Indonesian Journal of Pharmaceutical Science and Technology

Kayu jawa (Lannea coromandelica) merupakan salah satu tanaman yang banyak digunakan secara empiris oleh masyarakat di Sulawesi Selatan sebagai obat tradisional karena memiliki efek farmakologis seperti antiinflamasi yang merupakan respon protektif normal terhadap berbagai proses fisiologis di dalam tubuh serta memiliki efek biologis yang dapat bekerja pada target molekul. Inflamasi adalah respon perlindungan normal terhadap cedera jaringan yang disebabkan oleh trauma fisik, bahan kimia berbahaya, atau agen mikrobiologi. Tujuan penelitian ini adalah untuk mengetahui senyawa kimia apakah pada tanaman Kayu jawa (Lannea coromandelica) yang berpotensi sebagai antiinflamasi dengan mekanisme penghambatan reseptor TNF-α dan COX-2. Metode penelitian ini adalah  in silico menggunakan metode molecular docking dengan perangkat lunak Autodock. Tahapan penelitian antara lain simulasi doking reseptor dengan ligan uji kemudian di validasi, setelah itu di visualisasi menggunakan  discovery studio, kemudian dilanjutkan pada tahapan data analisis serta prediksi ADME. Adapun hasil penelitian Senyawa 3-hydroxy-4’,5,7-trimethoxyflavanone terhadap COX-2 dan senyawa uji morin terhadap TNF-α berpotensi sebagai antiinflamasi dengan kemampuan lebih rendah dibandingkan dengan liga alami untuk berkatan dengan sisi aktif pda reseptor target. Selanjutnya penelitian ini diharapkan menjadi pilot project produksi sediaan obat antiinflamasi yang dapat digunakan oleh masyarakat luas

Zhang Q, Zhang J, Xia P, et al. Anti-inflammatory activities of gentiopicroside against iNOS and COX-2 targets. Chinese Herb Med 2019; 11: 108–112.

Yatam S, Gundla R, Jadav SS, et al. Focused library design and synthesis of 2-mercapto benzothiazole linked 1,2,4-oxadiazoles as COX-2/5-LOX inhibitors. J Mol Struct 2018; 1159: 193–204.

Levita J, Rositama MR, Alias N, et al. Discovering COX-2 inhibitors from flavonoids and diterpenoids. J Appl Pharm Sci 2017; 7: 103–110.

Abdelazeem AH, Abdelatef SA, El-Saadi MT, et al. Novel pyrazolopyrimidine derivatives targeting COXs and iNOS enzymes; Design, synthesis and biological evaluation as potential anti-inflammatory agents. Eur J Pharm Sci 2014; 62: 197–211.

Shah K, Mujwar S, Gupta JK, et al. Molecular Docking and in Silico Cogitation Validate Mefenamic Acid Prodrugs as Human Cyclooxygenase-2 Inhibitor. Assay Drug Dev Technol 2019; 17: 285–291.

Yatam S, Jadav SS, Gundla KP, et al. 2-Mercapto Benzthiazole Coupled Benzyl Triazoles as New COX-2 Inhibitors: Design, Synthesis, Biological Testing and Molecular Modeling Studies. ChemistrySelect 2019; 4: 11081–11092.

Oliveira TLS, Morais SR de, Sá S de, et al. Antinociceptive, anti-inflammatory and anxiolytic-like effects of the ethanolic extract, fractions and Hibalactone isolated from Hydrocotyle umbellata L. (Acariçoba) – Araliaceae. Biomed Pharmacother 2017; 95: 837–846.

Hossain H, Al-Mansur A, Akter S, et al. Evaluation of Anti-Inflammatory Activity and Total Tannin Content From the Leaves of Bacopa Monnieri (Linn.). Int J Pharm Sci Res 2014; 5: 1246–1252.

Wahab A, Khera RA, Rehman R, et al. Kuth ( Saussurea lappa L .): A review of its traditional uses , phytochemistry and pharmacological potentials. Int J Chem Biochem Sci 2015; 8: 97–102.

Choodej S, Pudhom K, Mitsunaga T. Inhibition of TNF- α -Induced Inflammation by Sesquiterpene Lactones from Saussurea lappa and Semi-Synthetic Analogues. Planta Med 2018; 84: 329–335.

Jacques C, Gosset M, Berenbaum F, et al. The Role of IL-1 and IL-1Ra in Joint Inflammation and Cartilage Degradation. Vitam Horm 2006; 74: 371–403.

Lima KC, De Oliveira Martins DT, Macho A, et al. Chemical characterization of the hydroethanolic extract of the inner stem bark of dilodendron bipinnatum. comparative cytotoxic evaluation and anti-inflammatory potential of a simple mixture of its isolates 3-O-β-glucopyranosyl-β-sitosterol and 3-o-β-glucopyranosyl-stigmasterol. Nat Prod Commun 2019; 14: 23–26.

Sukmawati, Fawwaz M, Pratama M, et al. Potential of Astaxanthin from Asian Tiger Shrimp (Penaeus Monodon) Shell Extract as an Antibacterial and Anti-inflammatory. J Glob Pharma Technol; 11.

Tag HM, Khaled HE, Ismail HAA, et al. Evaluation of anti-inflammatory potential of the ethanolic extract of the Saussurea lappa root (costus) on adjuvant-induced monoarthritis in rats. J Basic Clin Physiol Pharmacol 2016; 27: 71–78.

