVO, L. Physico-chemical characterizations of the modifications I and II of (R,S) propranolol hydrochloride: solubility and dissolution studies. J. Pharm. Biomed., v.21, n.2, p.299-309, 1999.).

Ranitidine, Glibenclamide, and Estradiol

Ranitidine, which is prescribed for the treatment of ulcers, exhibits polymorphic forms I and II with similar solubility and bioavailability (Bawazir et al., 1998BAWAZIR, S.A.; GOUDA, M.W.; EL-SAYED, Y.M.; AL-KHAMIS, K.I.; AL-YAMANI, M.J.; NIAZY, E.M.; AL-RASHOOD, K.A. Comparative bioavailability of two tablet formulations of ranitidine hydrochloride in healthy volunteers. Int. J. Clin. Pharmacol. Ther., v.36, n.54, p.270-274, 1998.; Parkin et al., 2002PARK, H.J.; KIM, M.; KIM, J.; CHO, W.; PARK, J.; CHA, K.; YOUNG-SHIN, K.; SUNG-JOO, H. Solid-state carbon NMR characterization and investigation of intrinsic dissolution behavior of fluconazole polymorphs, anhydrate forms I and II. Chem. Pharm. Bull., v.58, n.9, p.1243-1247, 2010.). Notwithstanding, a slight difference in stability was observed between these forms, and phase transitions can occur via water absorption, mechanical strength (Carstensen et al., 1995CARSTENSEN, J.T.; FRANCHINI, M.K. Isoenergic polymorphs. Drug Dev. Ind. Pharm., v.21, n.5, p.523-536, 1995.; Foster et al., 1998FOSTER, A.; GORDON, K.; SCHMIERER, D.; SOPER, N.; WU, V.; RADER, T. Characterisation of two polymorphic forms of ranitidine–HCl. Internet J. Vib. Spectrosc., v.2, 1998. Available at: http://www.ijvs.com/volume2/edition2/section2.html. Accessed on: Jun. 2012.
http://www.ijvs.com/volume2/edition2/sec... ; Chieng et al., 2006CHIENG, N.; AALTONEN, J.; SAVILLE, D.; RADES, T. Physical characterization and stability of amorphous indomethacin and ranitidine hydrochloride binary systems prepared by mechanical activation. Eur. J. Pharm. Biopharm., v.71, n.1, p.47-54, 2009.) and during storage (Madan et al., 1994MADAN, T.; KAKKAR, A.P. Preparation and characterization of ranitidine-HC1 crystals. Drug Dev. Ind. Pharm., v.20, n.9, p.1571-1588, 1994.).

Glibenclamide form I is the most stable with a melting point of 175.4 °C and that of form II of 151.0 °C. Every form (I, II, III, and IV) was found to be stable below zero or 100% relative humidity, with form III as the most soluble (Sohn et al., 1997SOHN, Y.-T.; UM, B.-Y. Dissolution of glibenclamide polymorphs. Yakche Hakhoechi, v.27, n.3, p.233-239, 1997.).

A polymorphism effect was also found for estradiol. Transdermal adhesives, which contain this drug, formed crystals during storage. The crystals belonged to different estradiol polymorphs and also to the polymeric adhesive (Variankaval et al., 1999VARIANKAVAL, N.E.; JACOB, K.I.; DINH, S.M. Crystallization of betaestradiol in an acrylic transdermal drug delivery system. J. Biomed. Mater. Res., v.44, n.4, p.397-406, 1999.).

