Hasil Pencarian  ::  Simpan CSV :: Kembali

"Cervical cancer is the second most frequently occurring cancer among females all over the world. Since the best strategy against cancer is to kill the cancer cells without endangering the normal cells, discovering a potentially selective anticancer agent from plants has become very challenging for researchers worldwide. A previous study on Anredera cordifolia, known as binahong in Indonesia, revealed its cytotoxic activity on HeLa cervical cancer cells with IC50 75 µg/mL. However, the selectivity of the chemical agent and its molecular target was not investigated. Thus, this study was aimed at determining the selectivity of ethanolic extract of Anredera cordifolia leaf (EAC) on Vero cells and its molecular target on HeLa cells. The extracts were prepared by macerating A. cordifolia leaf powder in 70% ethanol. The viability of Vero cells was assessed using 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay. While the cell cycle of HeLa cells was analyzed using the flow cytometry, the molecular target of the extract was investigated by using the immunocytochemical staining. The results exhibited the selective cytotoxicity of EAC on HeLa cells compared to Vero cells with a Selectivity Index (SI) of 17.36. It arrested the G1/S phase of the cell cycle and suppressed the Bcl–2 expression, the anti-apoptotic protein, which also regulates the cell cycle. These findings confirmed the use of A. cordifolia leaf extract as a promising anticancer agent against cervical cancer, particularly the HeLa cells."

"Anredera cordifolia (Ten.) Steenis (binahong) merupakan salah satu bahan alam yang memiliki potensi dan digunakan untuk pengobatan tradisional. Efek farmakologi tanaman binahong dapat digunakan sebagai alternatif menurunkan kadar glukosa darah. Penelitian terdahulu melaporkan bahwa penggunaan bersama herbal dengan obat sintetik dapat menyebabkan terjadi perubahan pada farmakodinamika dan farmakokinetika obat sintetik. Informasi mengenai interaksi antara obat herbal dengan obat sintetik masih terbatas sehingga perlu diketahui efektivitas penggunaan kombinasi tersebut. Penelitian ini bertujuan untuk membuktikan adanya interaksi farmakodinamika dan farmakokinetika kombinasi ekstrak daun binahong dengan glibenklamid yang diberikan secara oral sebagai antidiabetes. Penelitian ini dilakukan secara ekperimental dan non ekperimental. Penelitian eksperimental dibagi menjadi dua bagian. Bagian pertama adalah pengujian interaksi farmakodinamika untuk efek antidiabetes dengan metode pengukuran kadar glukosa secara enzimatik. Kadar glukosa darah diukur sebelum perlakuan, setelah induksi pakan tinggi lemak (sukrosa 20 %, lemak sapi 20 %, mentega 10% dan pakan standar 50 %) dan setelah pemberian sediaan uji. Pengambilan sampel darah digunakan untuk pengujian TTGO, profil asam amino dan profil asam lemak. Bagian kedua adalah pengujian interaksi farmakokinetika dengan mengambil darah tikus pada titik tertentu setelah pemberian ekstrak daun binahong dan obat glibenklamid. Konsentrasi glibenklamid diukur dengan menggunakan kromatografi cair kinerja ultra tinggi-tandem spektrometri massa (KCKUT-SM/SM), selanjutnya dihitung nilai AUC, Tmaks, Cmaks, T1/2 dan Ke. Penelitian non ekperimental dilakukan drug design untuk memprediksikan ikatan antara kandidat molekul obat glibenklamid dan vitexin (senyawa yang terdapat dalam ekstrak binahong) sebagai antidiabetes dengan protein target CYP3A4 secara in silico dengan menggunakan molecular docking serta memprediksi interaksi antarprotein. Hasil uji pada farmakodinamika diperoleh kadar glukosa darah pada kombinasi glibenklamid (4,5 mg/kgBB) dengan ekstrak daun binahong dosis 1 (17,5 mg/kgBB), dosis 2 (35 mg/kgBB) dan dosis 3 (70mg/kgBB) dapat menurunkan kadar glukosa darah kembali normal namun persentase penurunan kadar glukosa pada hari ke 21 terbesar terdapat pada kelompok kontrol positif. Pada pengujian tes toleransi glukosa kelompok kombinasi memperoleh nilai AUC sebanding dengan nilai AUC kelompok positif yang diberi glibenklamid. Hasil penelitian pada profil asam lemak dan profil asam amino menunjukkan kelompok kombinasi obat dengan ekstrak daun binahong mengalami penurunan asam lemak dan peningkatan asam amino. Hasil uji profil farmakokinetika glibenklamid berbeda antara pemberian tunggal dengan kombinasi ekstrak daun binahong. Pemberian glibenklamid (4,5 mg/kgBB) dengan ekstrak daun binahong (70mg/kgBB) dapat menurunkan AUC dan Cmaks serta memperpanjang Tmaks. Hasil energi bebas gibs (ΔG) pada molecular docking diperoleh nilai glibenklamid dan vitexin yang berikatan dengan reseptor CYP3A4 dengan score ChemPLP sebesar -4,4 kkal/mol, glibenclamid dengan reseptor -3,2 kkal/mol dan vitexin dengan reseptor yaitu -3,2 kkal/mol, dapat disimpulkan bahwa pemberian kombinasi glibenklamid (4,5 mg/kgBB) dengan ekstrak daun binahong dosis 1 (17,5 mg/kgBB), dosis 2 (35 mg/kgBB) dan dosis 3 (70mg/kgBB) secara oral dapat menurunkan kadar glukosa darah pada tikus yang diinduksi pakan tinggi lemak. Persentase penurunan kadar glukosa darah lebih tinggi pada kelompok yang hanya diberikan glibenklamid 4,5 mg/kgBB (kelompok positif), sementara pada kelompok pemberian tunggal (ekstrak binahong dosis 1,2 dan 3), mengalami penurunan kadar glukosa tetapi tidak lebih tinggi persentase penurunan kadar glukosa darah dibandingkan dengan kelompok kontrol positif. Pada uji farmakokinetika pemberian kombinasi glibenklamid (4,5 mg/kgBB) dengan ekstrak daun binahong (70 mg/kgBB) secara oral dapat menurunkan kadar obat glibenklamid dalam plasma tikus.

