Research Article
BibTex RIS Cite
Year 2023, Volume: 10 Issue: 3, 729 - 744, 30.08.2023
https://doi.org/10.18596/jotcsa.1302567

Abstract

References

  • 1. Seremet L, Botez E, Nistor OV, Andronoiu DG, Mocanu GD. Effect of different drying methods on moisture ratio and rehydration of pumpkin slices. Food Chemistry. 2016;195:104-9.
  • 2. FAO. FAO Stat Crops and livestock product 2023 [Available from: <URL>.
  • 3. Guine RPP, Pinho S, Barroca MJ. Study of the convective drying of pumpkin (Cucurbita maxima). Food and Bioproducts Processing. 2011;89(C4):422-8.
  • 4. Yang ZH, Amrit BK, Zhao WR, Shi LH, Wu HJ, Barrow C, et al. Bioaccessibility and bioavailability changes of phenolic compounds in pumpkins (Cucurbita moschata): A review. Food Bioscience. 2022;47.
  • 5. Özdemirli N, Kamiloğlu S. Dondurma işleminin mandalina polifenollerinin biyoerişilebilirliği üzerine etkisi. Gıda ve Yem Bilimi Teknolojisi Dergisi. 2023(30):10-21.
  • 6. Zhang M, Tang J, Mujumdar AS, Wang S. Trends in microwave-related drying of fruits and vegetables. Trends in Food Science & Technology. 2006;17(10):524-34. Avaliable from: <URL>.
  • 7. Bandaru H, Bakshi M. Fruit Leather: Preparation, packaging and its effect on sensorial and physico-chemical properties: A review. Journal of Pharmacognosy and Phytochemistry. 2020;9(6):1699-709.
  • 8. Nizamlioglu NM, Yasar S, Bulut Y. Chemical versus infrared spectroscopic measurements of quality attributes of sun or oven dried fruit leathers from apple, plum and apple-plum mixture. Lwt-Food Science and Technology. 2022;153.
  • 9. Tontul I, Topuz A. Effects of different drying methods on the physicochemical properties of pomegranate leather (pestil). Lwt-Food Science and Technology. 2017;80:294-303.
  • 10. Arevalo-Pinedo A, Murr FEX. Kinetics of vacuum drying of pumpkin (Cucurbita maxima): Modeling with shrinkage. Journal of Food Engineering. 2006;76(4):562-7.
  • 11. Horuz E, Bozkurt H, Karatas H, Maskan M. Effects of hybrid (microwave-convectional) and convectional drying on drying kinetics, total phenolics, antioxidant capacity, vitamin C, color and rehydration capacity of sour cherries. Food Chemistry. 2017;230:295-305.
  • 12. Karabacak AO, Suna S, Dorak S, Copur OU. Drying characteristics, mineral content, texture and sensorial properties of pumpkin fruit leather. Latin American Applied Research. 2021;51(3):193-201.
  • 13. Koh S, Loh S. In vitro bioaccessibility of β-carotene in pumpkin and butternut squash subjected to different cooking methods. International Food Research Journal. 2018;25(1):188-95.
  • 14. Lencina MS, dos Santos Ferreira C, Archaina D, Gómez MB, Mazzobre MF. Stability and bioaccessibility of iron in pumpkin discs vacuum impregnated with ferrous gluconate, β-cyclodextrin and ascorbic acid. LWT. 2022;161:113342.
  • 15. Bergantin C, Maietti A, Tedeschi P, Font G, Manyes L, Marchetti N. HPLC-UV/Vis-APCI-MS/MS determination of major carotenoids and their bioaccessibility from “Delica”(Cucurbita maxima) and “Violina”(Cucurbita moschata) pumpkins as food traceability markers. Molecules. 2018;23(11):2791.
  • 16. Aydin E. Evaluation of phenolic acid, total phenolic content, antioxidant capacity and in-vitro simulated bioaccessibility of healthy snack: Aromatized pumpkin chips. Emirates Journal of Food and Agriculture. 2022.
  • 17. Zhang Z, Wang X, Li Y, Wei Q, Liu C, Nie M, et al. Evaluation of the impact of food matrix change on the in vitro bioaccessibility of carotenoids in pumpkin (Cucurbita moschata) slices during two drying processes. Food & function. 2017;8(12):4693-702.
  • 18. Nagao A, Kotake-Nara E, Hase M. Effects of fats and oils on the bioaccessibility of carotenoids and vitamin E in vegetables. Bioscience, biotechnology, and biochemistry. 2013;77(5):1055-60.
  • 19. Seymen S, Özcan Sinir G, Çopur Ö. Physicochemical and quality properties of pumpkin (Cucurbita Moschata Duch.) jam, marmalade and fruit leather. Philippine Agricultural Scientist. 2020;103(3).
  • 20. Thaosatien B. Development of fruit leather using Japanese pumpkin (Cucurbita maxima) and black plum (Prunus salicina) from the Royal Project. 2008.
  • 21. Minekus M, Alminger M, Alvito P, Ballance S, Bohn T, Bourlieu C, et al. A standardised static in vitro digestion method suitable for food - an international consensus. Food & Function. 2014;5(6):1113-24.
  • 22. Kamiloglu S, Capanoglu E. In vitro gastrointestinal digestion of polyphenols from different molasses (pekmez) and leather (pestil) varieties. International Journal of Food Science and Technology. 2014;49(4):1027-39.
  • 23. Obanda M, Owuor PO, Taylor SJ. Flavanol composition and caffeine content of green leaf as quality potential indicators of Kenyan black teas. Journal of the Science of Food and Agriculture. 1997;74(2):209-15.
  • 24. Katalinic V, Milos M, Kulisic T, Jukic M. Screening of 70 medicinal plant extracts for antioxidant capacity and total phenols. Food Chemistry. 2006;94(4):550-7.
  • 25. Apak R, Guclu K, Ozyurek M, Celik SE. Mechanism of antioxidant capacity assays and the CUPRAC (cupric ion reducing antioxidant capacity) assay. Microchimica Acta. 2008;160(4):413-9.
  • 26. Benzie IFF, Strain JJ. The ferric reducing ability of plasma (FRAP) as a measure of ''antioxidant power'': The FRAP assay. Analytical Biochemistry. 1996;239(1):70-6.
  • 27. Barba AIO, Hurtado MC, Mata MCS, Ruiz VF, de Tejada MLS. Application of a UV-vis detection-HPLC method for a rapid determination of lycopene and beta-carotene in vegetables. Food Chemistry. 2006;95(2):328-36.
