Raman Spectroscopic and Sensory Evaluation of Cocoa Liquor Prepared with Ecuadorian Cocoa Beans Treated with Gamma Irradiation or Induced Electromagnetic Field Fermentation
Abstract
:1. Introduction
2. Materials and Methods
2.1. Cocoa Bean Fermentation under Induced Magnetic Fields
2.2. Gamma Irradiation Treatment of Fermented Cocoa Beans
2.3. Cocoa Liquor Samples
2.4. Raman Spectral Measurements of Cocoa Liquor Samples
2.5. Sensorial Evaluation of Cocoa Liquor from Gamma-Irradiated Cocoa Beans
2.6. Multivariate Data Analysis of the Raman Spectra of Cocoa Liquor
3. Results and Discussion
3.1. Cocoa Liquor Raman Spectra
Experimental Wavenumber (cm−1) | Intensity | Assignment Vibrational Modes | Proposed Compound | Reported Wavenumber (cm−1) | Reference |
---|---|---|---|---|---|
626 | VW | Skeletal deformation of aromatic rings, substituent groups, and side chains | Native lignin | 634 | [53] |
- | Polygalacturonic (pectic) acid H–Pec | 621 | [59] | ||
C=C–C deformation | Theobromine | 626 | [50] | ||
OH out-of-plane deformation/(C=C) ring | Ascorbic acid | 621 | [71,72] | ||
779 | VW | Skeletal deformation of aromatic rings, substituent groups, and side chains | Native lignin | 787 | [53] |
Ring “breezing” | Polygalacturonic (pectic) acid H–Pec | 775 | [59] | ||
O=C–C deformation [68] | Theobromine | 777 [69] | [68,69] | ||
860 | VW | (C6–C5–O5–C1–O1) | Polygalacturonic (pectic) acid H–Pec (a-glycosidic bonds in H–Pec) | 853 | [59] |
N=C–H deformation | Caffeine | 850 | [68] | ||
1071 | M | (C–C) | C–C in cocoa butter | 1000–1150 | [44] |
(C–C) | Cocoa butter polymorphs form V | 1063 | [45] | ||
(C–O) ring modes | Cell wall of Valonia ventricosa cellulose | 1071 | [57] | ||
(CO) + (OH) | Polygalacturonic (pectic) acid H–Pec | 1079 | [59] | ||
(C–N) | Caffeine | 1080 | [68] | ||
(C–O–C) and (C-O-H) | Ascorbic acid | 1081 | [71,72] | ||
1135 | sh | A mode of coniferaldehyde unit | Native lignin | 1134 | [53] |
(COC) glycosidic bond, ring | Polygalacturonic (pectic) acid H–Pec | 1145 | [59] | ||
(C–N) | Caffeine | 1131 | [68] | ||
1301 | S | (CH2) | Cocoa butter polymorphs form V | 1297 | [45] |
(C–H) | C–H in cocoa butter | 1200–1400 | [44] | ||
Aryl-O of aryl-OH and aryl-O-CH3 and C=C stretching of coniferyl alcohol units | Native lignin | 1297 | [53] | ||
(HCC) and (HCO) | Softwood cellulose | 1298 | [55] | ||
(CH2) | Cell wall of Valonia ventricosa cellulose | 1293 | [57] | ||
(C–N) + (CH3) | Theobromine | 1298 | [69] | ||
(C–N) | Theobromine | 1296 | [50,68] | ||
(C=N) + (C–N) | Theobromine | 1360 | [69] | ||
1362 | VW | C–H deformation | Cell wall of Valonia ventricosa cellulose | 1359 | [57] |
w(CH2), (C–O–H) | Ascorbic acid | 1371 | [71,72] | ||
(C–H) | C–H in cocoa butter | 1400–1500 | [44] | ||
(C–H) | TAGs: tripalmitin, trimyristin, trilaurin, triundecanin, and triacetin | 1445 | [46,47] | ||
1445 | VS | Guaiacyl ring vibration | Native lignin | 1454 | [53] |
O–H deformation | Cell wall of Valonia ventricosa cellulose | 1454 | [57] | ||
(CH), CH2 scissoring | Ascorbic acid | 1452 | [71,72] | ||
1603 | W | Symmetric aryl-ring stretching | Native lignin | 1602 | [53] |
(C=C) | Aromatic ring from polyphenolic compounds | max. 1613 | [63] | ||
(C=C) + (C–N) + (CH3) | Theobromine | 1594 | [69] | ||
(C=C) | Caffeine | 1600 | [68] | ||
1659 | (C=C) | Cocoa butter region attributed to the olefinic band | 1600–1700 | [44] | |
Ring-conjugated (C=C) of coniferaldehyde | Native lignin | 1658 | [53] | ||
VW | (C=O) | Theobromine | 1660 | [68] | |
(C=O) | Caffeine | 1656 | [68] | ||
(C=C) ring stretching | Ascorbic acid | 1661 | [71,72] | ||
1747 | VW | (C=O) | C=O in cocoa butter | 1700–1800 | [44] |
(C=O)COOH | Polygalacturonic (pectic) acid H-Pec | 1740 | [59] |
3.2. Sensory Attributes of the Cocoa Liquor from the Gamma-Irradiated Cocoa Beans
4. Conclusions
Supplementary Materials
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Guzmán-Armenteros, T.M.; Ruales, J.; Cuesta-Plúa, C.; Bravo, J.; Sinche, M.; Vera, E.; Vera, E.; Vargas-Jentzsch, P.; Ciobotă, V.; Ortega-Ojeda, F.E.; et al. Raman Spectroscopic and Sensory Evaluation of Cocoa Liquor Prepared with Ecuadorian Cocoa Beans Treated with Gamma Irradiation or Induced Electromagnetic Field Fermentation. Foods 2023, 12, 3924. https://doi.org/10.3390/foods12213924
Guzmán-Armenteros TM, Ruales J, Cuesta-Plúa C, Bravo J, Sinche M, Vera E, Vera E, Vargas-Jentzsch P, Ciobotă V, Ortega-Ojeda FE, et al. Raman Spectroscopic and Sensory Evaluation of Cocoa Liquor Prepared with Ecuadorian Cocoa Beans Treated with Gamma Irradiation or Induced Electromagnetic Field Fermentation. Foods. 2023; 12(21):3924. https://doi.org/10.3390/foods12213924
Chicago/Turabian StyleGuzmán-Armenteros, Tania María, Jenny Ruales, Cristina Cuesta-Plúa, Juan Bravo, Marco Sinche, Edwin Vera, Edison Vera, Paul Vargas-Jentzsch, Valerian Ciobotă, Fernando E. Ortega-Ojeda, and et al. 2023. "Raman Spectroscopic and Sensory Evaluation of Cocoa Liquor Prepared with Ecuadorian Cocoa Beans Treated with Gamma Irradiation or Induced Electromagnetic Field Fermentation" Foods 12, no. 21: 3924. https://doi.org/10.3390/foods12213924
APA StyleGuzmán-Armenteros, T. M., Ruales, J., Cuesta-Plúa, C., Bravo, J., Sinche, M., Vera, E., Vera, E., Vargas-Jentzsch, P., Ciobotă, V., Ortega-Ojeda, F. E., Proaño, A., Echeverría, A., & Ramos-Guerrero, L. (2023). Raman Spectroscopic and Sensory Evaluation of Cocoa Liquor Prepared with Ecuadorian Cocoa Beans Treated with Gamma Irradiation or Induced Electromagnetic Field Fermentation. Foods, 12(21), 3924. https://doi.org/10.3390/foods12213924