Abstracts

Synthesis and characterization of solid 2-methoxycinnamylidenepyruvic acid

Síntese e caracterização do ácido 2-metoxicinamalpirúvico

C. T. de Carvalho^I; A. B. Siqueira^I; E. Y. Ionashiro^II; M. Pivatto^I; M. Ionashiro^I,* * massaoi@iq.unesp.br

^IInstituto de Química, UNESP, CP 355, CEP 14801-970, Araraquara, SP, Brazil

^IIInstituto de Química, UFG, Campus II, CEP74001-979, Goiânia, GO, Brazil

ABSTRACT

The 2-methoxycinnamylidenepyruvic acid (2-MeO-HCP) was synthesized and characterized for nuclear magnetic resonance (¹H and ¹³C NMR), mass spectrometry (MS), Infrared spectroscopy (FTIR) and differential scanning calorimetry (DSC). The application of DSC for purity determination is well documented in literature and is used in the analysis of pure organic compounds. The molecular geometry and vibrational frequencies of 2-MeO-HCP have been calculated.

Keywords: 2-methoxycinnamylidenepyruvic acid; synthesis; MS; NMR; IR.

RESUMO

O ácido 2-metoxicinamalpirúvico (2-MeO-HCP) foi sintetizado e caracterizado por ressonância magnética nuclear (¹H and ¹³C NMR), espectrometria de massas (MS), espectroscopia na região do infravermelho (FTIR) e calorimetria exploratória diferencial (DSC). A técnica DSC foi usada para determinação da pureza do composto e as principais bandas de absorção na região do infravermelho foram atribuídas utilizando-se o programa GaussView 3.0.

Palavras-chaves: ácido 2-metoxicinamalpirúvico; síntese; MS; NMR; IR.

Introduction

Various procedures concerning the preparation of α-keto acids have been reported in the literature.¹ The α-keto acids are of continuing interest as model substrates of enzymes, intermediates in chemical syntheses, in the development of enzyme inhibitors and drugs and in other ways.¹ The aldol condensation products between cinnamaldehyde and pyruvic acid as, 4-dimethylamino and cinnamylidenepyruvic acids has also been described in the literature^{2, 3}.

Extensive experimental and theoretical investigations have focused on elucidating the structure and normal vibrations of organic compounds⁴. Thus, calculations of optimal molecular geometry and vibrational of 2-MeO-HCP were made. The calculated harmonic frequencies are usually higher than the corresponding experimental quantities, due to a combination of electron correlation effects and basis set deficiencies. It is well known that Hartree-Fock (HF) method tends to overestimate vibrational frequencies. However, density functional theory (DFT) calculations are reported to provide excellent vibrational frequencies of organic compounds if the calculated frequencies are scaled to compensate for the approximate treatment of electron correlation for basis set deficiencies and the anharmonicity.⁵

In this paper, the 2-MeO-HCP was investigated by means of infrared spectroscopy (IR), mass spectrometry (MS), nuclear magnetic resonance (NMR) spectroscopy and differential scanning calorimetry (DSC). The results allowed us to acquire information about these compounds in the solid state. The DSC purity determination method was established using melting point (122 ºC) observations revealing a relation between a substance's melting point and its purity⁶.

The optimisation of the DSC purity determination method was done by Blaine et al.⁷ using a Nacional Institute of Standards and Technology (NIST) purity standard - phenacetin doped with p-aminobenzoic acid - in 1984. As a result of their investigations, the experimental parameters influencing purity results were assessed: specimen size, heating rate, level of impurity. An optimal specimen size (1.7 mg) and heating rate (0.5-2 ºC min^-1) were deduced.

The 2-methoxycinnamaldehyde, (CH₃OC₆H₄-(CH)₂-CHO, 96%) predominantly trans, was obtained from Aldrich and sodium pyruvate (H₃C-CO-COONa, 99%) was obtained from Sigma. 2-methoxycinnamylidenepyruvic acid (2MeO-HCP) was synthesized following the same procedure as described in literature,⁸ with some modifications, as follows: an aqueous solution of sodium pyruvate (1.5 g per 10 mL) was added dropwise with continuos stirring to a methanolic solution of 2-methoxycinnamaldehyde (2.0 g per 50mL). Five millilitres of an aqueous sodium hydroxide solution 1.25 mol L^-1 was added slowly while the reacting system was stirred and cooled in an ice bath. The rate of addition of alkali was regulated so that the temperature remained between 5 and 9 ºC. The system was stirred at ambient temperature (~28 ºC) for about 5 h. To the pale yellow solution was added dropwise with continuous stirring with a glass rod, twenty millilitres of chilled concentrated (12 mol L^-1) hydrochloric acid. The system was left to stand for ca. 16 h in a freezer (-6 ºC) and the yellow orange precipitate (impure 2-MeO-HCP) was filtered, washed with distilled water to remove most of the unreacted aldehyde and secondary products and dried on Whatman nº 44 filter paper. The aqueous suspension of the impure acid was dissolved with 5 mL of aqueous sodium hydroxide solution 2 mol L^-1 and filtered on Whatman nº 44 filter paper. The yellow solution was stirred with a glass rod and added slowly 20 mL of chilled concentrated (12 mol L^-1) hydrochloric acid and left to stand for ca. 16 h in freezer (-6 ºC). The orange precipitate of 2-MeO-CP was filtered and washed with distilled water until elimination of chloride ions and dried on Whatman nº 44 filter paper and kept in a desiccator over anhydrous calcium chloride. (yield = 28,6%).

