Studi Karakteristik Abu Sekam Padi Dengan Kitosan Molekul Tinggi Nanopartikel Sebagai Bahan Dentinogenesis Pada Kavitas Profunda (In Vitro)
DAFTAR PUSTAKA
Agusnar H., 1997. Kajian pengaruh Kitosan Sebagai Aditif ke atas Sifat-Sifat Kertas
dari Pulpa Batang Sawit. Disertasi. UKM: 133.
Bird dkk., 2012. In Vitro Evaluation of Dentinal Tubule Penetration and
Biomineralization Ability of a New Root-end Filling Material. J Endod ; 38:1093–6.
[BPPP Deptan] Balai Penelitian Pasca Panen Departemen Pertanian., 2001. Peluang
Agribisnis Arang Sekam. Terhubung berkala www.pustaka-deptan.go.id/publikasi/
[1 Februari 2010].
Bramante dkk., 2008. Presence of Arsenic in Different Types of MTA and White and
Gray Portland Cement. JOE; 98(3) : 376- 79.
Camilleri J., 2008. Characterization of Hydration Products of Mineral Trioxide
Aggregate. Int Endod J; 41: 408-17.
Camilleri J., 2010. Evaluation of Physical Properties of an Endodontic Portland
Cement Incoporating Alternative Radiopacifier Used as Root-End Filling Material .
Int Endod J; 43: 231-40.
Chair Effendi M, 2012. Nanopartikel Mineral Trioksida Meningkatkan Proliferasi
dan Diferensiasi Sel Punca Pulpa Gigi Serta Maturasi Sel ke Arah Odontoblas:
Program Doktor Ilmu Kedokteran Gigi, Fakultas Kedokteran Gigi, Universitas
Indonesia.
Chandra dkk., 2012. Isolasi dan Karakterisasi Silika dari Sekam Padi. Lembaga
Penelitian dan Pengabdian pada Masyarakat. Universitas Khatolik Parahyangan.
Chang SW., 2012. Chemical Characteristics of Mineral Trioxide Aggregate and Its
Hydration Reaction.Restorative Dentistry & Endodontics; 37(4): 188-93.
Dahl JE dan Ǿrstavik., 2010. Response of the pulp-dentin ogan to dental restorative
biomaerials. Endodontic Topics; 17: 65-71.
Diana., 2008. Pengaruh Semen Portland Abu-abu dan Semen Portland Putih
Terhadap Viabilitas Sel Pulpa [Tesis]. Jakarta; Fakultas Kedokteran Gigi Universitas
Indonesia.
Universitas Sumatera Utara
Eskandarizadeh A dkk., 2006. A comparative Study between Mineral Trioxide
Aggregate and Calcium Hydroxide as Pulp Capping Agents in Dog’s Teeth. Iran;
Vol.2;2.
Ferracane JL, Cooper PR, Smith AJ., 2010. Can Interaction of Materials with the
Dentin–Pulp Complex Contribute to Dentin Regeneration? Odontology; 98: 2–14.
Fridland M, Rasado, Chem., 2003. Mineral Trioxide Aggregate (MTA) Solubility and
Porosity with Different Water-to-Powder Ratios. The American Association of
Endodontics; 29(12): 814-7
Ghavamnasiri M, Mousavinasab M, Mohtahsam M., 2005. A Histopathologic Study
on Pulp Response to Glass Ionomer Cements in Human Teeth. J Dent; .2(4): 13541.
Goldberg M, Smith AJ., 2004. Cells and Extracellular Matrices of Dentin and Pulp: A
Biological Basis for Repair and Tissue Engineering. CROBM; 15: 13-27.
Hargreaves KM, Cohen S., 2011. Cohen’s Pathways of the Pulp 10th. Missouri,
Elsevier; 40,459.
Han L, Okiji T., 2011. Uptake of calcium and silicon released from calcium silicatebased endodontic materials into root canal dentine. Int Endod J ;44:1081-7.
Henny Sutrisman., 2013. Efek Penambahan Kitosan Molekul Tinggi Nanopartikel
pada Semen Ionomer Kaca Nanopartikel Terhadap Viabilitas Sel Pulpa (In
Vitro).Tesis. Medan: FKG USU.
