Pharmaceutical co-crystals of posaconazole for improvement of physicochemical properties

Nijhawan, Monika; Godugu, Monika; Saxena, Trapti; Farheen, Talat; Dwivedi, Kanchan

doi:10.1590/s2175-97902022e191024

Abstract

Posaconazole exerts an extended spectrum of antifungal activity against various strains of clinically relevant moulds and yeasts. In recent years, antifungal triazole posaconazole has become increasingly important for the prophylaxis and treatment of systemic mycoses. After oral administration of posaconazole, absolute bioavailability has been estimated to range from 8% to 47%. Pharmaceutical co-crystallization is a promising approach for improving dissolution rate or manipulating other physical properties of API. The objective of this study is to improve the dissolution rate of posaconazole by co-crystallization. A 1:1 stoichiometric co-crystals of adipic acid were prepared by solvent assisted grinding method. The prepared co-crystals were subjected to solid-state characterization by FTIR, PXRD and DSC studies. The physicochemical properties of posaconazole and co-crystals were assessed in terms of melting point, flowability and dissolution rate. The results indicated improvement in flow property and dissolution rate. In vitro dissolution profile of co-crystals showed a significant increased dissolution of posaconazole from initial period in 0.1 N hydrochloric acid solution. The dissolution efficiency for posaconazole-adipic acid co-crystal was 61.65 % against posaconazole, 46.58 %. Thus, co-crystallization can be a promising approach to prepare posaconazole-adipic acid co-crystals with improved physicochemical properties.

Keywords:
Co-crystal; Dissolution; Posaconazole; Adipic acid

INTRODUCTION

A co-crystal is a multi-component system in which all components are usually solid at room temperature in a stoichiometric ratio involving non-covalent interactions such as hydrogen bonds (most common interaction), Vander Waals bonds, ionic bonds between components. Co-crystals incorporate pharmaceutically acceptable guest molecules into a crystal lattice along with the API. Physiochemical properties of active pharmaceutical ingredients can be improved by employing crystal engineering technique. Co-crystallization with pharmaceutically acceptable GRAS (Generally Recognized As Safe) compounds do not affect the pharmacological activity of the API, but can improve physical properties, such as solubility, hygroscopicity, flowability, chemical stability, compaction behavior of nonionizable compounds (Gadade et al., 2016Gadade D, Pekamwar S, Lahoti S, Patni S, Sarode M. Co-crystallization of Etodolac: Prediction of co-crystallization, synthesis, solid state characterization and in vitro drug release. Marmara Pharm J. 2017;21:78-88.; Ross, Lamprou, Douroumis, 2016Ross S, Lamprou D, Douroumis D. ChemInform Abstract: Engineering and manufacturing of pharmaceutical co-crystals: A review of solvent-free manufacturing technologies. ChemInform. 2016;47(37).).

Co-crystal is a concept of supramolecular chemistry that is gaining the extensive interest of researchers from pharmaceutical and chemical sciences and of drug regulatory agencies. The approaches like hydrogen-bonding rules, solubility parameters, utility of Hansen solubility parameters, through the CSD database and thermodynamic characteristics can be utilized for the rational design of co-crystals and selection of coformers for the synthesis of multi-component co-crystals (Gadade et al., 2016Gadade D, Pekamwar S, Lahoti S, Patni S, Sarode M. Co-crystallization of Etodolac: Prediction of co-crystallization, synthesis, solid state characterization and in vitro drug release. Marmara Pharm J. 2017;21:78-88.; Mohammad, Alhalaweh, Velaga, 2011Mohammad M, Alhalaweh A, Velaga S. Hansen solubility parameter as a tool to predict cocrystal formation. Int J Pharm. 2011;407(1-2):63-71.; Desiraju, 1995Desiraju G. Supramolecular Synthons in Crystal Engineering-A New organic synthesis. Angew Chem Int Edition in English. 1995;34(21):2311-2327.; Etter, 1990Etter M. Encoding and decoding hydrogen-bond patterns of organic compounds. Acc Chem Res. 1990;23(4):120-126.).

