Isolation of Arbutin from Leaves and Fruits of Buni (Antidesma Bunius L. Spreng) As Tyrosinase Enzym Inhibitor

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Published Nov 29, 2021
https://doi.org/10.11594/bbrj.04.01.02
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Vol. 4 No. 1 (2021): Volume 4 Issue 1

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Gea Ocktiah Palensina
Universitas 17 Agustus 1945
Leni Rosita
Universitas 17 Agustus 1945
Zuraida Sagala
Universitas 17 Agustus 1945

Abstract

Several studies have shown that plant extractive substances have the potential as active compounds inhibiting the enzyme tyrosinase. Arbutin is an enzyme inhibitor of tyrosinase, known as a popular whitening agent used in cosmetics because of its effectiveness in overcoming skin hyperpigmentation. The purpose of this study was to conduct a qualitative and quantitative analysis of arbutin on Buni Leaves and Fruits (Antidesma bunius L. Spreng). The raw simplicia used are mature and young buni leaves, green, red and purple buni fruits. The extraction method is maceration using methanol as solvent. The initial screening for arbutin content was carried out using thin layer chromatography (TLC) and dichlormethan:methanol 50:50 used as mobile phase. Isolation of arbutin content was carried out using Preparative TLC with the same eluent. Qualitative and quantitative analysis were performed using High Pressured Liquid Chromatography (HPLC) with mobile phase of acetonitrile: water 60:40. The tyrosinase enzyme inhibition activity test was then carried out in vitro using 96-well microplate, l-tyrosine and l-dopa were used as substrate at a wavelength of 492 nm. The Rf values obtained ??for mature buni leaves and green buni fruits, respectively 0.61 and 0,62. The retention time of HPLC chromatogram respectively 2,784 minutes and 2,758 minutes. Arbutin levels in leaves and fruits are 7.9 mg / g and 2 mg / g. The activity of the enzyme tyrosinase of mature buni leaves on L-dopa and L-tyrosine substrate were respectively stated as IC50 values ??of 88.7191ppm and 101.33347 ppm. The activity of the enzyme tyrosinase of the green buni fruit on L-dopa and L-tyrosine substrate respectively stated IC50 values ??of 198,0293 ppm and 246,1296 ppm.

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How to Cite
Palensina, G. O. ., Rosita, L. . and Sagala, Z. (2021) “Isolation of Arbutin from Leaves and Fruits of Buni (Antidesma Bunius L. Spreng) As Tyrosinase Enzym Inhibitor”, Bioinformatics and Biomedical Research Journal, 4(1), pp. 8–18. doi: 10.11594/bbrj.04.01.02.

References

  1. Ardhi AM. 2011. Radikal bebas dan peran anti-oksidan dalam mencegah penuaan. Medicinus 24(1):3-9.
  2. Batubara I, Adfa M. 2013. Potensi daun kayu bawang (Protium javanicum) sebagai penghambat kerja enzim tirosinase. Journal Sains dan Matemat-ika. 1(2):52-56
  3. Park HY, Yaar M. Biology of melanocytes. Dalam: Goldsmith LA, Katz SI, Gilchrest BA, Paller AS, Leffell DJ, Wolff K, penyunting. Fitzpatrick's der-matology in general medicine. Edisi ke-8. New York: McGraw-Hill; 2012. hlm. 795–81.
  4. Ariyani F, Amin I, Fardiaz D, Budiyanto S. 2008. Aplikasi ekstrak daun sirih (Piper betle Linn) da-lam menghambat oksidasi lemak jambal patin (Pangasius hypophthalmus). Jurnal pasca panen dan bioteknologi kelautan dan perikanan 3(2):157-169.
  5. Stalling AF, Lupo MP. 2009. Practical Uses of Bo-tanicals in Skin Care. The Journal of Clinical Aes-thetic Dermatology. 2(1): 36-40.
  6. Hu, Z. M., Zhou, Q., Lei, T. C., Ding S. F., & Xu, S. Z. (2009). Effects of hydroquinone and its glucoside derivatives on melanogenesis and antioxidation as skin whitening agents. Journal of Dermatological Science, 55(3), 179–184.
  7. Wink, M. (2013). Evolution of secondary metabo-lites in legumes (Fabaceae). South African Journal of Botany, 89, 164–175. doi:10.1016/j.sajb.2013.06.006
  8. Swanprasert, 2018. The Analysis of Arbutin I Mao (Antidesma thwaitesianum Muell. Arg) Extracts. Pertanika Journal Tropical Agricultural Science. 41(2): 621-636.
  9. Batubara I, Darusman Lk, Mitsunaga T, Rahmni-wati M, Djauhari E, 2010. Patoncy Of Indonesia Medicinal Plants As Tyrosinase Inhibitors and An-tioxidant Agent. Journal Of Biologi Science, 10:138-144
  10. Sastrohamidjojo, Hardjono. 2007. Kimia Dasar. Yogyakarta: UGM Press
  11. Alam, Pravez. S.I., Alqasoumi. Faiyaz, S. Maged, A. 2011. HPTLC Densitometric Analysis of Arbutin in Bulk Drug and Methanolic Extracts of Arctostaphy-losuva-ursi. Natural Product Research. 25(17): 1671-1675
  12. Das, N. M. Veerabahu, R.M. Bagavathiperumal, P.P. 2015. Isolation, Purification and Characterization of Arbutin from Cleidionnitidum(Muell.-Arg.) Thw. ex Kurz. (Euphorbiaceae). International Journal of Science and Research. 2319-7064
  13. Hanachi, P. 2009. Using HPLC to Determination the Composition and Antioxidant Activity of Ber-beris vulgaris. European Journal of Scientific Re-search. 29(2): 47-54
  14. Anwar, K. Beny, R. Liling, T. dan Muhammad, I.R. 2017. The Influence of Leaf Age on Total Phenolic, Flavonoids, and Free Radical Scavenging Capacity of Aquilariabeccariana. Research Journal of Phar-maceutical, Biological and Chemical Sciences. 8(1): 129-133
  15. Wahyuningsih, Qori. 2013. Aktivitas Penghambat-an Tirosinase dari Ekstrak Etil Asetat Daun Bi-nahong (Anrederacordifolia (Tenore) Steen). Skripsi. Purwokerto: Universitas Muhammadiyah Purwokerto.