Indahyani DE, Hamzah Z, Barid I., 2011. Sifat Osteoinduktif Silika Amorphous
Sekam Padi. Dentika Dental Jurnal; 16: 116-20.
Kalapathy N, Proctor, Schultz., 2000. A Simple Method for Production of Pure Silica
from Rice Hull ash. Bioes. Technol. 73: 257- 62.
Kanjevac T, Milovanovic M, Yolarevic V, dkk., 2012. Cytotoxic Effects of Glass
Ionomer Cements on Human Dental Pulp Stem Cells Correlate with Flouride
Release. Medical Chemistry; 8: 40-45.
Lohbauer U., 2010. Dental Glass Ionomer Cements as Permanent Filling Materials
Properties, Limitations and Future Trends Materials; 3: 76-96.
Marist AI., 2011. Pelapisan Komposit Hidroksiapatit-Kitosan pada Logam Steinless
Steel 316 untuk Meningkatkan Ketahanaan Korosi [Tesis]. Bogor: Fakultas
Matematika dan Ilmu Pengetahuan Alam, Institut Pertanian Bogor.
Universitas Sumatera Utara
Makarim AK dan Suhartatik E. 2009. Morfologi dan Fisiologi Tanaman Padi.Balai
Besar Penelitian Tanaman Padi.
MCCabe JF, Walls AWG. 2008. Applied Dental Materials.9th Ed. Blackwell: 258-64.
Modena KC, Casas- Apayco LC, Atta MT, Costa CA, Hebling J, Sipert CR, Navarro
MF, Santos CF., 2009. Cytotoxicity and Biocompatibility of Direct and Indirect
Pulp Capping Materials. J Appl Oral Sci; 17(6): 544-54.
Moghaddam KM., 2008. An introduction to microbial metal nanoparticle preparation
method. The Journal of Young Investigators 19:19.
Murray PE, Lumley PJ, Smith AJ., 2002. Preserving the Vital Pulp in Operative
Dentistry: 3. Thickness of Reaimining Cavity Dentin as a key Mediator of Pulpal
Injury and Repair Responses; 29: 172-8.
Nagaraja Upadhya P and Kishore G., 2005. Glass Ionomer Cement – The Different
Generations. Trends Biomater. Artif. Organs; 18 (2): 158, 162.
Nicholson JW, Czarnecka B., 2008. The Biocompatibility of Resin Modified
GlassIonomer Cement for Dentistry. Dental Material; 24: 1702-8.
Ningsih W., 2010. Pengaruh Vikositas Larutan Kitosan Nanopartikel sebagai
Penyalut Asam Askorbat untuk Menyerap Asam Lemak Bebas (ALB) dalam
Minyak Goreng Curah. [Tesis]. Medan: Fakultas Matematika dan Ilmu Pengetahuan
Alam, Universitas Sumatera Utara.
Petri DFS, Donega J, Benassi AM, et al., 2007. Preliminary study on chitosan
modified glass ionomer restoratives. J Dent Materials; 23: 1004-10.
Preenan et all., 2004. Microtensile Bond Strength of Tooth-colored Materials to
Primary Tooth Dentin. Pediatric Dentistry; 26:1.
Putro AL, Prasetyoko D. 2007. Abu Sekam Padi sebagai Sumber Silika pada Sintesis
Ziolit ZSM-5 tanpa Menggunakan Templat Organik. Akta Kimia Indonesia. Vol
3(1): 33-36.
Queireoz AM, Asssed M, Leonardo MR., 2005. MTA and Calcium Hydroxide for
Pulp Capping. J Appl Oral Sci; 13(2): 126-30.
Rasinta Tarigan., 2013. Sketsa Gigi Premolar. Unpublish.
Universitas Sumatera Utara
Rao A, Rao A, Shenoy R. 2009. Mineral Trioxide Aggregate- A review. India. J Clin
Pediatr Dent: 34(1): 1-8.
