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Sains Malaysiana 48(7)(2019): 1417–1424
http://dx.doi.org/10.17576/jsm-2019-4807-10
Comparison of Phenolic Constituent in Hibiscus
sabdariffa cv.
UKMR-2 Calyx at Different Harvesting Times (Perbandingan
Sebatian Fenolik dalam Kaliks Hibiscus sabdariffa
kv. UKMR-2
pada Masa Penuaian Berbeza) SITI AISHAH
MOHD
ALI1,2*,
CHE
RADZIAH
CHE
MOHD3
& JALIFAH LATIP1 1Centre for Advanced Materials and
Renewable Resources, Faculty of Science and Technology, Universiti
Kebangsaan Malaysia, 43600 UKM Bangi, Selangor Darul Ehsan, Malaysia 2Faculty of Science and Natural Resources,
Universiti Malaysia Sabah, Jalan UMS, 88400 Kota Kinabalu,
Sabah, Malaysia 3School of Biosciences and Biotechnology,
Faculty of Science and Technology, Universiti
Kebangsaan Malaysia, 43600 UKM Bangi, Selangor Darul Ehsan, Malaysia Diserahkan: 10 Januari
2019/Diterima: 1 Mei 2019 ABSTRACT The metabolic changes in the
phenolics content of Hibiscus
sabdariffa cv. UKMR-2 were investigated at different
harvesting times based on the High-Performance Liquid Chromatographic
method using a photodiode array detector (HPLC-PDA)
with gradient elution. The antioxidant activity was also determined
using 2,2-diphenyl-1-picrylhydrazyl free radical scavenging activity
(DPPH)
assay. The cultivation was executed under a control condition, and
the calyces were separately harvested at four maturation stages.
UKMR-2
calyces were extracted with water via sonication (50°C, 30 min).
HPLC-PDA
analysis showed two predominant anthocyanins, namely
delphinidin-3-O-sambubioside (2.07-2.47 mg/g DW)
and cyanidin-3-O-sambubioside (0.55-1.01 mg/g DW).
In addition, ascorbic acid (3.34-9.88 mg/g DW),
caffeic acid (0.08-0.09 mg/g DW)
and chlorogenic acid (0.50-0.65 mg/g DW)
were also detected in all maturity stages. Cyanidin-3-O-sambubioside
content increased as the calyx became more mature, whereas the delphinidin-3-O-sambubioside,
ascorbic acid, and chlorogenic acid content
declined towards calyx maturity. The antioxidant activity gradually
increased as the calyx ripening progressed. However, the activities
did not differ significantly between the stages (p>0.05). The high content of total phenolic,
total anthocyanins, and free radical scavenging activity were detected
at Stage 4 (28-30 DAA) in UKMR-2,
suggesting that this stage is the most appropriate maturity stage
for harvesting H. sabdariffa cv.
UKMR-2 calyces compared to the other maturity stages.
Keywords: Antioxidant; H.
sabdariffa cv. UKMR-2; maturity stages; phenolic content ABSTRAK Perubahan metabolik bagi sebatian fenolik pada masa penuaian yang berbeza telah dikaji
dalam Hibiscus sabdariffa kv.
UKMR-2
berdasarkan kaedah
Kromatografi Cecair Berprestasi Tinggi menggunakan pengesan foto-diod (HPLC-PDA)
dengan elusi
kecerunan kepolaran. Aktiviti antioksidan juga ditentukan menggunakan asai penyah-radikal bebas 2,2-difenil-1-pikrilhidrazil (DPPH).
Penanaman dilakukan
di bawah keadaan terkawal
dan penuaian
kaliks dilakukan secara berasingan pada empat tahap
kematangan. Kaliks
rosel diekstrak dengan air secara sonikasi (50°C, 30 min). Analisis
HPLC-PDA
menunjukkan kehadiran
dua sebatian
antosianin iaitu delfinidin-3-O-sambubiosida
(2.07-2.47 mg/g BK) dan sianidin-3-O-sambubiosida
(0.55-1.01 mg/g BK).
Selain itu, asid
askorbik (3.34-9.88 mg/g BK),
asid kafeik (0.08-0.09 mg/g BK)
dan asid klorogenik (0.50-0.65 mg/g BK)
juga dikesan dalam
semua tahap kematangan.