Posaconazole is a newly developed extended spectrum triazole with proven efficacy as antifungal treatment and used to treat invasive infections by Candida species and Aspergillus species in severely immunogenic patients (Schiller, Fung, 2007Schiller D, Fung H. Posaconazole: An extended-spectrum triazole antifungal agent. Clin Ther. 2007;29(9):1862-1886.). It's in vitro antifungal activity against zygomyces species has been reported to be more pronounced compared to itraconazole (Connolly et al.,1999Connolly P, Wheat J, Schnizlein-Bick C, Durkin M, Kohler S, Smedema M et al. Comparison of a new triazole antifungal agent, schering 56592, with itraconazole and amphotericin B for treatment of histoplasmosis in immunocompetent mice. Antimicrob Agents Chemother. 1999;43(2):322-328.).

Solubility and dissolution are the key parameters for the therapeutic effect of a drug and to achieve the desired concentration of drug in systemic circulation for the pharmacological response. Posaconazole is a weakly dibasic drug that belongs to Class II of the Biopharmaceutical Classification System (BCS) (Amidon et al.,1995Amidon GL, Lennernäs H, Shah VP, Crison JRA .Theoretical basis for a biopharmaceutic drug classification: The correlation of in Vitro drug product dissolution and in Vivo bioavailability. Pharm Res. 1995;12(3):413−420.). Posaconazole is characterized by its low aqueous solubility of <1 μg/mL, high lipophilicity of Log P 4.6, and high molecular weight of 700.8 g/mol (Cristofoletti, Patel, Dressman, 2016Cristofoletti R, Patel N, Dressman JB. Differences in food effects for 2 weak bases with similar BCS drug-related properties: What Is happening in the intestinal lumen? J Pharm Sci . 2016;105(9):2712−2722.; Schiller, Fung, 2007Schiller D, Fung H. Posaconazole: An extended-spectrum triazole antifungal agent. Clin Ther. 2007;29(9):1862-1886.). Its large positive food effect and high solubility−pH dependence have resulted in low and erratic bioavailability (fraction absorbed <30%) in addition to daily doses of PSZ (300−600 mg) that are over 1000 times higher than what can be dissolved in a luminal volume of 250 mL. (Walravens et al.,2011Walravens J, Brouwers J, Spriet I, Tack J. Annaert P, Augustijns P. Effect of pH and comedication on gastrointestinal absorption of posaconazole: monitoring of intraluminal and plasma drug concentrations. Clin Pharmacokinet. 2011;50(11):725−34.; Amidon et al.,1982Amidon GL, Higuchi W, Ho NF. Theoretical and experimental studies of transport of micelle-solubilized solutes. J Pharm Sci. 1982;71(1):77-84.; Benet, Broccatelli, Oprea, 2011Benet L, Broccatelli F, Oprea T. BDDCS applied to over 900 drugs. AAPS J. 2011;13(4):519-547.). It has variable bioavailability following oral administration, leading to inconsistent pharmacokinetics of this agent. Current oral formulations include a suspension and a delayed-release tablet. Given its broad and unique spectrum of activity, there is a need for crystal forms of posaconazole that can be formulated as suspensions or solid dosage forms with less variability as well as better solubility, dissolution, stability, and properties suitable for pharmaceutical processing. Posaconazole is structurally analogous to itraconazole. Several salts and cocrystals of azole drugs have been discovered. Recently co-crystals of posaconazole with 4- aminobenzoic acid (4AMB) have been generated by the reaction crystallization method and demonstrated a superior solubility compared to posaconazole (Kuminek et al.,2019Kuminek G, Cavanagh KL, M.da Piedade MF, Hornedo NR. Posaconazole cocrystal with superior solubility and dissolution behavior. Cryst Growth Des . 2019;19:6592−6602.). Generation of cocrystals of PSZ with 4-aminobenzoic acid (4AMB) using supercritical CO₂ as an antisolvent in GAS (Gas Antisolvent) with acetonitrile, and as a solvent in CSS (Cocrystallization with supercritical solvent) methods are also reported (Long et al.,2020Long B, Verma V, Ryan KM, Padrela L. Generation and physicochemical characterization of posaconazole cocrystals using Gas Antisolvent (GAS) and Supercritical Solvent (CSS) methods. J Supercrit Fluid. 2020 (in press). ). However, there is no literature on solubility and dissolution rate enhancement of posaconazole with adipic acid as coformer by co-crystallization using solvent assisted grinding method. Subsequently, there is a need to deliver posaconazole in formulation with increased solubility and improved dissolution profile. The development of co-crystals is a remarkable approach to increase its bioavailability by enhancing its rate and extent of dissolution (Lee, Zhang, Flanagan, 2011Lee H, Zhang G, Flanagan D. Cocrystal intrinsic dissolution behavior using a rotating disk. J Pharm Sci . 2011;100(5):1736-1744.).

