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Chemometric Analysis of UV Characteristic Profile and Infrared Fingerprint Variations of Coffea arabica Green Beans under Different Space Management Treatments

Abstract

Ultraviolet characteristic profiles and infrared spectroscopic (FTIR) fingerprints of green bean extracts of Coffea arabica L., cv. IAPAR 59, cultivated in two planting patterns, rectangular and square, and at two different densities, 10,000 and 6,000 plants ha-1, identified as R10, R6, S10, and S6 were analyzed with principal component and hierarchical cluster analyses. A simplex centroid design for four solvents (ethanol, acetone, dichloromethane, hexane) was used for sample extraction. The largest chlorogenic acid (CGA) contents were found at the lower planting density. The dichloromethane extracts of the S10 treatment showed the highest levels of unsaponifiable lipids (cafestol and kahweol). The R6 treatment showed a slightly higher content of cafestol and kahweol. Cluster analysis of FTIR fingerprints confirmed that the CGA and caffeine levels differentiate the spatial arrangements. The FTIR fingerprints suggest that green beans from S6 and R10 were richer in lipids and the other two treatments had more sugars and proteins.

Keywords:
plant architecture; arabica coffee; UV-Vis spectroscopy; FTIR spectroscopy; chemometric analysis


Introduction

The chemical compositions of Coffea arabica green beans consist of hundreds of different metabolites. The production of these metabolites is influenced by coffee culture managements, soil, climate conditions (temperature and rainfall, solar radiation), plant architecture and harvesting and post-harvesting procedures such as drying, storage and roasting.11 da Matta, F. M.; Ramalho, J. D. C.; Braz. J. Plant Physiol. 2006, 18, 55.

2 Thierry, J.; Laffargue, A.; Descroix, F.; Doulbeau, S.; Bertrand, B.; Kochko, A.; Dussert, S.; Food Chem. 2010, 118, 693.

3 Gonzalez-Rios, O.; Suarez-Quiroz, M. L.; Boulanger, R.; Barel, M.; Guyot, B.; Guiraud, J. P.; Schorr-Galindo, S.; J. Food Compos. Anal. 2007, 20, 289.

4 Selmar, D.; Bytof, G.; Knopp, S. E.; Ann. Bot. 2008, 101, 31.
-55 Hečimović, I.; Belščak-Cvitanović, A.; Horžić, D.; Komes, D.; Food Chem. 2011, 129, 991. Chlorogenic acids (CGA) are related to sensory characteristics of brewed coffee drink, especially the astringent, acidic and bitter flavors. Significant and positive correlations have been found between the temperature and the formations of 3-caffeoylquinic (3-CQA) and 4-caffeoylquinic acid (4-CQA), whereas a negative correlations occurs for 5-caffeoylquinic acid (5-CQA), which corresponds to 70-80% of CGA in coffee.66 Jöet, T.; Laffarge, A.; Descroix, F.; Doulbeau, S.; Bertrand, B.; Kochko, A.; Dussert, S.; Food Chem. 2010, 118, 693. Altitude has significant and positive correlation with CGA concentration. However, no discussion was provided to prove whether this relationship owes to ground and climate conditions or temperature gradient.77 Bertrand, B.; Boulanger, R.; Dussert, S.; Ribeyre, F.; Berthiot, L.; Descroix, F.; Joët, T.; Food Chem. 2012, 135, 2575.

Coffee tree architecture is characterized by continuous growth and dimorphic axes-orthotropic and plagiotropic. An orthotropic axis follows an opposite-decussate phyllotaxy. At each node, it forms two plagiotropic axes of the 2nd order, even though sometimes, no branch or just one develops. In Coffea arabica L. (arabica coffee), the plagiotropic axes develop from the 2nd to the 5th orders; the highest branching orders appearing after three to four years.88 Rakocevic, M.; Androcioli-Filho, A.; Coffee Sci. 2010, 5, 154.

During the last twenty years high planting densities have been used to increase coffee production, by raising the planting densities from the traditional 700-800 per hectare to 5,000-10,000. The study of variations in densities and planting patterns in coffee culture studies has involved biological and agronomical analyses, such as fruit production99 Paulo, E. M.; Furlani Jr., E.; Sci. Agric. 2010, 67, 720. as well as ecophysiological explanations about light access, water stress1010 Santana, M. S.; Oliveira, C. A. S.; Quadros, M.; Eng. Agric. 2004, 24, 644.

