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Abstrak :
Dalam penyembuhan jaringan yang rusak dalam tubuh manusia, sebuah teknik bernama tissue engineering digunakan sebagai “jalur” yang di implantasikan kedalam tubuh sebagai jalur untuk regenerasi. Ini disebut dengan scaffold. Dalam bidang tissue engineering, sebuah metode bernama Organ Printing dikembangkan oleh Dr. Gabor Forgasc. Organ printing adalah sebuah teknik yang dikembangkan untuk mencetak sel baru yang dapat diimplantasikan ke dalam tubuh manusia untuk menggantikan fungsi jaringan organ yang rusak. Tujuan utama dari penelitian ini adalah untuk mencetak organ dengan material hydrogel gelatin. Sebuah system esktrusi dibuat untuk mencetak scaffold berbahan gelatin. Gelatin yang terekstrusi di karakterisasi dengan mengatur kecepatan dan konsentrasinya. Hasil yang optimal didapat pada kecepatan 800 mm/min dan konsentrasi 25%. Setelah itu, parameter yang optimal tersebut digunakan untuk memfabrikasi scaffold 2 dimensi dengan pola heksagonal dan kuadratik.Lebar garis dan ketebalan yang didapatkan adalah 364 μm dan 8.83 μm. ...... In the healing of damaged tissue in humans, a technique called tissue engineering uses a "track" that is implanted in the body as a pathway for regenerating. This “track” is called scaffold. In the field of tissue engineering, a method called Organ Printing was developed by Dr. Gabor Forgasc. Organ printing is a technique that was developed to print new cells that can be implanted inside human body to replace the function of the damaged organ tissue. The main purpose of this research is to print organs with gelatin hydrogel material. An extrusion system is realized to print gelatin scaffold. The extruded gelatin is characterized by modifying its speed and concentration. An optimal result is achieved at the speed of 800 mm/min and 25% concentration. Moreover, the optimal parameter is used to fabricate a 2-dimensional scaffold with hexagonal and quadratic patterns. The line width and thickness that is achieved are 364 !m and 8.83 !m respectively.

Abstrak :
This book about the cell-surface interaction, studying cell-surface interactions In vitro : a survey of experimental approaches and techniques, harnessing cell-biomaterial interactions for obsteochondral tissue regeneration, interaction of cells with decellularized biological materials, evaluation of biocompatibility using In vitro methods : interpretation and limitations, artificial scaffolds and mesenchymal stem cells for hard tissues, bioactive glass-based scaffolds for bone tissue engineering, microenvironment design for stem cell fate determination, stem cell differentiation depending on different surfaces, designing the biocompatibility of biohybrids, interaction of cartilage and ceramic matrix, and bioresorption and degradation of biomaterials.

Abstrak :
Resin kompositterus dikembangkan untuk meningkatkan performa estetiknya. Resin komposit terbaru yaitu nanofiller dan nanohybrid yang masih diperdebatkan ketahanannya terhadap zat warna minuman kopi. Penelitian ini bertujuan membandingkan perubahan warna permukaan resin komposit nanofiller dan nanohybrid setelah perendaman kopi. Terdapat 36 sampel yang dibagi dalam 6 kelompok dengan ukuran diameter 6 mm, tebal 3 mm. Pengukuran warna menggunakan vita easyshade classic yang diurutkan berdasarkan value. Hasil data dianalisis menggunakan Wilcoxon Test dan Mann-Whitney Test. Didapatkan Perubahan warna pada nanohybrid lebih sedikit dibandingkan pada nanofiller dan secara statistik berbeda bermakna (p<0,05). Sehingga nanohybrid memiliki ketahanan terhadap zat warna yang lebih baik daripada nanofiller. ...... Resin composites continue developed to improve aesthetic performance. The newest composite resin are nanofiller and nanohybrid where color resistance to coffee drinks still debating. The aim of this study is to compare surface discoloration nanofiller and nanohybrid resin composites after immersion coffee. There are 36 samples were divided into 6 groups with a diameter of 6 mm, thickness 3 mm. Color measurements using vita easyshade classic that is sorted by value.Results data were analyzed using the Wilcoxon test and Mann-Whitney Test. Changes in color on nanohybrid lower than the nanofiller and statistically significant (p<0.05). Therefore nanohybrid has resistance to color better than nanofiller.