  • 28. Rufian-Henares JA, Delgado-Andrade C. Effect of digestive process on Maillard reaction indexes and antioxidant properties of breakfast cereals. Food Research International. 2009;42(3):394-400.
  • 29. Maskan M. Drying, shrinkage and rehydration characteristics of kiwifruits during hot air and microwave drying. Journal of Food Engineering. 2001;48(2):177-82.
  • 30. Dadali G, Demirhan E, Ozbek B. Color change kinetics of spinach undergoing microwave drying. Drying Technology. 2007;25(10):1713-23.
  • 31. Swain S, Samuel DVK, Bal LM, Kar A. Thermal kinetics of colour degradation of yellow sweet pepper (Capsicum annum L.) undergoing microwave assisted convective drying. International Journal of Food Properties. 2014;17(9):1946-64.
  • 32. Stewart AJ, Bozonnet S, Mullen W, Jenkins GI, Lean MEJ, Crozier A. Occurrence of flavonols in tomatoes and tomato-based products. Journal of Agricultural and Food Chemistry. 2000;48(7):2663-9.
  • 33. Ozcan MM, Al Juhaimi F, Ahmed IAM, Uslu N, Babiker EE, Ghafoor K. Effect of microwave and oven drying processes on antioxidant activity, total phenol and phenolic compounds of kiwi and pepino fruits. Journal of Food Science and Technology-Mysore. 2020;57(1):233-42.
  • 34. Szychowski PJ, Lech K, Sendra-Nadal E, Hernandez F, Figiel A, Wojdylo A, et al. Kinetics, biocompounds, antioxidant activity, and sensory attributes of quinces as affected by drying method. Food Chemistry. 2018;255:157-64.
  • 35. Arslan D, Ozcan MM. Study the effect of sun, oven and microwave drying on quality of onion slices. Lwt-Food Science and Technology. 2010;43(7):1121-7.
  • 36. Ghanem N, Mihoubi D, Kechaou N, Mihoubi NB. Microwave dehydration of three citrus peel cultivars: Effect on water and oil retention capacities, color, shrinkage and total phenols content. Industrial Crops and Products. 2012;40:167-77.
  • 37. Hamrouni-Sellami I, Rahali FZ, Rebey IB, Bourgou S, Limam F, Marzouk B. Total Phenolics, Flavonoids, and Antioxidant Activity of Sage (Salvia officinalis L.) Plants as Affected by Different Drying Methods. Food and Bioprocess Technology. 2013;6(3):806-17.
  • 38. Que F, Mao LC, Fang XH, Wu T. Comparison of hot air-drying and freeze-drying on the physicochemical properties and antioxidant activities of pumpkin (Cucurbita moschata Duch.) flours. International Journal of Food Science and Technology. 2008;43(7):1195-201.
  • 39. Wootton-Beard PC, Moran A, Ryan L. Stability of the total antioxidant capacity and total polyphenol content of 23 commercially available vegetable juices before and after in vitro digestion measured by FRAP, DPPH, ABTS and Folin-Ciocalteu methods. Food Research International. 2011;44 (1):217-24.
  • 40. Kamiloglu S, Pasli AA, Ozcelik B, Capanoglu E. Evaluating the in vitro bioaccessibility of phenolics and antioxidant activity during consumption of dried fruits with nuts. Lwt-Food Science and Technology. 2014;56(2):284-9.
  • 41. Özdemirli N, Beştepe SK. Kavun çekirdeği şerbetinde (sübye) fenolik bileşiklerin biyoerişilebilirliğinin değerlendirilmesi. Gıda. 2022;47(6):1130-9.
  • 42. Bouayed J, Hoffmann L, Bohn T. Total phenolics, flavonoids, anthocyanins and antioxidant activity following simulated gastro-intestinal digestion and dialysis of apple varieties: Bioaccessibility and potential uptake. Food Chemistry. 2011;128(1):14-21.
  • 43. Kamiloglu S. Taze ve dondurulmuş elmalarda ve elma posasinda polifenol biyoerişilebilirliğinin değerlendirilmesi. Gıda. 2019;44(3):409-18.
  • 44. Dewanto V, Wu XZ, Liu RH. Processed sweet corn has higher antioxidant activity. Journal of Agricultural and Food Chemistry. 2002;50(17):4959-64.
  • 45. Kayacan S, Karasu S, Akman PK, Goktas H, Doymaz I, Sagdic O. Effect of different drying methods on total bioactive compounds, phenolic profile, in vitro bioaccessibility of phenolic and HMF formation of persimmon. Lwt-Food Science and Technology. 2020;118.
  • 46. Karabacak AO, Tunckal C, Tamer CE, Copur OU, Omeroglu PY. Bioacesibility of total phenolics and antioxidant activity of melon slices dried in a heat pump drying system. Journal of Food Measurement and Characterization. 2022;16(3):2154-71.
  • 47. Kamiloglu S, Ozkan G, Isik H, Horoz O, Van Camp J, Capanoglu E. Black carrot pomace as a source of polyphenols for enhancing the nutritional value of cake: An in vitro digestion study with a standardized static model. LWT. 2017;77:475-81.
  • 48. Capanoglu E, Kamiloglu S, Ozkan G, Apak R. Evaluation of antioxidant activity/capacity measurement methods for food products. Measurement of Antioxidant Activity & Capacity: Recent Trends and Applications. 2018:273-86.
  • 49. Capanoglu E, Kamiloglu S, Demirci Cekic S, Sozgen Baskan K, Avan AN, Uzunboy S, et al. Antioxidant activity and capacity measurement. Plant Antioxidants and Health. 2020:1-66.
  • 50. Nicoli MC, Anese M, Parpinel M. Influence of processing on the antioxidant properties of fruit and vegetables. Trends in Food Science & Technology. 1999;10(3):94-100.
  • 51. Al-Farsi M, Alasalvar C, Morris A, Baron M, Shahidi F. Comparison of antioxidant activity, anthocyanins, carotenoids, and phenolics of three native fresh and sun-dried date (Phoenix dactylifera L.) varieties grown in Oman. Journal of Agricultural and Food Chemistry. 2005;53(19):7592-9.