11 Melke, A.; Fetene, M.; Theor. Exp. Plant Physiol. 2014, 26, 225.
-1212 Nascimento, L. M.; Sphar, C. R.; Sandri, D.; Coffee Sci. 2014, 9, 354. and mineral absorption impacts.1313 Valadares, S. V.; Neves, J. C. L.; Novais, R. F.; Rosa, G. N. G. P.; Martinez, H. E. P.; Venegas, V. H. A.; R. Bras. Ci. Solo 2014, 38, 905.,1414 Prezotti, L. C.; da Rocha, A. C.; Bragantia 2004, 63, 239.

Information about chemical modifications in coffee leaves and beans when subjected to different plant managements can be obtained by metabolomic analysis. It consists on sampling, sample preparation, use of instrumental analytical techniques, processing and interpretation of data.1515 Dunn, W. B.; Ellis, D. I.; TrAC, Trends Anal. Chem. 2005, 24, 285. It produces metabolic profiles or fingerprints, providing information about changes in the plant under different growing conditions, soil, climate and other factors.1616 Villas-Bôas, S. G.; Gombert, A. K.; Biotecnologia Cienc. Desenvolv. 2006, 9, 58. During sample preparation, the extraction process is a key step because it aims isolating the metabolites of the vegetable matrix. The choice of extraction solvent can be made by appropriate statistical mixture designs.1717 Soares, P. K.; Bruns, R. E.; Scarmínio, I. S.; J. Sep. Sci. 2007, 30, 3302.

UV-Vis and infrared spectroscopic analytical techniques have been used in the identification and quantification of metabolome constituents in coffee. Sample preparation is relatively simple and the reagents and equipment are not very expensive. UV-Vis spectroscopy has been applied to caffeine quantification,1818 Belay, A.; Ture, K.; Redi, M.; Asfaw, A.; Food Chem. 2008, 108, 310.

19 Atomssa, T.; Gholap, A. V.; Afr. J. Pure Appl. Chem. 2011, 5, 1.

20 Dobrinas, S.; Soceanu, A.; Popescu, V.; Stanciu, G.; Smalberger, S.; St. Cerc. St. CICBIA 2013, 14, 71.
-2121 Delaroza, F.; Rakocevic, M.; Malta, G. B.; Bruns, R. E.; Scarminio, I. S.; J. Braz. Chem. Soc. 2014, 25, 1929. simultaneous determination of methylxanthines,2222 Martínez, L. L.; López-de-Alba, P. L.; Campos, R. G.; Rodríguez, L. M. L.; Anal. Chim. Acta 2003, 493, 83. determination of chlorogenic acids and their antioxidant activities2323 Atoui, A. K.; Mansouri, A.; Boskou, G.; Kefalas, P.; Food Chem. 2005, 89, 27.

24 Parras, P.; Martínez-Tomé, M.; Jiménez, A. M.; Murcia, M. A.; Food Chem. 2007, 102, 582.
-2525 Vignoli, J. A.; Bassoli, D. G.; Benassi, M. T.; Food Chem. 2011, 124, 863. as well as coffee classification.2626 Souto, U. T. C. P.; Pontes, M. J. C.; Silva, E. C.; Galvão, R. K. H.; Araújo, M. C. U.; Sanches, F. A. C.; Cunha, F. A. S.; Oliveira, M. S. R.; Food Chem. 2010, 119, 368. Fourier transform infrared (FTIR) is an important method for identifying chemical constituents and elucidating their structures and has been considered the best and simplest technique to identify and characterize biomolecules.2727 Kumar, J. K.; Prasad, A. G. D.; Drug Invent. Today 2012, 4, 616. This technique has been used in coffee samples to estimate methylxanthine amounts in tea and coffee;2828 Paradkar, M. M.; Irudayara, J.; J. Food Sci. 2002, 67, 2507. determine the effects of roasting conditions;2929 Lyman, D. J.; Benck, R.; Dell, S.; Merle, S.; Murray-Wijelath, J.; J. Agric. Food Chem. 2013, 51, 3268. discriminate between defective and non-defective roasted coffees3030 Craig, A. P.; França, A. S.; Oliveira, L. S.; Food Sci. Technol. 2012, 47, 505. and between roasted coffees and their adulterants.3131 Reis, N.; França, A. S.; Oliveira, L. S.; Food Sci. Technol. 2013, 50, 715.

