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All Journal Jurnal Ilmu Pertanian Indonesia JURNAL SAINS DAN TEKNOLOGI INDONESIA ALCHEMY Jurnal Penelitian Kimia Indonesian Journal of Chemistry Makara Journal of Science
Budi Arifin
Department Of Chemistry, Bogor Agricultural Institute, Jl. Agatis Kampus IPB Darmaga Bogor 16680
Agriculture, Biological Sciences & Forestry Chemical Engineering, Chemistry & Bioengineering Chemistry Computer Science & IT Education Energy Environmental Science Materials Science & Nanotechnology

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PERILAKU DISOLUSI KETOPROFEN DAN INDOMETASIN FARNESIL TERSALUT GEL KITOSAN-GOM GUAR Sugita, Purwantiningsih; Srijanto, Bambang; arifin, budi; amelia, fithri; mubarok, mahdi
Jurnal Sains dan Teknologi Indonesia Vol. 12 No. 1 (2010)
Publisher : Badan Pengkajian dan Penerapan Teknologi

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (271.557 KB) | DOI: 10.29122/jsti.v12i1.849

Abstract

Chitosan, a modification of shrimp-shell waste, has been utilized as microcapsule. However, it’s fragile gel property needs to be strengthened by adding glutaraldehyde (glu) and natural hydrocolloid guar gum (gg). This research’s purposes were to study dissolution behaviour of ketoprofen and infar through optimum chitosan-guar gum microcapsule. Into 228.6 mL of 1.75% (w/v) chitosan solution in 1% (v/v) acetic acid,38.1 mL of gg solution was added with concentration variation of 0.35, 0.55, and 0.75% (w/v) for ketoprofen microcapsules and 0.05, 0.19, and 0.33% (w/v) for infar microcapsules, and stirred with magnetic stirrer until homogenous. Afterwards, 7.62mL of glu was added slowly under stirring, with concentrations varied: 3, 3.5, and 4% (v/v) for ketoprofen microcapsules, and 4, 4.5, and 5% (v/v) for infar microcapsules. All mixtures were shaked for 20 minutes for homogenization. All mixtures wereshaked for 20 minutes for homogenization. Into each microcapsule mixture for ketoprofen, a solution of 2 g of ketoprofen in 250 mL of 96% ethanol was added, whereas solution of 100 mg of in 250 mL of 96% ethanol was added into each microcapsule mixture for infar. Every mixture was then added with 5 mL of 2% Tween-80 and stirred with magnetic stirrer for an hour at room temperature. Everymixture was then added with 5 mL of 2% Tween-80 and stirred with magnetic stirrer for an hour at room temperature. Conversion of suspension into fine powders/granules (microcapsules) was done by using spray dryer. The data of [gg], [glu], and medicine’s content from each microcapsule were treated with Minitab 14 software to obtain optimum [gg] and [glu] for microencapsulation. The dissolution behaviour of optimum ketoprofen and infar microcapsules were investigated. The result of optimization by using Minitab Release 14 software showed that among the microcapsule compositions of [gg] and [glu] were 0.35% (w/v) and 3.75% (v/v), respectively, optimum to coat ketoprofen, whereas [gg] and [glu] of 0.05% (w/v) and4.00% (v/v), respectively, optimum to coat infar, at constant chitosan concentration (1.75% [w/v]). In vitro dissolution profile showed that chitosan-guar gum gel microcapsule was more resistant in intestinal pH condition (rather basic) compared with that in gastric pH (very acidic).
Perilaku Disolusi Ketoprofen dan Indometasin Farnesil Tersalut Gel Kitosan-GG Purwantiningsih Sugita; Achmad Sjahriza; Bambang Srijanto; Budi Arifin
Jurnal Ilmu Pertanian Indonesia Vol. 13 No. 2 (2008): Jurnal Ilmu Pertanian Indonesia
Publisher : Institut Pertanian Bogor

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (687.004 KB)