---

Anredera cordifolia (Ten.) Steenis (binahong) is a natural ingredient with potential and is used in traditional medicine. The pharmacological effect of the binahong plant can be used as an alternative to lower blood glucose levels. Previous studies have reported that the concomitant use of herbs with synthetic drugs can cause changes in the pharmacodynamics and pharmacokinetics of synthetic drugs. Information regarding the interaction between herbal medicines and synthetic drugs is still limited, so it is necessary to know the effectiveness of using these combinations. This study aims to prove the pharmacodynamic and pharmacokinetic interactions of the combination of binahong leaf extract with glibenclamide administered orally as an anti-diabetic. This research was conducted experimentally and non-experimentally. Experimental research is divided into two parts. The first step is to test the pharmacodynamic interactions for the anti-diabetic effect using the enzymatic method of measuring glucose levels. Blood glucose level pressure was measured before treatment, after induction of a high-fat diet (20% sucrose, 20% beef fat, 10% butter, and 50% standard feed), and after administration of the test preparation. Blood sampling was used for testing OGTT, the amino acid profile, and the fatty acid profile. The second part is testing pharmacokinetic interactions by taking rat blood at a certain point after administration of binahong leaf extract and glibenclamide drug. The concentration of glibenclamide was measured using ultra-high performance liquid chromatography-tandem mass spectrometry (KCKUT-SM/SM), then the AUC, Tmax, Cmax, T1/2, and Ke values were calculated. Non-experimental research was conducted with drug design to predict the bond between candidate drug molecules glibenclamide and vitexin, one of the compounds contained in binahong extract as an anti-diabetic with CYP3A4 target protein in silico, by using molecular docking and predicting interactions between proteins. The results of the pharmacodynamic test obtained blood glucose levels in the combination of glibenclamide (4.5 mg/kg BW) with binahong leaf extract dose 1 (17.5 mg/kg BW), dose 2 (35 mg/kg BW), and dose 3 (70mg/kg BW) can reduce blood glucose levels back to normal, but the percentage of decrease in glucose levels on the 21st day is greatest in the positive control group. In the glucose tolerance test, the combined group obtained an AUC value comparable to the one in the positive group given glibenclamide. The study's results on the fatty acid profile and amino acid profile showed that the combination group of drugs with binahong leaf extract experienced a decrease in fatty acids and an increase in amino acids. The test results of the pharmacokinetic profile of glibenclamide were different between a single administration and a combination of binahong leaf extract. Giving glibenclamide (4.5mg/kg BW) with binahong leaf extract (70mg/kg BW) can reduce AUC and Cmax and prolong Tmax. The results of gibs free energy (ΔG) on molecular docking obtained the values of glibenclamide and vitexin, which bind to the CYP3A4 receptor with a ChemPLP score of -4.4 kcal/mol, glibenclamide with a receptor -3.2 kcal/mol and vitexin with a receptor of-3,2 kcal/mol. Conclusion The results of this study show that the administration of a combination of glibenclamide (4.5 mg/kg BW) with binahong leaf extract dose 1 (17.5 mg/kg BW), dose 2 (35 mg/kg BW) and dose 3 (70mg/kg BW) orally can lower blood glucose levels in rats induced by a high-fat diet, but the percentage reduction in blood glucose levels was better in the group that was only given glibenclamide 4.5 mg/kgBW (positive group), while in the group that was only given binahong extract doses of 1,2 and 3 also experienced a decrease in glucose levels but the percentage decrease in glucose levels was not greater than the positive control group. In the pharmacokinetic test orally administering a combination of glibenclamide (4.5 mg/kg BW) with binahong leaf extract (70 mg/kg BW) can reduce glibenclamide drug levels in rat plasma."

