Efek Penambahan Kitosan Molekul Tinggi Nanopartikel Pada Abu Sekam Padi Nanopartikel Terhadap Viabilitas Sel Pulpa (In Vitro).
DAFTAR PUSTAKA
Agusnar H., 1997. Kajian pengaruh kitosan sebagai aditif ke atas sifat-sifat kertas dari
pulpa batang sawit. Disertasi. UKM: 130-40.
Anonymous.
Proliferation
assay.
MTT
Protocol.
http://www.acsu.buffalo.edu/~chunglee/Product/Cell%2QViability%2QAssay.htm.
(11/6/2014).
Anonymous. Measuring cell viability/cytotoxicity. http://www.invitrotech.com.
(11/6/2014).
Anonymous. Cryopreserved human hepatocyte high-throughput screening protocol:
96-well MTT cytoxicity assay. http://www.invitrotech.com. 11/6/2014.
Bergenholtz B., 2010. Hørsted-Bindslev P, Reit C. 1st ed. Textbook of
endodontology. United Kingdom: Wiley-Blackwell: 11-30.
Beriat NC, Nalbant D., 2009. Water absorption and HEMA release of resin-modified
glass-ionomers. European J Dent; 3: 267-72.
Bodrumlu E., 2008. Biocompatibility of retrograde root filling materials: a review.
Aust Endod J; 34:30-5.
Bogen G, Kuttler S., 2009. Mineral Trioxide Aggregate obturation: a riview and case
series. Review Article; 777-90.
Bramante dkk., 2008. Presence of arsenic in different types of MTA and white and
gray portland cement. JOE; 98 (3): 376-9.
Camilleri J., 2008. Characterization of hydration products of Mineral Trioxide
Aggregate. Int Endod J; 41: 408-17.
Camps J, Déjou J, Rémusat M, About I., Smith AJ, Matthews JB, Hall RC., 2000.
Factors influencing pulpal response to cavity restorations. Dent Material; 16: 432–40.
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.
Dahl JE, Orstavik D., 2010. Responses of the pulp–dentin organ to dental restorative
biomaterials. Endodontic Topics; 17;65-73.
Diana., 2008. Pengaruh semen portland abu-abu dan semen portland putih terhadap
viabilitas sel pulpa [Tesis]. Jakarta; Fakultas Kedokteran Gigi Universitas Indonesia.
do Nascimento AB, Fontana UF, Teixeira HM, Costa CA. , 2000.Biocompatibility of
a resin-modified glass-ionomer cement applied as pulp capping in human teeth. Am J
Dent ; 13: 28–34.
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.
Freshney RI., 2000. Culture of animal. A manual of basic technique. 4th ed. New
York: Willey-Liss; l 6,.78, 89-104, 309-12, 329-37.
Geurtsen W., 2000. Biocompatibility of resin-modified filling materials. Crit Rev
Oral Biol Med; 11: 333–55.
Ghavamnasiri M, Mousavinasab M, Mohtahsam M., 2005. A histopathologic study
on pulp response to glass ionomer cements in human teeth. J Dent; 2(4): 135-41.
Goldberg M, Smith AJ., 2004. Cells and extracellular matrices of dentin and pulp: a
biological basis for repair and tissue engineering. Crit Rev Oral Biol Med;15:13–27.
Goldberg M., 2008. In vitro and In vivo studies on the toxicity of dental resin
components: A Review. Clin Oral Invest; 12: 1-8.
Gutmann JL, Dumsha TC, Lovdahl PE., 2006. Problem solving in endodontics
prevention, Identification and Management. 4th ed. Singapore, Elsevier ; 37.
Hafdani FN, Sadeghinia N., 2011. A review on application of chitosan as a natural
antimicrobial. World Academy of Science; 74: 257-61.
Hargreaves K, Cohen S., 2011. Cohen’s Pathways of the pulp.10th ed. St. Louis.
Elsevier; 14: 508, 534.
Harsono H., 2002. Pembuatan silika amorf dari limbah sekam padi. J Ilmu Dasar; 3:
98-103.
Hebling J, Giro EMA, Costa CAS., 1999. Human pulp response after an adhesive
system application in deep cavities. J Dent; 27: 557– 64.