Kandungan sianidin-3-O-sambubiosida meningkat apabila kaliks menjadi lebih matang, sebaliknya
kandungan delfinidin-3-O-sambubiosida,
asid askorbik dan
asid klorogenik
menurun apabila kaliks mencapai kematangan. Aktiviti antioksidan menunjukkan peningkatan berterusan mengikut tahap kematangan. Walau bagaimanapun, ia tidak menunjukkan kesan signifikan antara tahap kematangan
(p>0.05). Kandungan jumlah fenolik, jumlah antosianin dan aktiviti antioksidan
yang tinggi dikesan
pada Tahap 4 (28-30 DAA)
bagi UKMR-2, mencadangkan
tahap ini sebagai tahap kematangan
untuk penuaian
H. sabdariffa kv. UKMR-2 berbanding
dengan peringkat
kematangan yang lain. Kata kunci: Antioksidan;
H.
sabdariffa kv. UKMR-2; kandungan fenolik; tahap kematangan RUJUKAN Alighourchi, H. & Barzegar, M. 2009. Some physicochemical characteristics and
degradation kinetic of anthocyanin of reconstituted pomegranate
juice during storage. Journal of Food Engineering 90(2):
179-185. Amor, B.B. &
Allaf, K. 2009. Impact of texturing using
instant pressure drop treatment prior to solvent extraction of anthocyanins
from Malaysian roselle (Hibiscus sabdariffa).
Food Chemistry 115(3): 820-825. Bernal, F.A., Orduz-Diaz, L.L. & Coy-Barrera, E. 2016. Application of
FARAFAC and OPLS-DA analysis on HPLC fingerprints for the characterization
of Hibiscus sabdariffa calyces. Quimica
Nova 39(2): 160-166. Brahma, J., Singh,
B. & Rethy, P. 2014. Bioactive and
nutraceutical compound manipulation in Hibiscus sabdariffa L.
leaves: A common undershrub consumed by the Bodo tribes of BTC,
Assam, India. International Research Journal of Pharmacy 5(6):
463-467. Bureau, S., Renard, C.M.G.C., Reich, M., Ginies,
C. & Audergon, J.M. 2009. Change in
anthocyanin concentrations in red apricot fruits during ripening.
LWT-Food Science Technology 42(1): 372-377. Buta, J.G. & Spaulding,
D.W. 1997. Endogenous levels of phenolics
in tomato fruit during growth and maturation. Journal of Plant
Growth Regulation 16: 43-46. Castro, N.E.A.,
de Pinto, J.E.B.P., Cardoso, M.G., Morais,
A.R., Bertolucci, S.K.V., Silva, F.G. & Delu
Filho, N. 2004. Planting time for maximization
of yield of vinegar plant calyx (Hibiscus sabdariffa L.).
Ciencia e Agrotecnologia
28(3): 542-551. Chumsri, P., Airichote, A. & Itharat, A.
2008. Studies on the optimum conditions for the extraction and concentration
of roselle (Hibiscus sabdariffa Linn.)
extract. Songklanakarin Journal of Science and Technology
30(1): 133-139. Copeland, L.O.
& McDonald, M.B. 1995. Seed Vigor and Vigor Test, in Principles
of Seed Science and Technology. London: Chapman and Hall. p.
157. Da-Costa-Rocha,
I., Bonnlaender, B., Sievers,
H., Pischel, I. & Heinrich, M. 2014.
Hibiscus sabdariffa L. - A phytochemical and pharmacological
review. Food Chemistry 165: 424-443. Deshmukh, S.R., Wadegaonkar, V.P., Bhagat, R.P.
& Wadegaonkar, P.A. 2011. Tissue specific
expression of anthraquinones, flavonoids
and phenolics in leaf, fruit and root suspension cultures of Indian
mulberry (Morinda citrifola L.). Plant Omics Journal 4(1): 6-13.
Eltayeib, A.A. & Hamade, H. 2014. Phytochemical and chemical composition of
water extract of Hibiscus sabdariffa (Red Karkade
Calyces) in North Kordofan State-Sudan.
International Journal of Advanced Research in Chemical Science
1(6): 10-13. Fakir, M.S.A.,
Islam, M.M., Islam, A., Islam, F. & Chowdhury, M.M. 2012. Capsule
growth and calyx protein content in Hibiscus sabdariffa L.
var. sabdariffa. Journal of Agroforestry and Environment
6(2): 1-4. Fasoyiro, S.B., Babalola, S.O. & Owosibo, T.