Reyes-Carmona JF, Felippe MS, Felippe WT., 2009. The Biomineralization Ability
of Mineral Trioxide Aggregate and Portland Cement with Dentin in a Phosphate –
containing Fluid. J Endo; 35: 731-6.
Reyes-Carmona JF, Felippe MS, Felippe WT., 2010. The Biomineralization Ability
of Mineral Trioxide Aggregate and Portland Cement on Dentin Enhances the Pushout Strength. Brazil. J Endo; Vol.36: 286-91.
Robert TM, Heymann HO, Swift EJ. 2006. Sturdevant’s Art and Science of Operative
Dentistry. 5th ED. Missouri; Elsevier: 502-4.
Sauders SA., 2009. Current Partically of nanotechnology in Dentistry. Part I: Focus
on Nanocomposite Restoratives and Biomimetics. Clinical, Cosmetic and
Investigational Dentistry; 1:47-61.
Sarkar NK dkk., 2005. Physicochemical Basis of the Biologic Properties of Mineral
Trioxide Aggregate. J Endo; 31(2): 97-100.
Silva dkk., 2009. TNF-α Promotes on Odontoblastic Phenotype in Dental Pulp Cells.
J Dent Res; 88(4): 339-44.
Siregar M., 2009. Pengaruh Berat Molekul kitosan Nanopartikel untuk Menurunkan
Kadar Logam Besi (Fe) dan Zat Warna Pada Limbah Industri Tekstil Jeans. [Tesis].
Medan: Fakultas Pasca Sarjana, Universitas Sumatera Utara.
Smith AJ dkk., 2008. Dental Regeneration and Materials- a Partnership.Clin Oral
Invest; 12: 103-108.
Soeswanto B dan Lintang N., 2011. Pemanfaatan Limbah Sekam Padi menjadi
Natrium Silikat. Bandung; Jurnal fluida; Vol.11(1): 18-22.
Sugita P, Wukisari T, Sjahriza A, Wahyono A., 2009. Kitosan sumber biomaterial
masa depan. Bogor: IPB Press: 27, 125.
Sun W., 2007. Porous silicon based biomaterial fot bone tissue engineering. Partial
Fulfillment of the Requirements for the Degree Doctor of Philosophy Department of
Biomedical Engineering The College School of Engineering and Applied Science.
New York University of Rochester; 8-20.
Universitas Sumatera Utara
Suprastiwi E., 2011. Bioaktivitas Semen Ionomer Kaca dalam Menginduksi
Peningkatan Kadar ALP, DMP-1, dan Pembentukan Dentin Reparatif (Penelitian
InVivo pada Macaca Nemestrina). Disertasi. Jakarta: FKG UI.
Tiyaboonchai W., 2003. Chitosan Nanoparticles: A Promising System for Drug
Delivery. Naresuan University Journal; 11(3): 51-66.
Trimurni Abidin, Harry Agusnar; Wandania F., 2006/2007. Efek Dentinogenesis
Kitosan dan Derivatnya terhadap Inflamasi Jaringan Pulpa Gigi Reversibel.
Laporan Akhir Penelitian Riset Pembinaan IPTEK Kedokteran.
Trimurni Abidin., 2007. Inovasi Perawatan Konservasi Perawatan Konservasi Gigi
Melalui Teknologi Tissue Engineering. Pidato Pengukuhan Jabatan Guru Besar
Tetap dalam Bidang Ilmu Konservasi Gigi pada Fakultas Kedokteran Gigi
Universitas Sumatra Utara; 10-11.
Tyas MJ. 2006., Clinical Evaluation of Glass Ionomer Cement Restorations. J Appl
Oral Sci; 14: 10-13.
Yoshida K.; Bessho K.; Fujimura K.; Kaneshi Y.; Kusumoto K.; Ogawa Y. and
Lizuka T.1999. Enhancement by Recombinant Human Bone Morphogenetic
Protein-2 of Bone Formation by Means of Porous Hydroxyapatite in Mandibular
Bone Defects. J.Dent.Res. 28: 1505-10.
Zakaria M., 2002. Simen Portland Sebagai Bahan Pengikat Kepentingan dan
Cabarannya dalam Industri Komposit Papan Simen. Malaysia: 14.