Henny Sutrisman, Trimurni A, Harry Agusnar. 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 Dent J; 16: 116-20.
Ismunadji M., 1988. Padi buku I. Bogor: Badan Penelitian dan Pengembangan
Pertanian.
Koh ET, Torabinejad M, Pitt Ford TR, Brady K, McDonald F., 1997. Mineral
trioxide aggregate stimulates a biological response in human osteoblasts. J Biomed
Mater Res; 37:432–9.
Kuratate M, Yoshiba K, Shigetani Y, Yoshiba N, Ohshima H, Okiji T., 2008
Immunohistochemical analysis of nestin, osteopontin, and proliferating cells in the
reparative process of exposed dental pulp capped with mineral trioxide aggregate. J
Endod; 34: 970–4.
Lohbauer U., 2010. Dental glass ionomer cements as permanent filling materials? —
properties, limitations and future trends.Dent Materials; 3: 76-96.
Mantellini MG, Botero TM, Yaman P, Dennison JB, Hanks CT, Nor JE., 2003.
Adhesive resin induces apoptosis and cell-cycle arrest of pulp cells. J Dent Res;
82(8): 593-4.
Margono A., 2012. Potensi sel punca mesenkim asal jaringan lemak dengan produk
plasma untuk regenerasi sel Odontoblas. Program Doktor Ilmu Kedokteran Gigi,
Fakultas Kedokteran Gigi, Universitas Indonesia.
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.
Modena KC, Casas-Apayco LC, Atta MT et al., 2009. Cytotoxicity and
biocompatibility of direct and indirect pulp capping materials. J Appl Oral Sci; 17(6):
544-54.
Murray PE; Lumley JL; Smith AJ., 2002. Preserving the vital pulp in operative
dentistry: 3. Thickness of remaining cavity dentine as a key madiator of pulp injury
and repair responses, Dental Update; 29:178.
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 glass
ionomer cement for dentistry. Dental Material; 24: 1702-8.
Ningsih W., 2010. Pengaruh viskositas larutan kitosan nanopartikel sebagai penyalut
asam askorbat untuk menyerap asam lemak bebas (ALB) dalam minyak goreng
curah. Tesis. Medan: USU: 1-21.
Osman-Tolga H, Yusuf-Ziya B, Zuhal A, Abdulgani T., 2009. Cytotoxic effects of
TEGDMA on THP-1 cells in vitro. Med Oral Patol Oral Cir Bucal; 14 (9): 489-93.
Pameijer CH, Stanley HR, Ecker G., 1991. Biocompatibility of a glass ionomer luting
agent. Part II; crown cementation. Am J Dent; 4: 134–41.
Park B., 2007. Current and future applications of nanotechnology. Issues in
Environmental Science and Technology; 24: 1-18.
Pashley DH, Tay FR, Yiu C., 2004. Collagen degradation by hostderived enzymes
during aging, J Dent Res; 83: 216–21.
Petri DFS, Donega J, Benassi AM, et al., 2007. Preliminary study on chitosan
modified glass ionomer restoratives. J Dent Materials; 23: 1004-10.
Pretty FS Silalahi, Trimurni A, Harry Agusnar. 2014. Studi karakteristik abu sekam
padi dengan kitosan molekul tinggi nanopartikel sebagai bahan Ddentinogenesis pada
kavitas profunda (in vitro) Tesis. Medan: FKG USU
Quinlan CA, Zisterer DM, Tipton KF, O’Sullivan MI., 2002. In vitro cytotoxicity of a
composite resin and compomer. IEJ; 35: 47-55.
Queireoz AM, Asssed M, Leonardo MR., 2005. MTA and calcium hydroxide for
pulp capping. J Appl Oral Sci; 13(2): 126-30.
Rao Arathi, Rao Ashwini, Shenoy R., 2009. Mineral Trioxide Aggregate- a riview.
the journal of clinical pediatric dentistry; 34; 1-5.
Refitt DM, Ogston N, Jugdaohsingh R., 2003. Orthosilicic acid stimulates collagen
type I syntesis and osteoblastic differentiation in human osteoblast-like cells in vitro.