MATERIAL AND METHODS

Material

Posaconazole was obtained as a gift sample from Aurobindo Pharma-Hyderabad, adipic acid was procured from S.D. Fine Chemicals Limited, Mumbai. All other chemicals were of analytical grade.

Preparation of co-crystals by solvent assisted grinding technique

Posaconazole (1mmol) and coformer adipic acid (1mmol) were taken and mixed in a mortar pestle using ethanol (2-3 drops) as a solvent. The triturating process was carried out for 30-45 mins and co-crystals were stored in desiccators. The formation of new co-crystals was confirmed by melting point, FTIR, PXRD and DSC (Weyna et al.,2009Weyna D, Shattock T, Vishweshwar P, Zaworotko M. Synthesis and structural characterization of cocrystals and Pharmaceutical Cocrystals: Mechanochemistry vs slow evaporation from solution. Cryst Growt. Des. 2009;9(2):1106-1123.).

Determination of physical constant (melting point)

The melting point of posaconazole and co-crystals were determined using open capillary tube method. The sample was filled and placed in the melting point apparatus (Cheney et al.,2011Cheney M, Weyna DR, Shan N, Hanna M, Wojtas L, Zaworotko MJ. Coformer selection in pharmaceutical co-crystal development: A case study of a meloxicam aspirin co-crystal that exhibits enhanced solubility and pharmacokinetics. J Pharm Sci . 2011;100(6):2172-2181.) (Biotech India Melting apparatus, Mumbai).

Solid-state characterization

Fourier transform infrared spectroscopy (FTIR)

Fourier Transform-Infrared Spectroscopy (FTIR) is an analytical technique used to identify organic and, in some cases, inorganic materials. The infrared absorption bands identify molecular components and structures. IR spectroscopy was conducted using FTIR spectrophotometer (Shimadzu Corporation, Kyoto, Japan) with potassium bromide pellet method and background spectrum was collected under identical conditions. The spectrum was recorded in the wavelength region of 4000-400 cm⁻¹ (Mutalik et al.,2007Mutalik S, Manoj K, Reddy MS, Kushtagi P, Nayak Usha V, Parambil A et al. Chitosan and enteric polymer based once daily sustained release tablets of aceclofenac: In vitro and in vivo studies AAPS Pharm Sci Tech. 2008;9(2):651-659.).

Powder x-ray diffraction (PXRD)

The PXRD pattern of posaconazole and prepared co-crystals were studied to investigate the crystalline nature of posaconazole and co-crystals. The study was carried out using an x-ray diffractometer, Shimadzu module XRD 7000 (2θ=10-80 ºC, scan speed=2 deg/min) using Cu kα radiations. The tube operated at 40 kV (Tsutsumi et al.,2011Tsutsumi S, Lida M, Tada N, Kojima T, Ikeda Y. Characterization and evaluation of miconazole salts and co-crystals for improved physicochemical properties. Int J Pharm . 2011;421:230-236.).

Differential scanning calorimetry (DSC)

DSC method can be used as a screening tool for the detection of co-crystal formation in binary physical mixtures of drugs and co-former. Thermal analysis of posaconazole and prepared co-crystals were recorded on a DSC (Shimadzu DSC-60, Tokyo, Japan). The temperature axis and cell constant of DSC were previously calibrated with indium. A heating rate of 10 ºC/min was employed with nitrogen purging. Powder sample (5-10 mg) was filled into an aluminium pan and was subjected to heating from 0-300 ºC, using an empty aluminum pan as a reference and analyzed. (Rahman et al.,2011Rahman Z, Samy R, Sayeed V, Khan M. Physicochemical and mechanical properties of carbamazepine co-crystals with saccharin. Pharm Dev Technol. 2011;17(4):457-465.).

UV spectral interference of adipic acid with posaconazole

Since the analysis of posaconazole was done in presence of adipic acid, it was necessary to identify the interference of adipic acid. For this purpose, posaconazole solution, adipic acid solution, the posaconazole-adipic acid solution was scanned in the range of 200-400 nm. (Nijhawan et al.,2014Nijhawan M, Santhosh A, PR Sathesh Babu, Subrahmanyam CVS. Solid state manipulation of lornoxicam for cocrystals- physicochemical characterization. Drug Dev Ind Pharm . 2014;40(9):1163-1172.).