Universitas Sumatera Utara
Agusnar H., 1997. Kajian pengaruh Kitosan Sebagai Aditif ke atas Sifat-Sifat Kertas
dari Pulpa Batang Sawit. Disertasi. UKM: 133.
Bird dkk., 2012. In Vitro Evaluation of Dentinal Tubule Penetration and
Biomineralization Ability of a New Root-end Filling Material. J Endod ; 38:1093–6.
[BPPP Deptan] Balai Penelitian Pasca Panen Departemen Pertanian., 2001. Peluang
Agribisnis Arang Sekam. Terhubung berkala www.pustaka-deptan.go.id/publikasi/
[1 Februari 2010].
Bramante dkk., 2008. Presence of Arsenic in Different Types of MTA and White and
Gray Portland Cement. JOE; 98(3) : 376- 79.
Camilleri J., 2008. Characterization of Hydration Products of Mineral Trioxide
Aggregate. Int Endod J; 41: 408-17.
Camilleri J., 2010. Evaluation of Physical Properties of an Endodontic Portland
Cement Incoporating Alternative Radiopacifier Used as Root-End Filling Material .
Int Endod J; 43: 231-40.
Chair Effendi M, 2012. Nanopartikel Mineral Trioksida Meningkatkan Proliferasi
dan Diferensiasi Sel Punca Pulpa Gigi Serta Maturasi Sel ke Arah Odontoblas:
Program Doktor Ilmu Kedokteran Gigi, Fakultas Kedokteran Gigi, Universitas
Indonesia.
Chandra dkk., 2012. Isolasi dan Karakterisasi Silika dari Sekam Padi. Lembaga
Penelitian dan Pengabdian pada Masyarakat. Universitas Khatolik Parahyangan.
Chang SW., 2012. Chemical Characteristics of Mineral Trioxide Aggregate and Its
Hydration Reaction.Restorative Dentistry & Endodontics; 37(4): 188-93.
Dahl JE dan Ǿrstavik., 2010. Response of the pulp-dentin ogan to dental restorative
biomaerials. Endodontic Topics; 17: 65-71.
Diana., 2008. Pengaruh Semen Portland Abu-abu dan Semen Portland Putih
Terhadap Viabilitas Sel Pulpa [Tesis]. Jakarta; Fakultas Kedokteran Gigi Universitas
Indonesia.
Universitas Sumatera Utara
Eskandarizadeh A dkk., 2006. A comparative Study between Mineral Trioxide
Aggregate and Calcium Hydroxide as Pulp Capping Agents in Dog’s Teeth. Iran;
Vol.2;2.
Ferracane JL, Cooper PR, Smith AJ., 2010. Can Interaction of Materials with the
Dentin–Pulp Complex Contribute to Dentin Regeneration? Odontology; 98: 2–14.
Fridland M, Rasado, Chem., 2003. Mineral Trioxide Aggregate (MTA) Solubility and
Porosity with Different Water-to-Powder Ratios. The American Association of
Endodontics; 29(12): 814-7
Ghavamnasiri M, Mousavinasab M, Mohtahsam M., 2005. A Histopathologic Study
on Pulp Response to Glass Ionomer Cements in Human Teeth. J Dent; .2(4): 13541.
Goldberg M, Smith AJ., 2004. Cells and Extracellular Matrices of Dentin and Pulp: A
Biological Basis for Repair and Tissue Engineering. CROBM; 15: 13-27.
Hargreaves KM, Cohen S., 2011. Cohen’s Pathways of the Pulp 10th. Missouri,
Elsevier; 40,459.
Han L, Okiji T., 2011. Uptake of calcium and silicon released from calcium silicatebased endodontic materials into root canal dentine. Int Endod J ;44:1081-7.
Henny Sutrisman., 2013. Efek Penambahan Kitosan Molekul Tinggi Nanopartikel
pada Semen Ionomer Kaca Nanopartikel Terhadap Viabilitas Sel Pulpa (In
Vitro).Tesis. Medan: FKG USU.
