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"[Environmental silicate nano-biocomposites focuses on nano-biocomposites, which are obtained by the association of silicates such as bioclays with biopolymers. By highlighting recent developments and findings, green and biodegradable nano-composites from both renewable and biodegradable polymers are explored. This includes coverage of potential markets such as packaging, agricultures, leisure and the fast food industry. The knowledge and experience of more than twenty international experts in diverse fields, from chemical and biochemical engineering to applications, is brought together in four different sections covering : biodegradable polymers and silicates, clay/polyesters nano-biocomposites, clay/agropolymers nano-biocomposites, and Applications and biodegradation of nano-biocomposites. By exploring the relationships between the biopolymer structures, the processes, and the final properties Environmental silicate nano-biocomposites explains how to design nano-materials to develop new, valuable, environmentally friendly properties and uses. , Environmental silicate nano-biocomposites focuses on nano-biocomposites, which are obtained by the association of silicates such as bioclays with biopolymers. By highlighting recent developments and findings, green and biodegradable nano-composites from both renewable and biodegradable polymers are explored. This includes coverage of potential markets such as packaging, agricultures, leisure and the fast food industry. The knowledge and experience of more than twenty international experts in diverse fields, from chemical and biochemical engineering to applications, is brought together in four different sections covering : biodegradable polymers and silicates, clay/polyesters nano-biocomposites, clay/agropolymers nano-biocomposites, and Applications and biodegradation of nano-biocomposites. By exploring the relationships between the biopolymer structures, the processes, and the final properties Environmental silicate nano-biocomposites explains how to design nano-materials to develop new, valuable, environmentally friendly properties and uses. ]"

"Nanokomposit polimer-clay merupakan bahan dengan matrik polimer yang diperkuat dengan nanofiller seperti lapisan silika. Pada penelitian ini pembuatan nanokomposit diawali dengan pembuatan masterbatch organo clay dengan penggunaan pelarut kemudian dicampur dengan polimer. Masterbatch dalam penelitian ini dihasilkan dari pencampuran Organo Layered Silicate (OLS), Ethylene Glycol, dan Polypropylene grafted maleic An hydride (PP-g-MA). Pembuatan nanokomposit polipropilen clay dilakukan di dalam mesin Rheomex (twin screw extruder) dengan mencampur masterbatch dan PP. Pengujian material yang dilakukan adalah pengujian XRD, TEM, HDT, dan uji tarik. Hasil yang diperoleh pada pengukuran HDT menunjukkan kenaikan sebesar 22 % pada komposit OLS Nanomer I.44PT dibanding dengan nilai HDT PP murni. Modulus elastisitas menunjukkan kenaikan sebesar 36 % pada komposit OLS DTDA dibanding dengan PP murni.

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Polimer - clay nanocomposite is a material with a polimer matrix which is toughened by nanofiller such as silica particles. In this research,, nanocomposite was prepared from the production of organoclay masterbatch through a mixture of a solvent and a polymer. The masterbatch were produced from a mixture of organo layered silicate (OLS), Ethylene Glycol, and Polypropylene grafted maleic An hydride (PP-g-MA). The production of PP clay nanocomposite was done in Rheomex machine (twin screw extruder) by mixing the masterbatch and PP. The materials evaluated were using XRD, TEM, HDT, and tensile test. The results of HDT measurement showed that the OLS Nanomer composites were 22 % higher compared to the pristine PP. The modulus of elasticity of OLS ? DTDA composites increased 36 % compared to the pristine PP."

"Health and environmental safety of nanomaterials addresses concerns about the impact of nanomaterials on the environment and human health, and examines the safety of specific nanomaterials. Understanding the unique chemical and physical properties of nanostructures has led to many developments in the applications of nanocomposite materials. While these materials have applications in a huge range of areas, their potential for toxicity must be thoroughly understood.Part one introduces the properties of nanomaterials, nanofillers, and nanocomposites, and questions whether they are more toxic than their bulk counterparts. Part two looks at the release and exposure of nanomaterials. The text covers sampling techniques and data analysis methods used to assess nanoparticle exposure, as well as protocols for testing the safety of polymer nanocomposites. It explains characterization techniques of airborne nanoparticles and life cycle assessment of engineered nanomaterials. Part three focuses on the safety of certain nanomaterials, including nanolayered silicates, carbon nanotubes, and metal oxides. In particular, it explores the potential ecotoxicological hazards associated with the different structures of carbon nanotubes and the safe recycling of inorganic and carbon nanoparticles. The final two chapters address the risks of nanomaterials in fire conditions, their thermal degradation, flammability, and toxicity in different fire scenarios."

