Publisher: Shahid Beheshti University of Medical Sciences
  • Submission
  • Register
  • Login

Journal of Dental School

  • Home
  • About
    • About the Journal
    • Journal Metrics
    • Editorial Team
    • Aims & Scope
    • Indexing & Abstracting
    • Open Access
    • Publication Fees
    • Privacy Statement
  • Articles & Issues
    • Current
    • Archive
    • Accepted Manuscripts
  • Policies & Process
    • Peer Review Process
    • Complaints And Appeals
    • Conflicts of Interest
    • Data and Reproducibility
    • Plagiarism
    • Post Publication
    • Misconducts
    • Preprint
    • Archiving
    • Editorial Independence
    • Copyright
  • For Authors
    • Authorship
    • Forms
    • Ethical Guidelines and Considerations
    • Reporting Guidelines
  • Submission
    • Submit a New Manuscript
    • Track Your Submission
    • Instructions for Authors
    • Download Original Article Template
    • Download Title Page Form
    • Download Publishing Agreement Form
  • Register
  • Contact
Advanced Search
  1. Home
  2. Archives
  3. Vol. 34 No. 3 (2016): Summer
  4. Original Article

Vol. 34 No. 3 (2016)

September 2016

Comparison of Compressive Strength of Five Hydraulic Cements

  • Vagharedin Akhavan Zanjani
  • Seyedeh Mahsa Sheikh-Al-Eslamian
  • Kasra Tabari

Journal of Dental School, Vol. 34 No. 3 (2016), 30 September 2016 , Page 129-136
https://doi.org/10.22037/jds.v34i3.24632 Published: 2019-03-17

  • View Article
  • Download
  • Cite
  • References
  • Statastics
  • Share

Abstract

Objectives: Maintaining pulp vitality is a main goal in restorative dentistry. Introduction of pulp capping agents paved the way to eliminate the shortcomings of these materials and obtain successful restorations. On the other hand, nanotechnology is an emerging field of science with increasing use in dental materials. This study sought to assess the effect of addition of nano-TiO2, nano-SiO2 and nano-Al2O3 on compressive strength of five hydraulic cements.

Methods: In this in vitro, experimental study, three experimental formulations of nano hybrid MTA, MTA Angelus and MTA Angelus+ nano-oxide particles cements were placed in molds measuring 4±0.1mm in internal diameter and 6±0.1mm in height made of stainless steel (ISO9917-1). Ten samples were fabricated for each of the five groups of materials. Sound samples were stored at 37°C and 95±5% humidity and were subjected to compressive strength testing in a universal testing machine at a crosshead speed of 0.5mm/minute after 24 hours and one month. Two-way ANOVA, one-way ANOVA and independent samples t-test were used for comparison of compressive strength of groups at different time points.

Results: The highest compressive strength belonged to MTA Angelus+ nanohydroxyapatite and nano-hybrid MTA C at 24 hours and 30 days, respectively. The lowest compressive strength belonged to nano-hybrid MTA B and MTA Angelus at 24 hours and 30 days, respectively (P<0.05).

Conclusion: Addition of nanoparticles affected the compressive strength of cements. Compressive strength significantly increased over time in all groups.
Keywords:
  • Compressive Strength
  • Dental Cements
  • Mineral Trioxide Aggregate
  • PDF

How to Cite

Akhavan Zanjani, V., Sheikh-Al-Eslamian, S. M., & Tabari, K. (2019). Comparison of Compressive Strength of Five Hydraulic Cements. Journal of Dental School, 34(3), 129–136. https://doi.org/10.22037/jds.v34i3.24632
  • ACM
  • ACS
  • APA
  • ABNT
  • Chicago
  • Harvard
  • IEEE
  • MLA
  • Turabian
  • Vancouver
  • Endnote/Zotero/Mendeley (RIS)
  • BibTeX

References

Roberson TM, Heyman HO, Swift EJ Jr. Sturdevant’s art and science of operative dentistry. 5th ed. St. Louis: Mosby; 2013:6-7.

Cohen S, Burns RC, Hargreaves KM, Berman LH. Pathways of the pulp: Elsevier Mosby St. Louis, Mo; 2013: 116-117.

Asgary S, Ahmadyar M. Vital pulp therapy using calcium-enriched mixture: An evidence-based review. J Conserv Dent. 2013 Mar;16(2):92-8.

Hosseinzade M, Karimi Soflou R , Valian A, Nojehdehian H. Physicochemical properties of MTA, CEM, hydroxyapatite and nano hydroxyapatite-chitosan dental cements. Biomed Res- India 2016;27(2):442-8.

Guerreiro-Tanomaru JM, Vázquez-García FA, Bosso-Martelo R, Bernardi MI, Faria G, Tanomaru M Filho. Effect of addition of nano-hydroxyapatite on physico-chemical and antibiofilm properties of calciumsilicate cements. J Appl Oral Sci. 2016 May-Jun;24(3):204-10.

Saghiri MA, Garcia-Godoy F, Asatourian A, Lotfi M, Banava S, Khezri-Boukani K. Effect of pH on compressive strength of some modification of mineral trioxide aggregate. Med Oral Patol Oral Cir Bucal. 2013 Jul;18(4):e714-20.

Akbari M, Zebarjad SM, Nategh B, Rouhani A. Effect of nano silica on setting time and physical properties of mineral trioxide aggregate. J Endod. 2013 Nov;39(11):1448-51.