Saturation Solubility Study

Saturation solubility studies were performed in triplicate by adding an excess quantity of posaconazole-adipic acid co-crystals and pure drug in volumetric flasks containing 0.1 N hydrochloric acid. Volumetric flasks were agitated in an orbital shaker for 24 hours at 25 ºC at 100 RPM. The solutions were then filtered and amount of drug dissolved was analyzed spectrophotometrically.

Dissolution studies

Dissolution studies were carried out using USP dissolution test apparatus II in 900 ml of 0.1 N hydrochloric acid solution at 50 RPM, temperature was maintained at 37 ± 0.5 ºC. Posaconazole and posaconazole-adipic acid co-crystals containing the drug equivalent to 100 mg filled in hard gelatin capsules were added to the dissolution medium and samples were withdrawn at appropriate time intervals. The samples were filtered through a 0.45μm filter and analyzed spectrophotometrically at 255 nm (Shimadzu UV-2600 Tokyo, Japan) using 0.1 N hydrochloric acid as blank. The data obtained from dissolution studies were statistically validated, Further dissolution efficiency was calculated to compare dissolution performance of co-crystals with the pure drug by the following equation:

D . E . = \frac{\int_{0}^{t} y \times d t}{y_{100} \times d t} \times 100

where y is the percentage of the dissolved product. D.E. is the area under the dissolution curve between time points t ₁ and t ₂ expressed as a percentage of the curve at maximum dissolution, y₁₀₀, over the same time period (Costa, Sousa Lobo, 2001Costa P, Sousa lobo JM. Modeling and comparison of dissolution profiles. Eur J Pharm Sci . 2001;13:123-133. ).

Evaluation of micromeritic properties (Flowability)

In order to achieve uniformity in tablet weight, the feed crystals must flow smoothly into the die cavity of the tablet machine. Therefore, it is essential to improve the flow properties of powders. For this purpose, angle of repose, Carr's index and Hausner's ratio were calculated for posaconazole and prepared co-crystals using the standard procedure reported in the pharmacopoeia. Angle of repose was determined by the fixed funnel method and Carr’s index, Hausner’s ratio was calculated from bulk density and tapped density using the following equations.

Carr ’ s index = [(Tapped density - Bulk density) / Tapped density] x 100 Hausner ’ s ratio = Tapped density / Bulk density

RESULTS AND DISCUSSION

The formation of co-crystal or salt is generally guided by a thumb rule of ΔpKa (ΔpKa = pKa (base)-pKa (acid) value between active pharmaceutical ingredient (API) and coformer. The coformer is selected on basis of ∆pKa values, where ∆pKa is the difference between pKa of drug and coformer. If ∆pKa<0, a co-crystal will almost result and if ∆pKa>3, the result will most likely be a salt. The pKa and ∆pKa value of posaconazole and adduct was found to be 4.6 and 0.19 respectively which infers the chances of co-crystal formation (Cheney et al.,2010Cheney ML, Weyna DR, Shan N, Hanna M, Wojtas L, Zaworotko MJ. Supramolecular architectures of meloxicam carboxylic acid co-crystals, a crystal engineering case study. Cryst Growth Des. 2010;10(10):4401-4413.).

Determination of physical constant (melting point)

Posaconazole showed an endothermic peak at 168.4°C. Co-crystals of posaconazole prepared with adipic acid have shown melting endothermic peak at 128.6°C i.e., lower than the melting point of pure drug and adipic acid (152 °C). This observation clearly indicated the formation of co-crystals of API with the coformer used. Within the survey 50 cocrystalline samples were analyzed; 26/50 (51%) co-crystals had melting points between those of the API and coformer, while 19/50 (39%) were lower than either the API or coformer, only 3/50 (6%) were higher, and 2/50 (4%) had the same melting point as either the API or coformer. These statistics clearly show that the melting point of an API can be altered through forming co-crystals, and the outcome will usually be a product having a melting point that is in between that of the API and coformer or lower than the API or coformer. The co-crystals are formed by physical interaction between API and coformer and generally H bonding is expected between polar functional group of API and coformer. This interaction results in alterations in molecular arrangement of co-crystal formed, hence giving new crystal form having altered physical properties such as melting point and/or solubility, Thus the strength of hydrogen bonding will definitely influence the melting point characteristic of co-crystal (Mulya et al.,2012 Schultheiss, Newman, 2009Schultheiss N, Newman A. Pharmaceutical Cocrystals and Their Physicochemical Properties. Cryst Growth Des . 2009;9(6)2950-2967.; Stanton, Bak, 2008Stanton MK, Bak A. Physicochemical properties of pharmaceutical co-crystals: A case study of ten AMG 517 co-crystals. Cryst Growth Des . 2008;8:3856-3862.).