"Leukotrien adalah salah satu mediator inflamasi yang dihasilkan dari asam arakhidonat melalui jalur lipoksigenase. Pembentukan leukotrien dapat dicegah melalui penghambatan aktivitas enzim lipoksigenase dengan cara mengkhelat besi pada enzim lipoksigenase, sehingga tidak bereaksi dengan substrat untuk membentuk leukotrien. Daun Anredera cordifolia (Ten.) Steenis telah diteliti memiliki efek antiinflamasi pada dosis 50,4 mg/200 g BB dengan persentase penghambatan edema sebesar 10,49 %, namun aktivitas dalam menghambat enzim lipoksigenase belum diteliti. Tujuan dari penelitian ini adalah menguji efek antiinflamasi ekstrak etanol 96% dan fraksi daun Anredera cordifolia (Ten.) Steenis dengan metode penghambatan aktivitas enzim lipoksigenase yang diukur pada λ = 234 nm. Ekstrak etanol 96% diekstraksi secara maserasi dan diremaserasi sebanyak 10 kali. Selanjutnya difraksinasi secara partisi cair-cair, kemudian diuji penghambatan lipoksigenase. Hasil uji menunjukkan nilai IC50 yang diperoleh dari ekstrak etanol 96% adalah 0,115 μg/mL. Fraksi dengan aktivitas penghambatan tertinggi dari daun Anredera cordifolia (Ten.) Steenis adalah fraksi etil asetat diikuti oleh fraksi n-butanol dan fraksi n-heksana (IC50 0,197; 2,262 dan 7,812 μg/mL). Daun Anredera cordifolia (Ten.) Steenis memiliki aktivitas penghambatan enzim lipoksigenase yang tinggi bila dibandingkan dengan baikalein sebagai kontrol positif.

---

Leukotrienes are one of the mediators of inflammation which produced from arachidonic acid through the lipoxygenase pathway. The formation of leukotrienes can be prevented through the inhibition of lipoxygenase enzyme activity by chelated iron on lipoxygenase enzyme, so it does not react with the substrate to produce leukotrienes. Anredera cordifolia (Ten.) Steenis leaves have been studied have anti-inflammatory effects at a dose of 50,4 mg/200 g BB with edema inhibition percentage of 10,49%, but the activity in inhibiting the enzyme lipoxygenase has not been studied. The purpose of this study was to test the anti-inflammatory effects of ethanol 96% extract and fractions of Anredera cordifolia (Ten.) Steenis leaves by inhibiting the lipoxygenase enzyme activity measured at λ = 234 nm. Ethanol 96% extract extracted by maceration and 10 times remaceration. Furthermore fractionated by liquid-liquid partition then tested its inhibition of lipoxygenase. The test results showed IC50 values were obtained from the ethanol 96% extract was 0,115 μg/mL. The fraction with the highest inhibitory activity of Anredera cordifolia (Ten.) Steenis leaves is a fraction of ethyl acetate followed by a fraction n-butanol and n-hexane fraction (IC50 0,197; 2,262 and 7,812 μg/mL). Anredera cordifolia (Ten.) Steenis leaves has high activity for inhibiting the enzyme lipoxygenase if compared to baicalein as a positive control."