Indahyani DE, Hamzah Z, Barid I., 2011. Sifat Osteoinduktif Silika Amorphous
Sekam Padi. Dentika Dental Jurnal; 16: 116-20.
Kalapathy N, Proctor, Schultz., 2000. A Simple Method for Production of Pure Silica
from Rice Hull ash. Bioes. Technol. 73: 257- 62.
Kanjevac T, Milovanovic M, Yolarevic V, dkk., 2012. Cytotoxic Effects of Glass
Ionomer Cements on Human Dental Pulp Stem Cells Correlate with Flouride
Release. Medical Chemistry; 8: 40-45.
Lohbauer U., 2010. Dental Glass Ionomer Cements as Permanent Filling Materials
Properties, Limitations and Future Trends Materials; 3: 76-96.
Marist AI., 2011. Pelapisan Komposit Hidroksiapatit-Kitosan pada Logam Steinless
Steel 316 untuk Meningkatkan Ketahanaan Korosi [Tesis]. Bogor: Fakultas
Matematika dan Ilmu Pengetahuan Alam, Institut Pertanian Bogor.
Universitas Sumatera Utara
Makarim AK dan Suhartatik E. 2009. Morfologi dan Fisiologi Tanaman Padi.Balai
Besar Penelitian Tanaman Padi.
MCCabe JF, Walls AWG. 2008. Applied Dental Materials.9th Ed. Blackwell: 258-64.
Modena KC, Casas- Apayco LC, Atta MT, Costa CA, Hebling J, Sipert CR, Navarro
MF, Santos CF., 2009. Cytotoxicity and Biocompatibility of Direct and Indirect
Pulp Capping Materials. J Appl Oral Sci; 17(6): 544-54.
Moghaddam KM., 2008. An introduction to microbial metal nanoparticle preparation
method. The Journal of Young Investigators 19:19.
Murray PE, Lumley PJ, Smith AJ., 2002. Preserving the Vital Pulp in Operative
Dentistry: 3. Thickness of Reaimining Cavity Dentin as a key Mediator of Pulpal
Injury and Repair Responses; 29: 172-8.
Nagaraja Upadhya P and Kishore G., 2005. Glass Ionomer Cement – The Different
Generations. Trends Biomater. Artif. Organs; 18 (2): 158, 162.
Nicholson JW, Czarnecka B., 2008. The Biocompatibility of Resin Modified
GlassIonomer Cement for Dentistry. Dental Material; 24: 1702-8.
Ningsih W., 2010. Pengaruh Vikositas Larutan Kitosan Nanopartikel sebagai
Penyalut Asam Askorbat untuk Menyerap Asam Lemak Bebas (ALB) dalam
Minyak Goreng Curah. [Tesis]. Medan: Fakultas Matematika dan Ilmu Pengetahuan
Alam, Universitas Sumatera Utara.
Petri DFS, Donega J, Benassi AM, et al., 2007. Preliminary study on chitosan
modified glass ionomer restoratives. J Dent Materials; 23: 1004-10.
Preenan et all., 2004. Microtensile Bond Strength of Tooth-colored Materials to
Primary Tooth Dentin. Pediatric Dentistry; 26:1.
Putro AL, Prasetyoko D. 2007. Abu Sekam Padi sebagai Sumber Silika pada Sintesis
Ziolit ZSM-5 tanpa Menggunakan Templat Organik. Akta Kimia Indonesia. Vol
3(1): 33-36.
Queireoz AM, Asssed M, Leonardo MR., 2005. MTA and Calcium Hydroxide for
Pulp Capping. J Appl Oral Sci; 13(2): 126-30.
Rasinta Tarigan., 2013. Sketsa Gigi Premolar. Unpublish.
Universitas Sumatera Utara
Rao A, Rao A, Shenoy R. 2009. Mineral Trioxide Aggregate- A review. India. J Clin
Pediatr Dent: 34(1): 1-8.
Reyes-Carmona JF, Felippe MS, Felippe WT., 2009. The Biomineralization Ability
of Mineral Trioxide Aggregate and Portland Cement with Dentin in a Phosphate –
containing Fluid. J Endo; 35: 731-6.
