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"Latar Belakang: Salah satu material remineralisasi yang banyak digunakan adalah semen ionomer kaca (SIK). Namun dentin terdemineralisasi sesudah aplikasi SIK memiliki sifat mekanis yang berbeda dan lebih rendah daripada dentin normal karena remineralisasi yang terjadi adalah remineralisasi interfibril. Material carboxymethyl chitosan (CMC) bertindak sebagai analog protein nonkolagen yang mampu menstabilisasi nanocluster amorphous calcium phosphate (ACP) dalam proses remineralisasi intrafibril. Tujuan: Mengetahui pengaruh aplikasi modifikasi SIK-CMC5% dan SIK-CMC10% pada dentin terdemineralisasi terhadap kekerasan mikro, fasa mineral dan derajat kristalinitas dentin. Metode: Material SIK dilakukan pencampuran dengan CMC pada rasio 5% dan 10% menghasilkan SIK-CMC5% dan SIK-CMC10%. Kemudian, demineralisasi pada kavitas dentin terdemineralisasi dilakukan dengan aplikasi material SIK, SIK-CMC5% dan SIK-CMC10%. Akar gigi direndam dalam cairan phosphate-buffered saline selama 14 hari. Remineralisasi dentin dievaluasi dari kekerasan mikro melalui uji Vickers dan penilaian fasa mineral dan derajat kristalinitas dentin dari uji X-Ray Diffraction (XRD). Hasil: Kekerasan mikro dentin pada kelompok SIK-CMC5% dan SIK-CMC10% meningkat dibandingkan pada kelompok SIK. Pembentukan kristal hidroksiapatit ditemukan pada sampel SIK dan SIK-CMC, dengan derajat kristalinitas tertinggi pada sampel SIK-CMC10%. Kesimpulan: Semen Ionomer Kaca modifikasi Carboxymethyl Chitosan 10% lebih efektif dalam meningkatkan nilai kekerasan mikro dan mempengaruhi pembentukan fasa mineral kristal hidroksiapatit dan derajat kristalinitas.

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Background: One of the widely used remineralization materials is glass ionomer cement (GIC). However, demineralized dentine after GIC application has different and lower mechanical properties than normal dentin because the remineralization that occurs is interfibril remineralization. Carboxymethyl chitosan (CMC) acts as noncollagenous protein analog that can stabilize amorphous calcium phosphate (ACP) nanoclusters in intrafibril remineralization. Objective: To determine the effect of the application of modified GIC-CMC5% and GIC-CMC10% on the microhardness, mineral phase and degree of crystallinity of demineralized dentin. Methods: GIC material was mixed with CMC at ratio 5% and 10% to produce GIC-CMC5% and GIC-CMC10%. Remineralization of demineralized dentin cavity was carried out by applying GIC, GIC-CMC5% and GIC-CMC10% for 14 days. Remineralization was evaluated from microhardness value through Vickers test and assessment of mineral phase and degree of dentin crystallinity from X-Ray Diffraction (XRD) test. Results: Dentin microhardness in the GIC-CMC5% and GIC-CMC10% was increasing compared to the CIC group. The formation of hydroxyapatite crystals was found in the GIC and GIC-CMC samples with the highest degree of crystallinity in the GIC-CMC10% sample. Conclusion: Modified Glass Ionomer Cement with 10% Carboxymethyl Chitosan is more effective in increasing the microhardness value and affecting the formation of the hydroxyapatite crystalline mineral phase and the degree of crystallinity."

"Latar Belakang: Saat ini perawatan pulpa vital mengacu pada konsep minimal intervensi, yaitu dengan meninggalkan lapisan affected dentin saat ekskavasi karena masih terdapat ikatan silang kolagen sehingga dapat dilakukan upaya remineralisasi. Remineralisasi melalui aplikasi material bioaktif Mineral Trioxide Aggregate (MTA) belum dapat menghasilkan karakteristik dentin menyerupai dentin normal karena pembentukan mineral hanya terjadi pada ruang ekstrafibrillar. Penggunaan material analog protein non kolagen dibutuhkan untuk menstabilkan nano Amorphous Calcium Phosphate (ACP) agar dapat memasuki ruang intrafibrillar, salah satunya menggunakan Carboxymethyl Chitosan (CMC).Tujuan: mengevaluasi remineralisasi dentin pada permukaan dentin terdemineralisasi setelah aplikasi material MTA dan material modifikasi MTA-CMC dengan melihat morfologi permukaan dan komposisi ion pada dentin.Metode: remineralisasi dilakukan melalui aplikasi material MTA, MTA-CMC 5% dan 10% selama 14 hari pada permukaan sampel dentin yang terdemineralisasi. Pengamatan morfologi dilakukan dengan Scanning Electron Microscope (SEM) dan konfirmasi komposisi ion dengan Energy Dispersive X-ray Spectroscopy (EDX).Hasil: terdapat perbedaan morfologi pada permukaan dentin setelah dilakukan remineralisasi melalui aplikasi MTA, MTA-CMC 5%, dan MTA-CMC 10% selama 14 hari yang dievaluasi menggunakan SEM. Hasil analisis EDX mengonfirmasi adanya peningkatan kandungan kalsium dan fosfor pada permukaan dentin yang diremineralisasi dengan material MTA-CMC.Kesimpulan: remineralisasi melalui aplikasi material modifikasi MTA-CMC dapat memengaruhi morfologi permukaan dan komposisi ion pada permukaan dentin yang terdemineralisasi.