Amirah S, Sardini J, Idrus HH. Anti-Inflammatory Potential Of Extract Of Nothopanax Fruticosum ( L .) Miq By Method Of Erythrocyte Membrane Stability. Int J Med Sci Dent Res 2020; 03: 32–37.

Muchtaridi, Yusuf M. Molecular docking theory and practice. 1st editio. Bandung: Unpad Press, 2018.

Oyedapo O. Red Blood Cell Membrane Stabilizing Potentials of Extracts of Lantana Camara and Its Fractions. Int J Plant Physiol Biochem 2010; 2: 46–51.

Olson, Arthur J., et al. (2001). Automated Docking Of Flexible Ligand To Receptors version 3.0.5.from http://autodock.scripps.edu/faqs-help/manual/autodock-3-user sguide/AutoDock3.0.5_UserGuide.pdf

Trott, O., & Olson, A. (2009). Software News and Update Autodock Vina: Improving The Speed and Accuracy of Docking with a New Scoring Function, Efficient Optimization, and Multithreading. Journal of Computational Chemistry , 0, 1-7.

Tiikkainen, P. (2010). Study of Ligand-Based Virtual Screening Tools in Computer-Aided Drug Design. Medica-Odontologica , 1-98

Inbio-Indonesia. ‘Bioinformatics Training Eksplorasi Potensi Senyawa Bahan Alam secara In Silico’ Indonesian Institute of Bioinformatics. Malang: Universitas Brawijaya, 2016.

Syahputra G. Peran Bioinformatika Dalam Desain Kandidat Molekul Obat. Biotrends 2015; 6: 26–27.

K.Whalen, Finkel R, T.A. Lippincott Illustrated Reviews: Pharmacology 6th edition. Wolters Kluwer, 2012.

Ilakkiya R, Neelvizhi K, Tamil S, et al. A Comparative Study of Anti-Inflammatory Activities of Certain Herbal Leaf Extracts. Int J Pharm Integr Life Sci 2013; 1: 67–77.

Gandhisan, R. T, A. B. Antiinflammatory action of Lannea coromandelica Hrbc membrane stabilization. Fitotherapia. Fitotherapia 1991; 62: 82–83.

Damayanti DS, Utomo DH, Kusuma C. Revealing the potency of Annona muricata leaves extract as FOXO1 inhibitor for diabetes mellitus treatment through computational study. Silico Pharmacol; 5. Epub ahead of print 2017. DOI: 10.1007/s40203-017-0023-3.

IDA MUSFIROH, et al. IN SILICO STUDY OF ASIATIC ACID INTERACTION WITH INDUCIBLE NITRIC OXIDE SYNTHASE (INOS) AND CYCLOOXYGENASE-2 (COX-2) International Journal of Pharmacy and Pharmaceutical Sciences. ISSN- 0975-1491. Vol 5, Suppl 1, 2013

Lu H-M, Yin D-C, Ye Y-J, et al. Correlation Between Protein Sequence Similarity and X-Ray Diffraction Quality in the Protein Data Bank. Protein Pept Lett 2009; 16: 50–55.

Tasneem S, Liu B, Li B, et al. Molecular pharmacology of inflammation: Medicinal plants as anti-inflammatory agents. Pharmacol Res 2019; 139: 126–140.

Fernández MA, de las Heras B, Garcia MD, et al. New insights into the mechanism of action of the anti-inflammatory triterpene lupeol. J Pharm Pharmacol 2010; 53: 1533–1539.

Orlando BJ, Malkowski MG. Substrate-selective inhibition of cyclooxygeanse-2 by fenamic acid derivatives is dependent on peroxide tone. J Biol Chem 2016; 291: 15069–15081.

Sidhu RS, Lee JY, Yuan C, et al. Comparison of cyclooxygenase-1 crystal structures: Cross-talk between monomers comprising cyclooxygenase-1 homodimers. Biochemistry 2010; 49: 7069–7079.

Ekins S, Mestres J, Testa B. In silico pharmacology for drug discovery: Methods for virtual ligand screening and profiling. Br J Pharmacol 2007; 152: 9–20.

Hassan GS, Abdel Rahman DE, Abdelmajeed EA, et al. New pyrazole derivatives: Synthesis, anti-inflammatory activity, cycloxygenase inhibition assay and evaluation of mPGES. Eur J Med Chem 2019; 171: 332–342.

Villa-De La Torre F, Kinscherf R, Bonaterra G, et al. Anti-inflammatory and immunomodulatory effects of Critonia aromatisans leaves: Downregulation of pro-inflammatory cytokines. J Ethnopharmacol 2016; 190: 174–182.

Charde RM, Dhongade HJ, Charde MS, et al. Evaluation of antioxidant, wound healing and anti-inflammatory activity of ethanolic extract of leaves of Ficus religiosa. Int J Pharm Sci Res 2010; 1: 73–82.

Sandeep, Kumar A, Dimple, et al. Ficus religiosa: A wholesome medicinal tree. J Pharmacogn Phytochem 2018; 7: 32–37.

Gabay OH, Sanchez C, Chevy F, et al. Anti-Inflammatory Properties of Stigmasterol in Cartilage: New Insights. Osteoarthr Cartil 2008; 16: S79.

Ricardo T, Lima C De, Marques GS, et al. State of the Art of Anti-Inflammatory Drugs.