The spectra subjected to fingerprint analyses contain variance information that can be extracted using a wide variety of chemometric methods.3232 de Souza, R. M. N.; Benassi, M. T.; J. Braz. Chem. Soc. 2012, 23, 1347.

33 Moreira, I.; Scarminio, I. S.; Talanta 2013, 107, 416.
-3434 Moreira, I.; Scheel, G. L.; Hatumura, P. H.; Scarminio, I. S.; Quim. Nova 2014, 37, 39. Multivariate analysis methods, such as principal component analysis (PCA)3535 Marques, J. M.; Marques, M. A. M.; Rev. FAE Curitiba 2005, 8, 93. and cluster analysis (CA),3636 Miller, J. N.; Miller, J. C.; Statistics and Chemometrics for Analytical Chemistry, 6th ed.; Pearson: Gosport, UK, 2010. allow dimensionality reduction of multivariate data and the extraction of essential results from large data sets. These analytical techniques can be associated with adequate methods of multivariate analysis for extracting information about the influence of the space management treatments, such as density and planting patterns, in the production of metabolites in Coffea arabica L. beans. The aim of this work was to investigate ultraviolet (UV) and infrared spectral (FTIR) changes in green bean extracts of Coffea arabica cv. IAPAR 59 grown in two planting patterns and at two planting densities. The varying effects of different mixture design solvents on extraction from coffee samples increase the chances of observing the most important spectral changes.

Experimental

Site conditions and coffee plant management

Coffee plants (Coffea arabica L., cv. IAPAR 59) were cultivated in two planting patterns: rectangular (R) and square (S) at two densities: 10,000 and 6,000 plants ha-1 in experimental fields of the Agronomical Institute of Paraná, in the city of Londrina, Paraná State (23º18'S and 51º17'W), Brazil. The distance between plants was 1 m × 1 m (S10), 3 m × 0.33 m (R10), 1.29 m × 1.29 m (S6) and 3 m × 0.55 m (R6). Visually mature berries were collected in June of 2010, defining the first production year after very low pruning (carried out in 2008).

Reagents and sample preparation

The solvents used for extract preparation were ethanol from Exodo (Hortolândia, Brazil), acetone from Fmaia (Cotia, Brazil), dichloromethane and hexane both from Anidrol (Diadema, Brazil). Malic and citric acids were purchased from Synth (Diadema, Brazil). All were of analytical grade quality.

The coffee beans were dried in the sun on a concrete yard until reaching 12.5% moisture content. After drying, the beans were cleaned of bark and parchment and all visible defects removed. The beans were frozen with liquid N2 and were ground to a 0.5 mm particle size (mill Perten 3600). Posteriorly, they were sieved through a Granutest ABNT sieve 25, 071 mm, Tyler 24. The processed samples were packaged into plastic bags and sealed under vacuum in sealant Selovac model 120 BO. The samples were stored in a freezer/cooler Electrolux model 160M, at −18 ºC.

Simplex centroid design

A simplex centroid design for four components was used for obtaining the sample extracts from each treatment. Ethanol, acetone, dichloromethane, hexane and their binary, ternary and quaternary mixtures were investigated (Table 1). Because the coffee bioactive compounds have different polarities, the choice of solvents for extraction was based on this property. Previous studies developed in our laboratory have shown the efficiency of these solvents and their mixtures in the extraction of coffee compounds.2121 Delaroza, F.; Rakocevic, M.; Malta, G. B.; Bruns, R. E.; Scarminio, I. S.; J. Braz. Chem. Soc. 2014, 25, 1929.,3333 Moreira, I.; Scarminio, I. S.; Talanta 2013, 107, 416.,3434 Moreira, I.; Scheel, G. L.; Hatumura, P. H.; Scarminio, I. S.; Quim. Nova 2014, 37, 39.

Table 1
Simplex centroid design for four components: ethanol (e), acetone (a), dichloromethane (d) and hexane (h)

The extractions were performed with 2.50 g of crushed beans and 60 mL of extracting solvent in ultrasonic bath (Ultracleaner 1400 Unique), for 120 min and maintained at 15 ± 2 ºC with ice. After filtration, the filtrate was collected and the extraction cycle was repeated with the residue. The process was considered exhaustive when a complete overlap occurred between the UV-Vis spectra of two consecutive extractions. The spectrophotometer used was a Thermo Scientific Evolution 60. The solvent was removed in a rotary evaporator (Fisatom model 801) and then the extract was lyophilized at −81.5 ± 0.1 ºC and 20 ± 2 mTorr (Lyophilizer SP Scientific Virtis).