"Latar Belakang: Kemampuan adhesi siler terhadap dentin merupakan faktor penting dalam kesuksesan perawatan endodontik. Siler resin epoksi sebagai gold standart memiliki kemampuan adhesi yang superior, tetapi tidak memiliki sifat bioaktif sehingga berkembang siler kalsium silikat. Tujuan: Membandingkan kekuatan push-out bond strength dan failure mode siler AH Plus® Bioceramic dan Ceraseal dengan siler AH Plus®. Metode: Tiga puluh gigi premolar dibagi menjadi tiga kelompok untuk preparasi dan pengisian saluran akar menggunakan siler AH Plus® Bioceramic (kelompok 1), Ceraseal (kelompok 2) dan siler AH Plus® (kelompok 3). Sampel diinkubasi selama tujuh hari pada suhu 37oC, kemudian dipotong pada area sepertiga apikal dan medial. Nilai push-out bond strength dan failure mode dianalisis. Hasil: AH Plus® Bioceramic memiliki perbedaan nilai push-out bond strength dan failure mode yang signifikan dibanding AH Plus® dan Ceraseal. Ceraseal dan AH Plus® tidak memiliki perbedaan nilai secara signifikan. Analisis gambaran failure mode oleh dua orang observer menunjukkan reliabilitas data yang tinggi. AH Plus® Bioceramic memiliki dominasi kegagalan campuran, sedangkan Ceraseal dan AH Plus® memiliki persentasi kegagalan campuran dan kohesif yang seimbang. Kesimpulan: Seluruh kelompok siler menunjukkan kemampuan adhesi yang baik terhadap permukaan dentin, meskipun nilai push-out bond strength siler AH Plus® Bioceramic paling rendah diantara seluruh kelompok.

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Background: The adhesion of sealers to dentin is important for successful endodontic treatment. As the gold standard, epoxy resin sealers have superior adhesion, but lack bioactive properties, hence the development of calcium silicate sealers. Objective: To compare the push-out bond strength and failure mode of AH Plus® Bioceramic and Ceraseal sealers with AH Plus® Sealer. Methods: Thirty premolars were divided into three groups for root canal preparation and obturation with AH Plus® Bioceramic (group 1), Ceraseal (group 2), and AH Plus® (group 3). The samples were incubated at 37°C for seven days, then cut at the apical and medial third. Push-out bond strength and failure mode were analyzed. Results: AH Plus® Bioceramic demonstrated significant differences in push-out bond strength and failure mode values compared to AH Plus® and Ceraseal. Ceraseal and AH Plus® were not significantly different. Analysis of failure mode descriptions by two observers showed high data reliability. AH Plus® Bioceramic had a predominance of mixed failures, whereas Ceraseal and AH Plus® had equal percentages of mixed and cohesive failures. Conclusion: All sealer groups showed good adhesion to the dentin surface, although the push-out bond strength value of AH Plus® Bioceramic sealer was the lowest among the groups."

"Dalam penelitian ini telah dicoba untuk menambahkan partikel SiC dari 0 sampai 12,98% volume ke dalam tuangan paduan logam Aluminium-Silikon untuk meningkatkan sifat mekanis paduan tersebut. Pembuatan campuran ini adalah dengan metode pengecoran, yakni menggunakan dapur krusibel dan cetakan yang digunakan adalah cetakan logam. Dalam pengamatan yang dilakukan, didapat hasil bahwa dengan meningkatnya prosentase partikel SiC, didapat sifat mekanis bahan yaitu kuat tarik dan kekerasannya yang meningkat. Juga pengamatan jejak keausan dan hasil perhitungan laju keausan menunjukkan bahwa semakin tinggi prosentase SiC yang ditambahkan dalam campuran mempunyai titik optimal yaitu pada 11,25% volume SiC dimana pada penambahan partikel SiC dalam prosentase yang lebih besar lagi sifat mekanisnya akan turun."