General methods

Infrared spectra for 2-MeO-HCP were run on a Nicolet Model Impact 400 FTIR instrument within the 4000-400 cm^-1 range. The solid samples were pressed into KBr pellets.

DSC curve were obtained with DSC Q10 from TA Instruments. The purge gas was an air flow of 50 mL min^-1. A heating rate 0.5 K min^-1 for the DSC was adopted, with samples weighing about 1,5 mg. Aluminium crucibles with perforated covers were used for the DSC.

The 1D - (¹H, ¹³C and DEPT) and 2D - (¹H - ¹H gCOSY, gHMQC and gHMBC) NMR experiments were recorded on a Varian INOVA 500 spectrometer (11.7 T) at 500 MHz (¹H) and 125 MHz (¹³C) at 30 ºC and referenced using TMS as internal standard or residual solvent resonances of CDCl₃ at δ 7.20 and 77.0, respectively, for ¹H and ¹³C NMR.

High resolution mass spectra with ESI ionization was measured on UltrO-TOF instrument (Bruker Daltonics) operating in positive mode. MeOH/H₂O (4:1) was applied as solvent system.

Purity determination

The determination of purity is based on the assumption that an impurity will depress the melting point of a pure material whose melting is characterized by a melting point (T₀) and an enthalpy of fusion (ΔH_fus.). The effect of an impurity on T_o of the 2MeO-HCP was determined by DSC method basing on the Van't Hoff equation (1).

Where T_s is the sample temperature at equilibrium (K), T_o is the melting point of the pure component (K), R is the gas constant, x is the concentration of impurity (mole fraction) and F is the fraction molten at T_s .

The obtained DSC curve exhibits the endothermic event corresponding to 2-MeO-HCP melting point (ΔH_fus= +23.36 kJ mol^-1). The value of purity found was confirming low impurity content.

Structure elucidation

The molecular weight of 2-MeO-HCP, see Figure 1, was calculated from HRESIMS instrument operating in positive mode. The molecular formulae was established as C₁₃H₁₂O₄, with a hydrogen deficiency index of eight. The observed cationized adduct ion peaks at m/z 233,0815 [M + H]⁺ and m/z 255,0630 [M + Na]⁺ were calculated for C₁₃H₁₃O₄, 233,0814 and C₁₃H₁₂O₄Na, 255,0633, respectively. The ¹H NMR analysis of 2-MeO-HCP showed signals for a methoxy group at δ 3.90 (3H, s, H-7'), four aromatic hydrogen signals at δ 6.92 (1H, dd, J = 8.0; 1.0 Hz, H-3'), 7.35 (1H, ddd, J = 8.0; 8.0; 1.0 Hz, H-4'), 6.98 (1H, ddd, J = 8.0; 8.0; 1.0 Hz, H5'), and 7.53 (1H, dd, J = 8.0; 1.0 Hz, H-6'), respectively, were indicative of a 1,2-disubstituted aromatic system, in addition to four other olefinic hydrogen signals at δ 7.05 (1H, d, J = 15.5 Hz), 7.96 (1H, ddd, J = 15.5; 11.2 Hz), 7.10 (1H, ddd, J = 15.5; 11.2 Hz), and 7.53 (1H, d, J = 15.5 Hz), which were assigned to H-3, H4, H-5 and H-6, respectively, see Figure 1. Analysis of the ¹H-¹H COSY NMR spectrum allowed to confirm the assignment of the signals, see Table 1. The ¹³C NMR and DEPT spectra displayed 13 signals, including a methoxy group, eight methines, and four quaternary carbons (Table 1). The aromatic carbons signals were identified at δ 124.4 (C-1'), 158.2 (C-2'), 111.3 (C-3'), 131.7 (C-4'), 120.9 (C-5') and 128.3 (C6'). The presence of a conjugated carbonyl and a vicinal carboxylic carbonyl group were indicated by the chemical shifts at 182.0 (C-2) and 160.6 (C-1), respectively, in the ¹³C NMR spectrum of this compound, in addition to four other olefinic carbons at δ 120.4 (C-3), 152.8 (C-4), 127.2 (C5), and 142.3 (C-6) (Table 1). The aromatic ring was attached to the olefinic end-carbon (C-6), and this was evidenced by the observed gHMBC correlations between the signal at δ 7.53 (H-6) and that at δ 158.2 (C-2'), as well as between the signal at δ 7.53 (H-6') and C-6 (δ 142.3). Further more the 1,2-dissubstituted aromatic ring was confirmed by the correlations between the signal at δ 3.90 (OCH₃-7') with C-2' (δ 158.2) (Table 1). The E-configuration of the conjugated double bonds C-3-C-4 and C-5-C-6 in the olefin moiety were determined by the large coupling constant (15.5 Hz) between H-3-H-4 and H5-H-6. The structure of H-2-MeO-CP was therefore assigned as (3E,5E)-6-(2-methoxyphenyl)2-oxohexa-3,5-dienoic acid.