Abstract

Chitosan, a modification of shrimp-shell waste, has been utilized as microcapsule. However, it's fragile gel property needs to be strengthened by adding glutaraldehyde (glu) and natural hydrocolloid guar gum (gg). This research's purposes were to determine rheological properties of chitosan-guar gum gel, to study diffusion and dissolution behaviour of ketoprofen and infar through optimum chitosan-guar gum gel membrane and microcapsule, respectively, and to test the coating stability of both medicines by the gel microcapsules, which are new drug's preparation, to determine their shelf lives and to predict the degradation mechanisms. This research was designed in six (6) steps: (1) chitin isolation and chitosan synthesis; (2) synthesis and optimization of chitosan-guar gum gel membrane; (3) in vitro study of ketoprofen and infar diffusion behaviour through the optimum membrane; (4) synthesis and optimization of chitosan-guar gum gel microcapsule to coat ketoprofen and infar; (5) in vitro study of ketoprofen and infar dissolution behaviour from the optimum microcapsule; and (6) physical and chemical microcapsule stability test using relative humidity (RH) and temperature controlled climatic chamber method. Studies on ketoprofen diffusion through chitosan-guar gum membrane showed that the formation of membrane small pores were appeared to be caused by membrane swelling, which was supported by the forcing force resulted from the difference of ketoprofen concentrations in the diffusion cells and from the temperature increase. This unique pore opening process is excellent for drug delivery process as a microcapsule. Spray drying process had successfully coated ketoprofen and infar in chitosan-guar gum microcapsule. Optimization by using Minitab Release 14 software showed that among the microcapsule compositions studied, [gg] and [glu] of 0.35% (w/v) and 3.75% (v/v), respectively were optimum to coat ketoprofen, whereas [gg] and [glu] of 0.05% (w/v) and 4.00% (v/v), respectively were optimum to coat infar, at constant chitosan concentration (1.75% [w/v]). In vitro dissolution profile showed that chitosan-guar gum gel microcapsule was more resistant in intestinal pH condition (rather basic) compared with that in gastric pH (very acidic). From stability test, formulation of ketoprofen preparation composed of 1.75% (w/v) chitosan, 0.35% (w/v) gg, and 3.50% (v/v) glu, was relatively the best, ·with ketoprofen percentage left in microcapsule after 3 months, degradation rate constant, and shelf life of of 80.33%, 0.0351 % week-1 and 18.92 months, respectively. The degradation of ketoprofen was seem to follow autocatalytic reaction mechanism controlled by the formation and growth of reaction core. In the other hand, the formulation with composition of 1.75% (w/v) chitosan, 0.19% (w/v) gg, and 5.00% (v/v) glu, was relatively the best microcapsule, with infar percentage left in microcapsule after 3 months, degradation rate constant, and shelf life of 77.67%, 0.0008 %-2 week-1 , and 4.28 week or about 30 days, respectively. The degradation of infar was presumably caused by hydrolysis.   Keywords: Chitosan-guar gum, diffusion, dissolution, stability
Optimalisasi Sifat Reologi Hidrogel Kitosan-Hialuronat yang Ditaut-Silang dengan Glutaraldehida Pajri Samsi Nasution; Muhamad Alif Hamimdal; Gustini Syahbirin; Budi Arifin
ALCHEMY Jurnal Penelitian Kimia Vol 15, No 1 (2019): Maret
Publisher : UNIVERSITAS SEBELAS MARET (UNS)

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (461.927 KB) | DOI: 10.20961/alchemy.15.1.22536.24-43

