Evaluation of antioxidant capacity and bioactive compounds in Capsicum annum L. red peppers following drying in a polycarbonate greenhouse

1 Sikora, B.; Nowaczyk, P. Application of rapd technique for identification of interspecific hybrids from genus Capsicum. Acta Scientiarum Polonorum-Hortorum Cultus 2014, 13, 155-166. Search in Google Scholar

2 Pino, J.; González, M.; Ceballos, L.; Centurión-Yah, A.R.; Trujillo-Aguirre, J.; Latournerie-Moreno, L.; Sauri-Duch, E. Characterization of total capsaicinoids, colour and volatile compounds of Habanero chilli pepper (Capsicum chinense Jack.) cultivars grown in Yucatan. Food Chemistry 2007, 104, 1682-1686. Search in Google Scholar

3 Srinivasan, V.; Dinesh, R.; Hamza, S.; Parthasarathy, V. Nutrient management in black pepper (Piper nigrum L.). CABI Reviews 2008, 14 pp. Search in Google Scholar

4 Wahyuni, Y.; Ballester, A.-R.; Sudarmonowati, E.; Bino, R.J.; Bovy, A.G. Secondary metabolites of Capsicum species and their importance in the human diet. Journal of natural products 2013, 76, 783-793. Search in Google Scholar

5 Sanatombi, K.; Rajkumari, S. Effect of processing on quality of pepper: A review. Food Reviews International 2020, 36, 626-643. Search in Google Scholar

6 Di Scala, K.; Vega-Gálvez, A.; Uribe, E.; Oyanadel, R.; Miranda, M.; Vergara, J.; Quispe, I.; Lemus-Mondaca, R. Changes of quality characteristics of pepino fruit (Solanum muricatum Ait) during convective drying. International Journal of Food Science & Technology 2011, 46, 746-753. Search in Google Scholar

7 Turkmen, F.; Karasu, S.; Karadag, A. Effects of different drying methods and temperature on the drying behavior and quality attributes of cherry laurel fruit. Processes 2020, 8, 761. Search in Google Scholar

8 Kaewkiew, J.; Nabnean, S.; Janjai, S. Experimental investigation of the performance of a large-scale greenhouse type solar dryer for drying chilli in Thailand. Procedia Engineering 2012, 32, 433-439. Search in Google Scholar

9 Sahdev, R.K.; Kumar, M.; Dhingra, A.K. A review on applications of greenhouse drying and its performance. Agricultural Engineering International: CIGR Journal 2016, 18, 395-412. Search in Google Scholar

10 Baenas, N.; Belović, M.; Ilic, N.; Moreno, D.A.; García-Viguera, C. Industrial use of pepper (Capsicum annum L.) derived products: Technological benefits and biological advantages. Food chemistry 2019, 274, 872-885. Search in Google Scholar

11 Bogusz Jr, S.; Libardi, S.H.; Dias, F.F.; Coutinho, J.P.; Bochi, V.C.; Rodrigues, D.; Melo, A.M.; Godoy, H.T. Brazilian Capsicum peppers: Capsaicinoid content and antioxidant activity. Journal of the science of food and agriculture 2018, 98, 217-224. Search in Google Scholar

12 Juturu, V. Capsaicinoids modulating cardiometabolic syndrome risk factors: current perspectives. Journal of Nutrition and Metabolism 2016, 2016. Search in Google Scholar

13 Kumar Giri, T.; Alexander, A.; Kumar Barman, T.; Maity, S. Infringement of the Barriers of Cancer Via Dietary Phytoconstituents Capsaicin Through Novel Drug Delivery System. Current Drug Delivery 2016, 13, 27-39. Search in Google Scholar

14 Carcel, J.A.; Castillo, D.; Simal, S.; Mulet, A. Influence of temperature and ultrasound on drying kinetics and antioxidant properties of red pepper. Drying Technology 2019, 37, 486-493. Search in Google Scholar

15 Souza, C.S.; Daood, H.G.; Duah, S.A.; Vinogradov, S.; Palotás, G.; Neményi, A.; Helyes, L.; Pék, Z. Stability of carotenoids, carotenoid esters, tocopherols and capsaicinoids in new chili pepper hybrids during natural and thermal drying. LWT 2022, 113520. Search in Google Scholar

16 Kim, S.; Park, J.; Hwang, I. Composition of main carotenoids in Korean red pepper (capsicum annuum, L) and changes of pigment stability during the drying and storage process. Journal of Food Science 2004, 69, FCT39-FCT44. Search in Google Scholar

17 Topuz, A.; Dincer, C.; Özdemir, K.S.; Feng, H.; Kushad, M. Influence of different drying methods on carotenoids and capsaicinoids of paprika (Cv., Jalapeno). Food chemistry 2011, 129, 860-865. Search in Google Scholar

18 Wang, J.; Fang, X.-M.; Mujumdar, A.; Qian, J.-Y.; Zhang, Q.; Yang, X.-H.; Liu, Y.-H.; Gao, Z.-J.; Xiao, H.-W. Effect of high-humidity hot air impingement blanching (HHAIB) on drying and quality of red pepper (Capsicum annuum L.). Food Chemistry 2017, 220, 145-152. Search in Google Scholar

19 Deng, L.-Z.; Yang, X.-H.; Mujumdar, A.; Zhao, J.-H.; Wang, D.; Zhang, Q.; Wang, J.; Gao, Z.-J.; Xiao, H.-W. Red pepper (Capsicum annuum L.) drying: Effects of different drying methods on drying kinetics, physicochemical properties, antioxidant capacity, and microstructure. Drying Technology 2018, 36, 893-907. Search in Google Scholar