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Background: Vital pulp treatment refers to the concept of minimal intervention by preserving the affected dentin layer in the excavation process because there are still collagen cross-linked to induce remineralization. Remineralization through the application of bioactive material Mineral Trioxide Aggregate (MTA) produce different dentin characteristics to normal dentin because mineral formation only occurs in the extrafibrillar space. The use of non-collagen protein analog materials is needed to stabilize the nano Amorphous Calcium Phosphate (ACP) to get into the intrafibrillar space, one of which is Carboxymethyl Chitosan (CMC).

Objective: To evaluate dentin remineralization on the surface of demineralized dentin after the application of MTA and MTA-CMC modified material by looking at the surface morphology and ionic composition of the dentin.

Methods: The remineralization was carried out through the application of MTA,MTA-CMC 5%, MTA-CMC 10% materials for 14 days on the surface of demineralized dentin samples. Morphological observations were carried out by Scanning Electron Microscope (SEM) and confirmation of ion composition by Energy Dispersive X-ray Spectroscopy (EDX). Results: there were morphological differences on the dentin surface after remineralization through the application of MTA, MTA-CMC 5%, and MTA-CMC 10% for 14 days which were evaluated using SEM. The results of the EDX analysis confirmed an increase in the content of calcium and phosphorus on the dentin surface remineralized with MTA-CMC material.

Conclusion: remineralization through the application of MTA-CMC modified material can affect the surface morphology and ion composition on the demineralized dentin surface."

"Latar Belakang: Kegagalan perawatan karies gigi dapat terjadi jika mineral intrafibrillar dentin tidak teremineralisasi secara biomimetik. Semen ionomer kaca (SIK) merupakan bahan restorasi gigi dengan kemampuan melepaskan ion kalsium yang merupakan bahan baku remineralisasi. Carboxymethyl chitosan (CMC) merupakan analog protein non-kolagen alami yang terbukti dapat menstabilkan ion kalsium fosfat dalam keadaan amorf dalam proses remineralisasi biomimetik. Pencampuran kedua bahan tersebut berpotensi menghasilkan bahan restorasi baru yang dapat meremineralisasi dentin secara biomimetik. Tujuan: Mengevaluasi hasil remineralisasi dentin yang tedemineralisasi setelah aplikasi material modifikasi SIK dengan CMC 5% dan 10% dengan memeriksa perubahan morfologi dan komposisi ion kalsium dentin. Metode: Proses remineralisasi dilakukan dengan mengaplikasikan material SIK, SIK-CMC 5% dan 10% selama 14 hari pada kavitas dentin yang terdemineralisasi dengan EDTA 17% selama 7 hari. Evaluasi morfologi dilakukan dengan Scanning Electron Microscope (SEM) dan nilai komposisi ion diperiksa dengan Energy Dispersive X-ray (EDX). Hasil: Terlihat perubahan morfologi tubulus dan permukaan dentin setelah aplikasi bahan SIK, SIK-CMC 5%, dan SIK-CMC 10% selama 14 hari yang dievaluasi dengan SEM. Hasil pemeriksaan EDX memperlihatkan peningkatan kandungan ion kalsium dan pembentukan hidroksiapatit setelah aplikasi material SIK-CMC 10%. Kesimpulan: Aplikasi modifikasi SIK dengan CMC berpengaruh terhadap perubahan morfologi dan komposisi ion kalsium pada dentin yang terdemineralisasi.