Analysis by UV-Vis spectroscopy

UV-Vis spectra were obtained with 50 mg of each extract dissolved in 20 mL of respective extractor solvent. The mixture was placed in an ultrasound bath for 20 min. The spectra were obtained in the 190-800 nm range with the UV-Visible Thermo Scientific model Evolution 60S, using quartz cuvettes with a 1 cm optical path length.

Analysis by infrared spectroscopy (FTIR)

Spectra in the infrared region (4000-675 cm-1) of crude extracts were obtained with a Thermo Scientific Nicolet iS10 FT-IR spectrometer, using the ATR (attenuated total reflectance) accessory with a Ge window. The measurement was done in the transmittance mode, with 64 scans and 4 cm-1 resolution.

Data processing

Architectural data extraction from the Multiscale Tree Graphs (MTG's) was performed using AMAPstudio-Xplo software.3737 Griffon, S.; de Coligny, F.; Ecol. Modell. 2014, 290, 3. Special attention was paid to berry distribution along the orthotropic trunk and axes of second order. The extracted number of berries per rank/metamer/axes were used to generate berry distributions.

The Statistica 7.0 software was used in the statistical data analyses for the UV-Vis and infrared spectra. The spectra and loading graphs were plotted using the Origin Pro 8 software.

Results and Discussion

Architecture of orthotropic axis and average berry distribution over the coffee plants

The plant height did not differ between the planting patterns (PPs) and densities, but the metamer number at the orthotropic axes was higher in rectangular PPs than in square ones (Figure 1). In rectangular PP and higher density, the competition between plants in the row promoted apical dominance more than in square PP and lower density.

Figure 1
Mean and standard error values for height and metamer number of the orthotropic trunk. Plants were cultivated under two planting patterns (S-square and R-rectangular) and densities (6 and 10 thousand plants ha-1). In some cases, the two deviations overlap.

UV-Vis characteristic profile analysis

The absorption spectra data were subjected to PCA, in order to visualize the natural clusters in metabolites from green coffee beans caused by planting densities and patterns. Spectral data (absorbance) were arranged in a matrix of 601 rows and 80 columns, where each row represents a wavelength variable and each column a sample extract (20 simplex design mixtures for four spatial arrangements), to calculate the principal components and cluster analysis. The first three principal components explain 89.40% of the total variance of the data.

Although the scores of 2nd and 3rd principal components (PC) account for only 30.79% of the total data variance, they provided the important chemical feed-back (Figure 2). The graphical separations of the extraction points were due to the different sample properties and their solvent interactions in the varying solvent media. The separation of extracts along the 2nd factor (PC2) showed two clusters: on the negative side are the extract points from pure ethanol (e), dichloromethane (d) and hexane (h), the dh, de, eh binary mixtures and the deh ternary mixture. Their UV spectra represent the characteristic profile of the bioactive compounds of coffee (methylxanthines, chlorogenic acids and pentacyclic alcohols). The extracts obtained with acetone (a) and their mixtures with the other solvents are grouped on the positive side of PC2. Their profile indicate the presence of acids and phenolic compounds. Extracts of acetone and hexane:acetone (1:1 v/v) were separated from other solvents in factor 3 (PC3). Some metabolites were identified by their absorption spectra.

Figure 2
PC2 × PC3 score plots of UV-Vis characteristic profile of crude extracts of Coffea arabica, cv. IAPAR 59 green beans. Plants were cultivated under two planting patterns (S-square and R-rectangular) and densities (6 and 10 thousand plants ha-1).

The spectra of the ethanol extracts have two peaks: the first at 217 nm with a shoulder at 245 nm and the second peak at 329 nm with shoulder at 298 nm. The minimum was at 264 nm (Figure 3a). The two peaks with their shoulders correspond to HOMO → LUMO (highest occupied molecular orbital to the lowest unoccupied molecular orbital) electronic transitions. These spectra are typical of chlorogenic acids (CGA) and have been characterized and determined in coffee beans by UV-Vis spectroscopy.3838 Belay, A.; Gholap, A. V.; Afr. J. Pure Appl. Chem. 2009, 3, 234. The low planting density treatments (S6 and R6) showed higher CGA contents than the treatments with high planting density (S10 and R10). The larger space available for each plant at 6,000 plants ha-1 relative to that at 10,000 plants ha-1 allows an increase in solar radiation incidence. UV radiation generates free radicals that cause cell damage under this condition, and plants produce antioxidant compounds as defense mechanisms,3939 Heck, C. I.; Mejia, E. G.; J. Food Sci. 2007, 72, 138. therefore the CGA level increases. Furthermore, this result indicates that the chlorogenic acid content is related to plant height (Figure 1).