  • 52. Chang CH, Lin HY, Chang CY, Liu YC. Comparisons on the antioxidant properties of fresh, freeze-dried and hot-air-dried tomatoes. Journal of Food Engineering. 2006;77(3):478-85.
  • 53. Karabacak AO. Effects of different drying methods on drying characteristics, colour and in-vitro bioaccessibility of phenolics and antioxidant capacity of blackthorn pestil (leather). Heat and Mass Transfer. 2019;55(10):2739-50.
  • 54. Di Scala K, Vega-Galvez A, Uribe E, Oyanadel R, Miranda M, Vergara J, et al. Changes of quality characteristics of pepino fruit (Solanum muricatum Ait) during convective drying. International Journal of Food Science and Technology. 2011;46(4):746-53.
  • 55. Samoticha J, Wojdylo A, Lech K. The influence of different the drying methods on chemical composition and antioxidant activity in chokeberries. Lwt-Food Science and Technology. 2016;66:484-9.
  • 56. Devahastin S, Niamnuy C. Modelling quality changes of fruits and vegetables during drying: A review. International Journal of Food Science and Technology. 2010;45(9):1755-67.
  • 57. Benlloch-Tinoco M, Igual M, Rodrigo D, Martinez-Navarrete N. Comparison of microwaves and conventional thermal treatment on enzymes activity and antioxidant capacity of kiwifruit puree. Innovative Food Science & Emerging Technologies. 2013;19:166-72.
  • 58. Aly E, Sanchez-Moya T, Darwish AA, Ros-Berruezo G, Lopez-Nicolas R. In vitro digestion effect on CCK and GLP-1 release and antioxidant capacity of some plant-based milk substitutes. Journal of Food Science. 2022;87(5):1999-2008.
  • 59. Tagliazucchi D, Verzelloni E, Bertolini D, Conte A. In vitro bio-accessibility and antioxidant activity of grape polyphenols. Food Chemistry. 2010;120(2):599-606.
  • 60. Hernández-Ortega M, Kissangou G, Necoechea-Mondragón H, Sánchez-Pardo ME, Ortiz-Moreno A. Microwave dried carrot pomace as a source of fiber and carotenoids. 2013.
  • 61. Divya P, Puthusseri B, Neelwarne B. Carotenoid content, its stability during drying and the antioxidant activity of commercial coriander (Coriandrum sativum L.) varieties. Food Research International. 2012;45(1):342-50.
  • 62. Zhang ZY, Wei QY, Nie MM, Jiang N, Liu CJ, Liu CQ, et al. Microstructure and bioaccessibility of different carotenoid species as affected by hot air drying: Study on carrot, sweet potato, yellow bell pepper and broccoli. Lwt-Food Science and Technology. 2018;96:357-63.
  • 63. Rojas ML, Silveira I, Augusto PED. Ultrasound and ethanol pre-treatments to improve convective drying: Drying, rehydration and carotenoid content of pumpkin. Food and Bioproducts Processing. 2020;119:20-30.
  • 64. Lyu Y, Bi JF, Chen QQ, Wu XY, Qiao YN, Hou HN, et al. Bioaccessibility of carotenoids and antioxidant capacity of seed-used pumpkin byproducts powders as affected by particle size and corn oil during in vitro digestion process. Food Chemistry. 2021;343.
  • 65. Zhao Y, Yang QS, Zhou Q, Lu ZM, Fan RY, editors. Stability of Carotenoids in Russula alutacea Fr. Extraction. Advanced Materials Research; 2014: Trans Tech Publ.
  • 66. Veda S, Platel K, Srinivasan K. Enhanced bioaccessibility of beta-carotene from yellow-orange vegetables and green leafy vegetables by domestic heat processing. International Journal of Food Science and Technology. 2010;45(10):2201-7.
  • 67. Ribeiro EMG, Chitchumroonchokchai C, de Carvalho LMJ, de Moura FF, de Carvalho JLV, Failla ML. Effect of style of home cooking on retention and bioaccessibility of pro-vitamin A carotenoids in biofortified pumpkin (Cucurbita moschata Duch.). Food Research International. 2015;77:620-6.
  • 68. Elif K, Ömeroğlu PY. Geleneksel anjelika (melek otu) reçelinin fizikokimyasal ve duyusal özellikleri. Akademik Gıda. 2019;17(4):485-96.
  • 69. TSE. Turkish Standards Institute, Grape pestil, TS12680. Ankara, Turkey 2000.
  • 70. Kanar Y, Mazi BG. HMF formation, diastase activity and proline content changes in bee pollen dried by different drying methods. Lwt-Food Science and Technology. 2019;113.
  • 71. Turkiewicz IP, Wojdyło A, Lech K, Tkacz K, Nowicka P. Influence of different drying methods on the quality of Japanese quince fruit. LWT. 2019;114:108416.
  • 72. Wang SY, Bi YX, Zhou ZD, Peng WJ, Tian WL, Wang H, et al. Effects of pulsed vacuum drying temperature on drying kinetics, physicochemical properties and microstructure of bee pollen. Lwt-Food Science and Technology. 2022;169.
  • 73. Hou LX, Ling B, Wang SJ. Kinetics of color degradation of chestnut kernel during thermal treatment and storage. International Journal of Agricultural and Biological Engineering. 2015;8(4):106-15.
  • 74. Weemaes CA, Ooms V, Van Loey AM, Hendrickx ME. Kinetics of chlorophyll degradation and color loss in heated broccoli juice. Journal of Agricultural and Food Chemistry. 1999;47(6):2404-9.
  • 75. Lopez A, Pique MT, Boatella J, Romero A, Ferran A, Garcia J. Influence of drying conditions on the hazelnut quality .3. Browning. Drying Technology. 1997;15(3-4):989-1002.
  • 76. Uyan SE, Baysal T, Yurdagel O, El SN. Effects of drying process on antioxidant activity of purple carrots. Nahrung-Food. 2004;48(1):57-60.
  • 77. Chen BH, Peng HY, Chen HE. Changes of carotenoids, color, and vitamin-a contents during processing of carrot juice. Journal of Agricultural and Food Chemistry. 1995;43(7):1912-8.
  • 78. Jaiswal AK, Abu-Ghannam N. Degradation kinetic modelling of color, texture, polyphenols and antioxidant capacity of York cabbage after microwave processing. Food Research International. 2013;53(1):125-33.