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Background: Failure of dental caries treatment can occur if intrafibrillar dentin minerals are not biomimetically mineralized. Glass ionomer cement (GIC) is a dental restoration material with the ability to release calcium ions which are the raw material for remineralization. Carboxymethyl chitosan (CMC) is a natural non-collagen protein analogue which has been proven to stabilize calcium phosphate ions in an amorphous state in a biomimetic remineralization process. Mixing these two materials has the potential to produce new restorative materials that can biomimetically remineralize dentin. Objective: To evaluate the remineralization results of demineralized dentin after application of GIC modified material with 5% and 10% CMC by examining changes in the morphology and composition of dentin calcium ions. Method: The remineralization process was carried out by applying SIK material, SIK-CMC 5% and 10% for 14 days to the demineralized dentin cavity with 17% EDTA for 7 days. Morphological evaluation was carried out using a Scanning Electron Microscope (SEM) and ion composition values were examined using Energy Dispersive X-ray (EDX). Results: Changes in tubule morphology and dentin surface were seen after application of SIK, SIK-CMC 5%, and SIK-CMC 10% for 14 days as evaluated by SEM. The EDX examination results showed an increase in calcium ion content and hydroxyapatite formation after application of 10% SIK-CMC material. Conclusion: Application of GIC modification with CMC affects changes in morphology and calcium ion composition in demineralized dentin.

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"Latar Belakang : Remineralisasi Guided Tissue Remineralization (GTR) dentin digunakan untuk meningkatkan pembentukan kristal nano ke daerah gap zone serta membangun struktur mineral apatit pada kolagen demineralized dentin dan Carboxymethyl Chitosan (CMC) berperan sebagai protein analog serta memicu remineralisasi dentin. Tujuan: Mendapatkan novel semen carboxymethyl chitosan/amporphous calcium phosphate sebagai agen GTR dentin. Metode: Modifikasi CMC menjadi bubuk CMC/ACP (CA) melalui proses Freeze Dry dan modifikasi bubuk CA melalui proses milling 30 menit menjadi bubuk CMC/ACP paska milling (CAM) dan masing-masing dievaluasi menggunakan FTIR menganalisis gugus fungsi CMC dan gugus fungsi awal CA yang terbentuk. Bubuk CA dan CAM kemudian dicampurkan dengan gipsum hemihydrate pada rasio 5% dan 10% didapatkan kelompok novel semen CAG 5%, CAG 10%, CAMG 5% dan CAMG 10%. Kelompok tersebut dievaluasi menggunakan FTIR, XRD, SEM, setting time, ketahanan kompresi dan MTT assay. Novel semen tersebut diaplikasikan pada dentin terdemineralisasi selama 14 hari dan dievaluasi menggunakan TEM. Hasil: Gugus fungsi CMC berupa -CH2COOH dan N-H terlihat pada bubuk CA dan setelah dilakukan milling menjadi bubuk CAM. Tambahan gugus fungsi fosfat (-PO4) terlihat juga pada bubuk CA dan CAM. Gugus fungsi awal bubuk CA tetap terlihat pada bubuk CAM. Gugus fungsi fosfat (-PO4) terlihat juga pada kelompok novel semen CAG dan CAMG baik 5% dan 10%. Kombinasi bubuk CA dan CAM menggunakan gipsum mempengaruhi fasa mineral material. Kesan topografi berbeda pada novel semen CAG (5% dan 10%) dan novel semen CAMG (5% dan 10%). Terdapat perbedaan bermakna antara kelompok novel semen (CAG 5%, CAG 10%, CAMG 5% dan CAMG 10%) dibandingkan dengan gipsum (kontrol) pada setting time dan ketahanan kompresi (p<0.05). Viabilitas sel dari uji MTT assay menunjukkan novel semen CAMG 10% tidak toksik terhadap hDPSC. Novel semen CAG (5% dan 10%) dan novel semen CAMG (5% dan 10%) menunjukkan kesan remineralisasi dentin ekstrafibrillar dan intrafibrillar pada dentin terdemineralisasi. Kesimpulan: Modifikasi carboxymethyl chitosan melalui proses freeze dry dan milling serta pencampuran rasio 5% dan 10% menggunakan gipsum memiliki kemampuan untuk menginisiasi guided tissue remineralisazation dentin baik secara ekstrafibrillar dan intrafibrillar pada dentin terdemineralisasi.