Figure 3
Spectra of (a) ethanol; (b) dichloromethane; (c) hexane extracts of green beans of Coffea arabica, cv. IAPAR 59. Plants were cultivated under two planting patterns (S-square and R-rectangular) and two densities (6 and 10 thousand plants ha-1).

The dichloromethane and hexane extract spectra show the same profile with two peaks: 229-230 nm and 283-290 nm for the dichloromethane extracts (Figure 3b) and 221 and 286 nm, for the hexane extracts (Figure 3c). These peaks are characteristic for unsaponifiable lipids of coffee, cafestol and kahweol. Values for these pentacyclic alcohols were reported at 225 nm for cafestol and 288 nm, for kahweol.4040 Dias, R. C. E.; de Faria, A. F.; Mercadante, A. Z.; Bragagnolo, N.; Benassi, M. T.; J. Braz. Chem. Soc. 2013, 24, 492. The S10 treatment showed higher contents of cafestol and kahweol in the dichloromethane extract. In the hexane extract, the R6 treatment showed a slightly higher kahweol content compared with other treatments. Methylxanthines (caffeine, theobromine and theophylline) also absorb in this spectral region. Studies on caffeine in tea leaves showed that this methylxanthine absorbs between 244 and 300 nm when the solvent extractor was dichloromethane. In this case, the wavelength (λmax) was 276 nm.1919 Atomssa, T.; Gholap, A. V.; Afr. J. Pure Appl. Chem. 2011, 5, 1. In water extraction, the methylxanthines showed λmax between 270 and 280 nm.4141 Khanchi, A. R.; Mahani, M. K.; Hajihosseini, M.; Maragheh, M. G.; Chaloosi, M.; Bani, F.; Food Chem. 2007, 103, 1062. Consequently, the spectra of these alkaloids could be masked by the kahweol spectrum. In the PC2 × PC3 score plot of Figure 2, the dichloromethane and hexane extracts are grouped very closely, at negative PC2 scores. This confirms that their compositions are similar.

Pairs of extract spectra prepared in a/ah, ea/eah, da/dah and dea/deah exhibited the same spectral profile (Figure 2), indicating the same metabolite class but with higher intensity than those prepared in acetone. The extract spectra obtained with pure acetone and their mixtures with ethanol and/or hexane exhibited two peaks. The peak at 215 nm is characteristic of citric or malic acid, according to information obtained in our laboratory, having patterns of these acids dissolved in their respective solvent under the same conditions. The peak at 330 nm was not identified.

The principal component results were confirmed by cluster analysis (CA) as shown in the dendrogram of Figure 4. The treatments were identified with the numbers 1 (S6), 2 (S10), 3 (R6) and 4 (R10). When the dendrogram is examined at the point 7.0 (linkage distance), six groups are found. Each group consists of spectra having some similarities. Group I only contains extract spectra obtained with the dichloromethane:ethanol mixture. The profile spectra indicated that this mixture extracted different metabolites than those extracted by their pure solvents. Group II contains extracts obtained from the dea and deah mixtures. Therefore, these mixtures extracted the same types of metabolites having an unidentified peak at 330 nm. Group III corresponds to the spectra of the ea and eah extracts. The 215 nm peak differentiates between the spectra Groups II and III. The extract spectra obtained with ethanol and the ethanol:hexane mixture constitute Group IV, with chlorogenic acid profiles (Figure 3a). Group V is formed only by the S10 dichloromethane extract spectrum. This indicates differences in pentacyclic alcohol (cafestol and kahweol) contents when compared with the other three treatments. The spectra of S6, R10 and R6 dichloromethane extracts are grouped together with the extract spectra obtained with h, dh, deh, a, ah, and dah, forming Group VI. Figures 3b and 3c show similar profiles for the S6, R10 and R6 dichloromethane and hexane extract spectra. Together these extracts form a subgroup of Group VI.

Figure 4
Dendrogram of the UV spectra of extracts obtained from green grains of C. arabica, cv. IAPAR 59. Plants were cultivated under two planting patterns (S-square and R-rectangular) and two densities (6 and 10 thousand plants ha-1). The treatments were identified with the numbers 1 (S6), 2 (S10), 3 (R6) and 4 (R10).