"Adanya permasalahan mengenai tingkat emisi CO2, menyebabkan meningkatnya kesadaran untuk mengurangi emisi CO2 dengan penelitian untuk mengembangkan teknologi Carbon Capture, Storage, and Utilization (CCSU). Dikarenakan sumber magnesium silicate melimpah dan mudah untuk ditemukan di dunia, magnesium silicate digunakan untuk mengurangi emisi CO2dengan menangkap dan menyimpan CO2 menggunakan carbon capture storage (CCS). Pada penelitian ini, magnesium silicate diberikan perlakuan leaching untuk memulihkan kandungan unsur magnesiumnya. Filtrat hasil proses leachingakan digunakan untuk proses karbonasi dengan penambahan NH3 dan diinjeksikan oleh tekanan gas CO2. Perlakuan karbonasi menggunakan temperatur sebagai variabel bebas dengan variasi 30, 40, dan 50oC. Karakterisasi yang dilakukan yaitu pengujian X-ray Diffraction (XRD), X-Ray Fluorescence (XRF), Scanning Electron Microscope – energy dispersive X-ray (SEM–EDS), dan Inductively coupled plasma-optical emission spectrometry (ICP-OES) yang bertujuan untuk mengetahui morfologi mikrostruktur permukaan dan kandungan senyawa yang dihasilkan dari percobaan. Dari proses karbonasi didapatkan bahwa semakin tinggi temperatur proses karbonasi menghasilkan peningkatan konsentrasi unsur magnesium pada endapan yang dihasilkan. Pada proses karbonasi yang diinjeksi CO2 dengan penambahan NH3 membentuk senyawa hydromagnesite (Mg5(CO3)4(OH)2·4H2O), magnesium carbonate (MgCO3), dan calcium carbonate (CaCO3).

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The existence of problems regarding CO2 emission levels has led to increased awareness to reduce CO2 emissions with research to develop Carbon Capture, Storage, and Utilization (CCSU) technology. Because the source of magnesium silicate is abundant and easy to find in the world, magnesium silicate is used to reduce CO2 emissions by capturing and storing CO2 using carbon capture storage (CCS). In this study, magnesium silicate was treated with a leaching process to recover magnesium content. The leaching filtrate will be used for the carbonation process with the addition of NH3 and injected with CO2 gas pressure. The carbonation treatment uses temperature as an independent variable with variations of 30, 40 and 50oC. The characterization carried out was testing X-ray Diffraction (XRD), X-Ray Fluorescence (XRF), Scanning Electron Microscope-energy dispersive X-ray (SEM–EDS), and Inductively coupled plasma-optical emission spectrometry (ICP-OES) which aims to determine the morphology of the surface microstructure and the content of the experimental compounds. From the carbonation process it is known that the higher the temperature of the carbonation process results in an increase in the concentration of the element magnesium in the resulting precipitate. In the carbonation process, CO2 is injected with the addition of NH3 to form hydromagnesite (Mg5(CO3)4(OH)2·4H2O), magnesium carbonate (MgCO3), dan calcium carbonate (CaCO3)."