20 Rodríguez-Ramírez, J.; Méndez-Lagunas, L.L.; López-Ortiz, A.; Muñiz-Becerá, S.; Nair, K. Solar drying of strawberry using polycarbonate with UV protection and polyethylene covers: Influence on anthocyanin and total phenolic content. Solar Energy 2021, 221, 120-130. Search in Google Scholar

21 Waqas, M.; Ahmed, D.; Qamar, M.T. Surfactant-mediated extraction of capsaicin from Capsicum annuum L. fruit in various solvents. Heliyon 2022, 8, e10273. Search in Google Scholar

22 Zhishen, J.; Mengcheng, T.; Jianming, W. The determination of flavonoid contents in mulberry and their scavenging effects on superoxide radicals. Food chemistry 1999, 64, 555-559. Search in Google Scholar

23 Martins, G.R.; Monteiro, A.F.; do Amaral, F.R.L.; da Silva, A.S.A. A validated Folin-Ciocalteu method for total phenolics quantification of condensed tannin-rich açaí (Euterpe oleracea Mart.) seeds extract. Journal of Food Science and Technology 2021, 58, 4693-4702. Search in Google Scholar

24 Qureshi, T.M.; Amjad, A.; Nadeem, M.; Murtaza, M.A.; Munir, M. Antioxidant potential of a soft cheese (paneer) supplemented with the extracts of date (Phoenix dactylifera L.) cultivars and its whey. Asian-Australasian Journal of Animal Sciences 2019, 32, 1591. Search in Google Scholar

25 Kim, S.; Lee, K.W.; Park, J.; Lee, H.J.; Hwang, I.K. Effect of drying in antioxidant activity and changes of ascorbic acid and colour by different drying and storage in Korean red pepper (Capsicum annuum, L.). International journal of food science & technology 2006, 41, 90-95. Search in Google Scholar

26 Pochont, N.R.; Mohammad, M.N.; Pradeep, B.T.; Kumar, P.V. A comparative study of drying kinetics and quality of Indian red chilli in solar hybrid greenhouse drying and open sun drying. Materials Today: Proceedings 2020, 21, 286-290. Search in Google Scholar

27 Karunasena, H.; Hesami, P.; Senadeera, W.; Gu, Y.; Brown, R.; Oloyede, A. Scanning electron microscopic study of microstructure of gala apples during hot air drying. Drying Technology 2014, 32, 455-468. Search in Google Scholar

28 Zahoor, I.; Khan, M.A. Microwave assisted fluidized bed drying of red bell pepper: Drying kinetics and optimization of process conditions using statistical models and response surface methodology. Scientia Horticulturae 2021, 286, 110209. Search in Google Scholar

29 Özcan, M.M.; Uslu, N.; Efe, N.S.; Erdem, A.N.; Değerli, Z.; Kulluk, D.A.; Can Sağlık, N. Effect of thermal processing on the bioactive compounds and color parameters of types of three sweet pepper. Journal of Food Processing and Preservation 2021, 45, e15661. Search in Google Scholar

30 Özcan, M.M.; Uslu, N. Quantitative changes of bioactive properties and phenolic compounds in capia pepper (Capsicum annuum L.) fruits dried by the air, conventional heater, and microwave. Journal of Food Processing and Preservation 2022, e16897. Search in Google Scholar

31 Jimenez, D.; Vardanega, R.; Salinas, F.; Espinosa-Álvarez, C.; Bugueno-Munoz, W.; Palma, J.; Meireles, M.A.A.; Ruíz-Domínguez, M.C.; Cerezal-Mezquita, P. Effect of drying methods on biorefinery process to obtain capsanthin and phenolic compounds from Capsicum annuum L. The Journal of Supercritical Fluids 2021, 174, 105241. Search in Google Scholar

32 Liu, Y.; Zhang, Y.; Wei, X.; Wu, D.; Dai, J.; Liu, S.; Qin, W. Effect of radio frequency-assisted hot-air drying on drying kinetics and quality of Sichuan pepper (Zanthoxylum bungeanum maxim.). LWT 2021, 147, 111572, doi: https://doi.org/10.1016/j.lwt.2021.111572. Search in Google Scholar

33 Zhuang, Y.; Chen, L.; Sun, L.; Cao, J. Bioactive characteristics and antioxidant activities of nine peppers. Journal of Functional Foods 2012, 4, 331-338, doi: https://doi.org/10.1016/j.jff.2012.01.001. Search in Google Scholar

34 Kaur, R.; Kaur, K.; Sidhu, J.S. Drying kinetics, chemical, and bioactive compounds of yellow sweet pepper as affected by processing conditions. Journal of Food Processing and Preservation 2022, 46, e16330. Search in Google Scholar

35 Speranza, G.; Lo Scalzo, R.; Morelli, C.F.; Rabuffetti, M.; Bianchi, G. Influence of drying techniques and growing location on the chemical composition of sweet pepper (Capsicum annuum L., var. Senise). Journal of food biochemistry 2019, 43, e13031. Search in Google Scholar

36 Rybak, K.; Wiktor, A.; Kaveh, M.; Dadan, M.; Witrowa-Rajchert, D.; Nowacka, M. Effect of Thermal and Non-Thermal Technologies on Kinetics and the Main Quality Parameters of Red Bell Pepper Dried with Convective and Microwave–Convective Methods. Molecules 2022, 27, 2164. Search in Google Scholar

37 Floegel, A.; Kim, D.; Chung, S.; Koo, S.; Chun, O. comparison of ABTS/DPPH assays to measure antioxidants capacity in popular antioxidant-rich US foods. Journal of Food composition and Analysis 2011,24, 1043 - 1048. Search in Google Scholar