Solid-state characterization

Fourier transform infrared spectroscopy (FTIR)

Fourier-transform IR (FTIR), the simultaneous study of the spectra of the co-crystals individual components and of their final mixture with polymer matrices, etc., is an important tool in detecting co-crystal formation and the elucidation of their structures. The co-crystals provide a different spectrum from that of the components due to the presence of hydrogen bonds, especially when carboxylic acid is used as a coformer and when a neutral hydrogen bond O-H □ N is formed between an acid and a base (Karagianni, Malamatari, Kachrimanis, 2018Karagianni A, Malamatari M, Kachrimanis K. Pharmaceutical Cocrystals: New solid phase modification approaches for the formulation of APIs. Pharmaceutics. 2018;10(1)18.). The IR spectrum for co-crystals of posaconazole with adipic acid is shown in Figure 1. The characteristic bands were identified and associated changes were recorded in Table I along with the literature data. The results revealed considerable changes in the IR bands of posaconazole indicating the formation of co-crystals of posaconazole with adipic acid.

FIGURE 1
FTIR spectral comparison of posaconazole, adipic acid and posaconazole-adipic acid co-crystals.

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TABLE I
FTIR bands for characteristic changes of posaconazole and posaconazole-adipic acid co-crystals

Powder X-Ray Diffraction Studies (PXRD)

PXRD is a powerful technique for determining the presence of polymorphs and crystal habit modifications in drug crystals. PXRD gives a unique fingerprint diffraction pattern characteristic of a particular solid form. If a co-crystal has been formed between two solid phases, the diffraction pattern of the prepared co-crystal must be clearly distinct from drug and coformer by the superimposition of PXRD pattern. The PXRD pattern of posaconazole is shown in Figure 2 which indicates the crystalline nature of the drug. Sharp intense peaks at 19.63 º, 17.64 º, 15.72 º showed that sample is posaconazole. The pure adipic acid showed 2θ value for 100% intensity at 17.87 º. The powder XRD pattern of co-crystal showed intense peaks at 17.67 º, 19.37 º, 9.77 º indicating shifting in 2θ values. Prepared posaconazole-adipic acid co-crystals showed the presence of additional peaks, change in peak intensities that might be attributed to different crystal habits and arrangement of molecules indicating the formation of new crystal form which is again confirmed by DSC studies. Further, the relative intensities of their PXRD peaks were modified which might be attributed to the different crystal habits and arrangement of molecules, indicating the formation of new crystal form (Mulye et al.,2012Mulye SP, Jamadarv SA, Karekar PS, Pore YV, Dhawale SC. Improvement in physicochemical properties of ezetimibe using a crystal engineering technique. Powder Technol. 2012;222:131-138.; Garekani et al.,2001Garekani HA, Sadeghi F, Badiee A, Mostafa SA, Rajab-Siahboomi AR. Crystal habit modifications of ibuprofen and their physicochemical characteristics. Drug Dev Ind Pharm. 2001;803-809.).

FIGURE 2
PXRD pattern of posaconazole-adipic acid co-crystal and its individual components.

Differential scanning calorimetry (DSC)

DSC gives an accurate temperature for the onset of melting. DSC thermograms of posaconazole and co-crystals were shown in Figure 3. Posaconazole showed an endothermic peak at 168.48 °C corresponding to its melting point while the co-crystals showed a peak at 128.62 °C. The endothermic peak of co-crystals was found to be different the drug and co-crystal former, that confirms the formation of a new phase.

FIGURE 3
DSC thermogram of posaconazole, posaconazole-adipic acid co-crystals and adipic acid.

Flowability studies

Micromeritic properties which are represented in terms of angle of repose, Carr’s index and Hausner’s ratio are reported in Table II. It has been found that posaconazole-adipic acid co-crystals had improved flowability compared to that of pure drug. The poor flow properties of pure posaconazole crystals might be attributed to their smaller particle size. On the other hand, the co-crystallization of posaconazole is resulted in an increase in the size of co-crystals and a significant alteration in their shape. This might be the reason for the improved flowability of co-crystals as compared to pure drug crystals (Patric, 2011Patric JS. Martin’s physical pharmacy and pharmaceutical sciences. 6th edition. USA: Lippincott Williams and Wilkins. 2011;556-558.; Buckton, 1998Buckton G. Solid state properties, in: Aulton ME (Ed.), Pharmaceutics: The science of dosage form, Churchill Livingstone, 1998.).