Reyes-Carmona JF, Felippe MS, Felippe WT., 2010. The Biomineralization Ability
of Mineral Trioxide Aggregate and Portland Cement on Dentin Enhances the Pushout Strength. Brazil. J Endo; Vol.36: 286-91.
Robert TM, Heymann HO, Swift EJ. 2006. Sturdevant’s Art and Science of Operative
Dentistry. 5th ED. Missouri; Elsevier: 502-4.
Sauders SA., 2009. Current Partically of nanotechnology in Dentistry. Part I: Focus
on Nanocomposite Restoratives and Biomimetics. Clinical, Cosmetic and
Investigational Dentistry; 1:47-61.
Sarkar NK dkk., 2005. Physicochemical Basis of the Biologic Properties of Mineral
Trioxide Aggregate. J Endo; 31(2): 97-100.
Silva dkk., 2009. TNF-α Promotes on Odontoblastic Phenotype in Dental Pulp Cells.
J Dent Res; 88(4): 339-44.
Siregar M., 2009. Pengaruh Berat Molekul kitosan Nanopartikel untuk Menurunkan
Kadar Logam Besi (Fe) dan Zat Warna Pada Limbah Industri Tekstil Jeans. [Tesis].
Medan: Fakultas Pasca Sarjana, Universitas Sumatera Utara.
Smith AJ dkk., 2008. Dental Regeneration and Materials- a Partnership.Clin Oral
Invest; 12: 103-108.
Soeswanto B dan Lintang N., 2011. Pemanfaatan Limbah Sekam Padi menjadi
Natrium Silikat. Bandung; Jurnal fluida; Vol.11(1): 18-22.
Sugita P, Wukisari T, Sjahriza A, Wahyono A., 2009. Kitosan sumber biomaterial
masa depan. Bogor: IPB Press: 27, 125.
Sun W., 2007. Porous silicon based biomaterial fot bone tissue engineering. Partial
Fulfillment of the Requirements for the Degree Doctor of Philosophy Department of
Biomedical Engineering The College School of Engineering and Applied Science.
New York University of Rochester; 8-20.
Universitas Sumatera Utara
Suprastiwi E., 2011. Bioaktivitas Semen Ionomer Kaca dalam Menginduksi
Peningkatan Kadar ALP, DMP-1, dan Pembentukan Dentin Reparatif (Penelitian
InVivo pada Macaca Nemestrina). Disertasi. Jakarta: FKG UI.
Tiyaboonchai W., 2003. Chitosan Nanoparticles: A Promising System for Drug
Delivery. Naresuan University Journal; 11(3): 51-66.
Trimurni Abidin, Harry Agusnar; Wandania F., 2006/2007. Efek Dentinogenesis
Kitosan dan Derivatnya terhadap Inflamasi Jaringan Pulpa Gigi Reversibel.
Laporan Akhir Penelitian Riset Pembinaan IPTEK Kedokteran.
Trimurni Abidin., 2007. Inovasi Perawatan Konservasi Perawatan Konservasi Gigi
Melalui Teknologi Tissue Engineering. Pidato Pengukuhan Jabatan Guru Besar
Tetap dalam Bidang Ilmu Konservasi Gigi pada Fakultas Kedokteran Gigi
Universitas Sumatra Utara; 10-11.
Tyas MJ. 2006., Clinical Evaluation of Glass Ionomer Cement Restorations. J Appl
Oral Sci; 14: 10-13.
Yoshida K.; Bessho K.; Fujimura K.; Kaneshi Y.; Kusumoto K.; Ogawa Y. and
Lizuka T.1999. Enhancement by Recombinant Human Bone Morphogenetic
Protein-2 of Bone Formation by Means of Porous Hydroxyapatite in Mandibular
Bone Defects. J.Dent.Res. 28: 1505-10.
Zakaria M., 2002. Simen Portland Sebagai Bahan Pengikat Kepentingan dan
Cabarannya dalam Industri Komposit Papan Simen. Malaysia: 14.
Universitas Sumatera Utara