FTIR fingerprint analysis

PCA was also conducted on the complete FTIR spectra. The matrix was composed of 80 samples (extracts) and 1678 variables. The first two principal components explained 99.03% of the total data variance. The PC1 × PC2 score plot shows two groups separated on PC2 (Figure 5a), appearing very different from those at Figure 2, where extracts were grouped according to the extractor solvent. The spectral points lay on one of two almost straight lines indicating two major components (Figure 5a). Overlaying points with similar extracts fall at the intersection whereas the more divergent spectra occur at the two extreme limits. The pure hexane and dichloromethane solvents and binary and ternary mixtures containing acetone and dichloromethane (Group I) have positive values of PC2. The extracts of binary or ternary mixtures containing ethanol and hexane fall at negative PC2 values (Group II). In order to view the points of interest more easily, some symbols identifying the extracts were eliminated.

Figure 5
(a) PC1 × PC2 score plot; (b) their loading plot for the FTIR extract spectra obtained from green beans of C. arabica, cv. IAPAR 59. Plants were cultivated under two planting patterns (S-square and R-rectangular) and two densities (6 and 10 thousand plants ha-1).

Figure 5b shows the PC1 and PC2 loading plots. Along PC2, large positive loadings are found at 3342, 1648, 1604, 1048 and 990 cm-1 and correspond to the crude extracts of Group I (binary or ternary mixtures containing acetone and dichloromethane). The samples of Group II have large negative loadings for frequency values at 2922, 2846, 1742, 1470, 1174, 1098 and 722 cm-1. The bands in 1500-2000 cm-1 range were related to C=C and C=O stretching modes, but depending on the type of C=O bond bands can vary within the 1650-1830 cm-1region. C=N stretching also occurs in this region.4242 Pavia, D. L.; Lampman, G. M.; Kriz, G. S.; Introduction of Spectroscopy: A Guide for Students of Organic Chemistry, 2th ed.; Saunders College Publishing: Orlando, USA, 1996, pp. 511. In Group I, bands observed at 3342 (N−H stretching) and 1648 cm-1, probably correspond to caffeine. The dichloromethane solvent belongs to this group and has been used to decaffeinate and isolate caffeine from aqueous coffee extracts.4343 Toci, A.; Farah, A.; Trugo, L. C.; Quim. Nova 2006, 29, 965. In Group II, the band at 1742 cm-1characterizes the stretching vibration of the carbonyl group of methyl ester and the region between 1179 and 1166 cm-1is assigned to C−O stretching of esters.4444 Chapman, D.; J. Am. Oil Chem. Soc. 1965, 42, 353. The band at 1174 cm-1is characteristic of the stretching vibration of the C−O bond of higher esters.4545 Dufour, E. In Infrared Spectroscopy for Food Quality, Analysis and Control; Sun, D.-W., ed.; Academic Press: USA, 2009, pp. 448.,4646 Mistry, B. D.; Handbook of Spectroscopy Data: Chemistry-UV, IR, PMR, CNMR and Mass Spectroscopy; Oxford Book Company: Jaipur, India, 2009, pp. 242. The hexane extract belongs to Group II and this solvent is frequently used in the lipid extraction.4747 Brum, A. A. S.; Arruda, L. F.; Regitano-D'Arce, M. A. B.; Quim. Nova 2009, 32, 849. The bands at 2918 and 2861 cm-1are attributed respectively to the asymmetric and symmetric stretching vibrations of sp33 Gonzalez-Rios, O.; Suarez-Quiroz, M. L.; Boulanger, R.; Barel, M.; Guyot, B.; Guiraud, J. P.; Schorr-Galindo, S.; J. Food Compos. Anal. 2007, 20, 289. hybridized C−H bonds. The band at 1464 cm-1corresponds to the symmetrical angular deformation of methylene groups.4242 Pavia, D. L.; Lampman, G. M.; Kriz, G. S.; Introduction of Spectroscopy: A Guide for Students of Organic Chemistry, 2th ed.; Saunders College Publishing: Orlando, USA, 1996, pp. 511. These groups are present in the fatty acids studied in coffee.4848 Nikolova-Damyanova, B.; Velikova, R.; Jham, G. N.; Food Res. Int. 1998, 31, 479.

