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http://dx.doi.org/10.9799/ksfan.2017.30.3.609

Quality Characteristics of Blackberry Powder obtained by Various Drying Methods  

Choi, So-Ra (Jeollabukdo Agricultural Research & Extension Service)
Song, Eun-Ju (Jeollabukdo Agricultural Research & Extension Service)
Song, Young-Eun (Jeollabukdo Agricultural Research & Extension Service)
Choi, Min-Kyung (Jeollabukdo Agricultural Research & Extension Service)
Han, Hyun-Ah (Jeollabukdo Agricultural Research & Extension Service)
Lee, In-Sok (Jeollabukdo Agricultural Research & Extension Service)
Shin, So-Hee (Jeollabukdo Agricultural Research & Extension Service)
Lee, Ki-Kwon (Jeollabukdo Agricultural Research & Extension Service)
Kim, Eun-Ju (Jeollabukdo Agricultural Research & Extension Service)
Publication Information
The Korean Journal of Food And Nutrition / v.30, no.3, 2017 , pp. 609-617 More about this Journal
Abstract
This experiment was carried out to enhance the availability of blackberry. Since it is difficult to use blackberry as a fresh fruit, we investigated the quality characteristics of blackberry powder obtained by various drying methods (freeze drying and hot-air drying at $40{\sim}80^{\circ}C$). The L- and b-values of freeze-dried powder was higher than hot-air dried powder. The pH (3.2) was lowest and the acidity (14.4%) was highest in freeze-dried powder. In freeze drying, the brix degree was $65.7^{\circ}Bx$, but it increased from $54.7^{\circ}Bx$ to $68.5^{\circ}Bx$ with increasing temperature during hot air drying. The total polyphenol and flavonoids contents were the highest in freeze-dried powder, at 9.3 and 6.2 mg/g, respectively. The levels increased as temperature increased in hot air drying. Anthocyanin content in freeze-dried powder was 8.51 mg/g, while it sharply decreased to 1.17~2.45 mg/g in hot-air drying. Vitamin C content in freeze drying ($979.4{\mu}g/g$) was higher than that in hot-air drying ($48.3{\sim}303.2{\mu}g/g$). The sample concentration required for 50% reduction of DPPH free radical scavenging ($RC_{50}$) was $79.7{\mu}g/mL$ in freeze drying, and showed high antioxidant activity. Also it decreased from $122.4{\mu}g/mL$ to $87.7{\mu}g/mL$ with temperature increase during hot air drying. We therefore conclude from the above results that freeze drying is more suitable for the production of blackberry powder, because this method showed high value of chromaticity, total polyphenol, flavonoid, anthocyanin content, vitamin C and antioxidant activity.
Keywords
anthocyanin; blackberry; DPPH free radical scavenging activity; drying methods; total polyphenol; vitamin C;
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Times Cited By KSCI : 4  (Citation Analysis)
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1 Alonzo-Macias M, Cardador-Martinez A, Mounir S, Montejano-Gaitan G, Allaf K. 2013. Comparative study of the effects of drying methods on antioxidant activity of dried strawberry (Fragaria var. Camarosa). J Food Res 2:92-107   DOI
2 Chen Q, Zhang XN, Yu HW, Wang Y, Tang HR. 2012. Changes of total anthocyanins and proanthocyanidins in the developing blackberry fruits. Intl J ChemTech Res 4:129-137
3 Chen W, Xu Y, Zhang L, Su H, Zheng X. 2016. Blackberry subjected to in vitro gastrointestinal digestion affords protection against ethyl carbamate-induced cytotoxicity. Food Chem 212:620-627   DOI
4 Choi SR, Yu YJ, Ahn MS, Song EJ, Seo SY, Choi MK, Han HA, Song YJ, Kim HJ, Seo SY, Lee GK, Kim CK. 2014. Quality characteristics by various drying methods in ear mushroom (Auricularia auricula-judae Quel.). Korean J Med Crop Sci 22:497-503   DOI
5 Ferreira de Araujo PR, da Silva Santos V, Rodrigues Machado A, Gevehr Fernandes C, Silva JA, da Silva Rodrigues R. 2011. Benefits of blackberry nectar (Rubus spp.) relative to hypercholesterolemia and lipid peroxidation. Nutr Hosp 26:984-990
6 Folmer F, Basavaraju U, Jaspars M, Hold G, El-Omar E, Dicato M, Diederich M. 2014. Anticancer effects of bioactive berry compounds. Phytochem Rev 13:295-322   DOI