Bone; 32: 127-35.
Ryan
JA.,
2008.
Introduction
to
animal
cell
culture
http;://209.85.175.104/search?q=cache;qvQ3RevdVvs;wwwcorning..com/lifescienee/
technical
information/techDoes?intro
animal
cell
culture.pdf+Introduction+to+Animal+Cell+Culture&hl=id&et=clnk&cd=1&gl=id
Schmalz G, Arenholt-Bindslev D., 2009. Biocompatibility of dental materials. Berlin.
Springer; 149-58.
Sidhu SK, Schmalz G., 2001. The biocompatibility of glassionomer cement materials.
A status report for the American Journal of Dentistry. Am J Dent; 14: 387–96.
Siregar M., 2009. Pengaruh berat molekul kitosan nanopartikel untuk menurunkan
kadar logam besi (Fe) dan zat warna pada limbah industri tekstil jeans. Tesis. Medan:
Pasca sarjana USU: 5- 14.
Sinulingga K, Agusnar H, Wirjosentono B, Zakaria., 2014. The effect of mixing ice
husk ash and palm oil boiler ash on concrete strength. American Journal of Physical
Chemistry: 1-6.
Smith AJ., 2003.Vitality of the dentin-pulp complex in health and disease: growth
factors as key mediators. Journal of Dental Education; 67: 678-90.
Smith AJ, Matthews JB, Hall RC., 1998. Transforming growth factor-beta1 (TGFbeta1) in dentine matrix. Ligand activation and receptor expression. Eur J Oral Sci;
106 (Suppl 1): 179–84.
Stanley HR., 1968. Design for a human pulp study. Part I. Oral Surg, Oral Med, Oral
Pathol; 25: 633–47.
Subowo., 2007. Buku biologi sel. Bandung; Indonnesia: 13: 321-2.
Sugita P, Wukisari T, Sjahriza A, Wahyono A., 2009. Kitosan sumber biomaterial
masa depan. Bogor: IPB Press: 27, 125.
Suprastiwi E., 2011. Bioaktivitas semen ionomer kaca dalam menginduksi
peningkatan kadar ALP, DMP-1, dan pembentukan dentin reparatif (in vivo pada
Macaca Nemestrina). Disertasi. Jakarta: FKG UI.
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.
Tanomaru M, Morales V, Silva G, Bosso R, Reis J, Duarte M, Tanomoru JM. 2012.
Compressive strength and setting time of MTA and portland cement associated with
different radiopacifying agents. International Scholarly Research Network; 1-3.
Tani-Ishii N, Hamada N, Watanabe K, Tujimoto Y, Teranaka T, Umemoto T., 2007.
Expression of bone extracellular matrix proteins on osteoblast cells in the presence of
mineral trioxide. J Endod; 33: 836–9.
Tiyaboonchai W., 2003. Chitosan nanoparticles: a promising system for drug
delivery. Naresuan University Journal; 11(3): 51-66.
Torabinejad M, Hong CU, McDonald F, Pitt Ford TR., 1995. Physical and chemical
properties of a new root-end filling material. J Endod; 21:349-52.
Torabinejad M, Parirokh M., 2010. Mineral trioxide aggregate: a comprehensive
literature review-part II: leakage and biocompatibility investigations. J Endod;
36:190- 202.
Trimurni A, Harry A, Wandania F., 2007. Efek dentinogenesis kitosan dan derivatnya
terhadap inflamasi jaringan pulpa gigi reversible. Laporan Akhir Penelitian Riset
Pembinaan Iptek Kedokteran. Medan: FKG USU: 16-8, 27-30, 39-41.
Trimurni A., 2007. Inovasi perawatan konservasi gigi melalui teknologi tissue
engineering. Pidato Pengukuhan Jabatan Guru Besar Tetap dalam Bidang Ilmu
Konservasi Gigi pada Fakultas Kedokteran Gigi. Medan: 2.
Tyas MJ., 2006. Clinical evaluation of glass ionomer cement restorations. J Appl Oral
Sci; 14: 10-13.