Assessment of Total Phenolic Compounds, Antioxidant Capacity, β-Carotene Bioaccessibility, HMF Formation, and Color Degradation Kinetics in Pumpkin Pestils

Year 2023, Volume: 10 Issue: 3, 729 - 744, 30.08.2023
https://doi.org/10.18596/jotcsa.1302567

Abstract

Pestil, often known as fruit leather, is one of the most significant traditional foods manufactured and consumed throughout Türkiye. Due to its practical consumption, the availability of numerous nutrients, and the ability to meet energy requirements, pestil is recognized as a snack food. The aim of this study was to evaluate the bioaccessibility of total phenolic compounds (TPC), antioxidant capacity (AOC), and β-carotene in pumpkin pestils dried by hot air drying (HAD), vacuum drying (VCD), and microwave drying (MD) methods using an in vitro digestion model. Additionally, 5-hydroxymethylfurfural (HMF) formation and color degradation of pestils were evaluated. Changes in TPC and AOC were determined using spectrophotometric methods, whereas the detections of β-carotene and HMF were carried out with high performance liquid chromatography–photodiode array detector (HPLC–PDA). Significantly higher TPC (10.99–105.70%) and AOC (15.30–118.58%, 21.88–401.04% and 89.28–482.14%, in CUPRAC, FRAP, and DPPH assays, respectively) values were observed after drying (p<0.05). Moreover, it was observed that there were statistically significant increases in TPC and AOC values after digestion for all pumpkin pestils compared to undigested samples (p<0.05). Drying process resulted in lower β-carotene content (between 32.15–61.11%) in pumpkin pestils; however, it increased the percentage of bioaccessible β-carotene (max 62.16%) in the pestil samples. Compared to HD and VCD techniques, pumpkin pestils dried with MD exhibited significantly higher TPC, AOC and β-carotene content (p<0.05). All of the pumpkin pestils except those dried by MD at 180 W contain HMF below the Turkish Standards Institute legal limit of 50 mg/kg. L* value of pestils were described adequately to the zero- and first-order kinetic models while a* and b* values were only fitted to zero-order model. In conclusion, the findings obtained in this study pointed out that drying processes (especially by MD method) increased the bioaccessibility of TPC, AOC, and β-carotene.