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Background: Guided Tissue Remineralization (GTR) dentin is used to increase the formation of nanocrystals in the gap zone area and build an apatite mineral structure in demineralized dentin collagen and Carboxymethyl Chitosan (CMC) which acts as a protein analog and triggers dentin remineralization. Objective: To obtain a novel carboxymethyl chitosan/amorphous calcium phosphate cement as a dentinal GTR agent.Purpose: Obtained novel cement carboxymethyl chitosan/amporphous calcium phosphate as an agent for GTR. Methods: Modification of CMC into CMC/ACP (CA) powder through the Freeze Dry process and modification of CA powder through a 30-minute milling process into CMC/ACP powder after milling (CAM) and evaluated using FTIR, respectively, analyzing the CMC functional group and the initial CA functional group formed. CA and CAM powder were then mixed with gypsum hemihydrate at a ratio of 5% and 10% to obtain novel cement groups of CAG 5%, CAG 10%, CAMG 5%, and CAMG 10%. The groups were evaluated using FTIR, XRD, SEM, setting time, compression resistance, and MTT assay. The novel cement was applied to demineralized dentin for 14 days and evaluated using TEM. Result: The CMC functional group (-CH2COOH and N-H) was seen in CA and CAM powder. Addition of phosphate (-PO4) functional grup were detected in CA and CAM powder. Phosphate (-PO4) functional group was seen in novel cement CAG (5% and 10%) and CAMG (5% and 10%). The combination of gipsum using CA and CAM powders produces different mineral phases. Topographical impressions differed between Novel cement groups of CAG (5% and 10%) and CAMG (5% and 10%). There was a significant difference between the novel cement groups (CAG 5%, CAG 10%, CAMG 5%, and CAMG 10%) compared to gypsum (control) in setting time and compression resistance (p<0.05). Viability cell confirmation using MTT assay showed that novel cemen group of CAMG 10% did not toxic to hDPSC. Novel cement groups of CAG (5% and 10%) and CAMG (5% and 10%) demonstrated the effects of extrafibrillar and intrafibrillar dentin remineralization on demineralized dentin. Conclusion: Modifying carboxymethyl chitosan through freeze dry and milling processes and modifying the mixing ratio of 5% and 10% using gypsum can initiate guided tissue remineralization of dentin both extrafibrillarly and intrafibrillarly in demineralized dentin."

"ABSTRAKLatar Belakang: Carboxymethyl chitosan (CMC) merupakan bahan analog protein nonkolagen yang fungsinya menyerupai Dentin Matriks Protein 1 (DMP1). CMC menjaga agar amorphous calcium phosphate (ACP) tetap dalam ukuran nano agar dapat terjadi remineralisasi matriks dentin kolagen. Tujuan: Menganalisis pengaruh konsentrasi CMC pada sediaan CMC-ACP terhadap kemampuan remineralisasi dentin. Metode: Dari 25 sampel kavitas yang telah didemineralisasi dibagi menjadi 5 kelompok. Kelompok 1 merupakan kelompok kontrol, kelompok 2 diaplikasikan CMC-ACP dengan konsentrasi CMC 1%, kelompok 3 diaplikasikan CMC-ACP dengan konsentrasi CMC 2,5%, kelompok 4 diaplikasikan CMC-ACP dengan konsentrasi CMC 5%, dan kelompok 5 diaplikasikan CMC-ACP dengan konsentrasi CMC 10%. Selanjutnya dilakukan pemeriksaan dengan SEM untuk melihat morfologi permukaan dentin dan EDX untuk mengukur kandungan kalsium dan fosfat pada permukaan dentin.  Hasil: Hasil remineralisasi dentin tertinggi pada CMC konsentrasi 10%, diikuti dengan 5%, 2,5%, dan 1% yang paling kecil. Bila dibandingkan, kadar fosfat CMC konsentrasi 1%, 2,5%, 5%, dan 10% berbeda bermakna. Namun kadar kalsium CMC konsentrasi 2,5%, 5%, dan 10% tidak berbeda bermakna. Kesimpulan: Konsentrasi CMC 2,5% merupakan konsentrasi optimum yang dapat menghasilkan remineralisasi dentin.

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ABSTRACTBackground: Carboxymethyl chitosan (CMC) is a noncollagenous protein analog material that has similar function as Dentin Matrix Protein 1 (DMP1). CMC stabilizes amorphous calcium phosphate (ACP) therefore it can stay in nanoparticle form and remineralize matrix collagen dentin. Aim: To analyze the effect of CMC concentration in CMC-ACP towards dentin remineralization. Method: 25 cavity samples divided into 5 experimental groups. The first group is control group, the second group is applied with CMC-ACP that contains 1% CMC, the third group is applied with CMC-ACP that contains 2,5% CMC, the fourth group is applied with 5% CMC, and the fifth group is applied with CMC-ACP that contains 10% CMC. Remineralization was evaluated using SEM and EDX. Result: The highest dentin remineralization result is from  group 10% CMC, 5%, 2,5%, and the least dentin remineralization is from group 1% CMC. Statistically, the calcium level of group 2,5%, 5%, and 10% CMC in CMC-ACP is constant. Whereas the phosphate level of group 1%, 2,5%, 5% and 10% CMC in CMC-ACP is statistically significant. Conclusion: The optimum CMC concentration in CMC-ACP is 2,5% that resulted in dentin remineralization.