Abstract

Kitosan membentuk hidrogel polikationik dengan penambahan glutaraldehida sebagai penaut-silang. Penambahan hialuronat yang bersifat polianionik diharapkan akan meningkatkan sifat reologis hidrogel tersebut. Penelitian ini mengevaluasi pengaruh konsentrasi glutaraldehida dan hialuronat pada kekuatan gel, titik pecah, dan ketegaran, serta sifat pembengkakan dan pengerutan hidrogel kitosan, dan menentukan konsentrasi optimum keduanya melalui analisis data dengan perangkat lunak Modde 5Ò. Hialuronat meningkatkan kekuatan gel, titik pecah, dan ketegaran hidrogel kitosan pada konsentrasi glutaraldehida yang rendah, tetapi berpengaruh sebaliknya pada konsentrasi glutaraldehida yang tinggi. Sejalan dengan itu, pembengkakan juga menjadi relatif tinggi, sedangkan pengerutan menjadi relatif rendah setelah penambahan hialuronat, tetapi hanya pada konsentrasi glutaraldehida yang rendah. Berdasarkan hasil ini, hialuronat diperkirakan mengisi ruang kosong di antara taut-silang imina yang terbentuk antara glutaraldehida dan kitosan. Pada konsentrasi glutaraldehida yang tinggi, taut-silang ini tidak menyisakan lagi ruang kosong bagi hialuronat. Sebaliknya, air sedikit demi sedikit akan terdesak keluar dari dalam hidrogel dan memicu pengerutan. Komposisi optimum diperoleh pada konsentrasi kitosan 2,0% (b/v), hialuronat 0,3% (v/v) dan glutaraldehida 1,4% (v/v), yang memberikan kekuatan gel, titik pecah, ketegaran, pembengkakan dan pengerutan berturut-turut sebesar 678,4 g cm-2; 1,294 cm; 5,033 g cm-1; 2,634 g dan 0,148 g. Pengukuran sifat reologi hidrogel yang dibuat dengan komposisi optimum tersebut memberikan hasil yang lebih rendah (190,7 g cm-2; 0,767 cm; 1,675 g cm-1) untuk tiga sifat reologi pertama, tetapi lebih tinggi (2,844 g and 0,348 g) untuk dua sifat berikutnya.Optimization of Rheological Property of Chitosan-Hyaluronate Hydrogel Crosslinked by Glutaraldehyde. Chitosan forms a polycationic hydrogel by addition of glutaraldehyde as a crosslinker. The addition of hyaluronate which is polyanionic is expected to improve the rheological properties of the hydrogel. This study evaluated the effects of glutaraldehyde and hyaluronate concentration on the gel strength, breakpoint, and rigidity of the chitosan hydrogel as well as the swelling and shrinking properties. This study determined the optimum concentration of both of glutaraldehyde and hyaluronate by data analysis using Modde 5Ò software. Hyaluronate increased the gel strength, breakpoint, and rigidity at a low glutaraldehyde concentration, but showed the opposite effects at high glutaraldehyde concentration. At a low concentration of glutaraldehyde, relatively high swelling and low shrinking were revealed after hyaluronate addition. From these results, it was suggested that hyaluronate filled the empty spaces between the imine-crosslinks created by glutaraldehyde and chitosan. At high concentration of glutaraldehyde, the crosslinks became so extensive that no more space was left for hyaluronates. Otherwise, water would be squeezed out from the hydrogel and syneresis would happen. The optimum composition was obtained at 2.0% (w/v) chitosan, 0.3% (v/v) hyaluronate and 1.4% (v/v) glutaraldehyde, which achieved the gel strength, breakpoint, rigidity, swelling and shrinking of 678.4 g cm-2, 1.294 cm, 5.033 g cm-1, 2.634 g and 0.148 g, respectively. However, rheological property measurement of hydrogel synthesized by using the optimum composition gave lower results (190.7 g cm-2, 0.767 cm, 1.675 g cm-1) for the first three properties, but higher results (2.844 g and 0.348 g) for the latter two.
Transformation of Eugenol and Safrole into Hydroxychavicol Budi Arifin; Dumas Flis Tang; Suminar Setiati Achmadi
Indonesian Journal of Chemistry Vol 15, No 1 (2015)
Publisher : Universitas Gadjah Mada

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (503.955 KB) | DOI: 10.22146/ijc.21227

Abstract

Hydroxychavicol is found in betel leaf at low concentration and is reported to have antibacterial, anti-inflammatory, antioxidant, anticancer, and antimutagenic activities. This study aimed to synthesize hydroxychavicol from eugenol and safrole. Isolation of eugenol from clove oil by alkaline extraction method gave 71% yield, while the isolation of safrole from lawang oil by alkaline extraction method, followed by purification using preparative thin layer chromatography, gave 7% yield. Eugenol demethylation and safrole demethylenation with AlCl3 reagent were successfully produced hydroxychavicol. The yields were 28% and 24%, respectively. Mechanisms of the synthesis are proposed in this article.
DIFFUSION BEHAVIOR OF KETOPROFEN THROUGH CHITOSAN-ALGINATE MEMBRANES Purwantiningsih Sugita; Rini Siswati Asnel; Budi Arifin; Tuti Wukirsari
Indonesian Journal of Chemistry Vol 10, No 3 (2010)
Publisher : Universitas Gadjah Mada

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (416.425 KB) | DOI: 10.22146/ijc.21429

