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Abstract

Step-growth thiol-Michael photopolymerizable resins, constituting an alternative chemistry to the current methacrylate-based chain-growth polymerizations, were developed and evaluated for use as dental restorative materials. The beneficial features inherent to anion-mediated thiol-Michael polymerizations were explored, such as rapid photocuring, low stress generation, ester content tunability, and improved mechanical performance in a moist environment. An ester-free tetrafunctional thiol and a ultraviolet-sensitive photobase generator were implemented to facilitate thiol-Michael photopolymerization. Thiol-Michael resins of varied ester content were fabricated under suitable light activation. Polymerization kinetics and shrinkage stress were determined with Fourier-transform infrared spectroscopy coupled with tensometery measurements. Thermomechanical properties of new materials were evaluated by dynamic mechanical analysis and in 3-point bending stress-strain experiments. Photopolymerization kinetics, polymerization shrinkage stress, glass transition temperature, flexural modulus, flexural toughness, and water sorption/solubility were compared between different thiol-Michael systems and the BisGMA/TEGDMA control. Furthermore, the mechanical performance of 2 thiol-Michael composites and a control composite were compared before and after extensive conditioning in water. All photobase-catalyzed thiol-Michael polymerization matrices achieved >90% conversion with a dramatic reduction in shrinkage stress as compared with the unfilled dimethacrylate control. One prototype of ester-free thiol-Michael formulations had significantly better water uptake properties than the BisGMA/TEGDMA control system. Although exhibiting relatively lower Young’s modulus and glass transition temperatures, highly uniform thiol-Michael materials achieved much higher toughness than the BisGMA/TEGDMA control. Moreover, low-ester thiol-Michael composite systems show stable mechanical performance even after extensive water treatment. Although further resin/curing methodology optimization is required, the photopolymerized thiol-Michael prototype resins can now be recognized as promising candidates for implementation in composite dental restorative materials.

Keywords

polymer click chemistry methacrylate composite resin light-curing of dental resins dental leakage

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References

Adzima

Bowman

. 2012. The emerging role of click reactions in chemical and biological engineering. AIChE J. 58(10):2952–2965.

Boulden

Cramer

Schreck

Couch

Bracho-Troconis

Stansbury

Bowman

. 2011. Thiol-ene-methacrylate composites as dental restorative materials. Dent Mater. 27(3):267–272.

Braga

Ballester

Ferracane

. 2005. Factors involved in the development of polymerization shrinkage stress in resin-composites: a systematic review. Dent Mater. 21(10):962–970.

Burujeny

Yeganeh

Atai

Gholami

Sorayya

. 2017. Bactericidal dental nanocomposites containing 1,2,3-triazolium-functionalized POSS additive prepared through thiol-ene click polymerization. Dent Mater. 33(1):119–131.

Chan

Hoyle

Lowe

Bowman

. 2010. Nucleophile-initiated thiol-Michael reactions: effect of organocatalyst, thiol, and ene. Macromolecules. 43(15):6381–6388.

Chatani

Gong

Earle

Podgórski

Bowman

. 2014. Visible-light initiated thiol-Michael addition photopolymerization reactions. ACS Macro Lett. 3(4):315–318.

Chatani

Wang

Podgórski

Bowman

. 2014. Triple shape memory materials incorporating two distinct polymer networks formed by selective thiol-Michael addition reactions. Macromolecules. 47(15):4949–4954.

Cramer

Stansbury

Bowman

. 2011. Recent advances and developments in composite dental restorative materials. J Dent Res. 90(4):402–416.

Dewaele

Truffier-Boutry

Devaux

Leloup

. 2006. Volume contraction in photocured dental resins: the shrinkage-conversion relationship revisited. Dent Mater. 22(4):359–365.

10.

Eick

Kostoryz

Rozzi

Jacobs

Oxman

Chappelow

Glaros

Yourtee

. 2002. In vitro biocompatibility of oxirane/polyol dental composites with promising physical properties. Dent Mater. 18(5):413–421.

11.

Ferracane

. 2011. Resin composite—state of the art. Dent Mater. 27(1):29–38.

12.

Gonzalez-Bonet

Kaufman

Yang

Wong

Jackson

Huyang

Bowen

Sun

. 2015. Preparation of dental resins resistant to enzymatic and hydrolytic degradation in oral environments. Biomacromolecules. 16(10):3381–3388.

13.

Hamano

Chiang

Nyamaa

Yamaguchi

Ino

Hickel

Kunzelmann

. 2012. Repair of silorane-based dental composites: influence of surface treatments. Dent Mater. 28(8):894–902.

14.

Khatri

Stansbury

Schultheisz

Antonucci

. 2003. Synthesis, characterization and evaluation of urethane derivatives of Bis-GMA. Dent Mater. 19(7):584–588.

15.