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"Latar Belakang: Aplikasi Mineral Trioxide Aggregate (MTA) sebagai material bioaktif yang umum digunakan dalam upaya remineralisasi affected dentin memiliki peranan penting dalam preservasi jaringan gigi pada perawatan terapi pulpa vital, namun diketahui tidak dapat menghasilkan dentin dengan sifat mekanis menyerupai dentin sehat karena hanya menghasilkan remineralisasi ekstrafilbrillar. Carboxymethyl Chitosan (CMC) merupakan biomaterial alami yang dikembangkan sebagai analog protein non-kolagen pada dentin untuk menghambat laju presipitasi kalsium fosfat yang dihasilkan oleh interaksi antara material bioaktif dengan jaringan sehingga dapat memasuki ruang intrafibrillar kolagen. Tujuan: Mengetahui pengaruh penambahan CMC pada semen MTA terhadap perubahan karakteristik kristal hidroksiapatit dan kekerasan mikro dentin terdemineralisasi, yang diobservasi selama 14 hari periode remineralisasi. Metode: Remineralisasi dilakukan melalui aplikasi material MTA, MTA-CMC 5%, dan MTA-CMC 10% pada dasar kavitas sampel dentin terdemineralisasi. Akar gigi direndam selama 14 hari dalam cairan phosphate-buffered saline. Observasi karakteristik kristal hidroksiapatit dilakukan dengan alat uji X-ray Diffractomete dan perubahan kekerasan mikro dianalisis secara kuantitatif melalui uji Vickers Hardness.Hasil: Pembentukan kristal hidroksiapatit ditemukan pada sampel MTA dan MTA-CMC dengan derajat kristalinitas hidroksiapatit paling tinggi pada sampel MTA-CMC 10%. Kekerasan mikro dentin meningkat pada kelompok MTA-CMC 5% dan MTA-CMC 10% dibandingkan pada kelompok MTA. Kesimpulan: Aplikasi modifikasi material Mineral Trioxide Aggregate dengan Carboxymethyl Chitosan selama 14 hari menginisasi terbentuknya fase mineral hidroksiapatit dan meningkatkan derajat kristalinitas hidroksiapatit pada dentin terdemineralisasi serta meningkatkan kekerasan mikro dentin terdemineralisasi.

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Background: Application of Mineral Trioxide Aggregate (MTA) as remineralization agent of affected dentin which holds a vital role in the preservation of tooth structure has been widely used in clinical practice, however it’s only capable of generating extrafibrillar remineralization resulting in the inability to produce dentin with mechanical properties resembling sound dentin. Carboxymethyl Chitosan (CMC) is a natural biomaterial developed as analogue of dentin non-collagenous proteins to inhibit the spontaneous precipitation of calcium-phosphate produced by the interaction of dentin with remineralization agent so that intrafibrillar remineralization can be accomplished.

Objective: To evaluate hydroxyapatite crystals characteristic and assess the microhardness of demineralized dentin after 14 days application of CMC-modified MTA.

Method: Remineralization was performed by the application of MTA, MTA-CMC 5%, and MTA-CMC 10% on demineralized dentin samples. During the remineralization process, root canals of tooth models were immersed in phosphate-buffered saline solution. Hydroxyapatite crystals’ characteristic was observed by X-ray Diffractometer, while dentin microhardness score was assessed by Vickers Hardness test.

Result: Formation of hydroxyapatite crystals was identified in MTA and MTA-CMC samples. Highest degree of crystallinity was found in MTA-CMC10% sample. Microhardness score of demineralized dentins in MTA-CMC 5% group and MTA-CMC 10% group was significantly higher than those in MTA group.

Conclusion: CMC-modified MTA application on demineralized dentin in 14 days was found effective in initiating hydroxyapatite formation with higher degree of crystallinity and increasing the microhardness of demineralized dentin."