7 Giusti MM, Wrolstad RE. 2001. Characterization and measurement of anthocyanins by UV visible spectroscopy. Current Protocols in Food Anal Chem F1.2.1-F1.2.13
8 Horszwald A, Julien H, Andlauer W. 2013. Characterisation of Aronia powders obtained by different drying processes. Food Chem 141:2858-2863   DOI
9 Jung H, Lee HJ, Cho H, Lee K, Kwak HK, Hwang KT. 2015. Anthocyanins in Rubus fruits and antioxidant and anti-inflammatory activities in RAW 264.7 cells. Food Sci Biotechnol 24:1879-1886   DOI
10 Huang WY, Zhang HC, Liu WX, Li CY. 2012. Survey of antioxidant capacity and phenolic composition of blueberry, blackberry, and strawberry in Nanjing. J Zhejiang Univ-Sci B (Biomed & Biotechnol) 13:94-102   DOI
11 Jung HN, Lee HJ, Cho HN, Hwang KT. 2012. Antioxidant and anti-proliferative activities of Rubus fruits in Korea. J Korean Soc Food Sci Nutr 41:1649-1655   DOI
12 Kaume L, Gilbert WC, Brownmiller C, Howard LR, Devareddy L. 2012. Cyanidin 3-O-${\beta}$-d-glucoside rich blackberries modulate hepatic gene expression, and anti-obesity effects in ovariectomized rats. J Funct Foods 4:480-488   DOI
13 Lee SG, Vance TM, Nam TG, Kim DO, Koo SI, Chun OK. 2016. Evaluation of pH differential and HPLC methods expressed as cyanidin-3-glucoside equivalent for measuring the total anthocyanin contents of berries. J Food Meas Charact 10:562-568   DOI
14 Kim NM, Kim DH. 2000. Quality change of sinnamon extract prepared with various drying methods. Korean. J Food & Nutr 13:152-157
15 Lee S, Kim JK. 2015. Quality characteristics of Aronia melanocarpa by different drying method. Korean J Food Preserv 22:56-62   DOI
16 Lee SG, Vance TM, Nam TG, Kim DO, Koo SI, Chun OK. 2015. Contribution of anthocyanin composition to total antioxidant capacity of berries. Plant Foods Hum Nutr 70:427-432   DOI
17 Pantelidis GE, Vasilakakis M, Manganaris GA, Diamantidis GR. 2007. Antioxidant capacity, phenol, anthocyanin and ascorbic acid contents in raspberries, blackberries, red currants, gooseberries and Cornelian cherries. Food Chem 102:777-783   DOI
18 Rodriguez K, Ah-Hen KS, Vega-Galvez A, Vasquez V, Quispe-Fuentes I, Rojas P, Lemus-Mondaca R. 2016. Changes in bioactive components and antioxidant capacity of maqui, Aristotelia chilensis [Mol] Stuntz, berries during drying. LWT-Food Sci Technol 65:537-542   DOI
19 Park SJ, Choi YB, Ko JR, Rha YA, Lee HY. 2014. Effects of drying methods on the quality and physiological activities of blueberry (Vacciniu ashei). Korean J Culinary Res 20:55-64
20 Rodriguez K, Ah-Hen K, Vega-Galvez A, Lopez J, Quispe-Fuentes I, Lemus-Mondaca R, Galvez-Ranilla L. 2013. Changes in bioactive compounds and antioxidant activity during convective drying of murta (Ugni molinae T.) berries. Intl J Food Sci Technol 49:990-1000
21 Ryu JH, Kwon SJ, Jo YD, Jin CH, Nam BM, Lee SY, Jeong SW, Im SB, Oh SC, Cho L, Ha BK, and Kang SY. 2016. Comparison of phytochemicals and antioxidant activity in blackberry (Rubus fruticosus L.) fruits of mutant lines at the different harvest time. Plant Breed Biotech 4:242-251   DOI
22 Shin DS, You YM, Kim HY, Han GJ. 2015. Determine the effects of drying temperature on the quality change and antioxidant activity characteristics of blueberry. Korean J Food Preserv 22:505-511   DOI
23 Stefanut MN, Cata A, Pop R, Tanasie C, Boc D, Ienascu I, Ordodi V. 2013. Anti-hyperglycemic effect of bilberry, blackberry and mulberry ultrasonic extracts on diabetic rats. Plant Foods Human Nutr 68:378-384   DOI
24 Tavares L, Figueira I, McDougall GJ, Vieira HL, Stewart D, Alves PM, Ferreira RB, Santos CN. 2013. Neuroprotective effects of digested polyphenols from wild blackberry species. Eur J Nutr 52:225-236   DOI
25 Van de Velde F, Grace MH, Esposito D, Pirovani ME, Lila MA. 2016. Quantitative comparison of phytochemical profile, antioxidant, and anti-inflammatory properties of blackberry fruits adapted to Argentina. J Food Comp Anal 47:82-91   DOI