Computational Strategy

In the present investigation, the employed quantum chemical approach to determining the molecular structures was Becke three-parameter hybrid method⁹ using the Lee-Yang-Par (LYP) correlation functional¹⁰ and the basis sets used for calculations were the 6-311G.^11,12 The performed molecular calculations in this work were done using the Gaussian 03 routine.¹³

Molecular structure of the compound could not be determined by the single crystal X-ray diffraction technique, a geometry optimization was computed using the optimized algorithm of Berny.¹⁴

Theoretical infrared spectrum was calculated using a harmonic field¹⁵ based on C₁ symmetry (electronic state ¹A). Frequency values (not scaled), relative intensities, assignments and description of vibrational modes are presented. The calculations of vibrational frequencies were also implemented to determine an optimized geometry constitutes minimum or saddle points. The principal infrared-active fundamental modes assignments and descriptions were done by the GaussView 3.0 graphics routine.¹⁶

The optimized structure parameters of 2MeO-HCP dimer calculated by ab initio DFTB3LYP levels with the 6-311G basis set are listed in Table 2 in accordance with the atom numbering scheme given in Figure 2.

Optimized geometries and vibrational modes for studied molecular structures were compared with the experimental frequencies. The optimized geometric parameters (bond lengths and bond angles) obtained, see Table 2, did not can be compared with experimental parameters because the crystal structure of the title compound is not available until now. The Mulliken atomic charges, dipole moment and theoretically computed energies are gather in Table 3. Taking into account that the molecular geometry of the dimer alone in vapor phase may be different from that dimer in the solid phase, owing to extended hydrogen bonding and stacking interactions there is reasonable agreement between the calculated and experimental geometric parameters. As discussed by Johnson et al.¹⁷, DFT method predicts bond lengths which are systematically too long, particularly the CH bond lengths.

The experimental and theoretical IR spectra of 2-MeO-HCP are given in Figure 3. The resulting vibrational frequencies for the optimized geometries and the proposed vibrational assignments are given in Table 4. Comparisons between theoretical and experimental IR spectra indicated that vibrations were more intense in experimental than theoretical spectrum.

For 2-MeO-HCP group the vibrational modes are C-H stretch, C=O stretch, O-H stretch, O-CH₃ stretch, CH₃O-C_ar stretch, C-C stretch, C_co- C_ooo stretch, C-C-C bending, CH₃ bending, C-H bending, COO bending and ring bending.

O-H stretching band is characterized by very broad band appearing near about 2500-3600 cm^-1. This may be due combined effect of intermolecular hydrogen bonding. The O-H in plane bending vibration occurs in general at 1440-1395 cm^-1. The O-H out of plane bending vibration occurs in 960-875 cm^-1.¹⁸ In 2-MeO-HCP, O-H stretching were assigned at 3309 and 3358 cm^-1, and in plane and out of plane bending vibrations were assigned at 1385 and 957 cm^-1, respectively. Theoretically computed values (3300, 1400 and 970 cm^-1) were in agreement with experimental results.

The main feature of carboxylic group is a single band observed usually in the 1700-1800 cm^-1 region.¹⁸ This band is due to the C=O stretching vibration. Theoretically computed value of C=O (1750 cm^-1) band show is agreement with experimental data (1760 cm^-1).

Experimental vibration frequencies were in agreement with that theoretically calculated, see Table 4.

Conclusion

In conclusion, 2-MeO-HCP purity was determined for DSC and structural elucidation was made by MS, NMR and IR. Theoretical infrared spectra was calculated and compared with experimental data. The difference between the observed and scaled wavenumbers values of most of the fundamentals is very small. Any discrepancy noted between the observed and the calculated frequencies may be due to the fact that the calculations have been actually done on a single molecule contrary to the experimental values recorded in the presence of intermolecular interactions. Therefore, the assignments made at higher levels of theory with only reasonable deviations from the experimental values, seem to be correct.

Acknowledgements

The authors thanks Dr. Éder Tadeu Gomes Cavalheiro - IQ-USP São Carlos - SP for the computational facilities.

Received September 04 2008

Accepted October 29 2008

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