Zakaria M., 2002. Simen portland sebagai bahan pengikat kepentingan dan
cabarannya dalam industri komposit papan simen. Malaysia: 14.
Agusnar H., 1997. Kajian pengaruh kitosan sebagai aditif ke atas sifat-sifat kertas dari
pulpa batang sawit. Disertasi. UKM: 130-40.
Anonymous.
Proliferation
assay.
MTT
Protocol.
http://www.acsu.buffalo.edu/~chunglee/Product/Cell%2QViability%2QAssay.htm.
(11/6/2014).
Anonymous. Measuring cell viability/cytotoxicity. http://www.invitrotech.com.
(11/6/2014).
Anonymous. Cryopreserved human hepatocyte high-throughput screening protocol:
96-well MTT cytoxicity assay. http://www.invitrotech.com. 11/6/2014.
Bergenholtz B., 2010. Hørsted-Bindslev P, Reit C. 1st ed. Textbook of
endodontology. United Kingdom: Wiley-Blackwell: 11-30.
Beriat NC, Nalbant D., 2009. Water absorption and HEMA release of resin-modified
glass-ionomers. European J Dent; 3: 267-72.
Bodrumlu E., 2008. Biocompatibility of retrograde root filling materials: a review.
Aust Endod J; 34:30-5.
Bogen G, Kuttler S., 2009. Mineral Trioxide Aggregate obturation: a riview and case
series. Review Article; 777-90.
Bramante dkk., 2008. Presence of arsenic in different types of MTA and white and
gray portland cement. JOE; 98 (3): 376-9.
Camilleri J., 2008. Characterization of hydration products of Mineral Trioxide
Aggregate. Int Endod J; 41: 408-17.
Camps J, Déjou J, Rémusat M, About I., Smith AJ, Matthews JB, Hall RC., 2000.
Factors influencing pulpal response to cavity restorations. Dent Material; 16: 432–40.
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.
Dahl JE, Orstavik D., 2010. Responses of the pulp–dentin organ to dental restorative
biomaterials. Endodontic Topics; 17;65-73.
Diana., 2008. Pengaruh semen portland abu-abu dan semen portland putih terhadap
viabilitas sel pulpa [Tesis]. Jakarta; Fakultas Kedokteran Gigi Universitas Indonesia.
do Nascimento AB, Fontana UF, Teixeira HM, Costa CA. , 2000.Biocompatibility of
a resin-modified glass-ionomer cement applied as pulp capping in human teeth. Am J
Dent ; 13: 28–34.
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.
Freshney RI., 2000. Culture of animal. A manual of basic technique. 4th ed. New
York: Willey-Liss; l 6,.78, 89-104, 309-12, 329-37.
Geurtsen W., 2000. Biocompatibility of resin-modified filling materials. Crit Rev
Oral Biol Med; 11: 333–55.
Ghavamnasiri M, Mousavinasab M, Mohtahsam M., 2005. A histopathologic study
on pulp response to glass ionomer cements in human teeth. J Dent; 2(4): 135-41.
Goldberg M, Smith AJ., 2004. Cells and extracellular matrices of dentin and pulp: a
biological basis for repair and tissue engineering. Crit Rev Oral Biol Med;15:13–27.
Goldberg M., 2008. In vitro and In vivo studies on the toxicity of dental resin
components: A Review. Clin Oral Invest; 12: 1-8.
Gutmann JL, Dumsha TC, Lovdahl PE., 2006. Problem solving in endodontics
prevention, Identification and Management. 4th ed. Singapore, Elsevier ; 37.
Hafdani FN, Sadeghinia N., 2011. A review on application of chitosan as a natural
antimicrobial. World Academy of Science; 74: 257-61.
Hargreaves K, Cohen S., 2011. Cohen’s Pathways of the pulp.10th ed. St. Louis.
Elsevier; 14: 508, 534.
Harsono H., 2002. Pembuatan silika amorf dari limbah sekam padi. J Ilmu Dasar; 3:
98-103.
Hebling J, Giro EMA, Costa CAS., 1999. Human pulp response after an adhesive
system application in deep cavities. J Dent; 27: 557– 64.