Abstrak :
Osteoartritis merupakan penyakit kronis yang ditandai dengan kemunduran tulang rawan dan menyebabkan kekakuan, nyeri, dan gangguan pergerakan. Strategi rekayasa jaringan tulang menggunakan perancah dapat menjadi alternatif yang menjanjikan untuk regenerasi jaringan tulang yang rusak. Penelitian ini bertujuan untuk fabrikasi dan karakterisasi perancah dengan material chitosan (CS), hyaluronic acid (HA), hydroxyapatite (Hap) dengan kombinasi penambahan graphite (Gr), graphene oxide (GO), dan multiwalled carbon nanotube (MWNCT) untuk aplikasi rekayasa jaringan tulang. Dalam penelitian ini, dilakukan sintesis GO dan fungsionalisasi kimia dari material Gr dan MWNCT. Fabrikasi perancah dilakukan dengan metode freeze drying. Seluruh kelompok perancah dilakukan karakterisasi SEM dan FTIR, uji tekan dan porositas, uji swelling, wettability, dan laju degradasi. Fabrikasi perancah dibagi menjadi empat kelompok yaitu CS/HA/HAp, CS/HA/HAp/GO, CS/HA/HAp/f-Gr, dan CS/HA/HAp/f-MWNCT dengan ukuran diameter 1 cm, tinggi 1,5 cm, dan luas permukaan luas permukaan 4,71-6,28 cm2. Keseluruhan perancah memiliki ukuran pori yang bervariasi dan terdistribusi pada permukaan. Berdasarkan hasil FTIR, perancah mengandung gugus fungsi O-H, C=O, C-O-C, amida I, amida II, dan fosfat (PO43-). Pada uji kekuatan tekan, keseluruhan perancah memiliki CS/HA/HAp memiliki kekuatan tekan dan young modulus yang serupa dengan cancellous bone sebesar 5,76-6,14 MPa dan 3,95-471 MPa. Perancah memiliki laju porositas dengan rentang 13,8- 86,6%. Perancah memiliki kemampuan wettabiliy yang baik dengan rentang persentase 726-1069%. Rasio swelling perancah berada pada rentang 25,2-39,3%. Laju degradasi perancah cukup terkontrol dengan rentang 16,7-35,5%. Berdasarkan seluruh hasil karakterisitik, perancah CS/HA/HAp dengan penambahan GO merupakan kandidat terkuat sebagai perancah ideal pada penelitian ini. Perancah GO mempunyai karakteristik yang berada diantara perancah kontrol dan perancah f-MWNCT/f-Gr. ......Osteoarthritis is a chronic disease characterized by the deterioration of cartilage and causes stiffness, pain, and impaired movement. The bone tissue engineering strategy using scaffolds can be a promising alternative for the regeneration of damaged bone tissue. This study aims to fabricate and characterize scaffolds with chitosan (CS), hyaluronic acid (HA), hydroxyapatite (Hap) with a combination of addition of graphite (Gr), graphene oxide (GO), and multiwalled carbon nanotubes (MWNCT) for tissue engineering applications. In this study, GO synthesis and chemical functionalization of Gr and MWNCT materials were carried out. Scaffolding was done by freeze drying method. All groups of scaffolds were characterized by SEM and FTIR, compressive and porosity tests, swelling, wettability, and rate of degradation tests. Scaffolding was divided into four groups, namely CS/HA/HAp, CS/HA/HAp/GO, CS/HA/HAp/f-Gr, and CS/HA/HAp/f-MWNCT with a diameter of 1 cm, height 1, 5 cm, and a surface area of ​​4.71-6.28 cm2. The entire scaffold has varying pore sizes and is distributed over the surface. Based on the results of FTIR, the scaffold contains functional groups O-H, C=O, C-O-C, amide I, amide II, and phosphate (PO43-). In the compressive strength test, all scaffolds having CS/HA/HAp had similar compressive strength and young modulus with cancellous bone of 5.76-6.14 MPa and 3.95-471 MPa. Scaffolds have porosity rates in the range of 13.8-86.6%. Scaffolds have good wetability with a percentage range of 726-1069%. The swelling ratio of the scaffolds was in the range of 25.2-39.3%. The rate of degradation of the scaffold was quite controlled with a range of 16.7-35.5%. Based on all the characteristic results, the CS/HA/HAp scaffold with the addition of GO was the strongest candidate as the ideal scaffold in this study. The GO scaffold has characteristics that are between the control scaffold and the f-MWNCT/f-Gr scaffold.

Abstrak :
This book focuses on the mechanobiological principles in tissue engineering with a particular emphasis on the multiscale aspects of the translation of mechanical forces from bioreactors down to the cellular level. The book contributes to a better understanding of the design and use of bioreactors for tissue engineering and the use of mechanical loading to optimize in vitro cell culture conditions. It covers experimental and computational approaches and the combination of both to show the benefits that computational modelling can bring to experimentalists when studying in vitro cell culture within a scaffold. With topics from multidisciplinary fields of the life sciences, medicine, and engineering, this work provides a novel approach to the use of engineering tools for the optimization of biological processes and its application to regenerative medicine. The volume is a valuable resource for researchers and graduate students studying mechanobiology and tissue engineering. For undergraduate students it also provides deep insight into tissue engineering and its use in the design of bioreactors. The book is supplemented with extensive references for all chapters to help the reader to progress through the study of each topic.