2005. Chemical composition and sensory quality of fruit-flavoured
roselle (Hibiscus sabdariffa) drinks.
World Journal of Agricultural Sciences 1(2): 161-164. Giusti, M.M. & Wrolstad, R.E. 2001. Characterization and measurement of anthocyanins
by UV-Visible Spectroscopy. Current Protocols in Food Analytical
Chemistry 1(1): F1.2.1-F1.2.6. Goncalves, B., Silva, A.P.,
Moutinho-Pereira, J., Bacelar,
E., Rosa, E. & Meyer, A.S. 2007. Effect of ripeness and postharvest
storage on the evolution of colour and
anthocyanins in cherries (Prunus
avium L.). Food Chemistry 103(3):
976-984. Haryati, T., Nisa, C., Julianti, E. & Basyuni, M. 2018. Changes in size and weight of calyxes, weight
and moisture content of seeds of roselle
(Hibiscus sabdariffa L.) during development. Journal of
Physics: Conference Series 1116: 052027. Hassanein, R.A., Khattab, H.K.I., EL-Bassiouny, H.M.S.
& Sadak, M.S. 2005. Increasing the
active constituents of sepals of roselle
(Hibiscus sabdariffa L.) plant by applying gibberellic acid
and benzyladenine. Journal of Applied
Sciences Research 1(2): 137-146. Hussein, R.M.,
Shahein, Y.E., El Hakim, A.E. & Awad,
H.M. 2010. Biochemical and molecular characterization of three colored
types of roselle (Hibiscus sabdariffa
L.). Journal of American Science 6(11): 726-733. Ichiyanagi, T., Shida, Y., Rahman, M.M., Hatano,
Y. & Konishi, T. 2006. Bioavailability
and tissue distribution of anthocyanins in bilberry (Vaccinium
myrtillus L.) extract in rats. Journal
of Agriculture Food Chemistry 54(18): 6578-6587. Idris, M.H.M.,
Siti Balkis, B., Mohamad, O. & Jamaludin, M. 2012. Protective role of Hibiscus sabdariffa
calyx extract against streptozotocin
induced sperm damage in diabetic rats. EXCLI Journal 11:
659-669. Ijeomah, A.U., Ugwuona, F.U. & Abdullahi, H.
2012. Phytochemical composition and antioxidant properties of Hibiscus
sabdariffa and Moringa oleifera. Nigerian Journal of Agriculture, Food and Environment
8(1): 10-16. Izatus Shima, T.,
Siti Balkis,
B., Maizatul
Nadhirah, I., Satirah,
Z. & Jamaludin,
M. 2017. Kesan ekstrak akueus rosel (Hibiscus sabdariffa Linn.)
terhadap sperma
dan testis tikus diadministrasi nikotin. Sains Malaysiana 46(9):
1611-1616. Jafarian, S., Mortazavi,
A., Kenari, R.S. & Elhami
Rad, A.H. 2014. Total phenolic content & antioxidant
activity of roselle (Hibiscus sabdariffa
L.) calyces extracts. Journal of Applied Science and
Agriculture 9(9): 165-169. Khafaga, E.R. & Koch, H. 1980. Stage
of maturity and quality of roselle (Hibiscus
sabdariffa L. var. sabdariffa) - Organic acids. Angewandte
Botanik 54(5-6): 287-293. Kouakou, T.H., Konkon,
N.G., Ayolie, K., Obouayeba,
A.P., Abeda, Z.H. & Kone,
M. 2015. Anthocyanin production in calyx and callus of roselle
(Hibiscus sabdariffa L.) and its impact on antioxidant activity.
Journal of Pharmacognosy and Phytochemistry
4(3): 9-15. Lislivia, Y., Siti Aishah,
M.A., Jalifah, L., Norsyahida,
M.F., Siti Balkis, B. & Satirah,
Z. 2017. Roselle is cardioprotective in
diet-induced obesity rat model with myocardial infarction. Life
Sciences 191: 157-165. Macheix, J.J., Fleuriet,
A. & Billot, J. 1990. Fruit Phenolic.
Boca Raton: CRC. Manach, C., Scalbert,
A., Morand, C., Remesy,
C. & Jimenez, L. 2004. Polyphenols: Food sources and bioavailability.
The American Journal of Clinical Nutrition 79(5): 727-747.