References

  • 1. Seremet L, Botez E, Nistor OV, Andronoiu DG, Mocanu GD. Effect of different drying methods on moisture ratio and rehydration of pumpkin slices. Food Chemistry. 2016;195:104-9.
  • 2. FAO. FAO Stat Crops and livestock product 2023 [Available from: <URL>.
  • 3. Guine RPP, Pinho S, Barroca MJ. Study of the convective drying of pumpkin (Cucurbita maxima). Food and Bioproducts Processing. 2011;89(C4):422-8.
  • 4. Yang ZH, Amrit BK, Zhao WR, Shi LH, Wu HJ, Barrow C, et al. Bioaccessibility and bioavailability changes of phenolic compounds in pumpkins (Cucurbita moschata): A review. Food Bioscience. 2022;47.
  • 5. Özdemirli N, Kamiloğlu S. Dondurma işleminin mandalina polifenollerinin biyoerişilebilirliği üzerine etkisi. Gıda ve Yem Bilimi Teknolojisi Dergisi. 2023(30):10-21.
  • 6. Zhang M, Tang J, Mujumdar AS, Wang S. Trends in microwave-related drying of fruits and vegetables. Trends in Food Science & Technology. 2006;17(10):524-34. Avaliable from: <URL>.
  • 7. Bandaru H, Bakshi M. Fruit Leather: Preparation, packaging and its effect on sensorial and physico-chemical properties: A review. Journal of Pharmacognosy and Phytochemistry. 2020;9(6):1699-709.
  • 8. Nizamlioglu NM, Yasar S, Bulut Y. Chemical versus infrared spectroscopic measurements of quality attributes of sun or oven dried fruit leathers from apple, plum and apple-plum mixture. Lwt-Food Science and Technology. 2022;153.
  • 9. Tontul I, Topuz A. Effects of different drying methods on the physicochemical properties of pomegranate leather (pestil). Lwt-Food Science and Technology. 2017;80:294-303.
  • 10. Arevalo-Pinedo A, Murr FEX. Kinetics of vacuum drying of pumpkin (Cucurbita maxima): Modeling with shrinkage. Journal of Food Engineering. 2006;76(4):562-7.
  • 11. Horuz E, Bozkurt H, Karatas H, Maskan M. Effects of hybrid (microwave-convectional) and convectional drying on drying kinetics, total phenolics, antioxidant capacity, vitamin C, color and rehydration capacity of sour cherries. Food Chemistry. 2017;230:295-305.
  • 12. Karabacak AO, Suna S, Dorak S, Copur OU. Drying characteristics, mineral content, texture and sensorial properties of pumpkin fruit leather. Latin American Applied Research. 2021;51(3):193-201.
  • 13. Koh S, Loh S. In vitro bioaccessibility of β-carotene in pumpkin and butternut squash subjected to different cooking methods. International Food Research Journal. 2018;25(1):188-95.
  • 14. Lencina MS, dos Santos Ferreira C, Archaina D, Gómez MB, Mazzobre MF. Stability and bioaccessibility of iron in pumpkin discs vacuum impregnated with ferrous gluconate, β-cyclodextrin and ascorbic acid. LWT. 2022;161:113342.
  • 15. Bergantin C, Maietti A, Tedeschi P, Font G, Manyes L, Marchetti N. HPLC-UV/Vis-APCI-MS/MS determination of major carotenoids and their bioaccessibility from “Delica”(Cucurbita maxima) and “Violina”(Cucurbita moschata) pumpkins as food traceability markers. Molecules. 2018;23(11):2791.
  • 16. Aydin E. Evaluation of phenolic acid, total phenolic content, antioxidant capacity and in-vitro simulated bioaccessibility of healthy snack: Aromatized pumpkin chips. Emirates Journal of Food and Agriculture. 2022.
  • 17. Zhang Z, Wang X, Li Y, Wei Q, Liu C, Nie M, et al. Evaluation of the impact of food matrix change on the in vitro bioaccessibility of carotenoids in pumpkin (Cucurbita moschata) slices during two drying processes. Food & function. 2017;8(12):4693-702.
  • 18. Nagao A, Kotake-Nara E, Hase M. Effects of fats and oils on the bioaccessibility of carotenoids and vitamin E in vegetables. Bioscience, biotechnology, and biochemistry. 2013;77(5):1055-60.
  • 19. Seymen S, Özcan Sinir G, Çopur Ö. Physicochemical and quality properties of pumpkin (Cucurbita Moschata Duch.) jam, marmalade and fruit leather. Philippine Agricultural Scientist. 2020;103(3).
  • 20. Thaosatien B. Development of fruit leather using Japanese pumpkin (Cucurbita maxima) and black plum (Prunus salicina) from the Royal Project. 2008.
  • 21. Minekus M, Alminger M, Alvito P, Ballance S, Bohn T, Bourlieu C, et al. A standardised static in vitro digestion method suitable for food - an international consensus. Food & Function. 2014;5(6):1113-24.