QUALITY CONTROL OF POLYMORPHIC SOLID FORMS

Single crystal and powder X-ray diffraction techniques are the most suitable and more utilized tools to study and characterize polymorphs in pharmaceutical solids because they provide unequivocal proof of either polymorphism existence or polymorphism occurrence (FDA, 2007FDA. U.S. Food and Drug Administration. Guidance for Industry - ANDAs: Pharmaceutical Solid Polymorphism Chemistry, Manufacturing, and Controls Information, 2007. Available at: http://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Guidances/ucm072866.pdf. Accessed on: Apr. 2012.
http://www.fda.gov/downloads/Drugs/Guida... ). Powder X-ray diffraction is feasible for application in the quality control of polymorphism in capsules, tablets, and pastes, among others. For this purpose, the API must be crystalline and be present at a concentration greater than 5% (w/w) in the formulation, which is the commonly adopted detection limit for phase quantification using PXRD techniques. The pharmaceutical formulation can be analyzed after minimal or no pretreatment of the sample without a requirement to separate the API from the excipients because most excipients are not detected by X-rays. Moreover, it is possible to simultaneously identify more than one API in the formulation (Phadnis et al., 1997PHADNIS, N.V.; CAVATUR, R.K.; SURYANARAYANAN, R. Identification of drugs in pharmaceutical dosage forms by X-ray powder diffractometry. J. Pharm. Biomed. Anal., v.15, n.7, p.929-943, 1997.).

Others important techniques such as microscopy, thermal analysis (e.g., differential scanning calorimetry, thermal gravimetric analysis, and hot-stage microscopy), and spectroscopy (e.g., infrared [IR], Raman, and solid-state nuclear magnetic resonance [ssNMR]) are also commonly used in the quality control of polymorphism in drugs. Diffraction, spectroscopic, and thermal techniques are considered complementary in the study of polymorphs. Polymorphic transitions can also be detected using drug product dissolution testing (FDA, 2007FDA. U.S. Food and Drug Administration. Guidance for Industry - ANDAs: Pharmaceutical Solid Polymorphism Chemistry, Manufacturing, and Controls Information, 2007. Available at: http://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Guidances/ucm072866.pdf. Accessed on: Apr. 2012.
http://www.fda.gov/downloads/Drugs/Guida... ) because the test is demonstrably able to differentiate different forms.

Despite the vast accumulated scientific knowledge on the effects of phase transitions in APIs in the solid state, crystalline form characterization assays are not included in most monographs described in official compendia. Conversely, the FDA published the Guidance for Industry of FDA - ANDAs: Pharmaceutical Solid Polymorphism Chemistry, Manufacturing, and Controls Information that provides recommendations for the monitor and control of polymorphs in drug substances and/or drug products (FDA, 2007FDA. U.S. Food and Drug Administration. Guidance for Industry - ANDAs: Pharmaceutical Solid Polymorphism Chemistry, Manufacturing, and Controls Information, 2007. Available at: http://www.fda.gov/downloads/Drugs/GuidanceComplianceRegulatoryInformation/Guidances/ucm072866.pdf. Accessed on: Apr. 2012.
http://www.fda.gov/downloads/Drugs/Guida... ). However, in USP 35-NT 30, assays on powder X-ray diffraction are described in only 15 monographs from the 4,500 monographs that include APIs, excipients and drug products (United States Pharmacopeia, 2012UNITED States Pharmacopeia USP35; National Formulary NF30. Rockville: United States Pharmacopeial Convention, 2012. v.1-3, 5089 p.).

CONCLUSION

For many drugs present in medications that are available at the FPRP, according to the best of the authors’ knowledge, there are few studies that correlate polymorphism to possible influences on drug solubility as well as its clinical impact. Therefore, the existence of polymorphs may potentially be an important source of variation in pharmaceutical properties, which can cause problems concerning the stability, solubility and, consequently, efficacy and bioavailability of drug products. Relatively simple quality control tests allow the differentiation of polymorphs. However, the identification of the polymorphic phase is not a mandatory test for the large majority of drugs. Thus, more commitment is necessary by regulatory and quality control authorities to monitor polymorphism not only for FPRP medications but also for all commercial drugs. This monitoring includes the control of polymorphism in raw materials, manufacturing steps and finished products by the end of the shelf life of the drug. In this manner, possible public health concerns linked to polymorphism in medicines can be avoided.

ACKNOWLEDGEMENTS

We thank FAPEMIG (APQ-02685-09, APQ-01093-10, APQ-02600-12, and PPM-00524-12), FINEP (Refs. 134/08 and 0336/09), CAPES (PNPD-2007 and PNPD-2011) and CNPq (472623/2011-7 and 476870/2011-9) for their financial support of this study. We also thank CNPq, CAPES, and FAPEMIG for research fellowships (ACD, MEDR, MESL and JSS). We thank the CSIC of Spain for the license to use the CSD.

REFERENCES

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