Tanomaru-Filho M, Morales V, da Silva GF, Bosso R, Reis J, Duarte MA, et al. Compressive strength and setting time of MTA and Portland cement associated with different radiopacifying agents. ISRN Dent. 2012;2012:898051.

Kayahan MB, Nekoofar MH, McCann A, Sunay H, Kaptan RF, Meraji N, et al. Effect of acid etching procedures on the compressive strength of 4 calcium silicate–based endodontic cements. J Endod. 2013 Dec;39(12):1646-8.

Silva WJd, Souza PHC, Rosa EAR, Cury AADB, Rached RN. Mineral trioxide aggregate as root canal filing material: comparative study of physical properties. Revista Odonto Ciência. 2010 Dec;25(4):386-90.

Jo BW, Kim CH, Tae GH, Park JB. Characteristics of cement mortar with nano-SiO 2 particles. Construction and building materials. 2007 Jun;21(6):1351-5.

Li H, Xiao HG, Yuan J, Ou J. Microstructure of cement mortar with nano-particles. Composites Part B: Engineering. 2004 Mar;35(2):185-9.

Montazer M, Behzadnia A, Pakdel E, Rahimi MK, Moghadam MB. Photo induced silver on nano titanium dioxide as an enhanced antimicrobial agent for wool. J Photochem Photobiol B. 2011 Jun 2;103(3):207-14.

Jiang W, Mashayekhi H, Xing B. Bacterial toxicity comparison between nano-and micro-scaled oxide particles. Environ Pollut. 2009 May;157(5):1619-25.

Li Z, Wang H, He S, Lu Y, Wang M. Investigations on the preparation and mechanical properties of the nano-alumina reinforced cement composite. Materials Letters. 2006 Feb;60(3):356-9.

Brunet L, Lyon DY, Hotze EM, Alvarez PJ, Wiesner MR. Comparative photoactivity and antibacterial properties of C60 fullerenes and titanium dioxide nanoparticles. Environ Sci Technol. 2009 Jun;43(12):4355-60.

Massi S, Tanomaru-Filho M, Silva GF, Duarte MAH, Grizzo LT, Buzalaf MAR, et al. PH, calcium ion release, and setting time of an experimental mineral trioxide aggregate–based root canal sealer. J Endod. 2011 Jun;37(6):844-6.

Tanomaru-Filho M1, Chaves Faleiros FB, Saçaki JN, Hungaro Duarte MA, Guerreiro-Tanomaru JM. Evaluation of pH and calcium ion release of root-end filling materials containing calcium hydroxide or mineral trioxide aggregate. J Endod. 2009 Oct;35(10):1418-21.

Tanomaru-Filho M, Morales V, da Silva GF, Bosso R, Reis JM, Duarte MA, et al. Compressive Strength and Setting Time of MTA and Portland Cement Associated with Different Radiopacifying Agents. ISRN Dent. 2012;2012:898051.

Camilleri J. Modification of mineral trioxide aggregate. Physical and mechanical properties. IntEndod J. 2008;41(10):843-9.

Islam I, Chng HK, Yap AU. Comparison of the physical and mechanical properties of MTA and portland cement. J Endod. 2006 Mar;32(3):193-7.

Torabinejad M, Hong C, McDonald F, Pitt Ford T. Physical and chemical properties of a new root-end filling material. J Endod. 1995 Jul;21(7):349-53.

Abdullah D, Pitt Ford T, Papaioannou S, Nicholson J, McDonald F. An evaluation of accelerated portland cement as a restorative material. Biomaterials. 2002 Oct;23(19):4001-10.

Ford TR, Torabinejad M, McKendry DJ, Hong C-U, Kariyawasam SP. Use of mineral trioxide aggregate for repair of furcal perforations. Oral Surg Oral Med Oral Pathol Oral RadiolEndod. 1995 Jun;79(6):756-63.

Billington RW, Williams JA, Pearson GJ.Variation in powder/liquid ratio of a restorative glass-ionomer cement used in dental practice. Br Dent J. 1990 Sep;169(6):164-7.

Mount GJ. An atlas of glass-ionomer cements: a clinician's guide. 3th ed. Taylor &Francies e- Library, England: CRC Press; 2003.p350.

McLean JW, Wilson AD.The clinical development of the glass‐ionomer cements. I. Formulations and properties. Aust Dent J. 1977 Feb;22(1):31-6.

MohammadiBasir M, Ataei M, BagherRezvani M, Golkar P. Effect of incorporation of various amounts of nano-sized hydroxyapatite on the mechanical properties of resinmodified glass ionomer. Beheshti Univ Dent J. 2013;4:216-23.

  • Abstract Viewed: 219 times
  • PDF Downloaded: 130 times

Download Statastics

  • Linkedin
  • Twitter
  • Facebook
  • Google Plus
  • Telegram

Developed By

Open Journal Systems

Information

  • For Readers
  • For Authors
  • For Librarians

Make a Submission

Make a Submission
  • Home
  • Archives
  • Submissions
  • About the Journal
  • Editorial Team
  • Contact

e-ISSN: 2645-4351

Creative Commons License

This journal is open access and available under the Creative Commons Attribution-NonCommercial-NoDerivatives (CC BY-NC-ND) license (https://creativecommons.org/licenses/by-nc-nd/4.0/).

 
Powered by OJSPlus