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Sains Malaysiana
51(10)(2022):
http://doi.org/10.17576/jsm-2022-5110-09
Substituted 3-styryl-2-pyrazoline Derivatives as an Antimalaria:
Synthesis, in vitro Assay, Molecular
Docking, Druglikeness Analysis, and ADMET Prediction
(Penggantian Terbitan 3-styryl-2-pyrazoline sebagai Antimalaria:
Sintesis, Asai in vitro, Dok Molekul, Analisis Keserupaan Dadah dan
Ramalan ADMET)
LINDA EKAWATI1, BETA ACHROMI NUROHMAH1, JUFRIZAL SYAHRI2 & BAMBANG PURWONO1,*
1Department of Chemistry, Faculty
of Mathematics and Natural Science, Universitas Gadjah Mada, Jalan Kaliurang Sekip Utara Bulaksumur 21,
Yogyakarta, 55281 Indonesia
2Department of Chemistry, Faculty of Mathematics
and Natural Sciences, Universitas Muhammadiyah Riau, Jalan
Tuanku Tambusai Ujung Nomor 1, Pekanbaru Indonesia
Diserahkan: 23 Oktober
2021/Diterima: 12 Mei 2022
Abstract
The synthesis, in
vitro antimalarial assay, molecular docking, drug-likeness analysis, and
ADMET prediction of substituted 3-styryl-2-pyrazoline derivatives as antimalaria have been conducted. The synthesis of N-phenyl (1a‒3a) and N-acetyl-substituted (1b‒3b) 3-styryl-2-pyrazolines was carried
out using dibenzalacetone derivatives and hydrazine hydrate or phenylhydrazine.
An in vitro antimalarial assay was
conducted against the chloroquine-sensitive Plasmodium
falciparum 3D7 strain, while molecular docking was performed toward the crystal protein of Plasmodium
falciparum dihydrofolate reductase-thymidylate synthase (PfDHFR-TS) (PDB ID:
1J3I). Furthermore, the prediction of drug-like properties was determined by
assessing Lipinski’s rules, and the pharmacokinetic parameters were also
studied in-silico, including
absorption, distribution, metabolism, excretion, and toxicity (ADMET). The in vitro assay showed that 3a (IC50 0.101 µM) has excellent antimalarial activity, followed by 2a (0.177 µM), and 1b (0.258 µM). Molecular docking has supported the in vitro assay by showing the lowest
CDOCKER energy for 3a (‒56.316 kcal/mol), then 2a (‒51.2603
kcal/mol), and 1b (‒48.8774 kcal/mol). The drug-like properties
showed that all of the prepared compounds were acceptable based on Lipinski’s
rules and predicted to be potentially orally bioavailable. The ADMET analysis
provided information that 3a and 2a could be proposed as the best lead
antimalarial drugs with further modification to reduce the lipophilicity and
toxicity properties.
Keywords: ADMET; antimalarial; dibenzalacetone;
molecular docking; pyrazoline
Abstrak
Sintesis, asai
antimalaria in vitro, dok molekul, analisis keserupaan dadah dan ramalan
ADMET bagi terbitan 3-styryl-2-pyrazoline yang digantikan sebagai antimalaria
telah dijalankan. Sintesis N-fenil (1a‒3a) dan
N-acetyl-substituted (1b‒3b) 3-styryl-2-pyrazolines telah
dijalankan menggunakan terbitan dibenzalaseton dan hidrazina hidrat atau
fenilhidrazina. Ujian antimalaria in vitro telah dijalankan terhadap
strain Plasmodium falciparum 3D7 yang sensitif terhadap klorokuin,
manakala dok molekul dilakukan ke arah protein kristal Plasmodium falciparum dihidrofolat reduktase-timidilat sintase (PfDHFR-TS) (PDB ID: 1J3I). Tambahan
pula, ramalan sifat seperti ubat ditentukan dengan menilai peraturan Lipinski
dan parameter farmakokinetik juga dikaji secara in siliko, termasuk
penyerapan, pengedaran, metabolisme, perkumuhan dan ketoksikan (ADMET). Ujian in
vitro menunjukkan bahawa 3a (IC50 0.101 µM) mempunyai
aktiviti antimalaria yang sangat baik, diikuti oleh 2a (0.177 µM), dan 1b (0.258 µM). Dok molekul telah menyokong ujian in vitro dengan
menunjukkan tenaga CDOCKER terendah untuk 3a (‒56.316 kcal/mol),
kemudian 2a (‒51.2603 kcal/mol) dan 1b (‒48.8774 kcal/mol).
Sifat keserupaan dadah menunjukkan bahawa semua sebatian yang disediakan boleh
diterima berdasarkan peraturan Lipinski dan diramalkan berpotensi bio tersedia
secara oral. Analisis ADMET memberikan maklumat bahawa 3a dan 2a boleh dicadangkan sebagai ubat antimalaria terbaik dengan pengubahsuaian
selanjutnya untuk mengurangkan sifat lipofilis dan ketoksikan.
Kata kunci: ADMET; antimalaria; dibenzalaseton;
dok molekul; pirazolin
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*Pengarang untuk
surat-menyurat; email: purwono.bambang@ugm.ac.id
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