Abstrak :
Inflammatory response is a non-specific response to an injurious stimulus in vascularized tissue. The purpose of this response is to destruct noxious agent, limitation of its spread, and preparation for reconstitution or repair of injured area. Inflammation is classified into acute and chronic types. The classical features of redness, swelling, warmth, pain, and loss of function, all of which reflect the effects of cytokines and other inflammatory mediators on the local blood vessels in acute inflammation. The cellular response is mainly of neutrophil polymorphonuclear leucocytes. Furthermore, chronic inflammation, in contrast to acute inflammation is of long duration and consists of primarily of mononuclear cells-macrophages, lymphocytes, and plasma cells. A proliferation of blood vessels also occurs. There is also associated collagen production by fibroblasts resulting fibrosis. Cytokines secreted by machrophages, play prominent roles in inflammation. However, other soluble factors, such as vasoactive amines, lipid mediators, complement fragments C5a, C3a, and C4a, prostacyclin, and nitric oxide are also major players in inflammation. The inflammatory reactions in the mouth and teeth are identical to inflammatory reactions anywhere else in the body. Such as pulpitis is similar to inflammation in other connective tissues anywhere in the body.

Abstrak :
Latar belakang: Teknik rekayasa jaringan kartilago memiliki potensi besar dalam rekonstruksi trakea. Scaffold sebagai salah satu unsur utama rekayasa jaringan berperan dalam menyediakan lingkungan tempat sel punca bertumbuh. Komposit campuran kolagen tipe I dan II dipadukan dengan kondroitin serta teknik crosslinkingkedua bahan scaffolddengan genipin dilakukan untuk meningkatkan sifat mekanis. Tujuan: Mengetahui karakteristik morfologi permukaan, biomekanik, dan sitotoksisitas scaffold komposit kolagen-kondroitin crosslink secara in vitro. Metode: Scaffold campuran komposit kolagen tipe I dan tipe II perbandingan 3:1 kemudian dicampur kondroitin dengan rasio 1:3 dibagi dalam kelompok dengan dan tanpa genipin. Hasil: Gambaran morfologi permukaan scaffold dengan genipin menunjukkan matriks padat homogen sedangkan matriks scaffoldtanpa genipin berupa fibriler longgar. Hasil sitotoksisitas menunjukkan tidak terdapat perbedaan bermakna secara statistik (p=0,09) pada rerata jumlah sel pada scaffolddengan dan tanpa genipin serta kontrol. Kesimpulan: Scaffold kolagen kondroitin dengan genipin memiliki mikrostruktur yang lebih padat dan ukuran pori kecil. Genipin dapat menunjang mikrostruktur pada scaffold berbahan kolagen-kondroitin. Scaffold kolagen kondroitin dengan dan tanpa genipin tidak bersifat toksik terhadap sel punca mesenkimal. ......Background: Tissue engineering for trachea reconstruction nowadays plays an important rule to endow an ideal biomaterial for cartilage, the tracheal backbone. In this study, the biocomposit of collagen type I, type II, and chondroitin sulfate was investigated. Chemical crosslinking using genipin to improve its properties was then studied. Objective: To find out the surface morphology characteristics, biomechanics, and cytotoxicity of crosslinked scaffold collagen-chondroitin composites in vitro. Method: hydrogel mixture of collagen type I and type II at the ratio of 3:1, was then added into chondroitin sulfate (1 in 3), crosslinked using genipin. Sample without genipin was compared. Results: Crosslinked collagen chondroitin biocomposit showed a homogeneous shape while the non-crosslinked biocomposit had rough surface and bigger pore size. Both types of biocomposits were biocompatible, showed no toxic effects, as the ATP counts had no different compared to the cell colony only. Conclusion: collagen chondroitin crosslinked with genipin had generated a fine microstructure scaffold with smaller pore size, while no exhibition of residual toxicity.

