STUDIES OF THE PHYTOCHEMISTRY, ANTIOXIDANT AND TYROSINASE INHIBITORY ACTIVITIES OF CANISTEL (POUTERIA CAMPECHIANA (KUNTH.) BAEHNI.)
Exposure of UV light on the skin can induce the reactive oxygen species (ROS), which is called free radical. ROS will cause the accumulation of skin pigment in melanocytes. As a result, the accumulation of ROS in melanocytes will induce the action of tyrosinase which plays a role in the melanin...
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| Format: | Dissertations |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/66115 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Exposure of UV light on the skin can induce the reactive oxygen species (ROS),
which is called free radical. ROS will cause the accumulation of skin pigment in
melanocytes. As a result, the accumulation of ROS in melanocytes will induce the
action of tyrosinase which plays a role in the melanin synthesis. Antioxidants can
act to scavenge the mechanism of ROS.
Pouteria is widely spread in tropical countries. It has been reported that the
Pouteria genera contains phenolic and flavonoid groups. Phenolic compounds and
flavonoids can act as antioxidant and inhibitor of tyrosinase. Several species of
Pouteria have the potential as antioxidant and inhibitor of tyrosinase. One species
of Pouteria that has not been widely developed in the pharmaceutical field. In
Indonesia is Pouteria campechiana. Several phenolic and flavonoid compounds
from P. campechiana have been reported. Based on the closeness in plant
systematics, similarities in chemical contents and biological activities can be
shown.
This research aims to carry out a phytochemical study of P. campechiana guided
by antioxidant and tyrosinase inhibitory activities, so that it can be known the
extract, fractions and subfractions and active compound with antioxidant and or
tyrosinase inhibitory activities from of P. campechiana.
This research was started with a preliminary study of antioxidant and tyrosinase
inhibitory activity of four plant parts (mesocarps, seeds, twigs and leaves) of P.
campechiana). Four plant parts were characterized and extracted by continuous
extraction using Soxhlet apparatus with 96% ethanol. The concentrated extract was
tested for antioxidant activity by DPPH method and tyrosinase inhibitory activity
using L-DOPA as substrate, and total phenolic and determined for flavonoid
content. The plant part with the most potent antioxidant and tyrosinase inhibitory
activities were further studied.
The ethanol leaves extract of P. campechiana had the highest antioxidant (AAI
16.638 ± 0.677), and tyrosinase inhibitory activities IC50 of of 221.16 µg/mL and
total phenolic content 18.88 ± 0.08 g GAE/100 g extract. Based on these results,
the leaves were subject to further studies.
The leaves crude drug was extracted in a series of organic solvents with increasing
polarity namely n-hexane, ethyl acetate and ethanol. The three concentrated
extracts, n-hexane leaves extract (DN), ethyl acetate leaves extract (DEA) and
etanol leaves extract (DE) were monitored by thin layer chromatography (TLC),
determined for total phenol and flavonoid content and tested for antioxidant and
tyrosinase inhibitory activity. Antioxidant activity of DN, DEA and DE were
expressed in antioxidant acivity index (AAI), whose values were 2.320 ± 0.315;
18.94 ± 0.149; 20.345 ± 0.173, respectively, using ascorbic acid, as standards with
AAI of 34.562 ± 0.091. Statistically, using on way-ANOVA-post hoc Tukey’s, DEA
and DE were not significantly different from ascorbic acid. From the eximination
of tyrosinase inhibtion, it was found that DE and DEA were more potent than DN,
so DN was not continued for IC50 value. In tyrosinase inhibitory assay the IC50
values of DEA, DE, and the standard kojic acid were 828.54 ± 0.96 µg/mL, 176.55
± 0.46 µg/mL, and 10.513 ± 0.707, respectively. Based on this data, DEA was
further separated through fractionation, subfractionation and purification.
Fractionation of the ethyl acetate extract was performed using vaccum liquid
chromatography, while subfractionation was done using classical coloumn
chromatography and radial chromatography. Selection of fractions and
subfractions were based on antioxidant and tyrosinase inhibitory activities. The
respective ranges of AAI and IC50 were 0.89-14.50 and 1551.01 –2090.43µg/mL.
Based on the results obtained, fraction 5 (F.5) was further subfractionated. The
result of subfractionation was obtained 6 combined subfractions namely (SF5.1-
SF5.6). Based on activity, SF5.5 was continued to purify, which yielded isolate-1
and isolate-2.
The AAI of isolate-1 and isolate-2 were 6.139 ± 0.153 and 8.479 ± 0.187,
respectively, while the tyrosinase inhibitory activities of isolate-1 and isolate-2
expressed in % inhibition at a concentration of 1000 µg/mL, were 48.395 ± 0.494
and 47.325± 0.570, respectively. Isolate-1 and isolate-2 were characterized using
spectrodensitometry,
1
H-NMR,
13
C-NMR, mass spectroscopy and HPLC. The
results confirmed that isolate-1 was quercetin-3-O-rhamnoside (quercitrin) and
isolate-2 was quercetin 3-O-glucoside (isoquercitrin).
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