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TABLE II
Flow properties of posaconazole and posaconazole-adipic acid co-crystals

UV spectral interference of adipic acid with posaconazole

Based on the scans, it was observed that adipic acid did not show interference at the working concentration (255nm) as shown in Figure 4. Therefore, posaconazole was estimated at 255 nm for drug content and dissolution studies.

FIGURE 4
UV absorption spectrum of posaconazole, adipic acid and a mixture of posaconazole-adipic acid (10 µg/mL each) at 255 nm.

Saturation Solubility Study

The co-crystals have shown enhancement in solubility as compared to pure drug alone. Solubility of the pure drug was found to be 0.0053 mg/mL while posaconazole-adipic acid co-crystals showed 0.0107 mg/mL solubility in 0.1 N HCl. Solubility of co-crystals was increased (2 folds) with adipic acidolds) with sodium odium acetate. These results agreed with the observations made with melting point studies indicating the successful interaction of posaconazole with coformers and formation of co-crystals. The existence of a correlation between the melting point of co-crystals and their solubility has been well documented. In the AMG517 study, the authors reported that after a correlation analysis of the solubility parameters, the highest interdependence was the Log of solubility (Log Smax) versus the melting point. A correlation plot of Log Smax versus co-crystal melting point of the nine AMG517 cocrystals showed a 55% correlation of the variability in Log Smax to variability in the melting point of the co-crystal, suggesting that higher melting point of a co-crystal contributes to its lower solubility (Stanton, Bak, 2009Stanton MK, Bak A. Physicochemical properties of pharmaceutical co-crystals: A case study of ten AMG 517 co-crystals. Cryst Growth Des . 2008;8:3856-3862.).

In vitro dissolution study

In vitro dissolution studies reveal that co-crystals showed enhancement in the dissolution rate. This can be observed from the comparative dissolution profile shown in Figure 5. The enhancement in the dissolution rate of posaconazole was 7.12 folds from adipic acid co-crystals within 30 mins. The release of pure drug was found to be 77% while posaconazole-adipic acid co-crystals showed complete drug release within 120 mins. From the dissolution study, it was revealed that the prepared co-crystal exhibited rapid and complete drug release as compared to posaconazole. The dissolution efficiency was expressed in terms of percentage and found to be 61.65 % for posaconazole-adipic acid co-crystal compared to posaconazole (46.58 %) indicating dissolution efficiency has improved for co-crystal preparation (Yadav, Dabke, Shete, 2010Yadav AV, Dabke AP, Shete AS. Crystal engineering to improve physicochemical properties of mefloquine hydrochloride. Drug Dev Ind Pharm . 2010;36(9):1036-1045.). Similarity and Difference factors for co-crystal are calculated in comparison with pure drug. The values are found to be 35.1 and 39.2 for Similarity factor and Difference factor, respectively, indicating dissolution abilities of co-crystals are not similar to posaconazole (pure drug).

FIGURE 5
Dissolution-time profile of posaconazole and posaconazole-adipic acid co-crystal.

CONCLUSION

Through crystal engineering technique, multicomponent co-crystals of posaconazole were developed using adipic acid as a guest. Posaconazole-adipic acid co-crystal was successfully characterized by FTIR, DSC and PXRD. The co-crystals showed improved micromeritics properties and enhanced dissolution rate compared to pure drug. Based on the results, it can be concluded that pharmaceutical co-crystallization of posaconazole with adipic acid can be possible. It can be used as an alternative and effective approach for solid-state manipulation for improving physicochemical properties of posaconazole.

ACKNOWLEDGEMENT

The authors are thankful to B.R Nahata College of Pharmacy, Mandsaur, Madhya Pradesh for providing DSC facilities and Hyderabad Central University, Hyderabad for providing PXRD facility. We acknowledge the help rendered by Dr. N. Swathi, Associate professor, Department of Pharmaceutical chemistry, Gokaraju Rangaraju College of Pharmacy, Hyderabad.