Henny Sutrisman, Trimurni A, Harry Agusnar. 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 Dent J; 16: 116-20.
Ismunadji M., 1988. Padi buku I. Bogor: Badan Penelitian dan Pengembangan
Pertanian.
Koh ET, Torabinejad M, Pitt Ford TR, Brady K, McDonald F., 1997. Mineral
trioxide aggregate stimulates a biological response in human osteoblasts. J Biomed
Mater Res; 37:432–9.
Kuratate M, Yoshiba K, Shigetani Y, Yoshiba N, Ohshima H, Okiji T., 2008
Immunohistochemical analysis of nestin, osteopontin, and proliferating cells in the
reparative process of exposed dental pulp capped with mineral trioxide aggregate. J
Endod; 34: 970–4.
Lohbauer U., 2010. Dental glass ionomer cements as permanent filling materials? —
properties, limitations and future trends.Dent Materials; 3: 76-96.
Mantellini MG, Botero TM, Yaman P, Dennison JB, Hanks CT, Nor JE., 2003.
Adhesive resin induces apoptosis and cell-cycle arrest of pulp cells. J Dent Res;
82(8): 593-4.
Margono A., 2012. Potensi sel punca mesenkim asal jaringan lemak dengan produk
plasma untuk regenerasi sel Odontoblas. Program Doktor Ilmu Kedokteran Gigi,
Fakultas Kedokteran Gigi, Universitas Indonesia.
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.
Modena KC, Casas-Apayco LC, Atta MT et al., 2009. Cytotoxicity and
biocompatibility of direct and indirect pulp capping materials. J Appl Oral Sci; 17(6):
544-54.
Murray PE; Lumley JL; Smith AJ., 2002. Preserving the vital pulp in operative
dentistry: 3. Thickness of remaining cavity dentine as a key madiator of pulp injury
and repair responses, Dental Update; 29:178.
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 glass
ionomer cement for dentistry. Dental Material; 24: 1702-8.
Ningsih W., 2010. Pengaruh viskositas larutan kitosan nanopartikel sebagai penyalut
asam askorbat untuk menyerap asam lemak bebas (ALB) dalam minyak goreng
curah. Tesis. Medan: USU: 1-21.
Osman-Tolga H, Yusuf-Ziya B, Zuhal A, Abdulgani T., 2009. Cytotoxic effects of
TEGDMA on THP-1 cells in vitro. Med Oral Patol Oral Cir Bucal; 14 (9): 489-93.
Pameijer CH, Stanley HR, Ecker G., 1991. Biocompatibility of a glass ionomer luting
agent. Part II; crown cementation. Am J Dent; 4: 134–41.
Park B., 2007. Current and future applications of nanotechnology. Issues in
Environmental Science and Technology; 24: 1-18.
Pashley DH, Tay FR, Yiu C., 2004. Collagen degradation by hostderived enzymes
during aging, J Dent Res; 83: 216–21.
Petri DFS, Donega J, Benassi AM, et al., 2007. Preliminary study on chitosan
modified glass ionomer restoratives. J Dent Materials; 23: 1004-10.
Pretty FS Silalahi, Trimurni A, Harry Agusnar. 2014. Studi karakteristik abu sekam
padi dengan kitosan molekul tinggi nanopartikel sebagai bahan Ddentinogenesis pada
kavitas profunda (in vitro) Tesis. Medan: FKG USU
Quinlan CA, Zisterer DM, Tipton KF, O’Sullivan MI., 2002. In vitro cytotoxicity of a
composite resin and compomer. IEJ; 35: 47-55.
Queireoz AM, Asssed M, Leonardo MR., 2005. MTA and calcium hydroxide for
pulp capping. J Appl Oral Sci; 13(2): 126-30.
Rao Arathi, Rao Ashwini, Shenoy R., 2009. Mineral Trioxide Aggregate- a riview.
the journal of clinical pediatric dentistry; 34; 1-5.
Refitt DM, Ogston N, Jugdaohsingh R., 2003. Orthosilicic acid stimulates collagen
type I syntesis and osteoblastic differentiation in human osteoblast-like cells in vitro.
Bone; 32: 127-35.
Ryan
JA.,
2008.