"Azithromycin (AZI) adalah antibiotika yang digunakan secara luas. AZI merupakan obat yang memiliki spesifikasi kelarutan yang rendah dalam air serta memiliki nilai bioavailabilitas oral rendah yaitu sebesar 37%. Rendahnya kelarutan dan bioavailabilitas oral AZI dapat berdampak pada rendahnya efek terapetik obat tersebut. Teknik enkapsulasi dan sistem penghantar obat melalui nanocarrier adalah metode alternatif untuk meningkatkan bioavailabilitas obat yang memiliki kelarutan rendah dalam air. Nanopartikel kitosan (NPKS) adalah salah satu polimer yang paling umum digunakan sebagai penghantar obat. Pada penelitian ini nilai efisiensi enkapsulasi dan kapasitas pemuatan AZI pada NPKS berhasil ditingkatkan dengan memodifikasi NPKS menggunakan ekstrak daun binahong (EDB). Metabolit sekunder pada EDB dapat bereaksi dengan gugus amina pada NPKS dan meningkatkan sifat hidrofobiknya sehingga interaksi antara NPKS dengan AZI menjadi lebih baik. Hal tersebut dapat terlihat dari nilai efisiensi enkapsulasi dan kapasitas pemuatan AZI yang sangat baik untuk NPKS- EDB-AZI yaitu pada nilai 95,24 ± 1,30% dan 55,74 ± 1,03%. Hasil karakterisasi TEM menunjukkan bahwa NPKS-EDB-AZI terdistribusi secara homogen dengan ukuran partikel 24,6 ± 2,9 nm. Berdasarkan hasil uji pelepasan obat in vitro, NPKS-EDB-AZI melepaskan AZI sebesar 1,12 ± 0,33% ketika ditempatkan pada pH 1,6 selama 2 jam, 82,05 ± 2,23% pada pH 6,8 selama 6 jam, dan 93,44 ± 1,94% ketika ditempatkan pada pH 7,4 selama 16 jam. Penelitian ini menunjukan bahwa NPKS yang termodifikasi EDB dapat dimanfaatkan sebagai sistem penghantar azithromycin dengan nilai efisiensi pemuatan dan kapasitas pemuatan yang baik, serta memberikan sifat pelepasan obat secara terkontrol.

---

Azithromycin (AZI) is a widely used antibiotic. AZI is a drug that has a low solubility in water and a low oral bioavailability value of 37%. The low solubility and oral bioavailability of AZI can have an impact on the low therapeutic effect of the drug. Encapsulation techniques and drug delivery systems via nanocarriers are alternative methods to improve the bioavailability of drugs that have low solubility in water. Chitosan nanoparticles (NPKS) are one of the most commonly used polymers as drug conductors. In this study, the value of encapsulation efficiency and AZI loading capacity on NPKS was successfully increased by modifying NPKS using binahong leaf extract (EDB). Secondary metabolites in EDB can react with amine groups in NPKS and increase their hydrophobic properties so that the interaction between NPKS and AZI becomes better. This can be seen from the excellent encapsulation efficiency and AZI loading capacity values for NPKS-EDB-AZI, namely 95.24 ± 1.30% and 55.74 ± 1.03%. The results of TEM characterization showed that NPKS-EDB-AZI was homogeneously distributed with a particle size of 24.6 ± 2.9 nm. Based on the results of in vitro drug release tests, NPKS-EDB-AZI released AZI of 1.12 ± 0.33% when placed at pH 1.6 for 2 hours, 82.05 ± 2.23% at pH 6.8 for 6 hours, and 93.44 ± 1.94% when placed at pH 7.4 for 16 hours. This study shows that EDB-modified NPKS can be used as an azithromycin delivery system with good loading efficiency and loading capacity and controlled drug release properties.

"

"Penyakit COVID-19 yang merebak di seluruh dunia pada akhir tahun 2019 diakibatkan oleh virus SARS-CoV-2. Penelitian ini membahas simulasi penambatan serta dinamika molekuler dari beberapa senyawa herbal dari tumbuhan Anredera cordifolia (binahong) yaitu procyanidin, metil linoleat, asam oleat dan vitexin dengan protein target (Mpro SARS-CoV-2). Simulasi dinamika molekuler dilakukan selama 20 ns. Selain itu, analisis toksikologi dan farmakologi (ADMET) dilakukan untuk setiap ligan. Hasil simulasi ini dibandingkan dengan ligan kontrol quercetin yang sudah terbukti memiliki interaksi yang baik dengan protein target (Mpro SARS-CoV-2). Hasil prediksi ADMET menunjukkan bahwa semua ligan baik untuk dijadikan obat, kecuali metil linoleat dan asam oleat. Simulasi penambatan molekuler menunjukkan procyanidin serta vitexin memiliki skor penambatan dan binding energy paling baik. Hasil dinamika molekuler juga membuktikan procyanidin, vitexin dan quercetin memiliki nilai RMSD dan RMSF paling baik dan menunjukkan interaksi paling stabil dan kompleks dengan protein target. Sehingga, secara keseluruhan, procyanidin dan vitexin berpotensi untuk menjadi inhibitor Mpro SARS-CoV-2.