"Latar Belakang : SIK sebagai bahan restorasi memiliki kemampuan untuk berikatan secara kimiawi terhadap struktur gigi dan kemampuan melepaskan fluoride sehingga cocok digunakan pada pasien dengan risiko karies tinggi namun memiliki kekuatan mekanis yang buruk. Modifikasi bahan restorasi SIK melalui penggabungan dengan bahan bioaktif untuk mendapatkan manfaat seperti meningkatnya sifat mekanis, sifat antibakteri dan potensi remineralisasi telah di sebutkan pada beberapa literatur penelitian. Pada studi ini, bubuk carboxymetyl-chitosan (CMC) ditambahkan pada komponen bubuk dari SIK konvensional. Tujuan: Menganalisis pengaruh modifikasi material semen ionomer kaca (SIK) dengan carboxymetyl-chitosan (CMC) terhadap Kekuatan kompresi dan morfologi permukaan. Metode: Tiga puluh lubang pada cetakan akrilik silindris Diameter 4 mm tinggi 8 mm diisi dengan material SIK (FUJI IX, GC corp, Japan), modifikasi SIK dengan CMC 5% dan 10% yang di campurkan pada komponen bubuk SIK. Sampel dibagi menjadi 3 kelompok yaitu kelompok kontrol SIK (n=10) dan kelompok SIK-CMC 5% (n=10) serta kelompok SIK-CMC 10% (n=10). Kekuatan kompresi diukur dengan menggunakan Universal Testing Machine (Tensilon RTG-10Kn, A&D, Japan) dan dihitung dengan rumus KK= P/(πr2) dimana P adalah beban maksimum dan r adalah radius dari spesimen. Data dianalisis dengan analisis statistik menggunakan One-Way ANOVA dan Post hoc Bonferroni (p<0,5). Morfologi permukaan material modifikasi SIK-CMC dan kontrol di amati dengan menggunakan Scanning Electronic Microscope (EVO MA-0, Zeiss, Germany). Hasil: Terdapat perbedaan bermakna antara kelompok modifikasi SIK-CMC 5% dan SIK-CMC 10% dengan kelompok kontrol (One-Way ANOVA; p<0,05). Berdasarkan uji Post Hoc Bonferroni (p<0,5) terdapat perbedaan yang bermakna Kekuatan kompresi pada material modifikasi SIK-CMC 5 % dan SIK-CMC 10% dengan kelompok kontrol SIK. Modifikasi SIK dengan CMC mempengaruhi perubahan morfologi berupa berkurangnya porusitas dan bertambahnya permukan retakan seiring dengan penambahan persentase CMC.Kesimpulan: Modifikasi SIK dengan Penambahan CMC Mengurangi kekuatan kompresi dengan rerata hasil paling rendah pada penambahan CMC 10%. Porusitas permukaan material modifikasi SIK dengan penambahan CMC memiliki kecenderungan berkurang dan bertambahnya permukaan retakan yang melebar seiring dengan penambahan persentase CMC

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Background: GIC as a restorative material has the ability to chemically bond to the structure of teeth and the ability to release fluoride so that it is suitable for use in patients with a high caries risk but has poor mechanical strength. Modification of GIC restorative materials with combination with bioactive materials to obtain benefits such as increasing mechanical properties, antibacterial properties and remineralization potential has been mentioned in some research literature. In this study, Carboxymethyl-chitosan (CMC) is added to the powder phase of conventional GIC to increase the compressive strength. Objective: to analyze the influence of modified GIC with the addition of CMC on compressive strength and surface morphology. Methods: Thirty holes in a cylindrical acrylic mold, each hole has a diameter of 4 mm and thickness of 8 mm, were filled with conventional GIC restorative material (FUJI IX, GC corp, Japan), modified GIC with 5% CMC and 10% CMC added in the powder phase. The samples were divided into 3 groups: control group GIC (n=10), GIC-CMC 5% group (n=10) and GIC-CMC 10% group (n=10). The compressive strength measurement performed with Universal testing machine (Tensilon RTG-10Kn, A&D, Japan), and were calculated according to the following equation: CS= P/(πr2)

Where P is the maximum load and r is the radius of the cylinder-shaped specimen

Statistical analysis was done by One-Way ANOVA and Post hoc Bonferroni (p<0.05). The surface morphology of the material modification of GIC-CMC and control group was observed using the Scanning Electronic Microscope (EVO MA-0, Zeiss, Germany).

Results: There is a significant difference between the GIC-CMC 5% and GIC-CMC 10% modification groups and the control group (One-Way ANOVA; p<0.05). Based on the Post Hoc Bonferroni (p<0.5) test there is a significant difference in compressive strength in SIK-CMC modification materials of 5% and SIK-CMC of 10% with the SIK control group. Modification of SIK with CMC affects morphological changes in the form of reduced porosity and increased fractures along with the addition of CMC percentage.Conclusion: Modification of GIC with CMC addition reduces compressive strength with the lowest average yield at 10% CMC addition. The surface porusity of SIK modification material with the addition of CMC tends to decrease and increase the surface of cracks that widen along with the addition of CMC percentage."