  • 22. Kamiloglu S, Capanoglu E. In vitro gastrointestinal digestion of polyphenols from different molasses (pekmez) and leather (pestil) varieties. International Journal of Food Science and Technology. 2014;49(4):1027-39.
  • 23. Obanda M, Owuor PO, Taylor SJ. Flavanol composition and caffeine content of green leaf as quality potential indicators of Kenyan black teas. Journal of the Science of Food and Agriculture. 1997;74(2):209-15.
  • 24. Katalinic V, Milos M, Kulisic T, Jukic M. Screening of 70 medicinal plant extracts for antioxidant capacity and total phenols. Food Chemistry. 2006;94(4):550-7.
  • 25. Apak R, Guclu K, Ozyurek M, Celik SE. Mechanism of antioxidant capacity assays and the CUPRAC (cupric ion reducing antioxidant capacity) assay. Microchimica Acta. 2008;160(4):413-9.
  • 26. Benzie IFF, Strain JJ. The ferric reducing ability of plasma (FRAP) as a measure of ''antioxidant power'': The FRAP assay. Analytical Biochemistry. 1996;239(1):70-6.
  • 27. Barba AIO, Hurtado MC, Mata MCS, Ruiz VF, de Tejada MLS. Application of a UV-vis detection-HPLC method for a rapid determination of lycopene and beta-carotene in vegetables. Food Chemistry. 2006;95(2):328-36.
  • 28. Rufian-Henares JA, Delgado-Andrade C. Effect of digestive process on Maillard reaction indexes and antioxidant properties of breakfast cereals. Food Research International. 2009;42(3):394-400.
  • 29. Maskan M. Drying, shrinkage and rehydration characteristics of kiwifruits during hot air and microwave drying. Journal of Food Engineering. 2001;48(2):177-82.
  • 30. Dadali G, Demirhan E, Ozbek B. Color change kinetics of spinach undergoing microwave drying. Drying Technology. 2007;25(10):1713-23.
  • 31. Swain S, Samuel DVK, Bal LM, Kar A. Thermal kinetics of colour degradation of yellow sweet pepper (Capsicum annum L.) undergoing microwave assisted convective drying. International Journal of Food Properties. 2014;17(9):1946-64.
  • 32. Stewart AJ, Bozonnet S, Mullen W, Jenkins GI, Lean MEJ, Crozier A. Occurrence of flavonols in tomatoes and tomato-based products. Journal of Agricultural and Food Chemistry. 2000;48(7):2663-9.
  • 33. Ozcan MM, Al Juhaimi F, Ahmed IAM, Uslu N, Babiker EE, Ghafoor K. Effect of microwave and oven drying processes on antioxidant activity, total phenol and phenolic compounds of kiwi and pepino fruits. Journal of Food Science and Technology-Mysore. 2020;57(1):233-42.
  • 34. Szychowski PJ, Lech K, Sendra-Nadal E, Hernandez F, Figiel A, Wojdylo A, et al. Kinetics, biocompounds, antioxidant activity, and sensory attributes of quinces as affected by drying method. Food Chemistry. 2018;255:157-64.
  • 35. Arslan D, Ozcan MM. Study the effect of sun, oven and microwave drying on quality of onion slices. Lwt-Food Science and Technology. 2010;43(7):1121-7.
  • 36. Ghanem N, Mihoubi D, Kechaou N, Mihoubi NB. Microwave dehydration of three citrus peel cultivars: Effect on water and oil retention capacities, color, shrinkage and total phenols content. Industrial Crops and Products. 2012;40:167-77.
  • 37. Hamrouni-Sellami I, Rahali FZ, Rebey IB, Bourgou S, Limam F, Marzouk B. Total Phenolics, Flavonoids, and Antioxidant Activity of Sage (Salvia officinalis L.) Plants as Affected by Different Drying Methods. Food and Bioprocess Technology. 2013;6(3):806-17.
  • 38. Que F, Mao LC, Fang XH, Wu T. Comparison of hot air-drying and freeze-drying on the physicochemical properties and antioxidant activities of pumpkin (Cucurbita moschata Duch.) flours. International Journal of Food Science and Technology. 2008;43(7):1195-201.
  • 39. Wootton-Beard PC, Moran A, Ryan L. Stability of the total antioxidant capacity and total polyphenol content of 23 commercially available vegetable juices before and after in vitro digestion measured by FRAP, DPPH, ABTS and Folin-Ciocalteu methods. Food Research International. 2011;44 (1):217-24.
  • 40. Kamiloglu S, Pasli AA, Ozcelik B, Capanoglu E. Evaluating the in vitro bioaccessibility of phenolics and antioxidant activity during consumption of dried fruits with nuts. Lwt-Food Science and Technology. 2014;56(2):284-9.