REFERENCES

Amidon GL, Higuchi W, Ho NF. Theoretical and experimental studies of transport of micelle-solubilized solutes. J Pharm Sci. 1982;71(1):77-84.
Amidon GL, Lennernäs H, Shah VP, Crison JRA .Theoretical basis for a biopharmaceutic drug classification: The correlation of in Vitro drug product dissolution and in Vivo bioavailability. Pharm Res. 1995;12(3):413−420.
Benet L, Broccatelli F, Oprea T. BDDCS applied to over 900 drugs. AAPS J. 2011;13(4):519-547.
Buckton G. Solid state properties, in: Aulton ME (Ed.), Pharmaceutics: The science of dosage form, Churchill Livingstone, 1998.
Cheney M, Weyna DR, Shan N, Hanna M, Wojtas L, Zaworotko MJ. Coformer selection in pharmaceutical co-crystal development: A case study of a meloxicam aspirin co-crystal that exhibits enhanced solubility and pharmacokinetics. J Pharm Sci . 2011;100(6):2172-2181.
Cheney ML, Weyna DR, Shan N, Hanna M, Wojtas L, Zaworotko MJ. Supramolecular architectures of meloxicam carboxylic acid co-crystals, a crystal engineering case study. Cryst Growth Des. 2010;10(10):4401-4413.
Connolly P, Wheat J, Schnizlein-Bick C, Durkin M, Kohler S, Smedema M et al. Comparison of a new triazole antifungal agent, schering 56592, with itraconazole and amphotericin B for treatment of histoplasmosis in immunocompetent mice. Antimicrob Agents Chemother. 1999;43(2):322-328.
Costa P, Sousa lobo JM. Modeling and comparison of dissolution profiles. Eur J Pharm Sci . 2001;13:123-133.
Cristofoletti R, Patel N, Dressman JB. Differences in food effects for 2 weak bases with similar BCS drug-related properties: What Is happening in the intestinal lumen? J Pharm Sci . 2016;105(9):2712−2722.
Desiraju G. Supramolecular Synthons in Crystal Engineering-A New organic synthesis. Angew Chem Int Edition in English. 1995;34(21):2311-2327.
Etter M. Encoding and decoding hydrogen-bond patterns of organic compounds. Acc Chem Res. 1990;23(4):120-126.
Gadade D, Pekamwar S, Lahoti S, Patni S, Sarode M. Co-crystallization of Etodolac: Prediction of co-crystallization, synthesis, solid state characterization and in vitro drug release. Marmara Pharm J. 2017;21:78-88.
Garekani HA, Sadeghi F, Badiee A, Mostafa SA, Rajab-Siahboomi AR. Crystal habit modifications of ibuprofen and their physicochemical characteristics. Drug Dev Ind Pharm. 2001;803-809.
Karagianni A, Malamatari M, Kachrimanis K. Pharmaceutical Cocrystals: New solid phase modification approaches for the formulation of APIs. Pharmaceutics. 2018;10(1)18.
Kuminek G, Cavanagh KL, M.da Piedade MF, Hornedo NR. Posaconazole cocrystal with superior solubility and dissolution behavior. Cryst Growth Des . 2019;19:6592−6602.
Lee H, Zhang G, Flanagan D. Cocrystal intrinsic dissolution behavior using a rotating disk. J Pharm Sci . 2011;100(5):1736-1744.
Long B, Verma V, Ryan KM, Padrela L. Generation and physicochemical characterization of posaconazole cocrystals using Gas Antisolvent (GAS) and Supercritical Solvent (CSS) methods. J Supercrit Fluid. 2020 (in press).
Mohammad M, Alhalaweh A, Velaga S. Hansen solubility parameter as a tool to predict cocrystal formation. Int J Pharm. 2011;407(1-2):63-71.
Mulye SP, Jamadarv SA, Karekar PS, Pore YV, Dhawale SC. Improvement in physicochemical properties of ezetimibe using a crystal engineering technique. Powder Technol. 2012;222:131-138.
Mutalik S, Manoj K, Reddy MS, Kushtagi P, Nayak Usha V, Parambil A et al. Chitosan and enteric polymer based once daily sustained release tablets of aceclofenac: In vitro and in vivo studies AAPS Pharm Sci Tech. 2008;9(2):651-659.
Nijhawan M, Santhosh A, PR Sathesh Babu, Subrahmanyam CVS. Solid state manipulation of lornoxicam for cocrystals- physicochemical characterization. Drug Dev Ind Pharm . 2014;40(9):1163-1172.
Patric JS. Martin’s physical pharmacy and pharmaceutical sciences. 6th edition. USA: Lippincott Williams and Wilkins. 2011;556-558.
Rahman Z, Samy R, Sayeed V, Khan M. Physicochemical and mechanical properties of carbamazepine co-crystals with saccharin. Pharm Dev Technol. 2011;17(4):457-465.
Ross S, Lamprou D, Douroumis D. ChemInform Abstract: Engineering and manufacturing of pharmaceutical co-crystals: A review of solvent-free manufacturing technologies. ChemInform. 2016;47(37).
Schiller D, Fung H. Posaconazole: An extended-spectrum triazole antifungal agent. Clin Ther. 2007;29(9):1862-1886.
Schultheiss N, Newman A. Pharmaceutical Cocrystals and Their Physicochemical Properties. Cryst Growth Des . 2009;9(6)2950-2967.
Stanton MK, Bak A. Physicochemical properties of pharmaceutical co-crystals: A case study of ten AMG 517 co-crystals. Cryst Growth Des . 2008;8:3856-3862.
Tsutsumi S, Lida M, Tada N, Kojima T, Ikeda Y. Characterization and evaluation of miconazole salts and co-crystals for improved physicochemical properties. Int J Pharm . 2011;421:230-236.
Walravens J, Brouwers J, Spriet I, Tack J. Annaert P, Augustijns P. Effect of pH and comedication on gastrointestinal absorption of posaconazole: monitoring of intraluminal and plasma drug concentrations. Clin Pharmacokinet. 2011;50(11):725−34.
Weyna D, Shattock T, Vishweshwar P, Zaworotko M. Synthesis and structural characterization of cocrystals and Pharmaceutical Cocrystals: Mechanochemistry vs slow evaporation from solution. Cryst Growt. Des. 2009;9(2):1106-1123.
Yadav AV, Dabke AP, Shete AS. Crystal engineering to improve physicochemical properties of mefloquine hydrochloride. Drug Dev Ind Pharm . 2010;36(9):1036-1045.