"Latar Belakang: SIK sebagai bahan restorasi memiliki kemampuan untuk berikatan secara kimiawi terhadap struktur gigi dan kemampuan melepaskan fluoride sehingga cocok digunakan pada pasien dengan risiko karies tinggi namun memiliki kekuatan mekanis yang buruk. Modifikasi bahan restorasi SIK melalui penggabungan dengan bahan bioaktif untuk mendapatkan manfaat seperti meningkatnya sifat mekanis, sifat antibakteri dan potensi remineralisasi telah di sebutkan pada beberapa literatur penelitian. Pada studi ini, bubuk carboxymetyl-chitosan (CMC) ditambahkan pada komponen bubuk dari SIK konvensional. Tujuan: Menganalisis pengaruh modifikasi material semen ionomer kaca (SIK) dengan carboxymetyl-chitosan (CMC) terhadap Kekuatan kompresi dan morfologi permukaan. Metode: Tiga puluh lubang pada cetakan akrilik silindris Diameter 4 mm tinggi 8 mm diisi dengan material SIK (FUJI IX, GC corp, Japan), modifikasi SIK dengan CMC 5% dan 10% yang di campurkan pada komponen bubuk SIK. Sampel dibagi menjadi 3 kelompok yaitu kelompok kontrol SIK (n=10) dan kelompok SIK-CMC 5% (n=10) serta kelompok SIK-CMC 10% (n=10). Kekuatan kompresi diukur dengan menggunakan Universal Testing Machine (Tensilon RTG-10Kn, A&D, Japan) dan dihitung dengan rumus KK= P/(πr2) dimana P adalah beban maksimum dan r adalah radius dari spesimen. Data dianalisis dengan analisis statistik menggunakan One-Way ANOVA dan Post hoc Bonferroni (p<0,5). Morfologi permukaan material modifikasi SIK-CMC dan kontrol di amati dengan menggunakan Scanning Electronic Microscope (EVO MA-0, Zeiss, Germany). Hasil: Terdapat perbedaan bermakna antara kelompok modifikasi SIK-CMC 5% dan SIK-CMC 10% dengan kelompok kontrol (One-Way ANOVA; p<0,05). Berdasarkan uji Post Hoc Bonferroni (p<0,5) terdapat perbedaan yang bermakna Kekuatan kompresi pada material modifikasi SIK-CMC 5 % dan SIK-CMC 10% dengan kelompok kontrol SIK. Modifikasi SIK dengan CMC mempengaruhi perubahan morfologi berupa berkurangnya porusitas dan bertambahnya permukan retakan seiring dengan penambahan persentase CMC.Kesimpulan: Modifikasi SIK dengan Penambahan CMC Mengurangi kekuatan kompresi dengan rerata hasil paling rendah pada penambahan CMC 10%. Porusitas permukaan material modifikasi SIK dengan penambahan CMC memiliki kecenderungan berkurang dan bertambahnya permukaan retakan yang melebar seiring dengan penambahan persentase CMC.

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Background: GIC as a restorative material has the ability to chemically bond to the structure of teeth and the ability to release fluoride so that it is suitable for use in patients with a high caries risk but has poor mechanical strength. Modification of GIC restorative materials with combination with bioactive materials to obtain benefits such as increasing mechanical properties, antibacterial properties and remineralization potential has been mentioned in some research literature. In this study, Carboxymethyl-chitosan (CMC) is added to the powder phase of conventional GIC to increase the compressive strength.

Objective: to analyze the influence of modified GIC with the addition of CMC on compressive strength and surface morphology.

Methods: Thirty holes in a cylindrical acrylic mold, each hole has a diameter of 4 mm and thickness of 8 mm, were filled with conventional GIC restorative material (FUJI IX, GC corp, Japan), modified GIC with 5% CMC and 10% CMC added in the powder phase. The samples were divided into 3 groups: control group GIC (n=10), GIC-CMC 5% group (n=10) and GIC-CMC 10% group (n=10). The compressive strength measurement performed with Universal testing machine (Tensilon RTG-10Kn, A&D, Japan), and were calculated according to the following equation: CS= P/(πr2)

Where P is the maximum load and r is the radius of the cylinder-shaped specimen Statistical analysis was done by One-Way ANOVA and Post hoc Bonferroni (p<0.05). The surface morphology of the material modification of GIC-CMC and control group was observed using the Scanning Electronic Microscope (EVO MA-0, Zeiss, Germany).