  • 41. Özdemirli N, Beştepe SK. Kavun çekirdeği şerbetinde (sübye) fenolik bileşiklerin biyoerişilebilirliğinin değerlendirilmesi. Gıda. 2022;47(6):1130-9.
  • 42. Bouayed J, Hoffmann L, Bohn T. Total phenolics, flavonoids, anthocyanins and antioxidant activity following simulated gastro-intestinal digestion and dialysis of apple varieties: Bioaccessibility and potential uptake. Food Chemistry. 2011;128(1):14-21.
  • 43. Kamiloglu S. Taze ve dondurulmuş elmalarda ve elma posasinda polifenol biyoerişilebilirliğinin değerlendirilmesi. Gıda. 2019;44(3):409-18.
  • 44. Dewanto V, Wu XZ, Liu RH. Processed sweet corn has higher antioxidant activity. Journal of Agricultural and Food Chemistry. 2002;50(17):4959-64.
  • 45. Kayacan S, Karasu S, Akman PK, Goktas H, Doymaz I, Sagdic O. Effect of different drying methods on total bioactive compounds, phenolic profile, in vitro bioaccessibility of phenolic and HMF formation of persimmon. Lwt-Food Science and Technology. 2020;118.
  • 46. Karabacak AO, Tunckal C, Tamer CE, Copur OU, Omeroglu PY. Bioacesibility of total phenolics and antioxidant activity of melon slices dried in a heat pump drying system. Journal of Food Measurement and Characterization. 2022;16(3):2154-71.
  • 47. Kamiloglu S, Ozkan G, Isik H, Horoz O, Van Camp J, Capanoglu E. Black carrot pomace as a source of polyphenols for enhancing the nutritional value of cake: An in vitro digestion study with a standardized static model. LWT. 2017;77:475-81.
  • 48. Capanoglu E, Kamiloglu S, Ozkan G, Apak R. Evaluation of antioxidant activity/capacity measurement methods for food products. Measurement of Antioxidant Activity & Capacity: Recent Trends and Applications. 2018:273-86.
  • 49. Capanoglu E, Kamiloglu S, Demirci Cekic S, Sozgen Baskan K, Avan AN, Uzunboy S, et al. Antioxidant activity and capacity measurement. Plant Antioxidants and Health. 2020:1-66.
  • 50. Nicoli MC, Anese M, Parpinel M. Influence of processing on the antioxidant properties of fruit and vegetables. Trends in Food Science & Technology. 1999;10(3):94-100.
  • 51. Al-Farsi M, Alasalvar C, Morris A, Baron M, Shahidi F. Comparison of antioxidant activity, anthocyanins, carotenoids, and phenolics of three native fresh and sun-dried date (Phoenix dactylifera L.) varieties grown in Oman. Journal of Agricultural and Food Chemistry. 2005;53(19):7592-9.
  • 52. Chang CH, Lin HY, Chang CY, Liu YC. Comparisons on the antioxidant properties of fresh, freeze-dried and hot-air-dried tomatoes. Journal of Food Engineering. 2006;77(3):478-85.
  • 53. Karabacak AO. Effects of different drying methods on drying characteristics, colour and in-vitro bioaccessibility of phenolics and antioxidant capacity of blackthorn pestil (leather). Heat and Mass Transfer. 2019;55(10):2739-50.
  • 54. Di Scala K, Vega-Galvez A, Uribe E, Oyanadel R, Miranda M, Vergara J, et al. Changes of quality characteristics of pepino fruit (Solanum muricatum Ait) during convective drying. International Journal of Food Science and Technology. 2011;46(4):746-53.
  • 55. Samoticha J, Wojdylo A, Lech K. The influence of different the drying methods on chemical composition and antioxidant activity in chokeberries. Lwt-Food Science and Technology. 2016;66:484-9.
  • 56. Devahastin S, Niamnuy C. Modelling quality changes of fruits and vegetables during drying: A review. International Journal of Food Science and Technology. 2010;45(9):1755-67.
  • 57. Benlloch-Tinoco M, Igual M, Rodrigo D, Martinez-Navarrete N. Comparison of microwaves and conventional thermal treatment on enzymes activity and antioxidant capacity of kiwifruit puree. Innovative Food Science & Emerging Technologies. 2013;19:166-72.
  • 58. Aly E, Sanchez-Moya T, Darwish AA, Ros-Berruezo G, Lopez-Nicolas R. In vitro digestion effect on CCK and GLP-1 release and antioxidant capacity of some plant-based milk substitutes. Journal of Food Science. 2022;87(5):1999-2008.
  • 59. Tagliazucchi D, Verzelloni E, Bertolini D, Conte A. In vitro bio-accessibility and antioxidant activity of grape polyphenols. Food Chemistry. 2010;120(2):599-606.
  • 60. Hernández-Ortega M, Kissangou G, Necoechea-Mondragón H, Sánchez-Pardo ME, Ortiz-Moreno A. Microwave dried carrot pomace as a source of fiber and carotenoids. 2013.