---

COVID-19 that spread across the globe at the end of 2019 is caused by the SARS-CoV-2. This virus attacks human respiratory cell. Until now, there is no efficacious drug to treat this disease. This sudy discusses molecular docking and molecular dynamics simulations of four herbal compounds from Anredera cordifolia (binahong), which are procyanidin, methyl linoleate, oleic acid, as well as vitexin with Mpro SARS-CoV-2 as the protein target. The molecular dynamics simulations were carried out for 20 ns. In addition, toxicological and pharmacological analyses (ADMET) were performed for each ligand. The results were compared to quercetin as the control ligand, which has been shown to have good interaction with the protein target. ADMET prediction results show that all ligands are good for use as drugs, except methyl linoleic and oleic acid. Molecular docking simulation results show that procyanidin and vitexin have the docking scores and binding energy scores. The results of molecular dynamics also prove that procyanidin, vitexin and quercetin have the best RMSD and RMSF values ​​and show the most stable as well as complex interactions with target proteins. Thus, procyanidin and vitexin have the potential to be Mpro SARS-CoV-2 inhibitors."

"Telah dilakukan penelitian untuk mengetahui pengaruh campuran ekstrak tanaman binahong (Anredera cordifolia (Ten.) Steenis) dan sambiloto (Andrographis paniculata Nees) terhadap kadar glukosa darah tikus putih (Rattus norvegicus L.) jantan. Tikus dikelompokkan menjadi delapan kelompok. Kelompok kontrol normal tidak diinduksi aloksan dan diberi larutan Carboxy Methyl Cellulose (CMC). Kelompok lainnya diinduksi aloksan dosis 100 mg/kg bb secara intraperitoneal dan masing-masing diberi larutan CMC (kelompok kontrol negatif), Glibenclamide® (kelompok kontrol positif), ekstrak binahong dosis 250 mg/kg bb (kelompok perlakuan ekstrak binahong), ekstrak sambiloto dosis 500 mg/kg bb (kelompok perlakuan ekstrak sambiloto), dan campuran ekstrak dosis 750 mg/kg bb (kelompok perlakuan campuran ekstrak dosis 1); dosis 375 mg/kg bb (kelompok perlakuan campuran ekstrak dosis 2); serta dosis 187,5 mg/kg bb (kelompok campuran ekstrak dosis 3). Pemberian bahan uji dilakukan secara oral selama 21 hari berturut-turut. Hasil uji Kruskal-Wallis dan Anava 1-faktor (P < 0,05) menunjukkan bahwa ketiga dosis campuran ekstrak berpengaruh nyata terhadap penurunan rerata kadar glukosa darah. Penurunan kadar glukosa darah terbesar dicapai oleh kelompok dosis 750 mg/kg bb dengan rerata kadar glukosa darah mendekati nilai kelompok normal, yakni pada hari ke-15 sebesar 121,36 mg/dl dan pada hari ke-22 sebesar 85,37 mg/dl.

---

The research was done in order to determine the effect of a mixture of extract binahong (Anredera cordifolia (Ten.) Steenis) and sambiloto (Andrographis paniculata Nees) on blood glucose levels of male white rats (Rattus norvegicus L.). The male rats were divided into eight groups. Normal control group was not induced alloxan and given Carboxy Methyl Cellulose (CMC) solution. The others were induced alloxan at dose of 100 mg/kg body weight intraperitoneally and each of them was given CMC solution (negative control group), Glibenclamide® (positive control group), binahong extract at dose of 250 mg/kg body weight (binahong group), sambiloto extract at dose of 500 mg/kg body weight (sambiloto group), and mixture extract at dose of 750 mg/kg body weight; 375 mg/kg body weight; and 187,5 mg/kg body weight. The test materials were administrated for 21 consecutive days orally. The result of this experiment showed that statistically both single and mixture extract could decrease blood glucose levels significantly (P < 0,05). The highest decrease of blood glucose levels was achieved by the mixture extract at dose of 750 mg/kg body weight with an average value of blood glucose level 121,36 mg/dl (14 days after treatment) and 85,37 mg/dl (21 days after treatment). "