The spectra of the points of Groups I and II (Figure 5a) were plotted to examine their behavior. The dichloromethane extract R6 (R6 d) was chosen to represent the extreme of Group I. The ethanol:hexane extract of R6 (R6 eh) and the dichloromethane:ethanol:hexane extract of R10 (R10 deh) represented the extreme of the Group II (Figure 5a). Similarly, their corresponding spectra of the square arrangement S10 deh, S6 eh and S6 d extracts were plotted to search for possible changes in metabolite production owing to planting pattern. Their FTIR fingerprint are presented in Figure 6.

Figure 6
FTIR spectra of (a) R10 deh; (b) R6 eh; (c) R6 d; (d) S10 deh; (e) S6 eh; (f) S6 d obtained from green bean extracts of C. arabica, cv. IAPAR 59. Plants were cultivated under two planting patterns (S-square and R-rectangular) and two densities (6 and 10 thousand plants ha-1).

The R10 deh, R6 eh and S10 deh spectra (Figures 6a, 6b and 6d) have different characteristics from those provided by the loading plot for Group II (Figure 5b). These spectra have a broad band around 3333 cm-1 and sharper ones at 1644, 1600, 1050 and 993 cm-1. These bands are coincident with the Group I peaks in the loading plot. Other bands were observed for these extracts at 1747 (fatty acid esters) and 1704 (organic acid) cm-1.4949 Dimitrić-Marković, J. M.; Mioć, U. B.; Baranac, J. M.; Nedić, Z. P.; J. Serb. Chem. Soc. 2001, 66, 451. The region with bands at 1452, 1380, 1260, 1128 and 1059 cm-1 can be attributed to chlorogenic acids.5050 Segneanu, A. E.; Grozescu, I.; Sfirloaga, P.; Dig. J. Nanomater. Bios. 2013, 8, 1423. The spectral bands of beans collected from rectangular planting patterns (R10 deh and R6 eh) were more intense than those of bean extracts of the S10 spectra (S10 deh). The R6 d and S6 d extract spectra (Figures 6c and 6f) exhibit the same profile but they do not have the characteristic bands of Group I: 3342, 1648, 1604, 1048 and 990 cm-1 as shown on the positive values of the loading plot (Figure 5b). These spectra present bands at 2920, 2865, 1735, 1459, 1165, 1095 and 721 cm-1, the same as those of Group II. Other bands characterize these extracts: 3010 (=C−H stretching), 1380 (C−H bending of CH3 group), and 721 cm-1 (rocking motion of (CH2)n when n ≥ 4)42 and the region between 1300 and 1000 (C−O stretching).4444 Chapman, D.; J. Am. Oil Chem. Soc. 1965, 42, 353. This information indicates the possible presence of fatty acid esters in the R6 and S6 dichloromethane grain extracts, meaning that more available soil space for plants leads to the formation of more fatty acids.

The S6 eh spectrum (Figure 6e) has a similar profile to the R6 d and S6 d spectra (Figures 6c and 6f) and these extracts were placed in Group I (Figure 5a). The ethanol:hexane extracts of the other three treatments (R6, R10 and S10) are in Group II. This suggests that the S6 metabolites extracted by the ethanol:hexane mixture are different from those of the S10, R6 and R10 metabolites, due to the distribution over the coffee plant architecture (Figure 1).

The results of PCA were confirmed by CA. A linkage distance of 0.6 discriminates three groups (Figure 7). Group I (extracts of binary or ternary mixtures of acetone and dichloromethane) (Figure 5a) is located on the right of the dendrogram whereas Group II extracts of binary or ternary mixtures of ethanol and hexane are located on the left while the third group is not clearly characterized. Group III contained extracts obtained with the quaternary mixtures of solvents and those obtained with the ethanol:dichloromethane mixture. Figure 7 also shows that space management treatments are separated by the pure ethanol and dichloromethane solvents, indicating that levels of chlorogenic acids and cafestol/kahweol or caffeine could discriminate these treatments. These results can be compared with those obtained for the UV-Vis spectra of ethanol and dichloromethane extracts (Figures 3a and 3b). The spectra of the ethanol extracts showed a CGA profile with the S6 treatment having the highest contents of these acids (Figure 3a). In the CA of infrared fingerprint, the S6 ethanol extract is isolated from the others (S10 e, R6 e and R10 e) in Group III (Figure 7). In the UV-Vis characteristic profile (Figure 3b), the S10 treatment exhibits the highest content of cafestol and kahweol and it appears separated from the others in Group III of the infrared dendrogram (Figure 7).