"Latar Belakang : Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi saat ini sedang dikembangkan untuk material perawatan di bidang kedokteran gigi, diantaranya sebagai material kaping pulpa. Tujuan utama dari perawatan ini adalah untuk menjaga vitalitas jaringan pulpa. Material kaping pulpa diharapkan bersifat biokompatibel dan memiliki sitositotoksisitas rendah sehingga beberapa pengujian perlu dilakukan untuk menentukan layak atau tidaknya bahan tersebut agar tidak menimbulkan respon biologis merugikan, karena maerial ini akan ditempatkan dekat dengan pulpa. Dasar dari uji sitositotoksisitas adalah kemampuan sel untuk bertahan hidup karena adanya senyawa toksik yang diberikan.  Tujuan : Mengetahui efek sitotoksisitas Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi terhadap sel fibroblas.Metode : Sel fibroblas NIH3T3 yang telah mengalami serum starvation selama 24 jam, diberikan media kultur semen hidraulik dikalsium silika campuran cangkang telur dan silika sekam padi dengan konsentrasi 1:1, 1:2, 1:4 dan DMEM sebagai kontrol negatif. Efek sitotoksisitas diuji pada 24 jam dan 48 jam menggunakan MTT Assay, hasil yang didapatkan dianalisis dengan uji statistik uji non parametrik Kruskal Wallis dilanjutkan dengan Post Hoc menggunakan Mann-Whitney untuk kelompok observasi 24 jam. Sedangkan pada observasi 48 jam didapatkan dianalisis dengan uji statistik uji parametrik One Way Annova dilanjutkan dengan Post Hoc menggunakan T-Test. Hasil : Tidak terdapat perbedaan bermakna nilai viabilitas sel pada pemberian semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi berbagai konsentrasi (1:1, 1:2, 1:4) terhadap sel fibroblas NIH3T3 pada observasi waktu 24 jam, dengan rerata nilai viabilitas tertinggi pada konsentrasi 1:4. Pada observasi 48 jam, terdapat perbedaan bermakna nilai viabilitas sel pada pemberian Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi berbagai konsentrasi (1:1, 1:2, 1:4) terhadap sel fibroblas NIH3T3, dengan rerata nilai viabilitas tertinggi kelompok perlakuan pada konsentrasi 1:4.Kesimpulan : Semen hidroulik dikalsium silikat campuran kalsium cangkang telur dan silika sekam padi berbagai konsentrasi (1:1, 1:2, 1:4) tidak memiliki efek  sitotoksisitas terhadap sel fibroblas NIH3T3 pada observasi waktu 24 jam dan 48 jam. Nilai viabilitas sel fibroblas NIH3T3 tertinggi pada observasi waktu 24 jam dan 48 jam terdapat pada konsentrasi 1:4.

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Background : Dicalcium silicate hydraulic cement, a mixture of eggshell calcium and rice husk silica, is currently being developed for treatment materials in dentistry, including pulp capping material. The main goal of this treatment is to maintain the vitality of the pulp tissue. The pulp capping material is expected to be biocompatible and have low cytotoxicity so that several tests need to be carried out to determine whether or not the material is feasible so as not to cause an adverse biological response, because this material will be placed close to the pulp. The basis of the cytotoxicity test is the ability of cells to survive in the presence of a given toxic compound.

Objective : To determine the cytotoxicity effect of hydraulic cement dicalcium silicate mixture of eggshell calcium and rice husk silica on fibroblast cells.

Methods : NIH3T3 fibroblast cells that had undergone serum starvation for 24 hours were given hydraulic cement culture media of dicalcium silica mixture of eggshell and rice husk silica with concentrations of 1:1, 1:2, 1:4 and DMEM as a negative control. The cytotoxicity effect was tested at 24 hours and 48 hours using MTT Assay, the results obtained were analyzed by statistical non-parametric Kruskal Wallis test followed by Post Hoc using Mann-Whitney for the 24-hour observation group. Meanw hile the 48-hour observation obtained was analyzed by statistical test One Way Annova parametric test followed by Post Hoc using T-Test.

Results: There was no significant difference in the value of cell viability in the administration of hydraulic cement dicalcium silicate mixture of eggshell calcium and rice husk silica at various concentrations (1:1, 1:2, 1:4) against NIH3T3 fibroblast cells at 24 hours of observation, with a mean the highest viability value at a concentration of 1:4. At 48 hours of observation, there was a significant difference in the value of cell viability in the administration of dicalcium silicate hydraulic cement, a mixture of eggshell calcium and rice husk silica at various concentrations (1:1, 1:2, 1:4) to NIH3T3 fibroblast cells, with the highest mean viability value. treatment group at a concentration of 1:4.

Conclusion : Dicalcium silicate hydraulic cement mixed with eggshell calcium and rice husk silica in various concentrations (1:1,1:2,1:4) did not have a cytotoxic effect on NIH3T3 fibroblast cells at 24 hours and 48 hours. The highest NIH3T3 fibroblast cell viability value at 24 hours and 48 hours was observed at a concentration of 1:4."