Introduction
to
animal
cell
culture
http;://209.85.175.104/search?q=cache;qvQ3RevdVvs;wwwcorning..com/lifescienee/
technical
information/techDoes?intro
animal
cell
culture.pdf+Introduction+to+Animal+Cell+Culture&hl=id&et=clnk&cd=1&gl=id
Schmalz G, Arenholt-Bindslev D., 2009. Biocompatibility of dental materials. Berlin.
Springer; 149-58.
Sidhu SK, Schmalz G., 2001. The biocompatibility of glassionomer cement materials.
A status report for the American Journal of Dentistry. Am J Dent; 14: 387–96.
Siregar M., 2009. Pengaruh berat molekul kitosan nanopartikel untuk menurunkan
kadar logam besi (Fe) dan zat warna pada limbah industri tekstil jeans. Tesis. Medan:
Pasca sarjana USU: 5- 14.
Sinulingga K, Agusnar H, Wirjosentono B, Zakaria., 2014. The effect of mixing ice
husk ash and palm oil boiler ash on concrete strength. American Journal of Physical
Chemistry: 1-6.
Smith AJ., 2003.Vitality of the dentin-pulp complex in health and disease: growth
factors as key mediators. Journal of Dental Education; 67: 678-90.
Smith AJ, Matthews JB, Hall RC., 1998. Transforming growth factor-beta1 (TGFbeta1) in dentine matrix. Ligand activation and receptor expression. Eur J Oral Sci;
106 (Suppl 1): 179–84.
Stanley HR., 1968. Design for a human pulp study. Part I. Oral Surg, Oral Med, Oral
Pathol; 25: 633–47.
Subowo., 2007. Buku biologi sel. Bandung; Indonnesia: 13: 321-2.
Sugita P, Wukisari T, Sjahriza A, Wahyono A., 2009. Kitosan sumber biomaterial
masa depan. Bogor: IPB Press: 27, 125.
Suprastiwi E., 2011. Bioaktivitas semen ionomer kaca dalam menginduksi
peningkatan kadar ALP, DMP-1, dan pembentukan dentin reparatif (in vivo pada
Macaca Nemestrina). Disertasi. Jakarta: FKG UI.
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.
Tanomaru M, Morales V, Silva G, Bosso R, Reis J, Duarte M, Tanomoru JM. 2012.
Compressive strength and setting time of MTA and portland cement associated with
different radiopacifying agents. International Scholarly Research Network; 1-3.
Tani-Ishii N, Hamada N, Watanabe K, Tujimoto Y, Teranaka T, Umemoto T., 2007.
Expression of bone extracellular matrix proteins on osteoblast cells in the presence of
mineral trioxide. J Endod; 33: 836–9.
Tiyaboonchai W., 2003. Chitosan nanoparticles: a promising system for drug
delivery. Naresuan University Journal; 11(3): 51-66.
Torabinejad M, Hong CU, McDonald F, Pitt Ford TR., 1995. Physical and chemical
properties of a new root-end filling material. J Endod; 21:349-52.
Torabinejad M, Parirokh M., 2010. Mineral trioxide aggregate: a comprehensive
literature review-part II: leakage and biocompatibility investigations. J Endod;
36:190- 202.
Trimurni A, Harry A, Wandania F., 2007. Efek dentinogenesis kitosan dan derivatnya
terhadap inflamasi jaringan pulpa gigi reversible. Laporan Akhir Penelitian Riset
Pembinaan Iptek Kedokteran. Medan: FKG USU: 16-8, 27-30, 39-41.
Trimurni A., 2007. Inovasi perawatan konservasi gigi melalui teknologi tissue
engineering. Pidato Pengukuhan Jabatan Guru Besar Tetap dalam Bidang Ilmu
Konservasi Gigi pada Fakultas Kedokteran Gigi. Medan: 2.
Tyas MJ., 2006. Clinical evaluation of glass ionomer cement restorations. J Appl Oral
Sci; 14: 10-13.
Zakaria M., 2002. Simen portland sebagai bahan pengikat kepentingan dan
cabarannya dalam industri komposit papan simen. Malaysia: 14.