Results: There is a significant difference between the GIC-CMC 5% and GIC-CMC 10% modification groups and the control group (One-Way ANOVA; p<0.05). Based on the Post Hoc Bonferroni (p<0.5) test there is a significant difference in compressive strength in SIK-CMC modification materials of 5% and SIK-CMC of 10% with the SIK control group. Modification of SIK with CMC affects morphological changes in the form of reduced porosity and increased fractures along with the addition of CMC percentage.

Conclusion: Modification of GIC with CMC addition reduces compressive strength with the lowest average yield at 10% CMC addition. The surface porusity of SIK modification material with the addition of CMC tends to decrease and increase the surface of cracks that widen along with the addition of CMC percentage."

"Penelitian bertujuan mengetahui pengaruh besar tekanan dan lama scrubbing terhadap kuat rekat geser self adhering flowable composite pada dentin. Self adhering flowable composite diaplikasikan dengan tekanan scrubbing 1, 2, dan 3 gram masing-masing selama 15, 20, dan 25 detik. Resin komposit diaplikasikan secara inkremental. Polimerisasi dengan sinar selama 20 detik. Kuat rekat geser diuji menggunakan Testing Machine dan dianalisa dengan ANOVA diikuti Post Hoc Test Bonferroni. Daerah patahan diobservasi menggunakan SEM. Kuat rekat geser tertinggi pada tekanan scrubbing 3 gram selama 25 detik. Perbedaan besar tekanan dan waktu saat scrubbing mempengaruhi kuat rekat geser self adhering flowable composite pada dentin.

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Effect of different scrubbing pressure and duration on shear bond strength of self adhering flowable composite to dentin was evaluated. Self adhering flowable composite was applied on dentin with 1, 2, and 3 grams pressure for 15, 20, and 25 seconds. Composite was constructed incrementally. Polymerization for 20 seconds. Shear bond strength was tested with a Testing Machine and analyzed by ANOVA and Bonferroni. Fractured area was observed with a SEM. The highest shear bond strength was obtained in 3 grams scrubbing pressure for 25 seconds. The different scrubbing pressure and duration influenced shear bond strength of self adhering flowable composite to dentin."

"Latar belakang: Pada lesi karies dalam sisa ketebalan dentin yang masih tersisa sangat tipis sehingga pembuangan seluruh infected dentin beresiko besar terhadap terbukanya pulpa. Teknik minimal invasif diperlukan, yaitu partial caries excavation dengan metode pembuangan jaringan infected dentin sebagian dan penggunaan material bioaktif MTA yang dapat memicu terjadinya remineralisasi. Tujuan: Untuk membandingkan remineralisasi pada affected dentin lesi karies dalam dengan pembuangan seluruh dan sebagian infected dentin setelah aplikasi MTA. Metode: Subjek dibagi dua kelompok, kelompok I dilakukan pembuangan sebagian infected dentin dan diaplikasikan MTA, kelompok II dilakukan pembuangan seluruh infected dentin dan diaplikasikan MTA. Masing-masing kelompok diukur pixel gray value sebelum dan 4 minggu setelah dilakukan aplikasi MTA, lalu dibandingkan. Selain itu dibandingkan peningkatan gray value pada kedua kelompok tersebut. Hasil: Terjadi remineralisasi affected dentin kelompok I dan II setelah aplikasi MTA. Tidak terdapat perbedaan bermakna tingkat remineralisasi affected dentin pada kelompok 1 dan 2 setelah aplikasi MTA selama 4 minggu. Kesimpulan: Terjadi remineralisasi affected dentin pada kedua kelompok baik dengan pembuangan sebagian maupun seluruh infected dentin lesi karies dalam.

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Background Deep carious lesion that only thin dentin remains in the remaining dentin thickness that caused a high risk to the pulp exposure in the removal of all infected dentin. Minimally invasive techniques are required, which are a partial caries excavation method in infected dentin tissue and the use of bioactive material that can promote MTA remineralization. Aim to compare the remineralization of deep carious lesion affected dentin with the removal in some parts and all of the infected dentin after the application of the MTA. Methods Subjects are divided into two groups, in which group I is getting the removal in only some parts of the infected dentin and the application of the MTA, group II is getting the removal in all of the infected dentin and the MTA application. Each group is measured on the pixel grey value before and four weeks after the application of the MTA, and then compare. Moreover, compare the enhancement of the grey value of those groups. Result Reminalisation is occurred in both of the groups after the application of the MTA. there is no significance difference in the reminalization level of the affected dentin in both group I and group II after the application of the MTA during four weeks. Conclusion Reminalization is occurred in the affected dentin in both of the groups either by only removal in some part or all of the carious lesion infected dentin."