Publication Dates

Publication in this collection
02 Sept 2022
Date of issue
2022

History

Received
06 May 2020
Accepted
15 Feb 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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Drug	Characteristic bands, cm^-1	Inference
Posaconazole	C=O - 1685.79	Characteristic peaks have been observed
	-CH (aliphatic) - 2964.59
	C-H (deformation in aromatic rings) - 1548.84
	C=N - 1510.26
	OH - 3116.97
	=C-H (stretching) - 3053.32
Name of co-crystals	Characteristic bands, cm^-1	Inference
Posaconazole-adipic acid	C=O - 1703.15	C=O shift has been observed. Co-crystals might have formed.
	-CH (aliphatic) - 2966.52
	C-H (deformation in aromatic rings) - 1548.84
	C=N - 1510.26
	OH - 3116.97
	=C-H (stretching) - 3053.32

Name	Bulk density	Tapped density	Carr’s index	Hausner’s ratio	Angle of repose	Property
Posaconazole	0.15±0.005	0.25±0.01	35±0.003	1.54±0.03	-	Very poor
Posaconazole- adipic acid co-crystal	0.36±0.005	0.47±0.01	17.55±0.2	1.27±0.02	31.22±1.2	Fair

Brasil

Brasil

Pharmaceutical co-crystals of posaconazole for improvement of physicochemical properties

Abstract

INTRODUCTION

MATERIAL AND METHODS

Material

Preparation of co-crystals by solvent assisted grinding technique

Determination of physical constant (melting point)

Solid-state characterization

Fourier transform infrared spectroscopy (FTIR)

Powder x-ray diffraction (PXRD)

Differential scanning calorimetry (DSC)

UV spectral interference of adipic acid with posaconazole

Saturation Solubility Study

Dissolution studies

Evaluation of micromeritic properties (Flowability)

RESULTS AND DISCUSSION

Determination of physical constant (melting point)

Solid-state characterization

Fourier transform infrared spectroscopy (FTIR)

Powder X-Ray Diffraction Studies (PXRD)

Differential scanning calorimetry (DSC)

Flowability studies

UV spectral interference of adipic acid with posaconazole

Saturation Solubility Study

In vitro dissolution study

CONCLUSION

ACKNOWLEDGEMENT

REFERENCES

Publication Dates

History