Abstrak :
Kitosan dan deksametason merupakan material yang digunakan dalam rekayasa jaringan tulang. Kitosan biasa digunakan sebagai scaffold, sedangkan deksametason sering digunakan sebagai sinyal. Salah satu penanda diferensiasi osteoblas adalah Alkaline phosphatase (ALP). Penelitian ini bertujuan menganalisis efek kitosan dibandingkan deksametason dalam menginduksi diferensiasi osteoblas melalui aktivitas ALP pada sel punca pulpa gigi (SPPG). Aktivitas ALP dianalisis dengan ALP assay. Terdapat 4 perlakuan yang memiliki aktivitas ALP diatas kontrol, yakni kitosan 5 ng/ml, deksametason 10 nM dan 100 nM, serta campuran kitosan 5 ng/ml dan deksametason 10 nM. Peningkatan konsentrasi deksametason meningkatkan aktivitas ALP. Peningkatan konsentrasi kitosan menurunkan aktivitas ALP. ......Chitosan and dexamethasone are materials that can be used in bone tissue engineering. Chitosan is often used as a scaffold, while dexamethasone is often used as signal. One of the markers of osteoblast differentiation is Alkaline phosphatase (ALP). This research objective is to analyse the effects of chitosan compared to dexamethasone in inducing osteoblast differentiation through ALP activity in Dental Pulp Stem Cells (DPSCs). ALP activity determined by ALP Assay. There were four treatments that have higher activity than the control, they are chitosan 5 ng/ml, 10 nM dexamethasone and 100 nM, and mixture of chitosan 5 ng/ml and 10 nM dexamethasone. The increased concentrations of dexamethasone increases ALP activity and the higher concentration of chitosan will decrease the ALP activity.

Abstrak :
Kitosan telah diketahui sebagai material scaffold poten pada rekayasa jaringan tulang. Penelitian ini bertujuan menganalisis potensi lain kitosan sebagai induktor diferensiasi sel punca pulpa gigi (SPPG) menjadi osteoblas dibandingkan dengan deksametason yang telah umum digunakan, melalui ekspresi mRNA Col1A1. SPPG dikultur pada medium yang mengandung kitosan, deksametason dan kombinasi keduanya selama 7 hari. Ekspresi mRNA Col1A1 diuji dengan metode comparative CT real-time PCR. Medium mineralizing yang ditambahkan 5 ng/ml kitosan dapat meningkatkan ekspresi mRNA Col1A1 pada SPPG dibandingkan dengan kontrol dan kelompok perlakuan lainnya (p<0,05). Kitosan dapat menginduksi diferensiasi tahap awal SPPG menjadi osteoblas bergantung pada konsentrasi yang diberikan.

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Chitosan has been proven as potential scaffold in bone tissue engineering. This research intends to analyze the other potency of chitosan as inductor in dental pulp stem cell (DPSC) differentiation into osteoblast compared to dexamethasone which is commonly used, by Col1A1 mRNA expression. DPSC were cultured in medium loaded with chitosan, dexamethasone and combination of both for 7 days. Col1A1 mRNA expression was analyzed by comparative CT method real time PCR. Mineralizing medium loaded with 5 ng/ml chitosan could enhance Col1A1 mRNA expression compared to control and another treated group on p<0,05. Chitosan could stimulate early stage of osteoblast differentiation. The effect was dose-dependent.

Abstrak :
ABSTRAK
Fabrikasi mikro merupakan teknologi advanced untuk manufaktur produk ukuran kecil yang kini telah diaplikasikan luas dalam berbagai bidang termasuk kesehatan. Tissue engineering adalah salah satu bidang dari aplikasi teknologi ini dengan berfokus pada rekayasa fabrikasi scaffold. Scaffold yang ideal dipersyaratkan memiliki konstruksi yang mirip dengan lingkungan jaringan target dengan struktur 3D, biodegradable, berpori dan vaskularis. Saat ini, hidrogel gelatin merupakan salah satu material biomatriks yang tepat untuk fabrikasi scaffold. Gelatin tersebut dibentuk dengan metode photo-patterning menggunakan sensitizer rose bengal pada panjang gelombang cahaya tampak. Penelitian ini bertujuan untuk mengembangkan dan merealisasikan bentuk scaffold 2D sebagai dasar pembentukan struktur jaringan 3D. Karakterisasi hasil photo-patterning dilakukan dengan mengukur dimensi pattern width, ketebalan resolusi dan intensitas. Proses ini menghasilkan daerah kerja optimum pada konsentrasi 2% dengan waktu 3 menit.

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ABSTRACT
Microfabrication is an advanced technology for manufacturing products of small size that has now been widely applied in various fields including health area. Tissue engineering becomes ones application of this technology focused on engineering scaffold fabrication. The ideal scaffold required to have a construction similar to the target network environment with a 3D structure, biodegradable, porous and vaskularize. At present, the gelatin hydrogel is appropriate biomatrix material for fabricating the scaffold. Gelatin is formed by photo-patterning method using the sensitizer rose bengal at visible light’s wavelength. This study aims to develop and realize the basic shape of the scaffold 2D as 3D tissue structure formation. Characterization results of photo-patterning is done by measuring the dimensions of the pattern width, thickness and intensity resolution. This process resulted in optimum working area at a concentration of 2% with a time of 3 minutes.