  • 61. Divya P, Puthusseri B, Neelwarne B. Carotenoid content, its stability during drying and the antioxidant activity of commercial coriander (Coriandrum sativum L.) varieties. Food Research International. 2012;45(1):342-50.
  • 62. Zhang ZY, Wei QY, Nie MM, Jiang N, Liu CJ, Liu CQ, et al. Microstructure and bioaccessibility of different carotenoid species as affected by hot air drying: Study on carrot, sweet potato, yellow bell pepper and broccoli. Lwt-Food Science and Technology. 2018;96:357-63.
  • 63. Rojas ML, Silveira I, Augusto PED. Ultrasound and ethanol pre-treatments to improve convective drying: Drying, rehydration and carotenoid content of pumpkin. Food and Bioproducts Processing. 2020;119:20-30.
  • 64. Lyu Y, Bi JF, Chen QQ, Wu XY, Qiao YN, Hou HN, et al. Bioaccessibility of carotenoids and antioxidant capacity of seed-used pumpkin byproducts powders as affected by particle size and corn oil during in vitro digestion process. Food Chemistry. 2021;343.
  • 65. Zhao Y, Yang QS, Zhou Q, Lu ZM, Fan RY, editors. Stability of Carotenoids in Russula alutacea Fr. Extraction. Advanced Materials Research; 2014: Trans Tech Publ.
  • 66. Veda S, Platel K, Srinivasan K. Enhanced bioaccessibility of beta-carotene from yellow-orange vegetables and green leafy vegetables by domestic heat processing. International Journal of Food Science and Technology. 2010;45(10):2201-7.
  • 67. Ribeiro EMG, Chitchumroonchokchai C, de Carvalho LMJ, de Moura FF, de Carvalho JLV, Failla ML. Effect of style of home cooking on retention and bioaccessibility of pro-vitamin A carotenoids in biofortified pumpkin (Cucurbita moschata Duch.). Food Research International. 2015;77:620-6.
  • 68. Elif K, Ömeroğlu PY. Geleneksel anjelika (melek otu) reçelinin fizikokimyasal ve duyusal özellikleri. Akademik Gıda. 2019;17(4):485-96.
  • 69. TSE. Turkish Standards Institute, Grape pestil, TS12680. Ankara, Turkey 2000.
  • 70. Kanar Y, Mazi BG. HMF formation, diastase activity and proline content changes in bee pollen dried by different drying methods. Lwt-Food Science and Technology. 2019;113.
  • 71. Turkiewicz IP, Wojdyło A, Lech K, Tkacz K, Nowicka P. Influence of different drying methods on the quality of Japanese quince fruit. LWT. 2019;114:108416.
  • 72. Wang SY, Bi YX, Zhou ZD, Peng WJ, Tian WL, Wang H, et al. Effects of pulsed vacuum drying temperature on drying kinetics, physicochemical properties and microstructure of bee pollen. Lwt-Food Science and Technology. 2022;169.
  • 73. Hou LX, Ling B, Wang SJ. Kinetics of color degradation of chestnut kernel during thermal treatment and storage. International Journal of Agricultural and Biological Engineering. 2015;8(4):106-15.
  • 74. Weemaes CA, Ooms V, Van Loey AM, Hendrickx ME. Kinetics of chlorophyll degradation and color loss in heated broccoli juice. Journal of Agricultural and Food Chemistry. 1999;47(6):2404-9.
  • 75. Lopez A, Pique MT, Boatella J, Romero A, Ferran A, Garcia J. Influence of drying conditions on the hazelnut quality .3. Browning. Drying Technology. 1997;15(3-4):989-1002.
  • 76. Uyan SE, Baysal T, Yurdagel O, El SN. Effects of drying process on antioxidant activity of purple carrots. Nahrung-Food. 2004;48(1):57-60.
  • 77. Chen BH, Peng HY, Chen HE. Changes of carotenoids, color, and vitamin-a contents during processing of carrot juice. Journal of Agricultural and Food Chemistry. 1995;43(7):1912-8.
  • 78. Jaiswal AK, Abu-Ghannam N. Degradation kinetic modelling of color, texture, polyphenols and antioxidant capacity of York cabbage after microwave processing. Food Research International. 2013;53(1):125-33.
There are 78 citations in total.

Details

Primary Language English
Subjects Analytical Chemistry, Instrumental Methods
Journal Section RESEARCH ARTICLES
Authors

Azime Özkan Karabacak 0000-0003-4175-4477

Publication Date August 30, 2023
Submission Date May 25, 2023
Acceptance Date June 26, 2023
Published in Issue Year 2023 Volume: 10 Issue: 3

Cite

Vancouver Özkan Karabacak A. Assessment of Total Phenolic Compounds, Antioxidant Capacity, β-Carotene Bioaccessibility, HMF Formation, and Color Degradation Kinetics in Pumpkin Pestils. JOTCSA. 2023;10(3):729-44.