Abstract

Chitosan-alginate membrane diffusion behavior has been investigated for its application in drugs delivery system. Ketoprofen diffusion behavior assay were performed at 37 and 42 °C to membrane thickness (h) and donor cell concentration of ketoprofen variations (A). The results showed that equilibrium concentrations (Cs) of ketoprofen equation was 27.0087 + 0.09067T - 1.7499h + 0.1030A + 0.0161h2 - 0.0022A2 + 0.0040Th - 0.0018TA + 0.0095hA. The value of Cs was closer to the expected therapy concentration at 50 and 75 mg/L with thin membrane (10-34 μm). Based on Higuchi equation, the model for J and D were J = 11.0849 - 0.2713T - 0.3132h - 0.7461Cs - 0.0096A - 0.0001h2 - 0.0131Cs2 + 0.0002A2 + 0.0084Th + 0.0275TCs - 0.0018TA - 0.0059hCs + 0.0021hA + 0.0037CsA with R2 = 97.9% and D = -12.5000 + 0.2266T + 0.1313h + 0.1538Cs + 0.1200A - 0.0009h2 + 0.0240 Cs2 - 0.0009A2 + 0.0015Th - 0.0150 TCs - 0.0011TA - 0.0096hCs + 0.0004hA + 0.0039CsA with R2 = 98.7%, respectively. The two dimensional contour maps of J versus A and h, both at 37 and 42 °C, showed an increasing of J value as A, h, or T increased.
STABILITY OF KETOPROFEN COATED BY CHITOSAN-GUAR GUM GEL Purwantiningsih Sugita; Bambang Srijanto; Budi Arifin; Ellin Vina Setyowati
Indonesian Journal of Chemistry Vol 9, No 3 (2009)
Publisher : Universitas Gadjah Mada

Show Abstract | Download Original | Original Source | Check in Google Scholar | Full PDF (356.602 KB) | DOI: 10.22146/ijc.21504

Abstract

The coating stability of ketoprofen by chitosan-guar gum gel has been studied. Into 228.6 mL of 1.75% (w/v) chitosan solution in 1% (v/v) acetic acid, 38.1 mL of guar gum (gg) solution was added with concentration variation of 0.35, 0.55, and 0.75% (w/v) for ketoprofen microcapsules, and stirred with magnetic stirrer until homogenous. Afterwards, 7.62 mL of glutaraldehyde (glu) was added slowly under stirring, with concentrations varied: 3, 3.5, and 4% (v/v). All mixtures were shaked for 20 min for homogenization. Into each microcapsule mixture for ketoprofen, a solution of 2 g of ketoprofen in 250 mL of 96% ethanol was added. Every mixture was then added with 5 mL of 2% Tween-80 and stirred with magnetic stirrer for an hour at room temperature. Conversion of suspension into fine powders/granules (microcapsules) was done by using spray dryer. Every microcapsule formula was packed into capsules, as much as 100 g per capsule. The capsules were contained in 100-mL dark bottles and the bottles were kept in climatic chamber at (40 ± 2) °C and RH (75 ± 5) % for 3 months. The microcapsule stabilities were tested chemically and physically. The result showed that formulation of ketoprofen preparation composed of 1.75% (w/v) chitosan, 0.35% (w/v) gg, and 3.50% (v/v) glu, was relatively the best, with ketoprofen percentage left in microcapsule after 3 months, degradation rate constant, and shelf life of 80.33%, 0.0351 % week-1, and 18.92 months, respectively. Reaction kinetic model for this formula followed Prout-Tompkins equation and the degradation of ketoprofen was seem to follow autocatalytic reaction mechanism controlled by the formation and growth of reaction core.
Blended Film from PVA and Sansevieria trifasciata Dichloromethane Fraction for Reducing Heat Radiation from Smartphones Ilmiawati, Auliya; Pujiyati,; Hidayat, Asep; Sugita, Purwantiningsih; Irfana, Luthfan; Arifin, Budi
Makara Journal of Science
Publisher : UI Scholars Hub

Show Abstract | Download Original | Original Source | Check in Google Scholar

Abstract

It has been reported that the lidah mertua plant (Sansevieria trifasciata) can absorb electromagnetic radiation from vari-ous electronic equipment. The current study aimed to make a film layer from polyvinyl alcohol (PVA) and a dichloro-methane (DCM) fraction of S. trifasciatato reduce heat radiation from smartphones. S. trifasciataleaves were macer-ated using ethanol and partitioned with ethyl acetate, DCM, and n-butanol. The DCM fraction was chosen to create the film, for which PVA was also used. The blended film made from PVA and 0.02% DCM reduced heat radiation from smartphones by up to 4.4 °C starting from the first minute of use; its heat reduction remained stable until the 20th mi-nute. Based on these results, it was determined that the active compounds in the DCM fraction are closely related to saponin-type steroids.
Co-Authors Achmad Sjahriza Asep Hidayat Asep Hidayat Auliya Ilmiawati Bambang Srijanto Bambang Srijanto Bambang Srijanto Dumas Flis Tang Ellin Vina Setyowati fithri amelia Gustini Syahbirin Luthfan Irfana mahdi mubarok Muhamad Alif Hamimdal Pajri Samsi Nasution Pujiyati Pujiyati Pujiyati, Purwantiningsih Sugita Rini Siswati Asnel Suminar Setiati Achmadi Tuti Wukirsari