McClaleb, R.S. 1998. Hibiscus production
manual. Ciencia e Agrotecnologia
28(3): 542-551. Mohamed, R., Fernandez, J., Pineda,
M. & Aguilar, M. 2007. Roselle (Hibiscus sabdariffa)
seed oil is a rich source of gamma-tocopherol. Journal of Food
Science 72(3): 207-211. Miletić, N., Popović,
B., Mitrović, O. & Kandić,
M. 2012. Phenolic content and antioxidant capacity of fruits of
plum cv. ‘Stanley’ (Prunus domestica
L.) as influenced by maturity stage and on-tree ripening. Australian
Journal of Crop Science 6(4): 681-687. Mungole, A. & Chaturvedi,
A. 2011. Hibiscus sabdariffa L: A rich source of secondary
metabolites. International Journal of Pharmaceutical Sciences
Review and Research 6(1): 83-87. Nur Amirah, Y., Alias, A.A. &
Wan Zaliha, W.S. 2015. Growth and water
relations of roselle grown on BRIS soil under partial root zone drying.
Malaysia Applied Biology 44(1): 63-67. Obouayeba, A.P., Djyh,
N.B., Diabate, S., Djaman,
A.J., N’guessan, J.D., Kone,
M. & Kouakou, T.H. 2014. Phytochemical
and antioxidant activity of roselle (Hibiscus
sabdariffa L.) petal extracts. Research Journal of Pharmaceutical,
Biological and Chemical Sciences 5(2): 1453-1465. Osman, M., Golam, F., Saberi, S., Majid, N.A., Nagoor,
N.H. & Zulqarnain, M. 2011. Morpho-agronomic
analysis of three roselle (Hibiscus
sabdariffa L.) mutants in tropical Malaysia. Australian Journal
of Crop Science 5(10): 1150-1156. Puro, K., Sunjukta,
R., Samir, S., Ghatak, S., Shakuntala,
I. & Sen, A. 2014. Medicinal uses of roselle
plant (Hibiscus sabdariffa L.): A mini review. Indian
Journal of Hill Farming 27(1): 81-90. Raffo, A., Cherubino,
L., Vincenzo, F., Ambrozino, P., Salucci,
M., Gennaro, L., Bugianesi,
R., Giuffrida, F. & Quaglia,
G. 2002. Nutritional value of cherry tomatoes (Lycopersicon
esculentum cv. Naomi F1) harvested
at different ripening stages. Journal of Agricultural and Food
Chemistry 50(22): 6550-6556. Ryu, J., Soon-Jae, K.S.J., Jo, Y.D.,
Jin, C.H., Nam, B.M., Lee, S.Y., Jeong,
S.W., Im, S.B., Oh, S.C., Cho, L., Ha,
B.K. & Kang, S.Y. 2016. Comparison of phytochemicals and antioxidant
activity in blackberry (Rubus
fruticosus L.) fruits of mutant lines
at the different harvest time. Plant Breeding and Biotechnology
4(2): 242-251. Satirah, Z., Siti Nor
Farhanah, S.N.S. & Siti Balkis,
B. 2016. Hibiscus sabdariffa Linn. (roselle)
protects against nicotine-induced heart damage in rats. Sains
Malaysiana 45(2): 207-214. Sharara, M.S. 2017. Copigmentation
effect of some phenolic acids on stabilization of roselle
(Hibiscus sabdariffa) anthocyanin extract. American Journal
of Food Science and Technology 5(2): 45-52. Siti Aishah,
M.A., Che Radziah, C.M.Z. & Jalifah,
L. 2019. Influence of elevated CO2 on the growth and
phenolic constituents production in Hibiscus sabdariffa var.
UKMR-2. Jurnal Teknologi 81(3):
109-118. Siti Aishah,
M.A., Jalifah, L. & Che Radziah,
C.M.Z. 2017. Phenolic content of roselle’s
calyces (Hibiscus sabdariffa var. UKMR-2) at different maturation
stages. UKM-UR-UII-PSU Joint Seminar 2017 Abstract Book.
p. 34. Sukwattanasinit, T., Burana-osot,
J. & Sotanaphun, U. 2007. Spectrophotometric
method for quantitative determination of total anthocyanins and
quality characteristics of roselle (Hibiscus
sabdariffa). Planta Medica 73(14):
1517-1522. Waterhouse, A.L. 2002. Determination
of total phenolics. Current Protocols
in Food Analytical Chemistry 6(1): I1.1.1-I1.1.8. *Pengarang untuk surat-menyurat; email: jalifah@ukm.edu.my
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