Figure 7
Dendrogram of the FTIR spectra of extracts obtained from green grains of C. arabica, cv. IAPAR 59. Plants were cultivated under two planting patterns (S-square and R-rectangular) and two densities (6 and 10 thousand plants ha-1). The treatments were identified with the numbers 1 (S6), 2 (S10), 3 (R6) and 4 (R10).

The four FTIR spectra of bean extracts obtained with the ethanol:dichloromethane mixture showed similar spectral profiles (Figure 8a). The bands at 3331 (N−H) and 1695, 1648 and 1604 cm-1 can be attributed to C=C and C=N stretching. These groups are present in caffeine. The bands at 1742 cm-1 (C=O stretching), 2841 and 2920 cm-1(C−H stretching of CH2 and CH3 groups) and 1165 cm-1 (C−O stretching) can be assigned to triacylglycerols.4444 Chapman, D.; J. Am. Oil Chem. Soc. 1965, 42, 353. The weak band at 3009 cm-1 can be attributed to C−H stretching in =C−H.5151 Schulz, H.; Baranska, M.; Vib. Spectrosc. 2007, 43, 13. This indicates the presence of unsaturated fatty acids.

Figure 8
FTIR spectra of (a) ethanol:dichloromethane; (b) ethanol extracts obtained from green beans of C. arabica, cv. IAPAR 59. Plants were cultivated under two planting patterns (S-square and R-rectangular) and two densities (6 and 10 thousand plants ha-1).

The FTIR spectra of ethanol extracts for S10 and R6 showed bands in various regions that were different from those of the S6 and R10 spectra (Figure 8b). Only spectra from first two have a broad band in the 3100-3600 cm-1 region attributed to the presence of compounds with O−H and N−H groups.4646 Mistry, B. D.; Handbook of Spectroscopy Data: Chemistry-UV, IR, PMR, CNMR and Mass Spectroscopy; Oxford Book Company: Jaipur, India, 2009, pp. 242. The band at 1742 cm-1 corresponds to the ester group of triacylglycerols and is less intense than in the ethanolic spectra of R10 and S6. The region between 1700 and 1500 cm-1 can be assigned to the peptide bond (C−NH) absorption of the protein backbone.4545 Dufour, E. In Infrared Spectroscopy for Food Quality, Analysis and Control; Sun, D.-W., ed.; Academic Press: USA, 2009, pp. 448. Moreover, they present several intense bands in the region between 1325 and 950 cm-1. This region can be associated with carbohydrates.4545 Dufour, E. In Infrared Spectroscopy for Food Quality, Analysis and Control; Sun, D.-W., ed.; Academic Press: USA, 2009, pp. 448. The S6 and R10 spectra have characteristic triacylglicerols bands: 1742 (intense), the 3000-2800 cm1 region corresponding to C−H stretching, 1463 and 1379 cm1 (CH2 and CH3 scissoring) and 1121 and 720 cm-1 (CH3 and CH2 wagging).4444 Chapman, D.; J. Am. Oil Chem. Soc. 1965, 42, 353. This suggests that these space management treatments may have higher triacylglycerol contents than S10 and R6. This triacylglycerol metabolomic fingerprint could be related to the berry distribution (Figure 1).

Conclusions

The PCA of the UV-Vis spectra showed that characteristic profile differences were assigned mainly to ethanol extracts that exhibit a characteristic chlorogenic acid profile. The highest CGA content was found for the lower planting density treatments (S6 and R6). The dichloromethane and hexane spectra showed cafestol and kahweol peaks. The S10 treatment showed higher contents of these unsaponifiable lipids in the dichloromethane extract. The hexane extract of the R6 treatment showed a slightly higher content of these pentacyclic alcohols relative to those of the other treatments. Based in this analysis, bioactive coffee compounds can be extracted using the pure solvents. The cluster analysis of FTIR fingerprints confirmed that the levels of chlorogenic acids and caffeine differentiated these treatments. The FTIR spectra analysis suggests that S6 and R10 present more lipid contents whereas S10 and R6 treatments have more content of sugars and proteins.

  • FAPESP has sponsored the publication of this article.

Acknowledgments

This work was support by CNPq, Fundação Araucária and Consórcio Brasileiro de Pesquisa e Desenvolvimento de Cafés, Brazilian granting agencies.

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Publication Dates

  • Publication in this collection
    July 2016

History

  • Received
    20 Oct 2015
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