Kolb

Finn

Sharpless

. 2001. Click chemistry: diverse chemical function from a few good reactions. Angew Chem Int Ed Engl. 40(11):2004–2021.

16.

Lovell

Elliott

Stansbury

Bowman

. 2001. The effect of cure rate on the mechanical properties of dental resins. Dent Mater. 17(6):504–511.

17.

McCabe

Rusby

. 2004. Water absorption, dimensional change and radial pressure in resin matrix dental restorative materials. Biomaterials. 25(18):4001–4007.

18.

Moszner

Salz

. 2001. New developments of polymeric dental composites. Prog Polym Sci. 26(4):535–576.

19.

Pferifer

Ferracane

, inventors; Oregon Health and Science University, assignee. 2017 Mar 30. Dental Composites. United States patent US 15,126,751.

20.

Podgorski

Becka

Chatani

Claudino

Bowman

. 2015. Ester-free thiol-X resins: new materials with enhanced mechanical behavior and solvent resistance. Polym Chem. 6(12):2234–2240.

21.

Podgorski

Becka

Claudino

Flores

Shah

Stansbury

Bowman

. 2015a. Ester-free thiol-ene dental restoratives—part A: resin development. Dent Mater. 31(11):1255–1262.

22.

Podgorski

Becka

Claudino

Flores

Shah

Stansbury

Bowman

. 2015b. Ester-free thiol-ene dental restoratives—part B: composite development. Dent Mater. 31(11):1263–1270.

23.

Podgorski

Chatani

Bowman

. 2014. Development of glassy step-growth thiol-vinyl sulfone polymer networks. Macromol Rapid Commun. 35(17):1497–1502.

24.

Rahim

Mohamad

Md Akil

Ab Rahman

. 2012. Water sorption characteristics of restorative dental composites immersed in acidic drinks. Dent Mater. 28(6):e63–e70.

25.

Sarker

Kaneko

Neckers

. 2001. Synthesis of tetraorganylborate salts: photogeneration of tertiary amines. Chem Mater. 13(11):3949–3953.

26.

Shah

Stansbury

. 2006. Polymer-brush modified fillers for dental composites. Papers of the American Chemical Society. 231. http://oasys2.confex.com/acs/231nm/techprogram/P938474.HTM

27.

Sideridou

Achilias

Spyroudi

Karabela

. 2004. Water sorption characteristics of light-cured dental resins and composites based on bis-EMA/PCDMA. Biomaterials. 25(2):367–376.

28.

Sideridou

Tserki

Papanastasiou

. 2003. Study of water sorption, solubility and modulus of elasticity of light-cured dimethacrylate-based dental resins. Biomaterials. 24(4):655–665.

29.

Song

Sowan

Shah

Baranek

Flores

Stansbury

Bowman

. 2016. Reduced shrinkage stress via photo-initiated copper(I)-catalyzed cycloaddition polymerizations of azide-alkyne resins. Dent Mater. 32(11):1332–1342.

30.

Stansbury

Dickens

. 2001. Network formation and compositional drift during photo-initiated copolymerization of dimethacrylate monomers. Polymer. 42(15):6363–6369.

31.

Suyama

Araki

Shirai

. 2006. Quaternary ammonium salt as DBU-generating photobase generator. J Photopolym Sci Tec. 19(1):81–84.

32.

Suyama

Shirai

. 2009. Photobase generators: recent progress and application trend in polymer systems. Prog Polym Sci. 34(2):194–209.

33.

Wang

Zhang

Podgórski

Shah

Stansbury

Bowman

. 2015. Monodispersity/narrow polydispersity cross-linked microparticles prepared by step-growth thiol-Michael addition dispersion polymerizations. Macromolecules. 48(23):8461–8470.

34.

Krieger

Kloxin

Bowman

. 2013. A new photoclick reaction strategy: photo-induced catalysis of the thiol-Michael addition via a caged primary amine. Chem Commun (Camb). 49(40):4504–4506.

35.

Peng

Aguirre-Soto

Kloxin

Stansbury

Bowman

. 2014. Spatial and temporal control of thiol-Michael addition via photocaged superbase in photopatterning and two-stage polymer networks formation. Macromolecules. 47(18):6159–6165.

36.

Yap

Siow

. 2001. Soft-start polymerization: influence on effectiveness of cure and post-gel shrinkage. Oper Dent. 26(3):260–266.

37.

Zhang

Wang

Podgorski

Bowman

. 2016. Visible-light-initiated thiol-Michael addition polymerizations with coumarin-based photobase generators: another photoclick reaction strategy. ACS Macro Lett. 5(2):229–233.

38.

Zustiak

Leach

. 2010. Hydrolytically degradable poly (ethylene glycol) hydrogel scaffolds with tunable degradation and mechanical properties. Biomacromolecules. 11(5):1348–1357.

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Dental Restorative Materials Based on Thiol-Michael Photopolymerization

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