1. Lin, M., et al., A review of heat transfer in human tooth—Experimental characterization and mathematical modeling. dental materials, 2010. 26: p. 501-513.
2. Millen, C., et al., A study of temperature rise in the pulp chamber during composite polymerization with different light-curing units. J Contemp Dent Pract, 2007. 8(7): p. 29-37.
3. Zach, L. and G. Cohen, Pulp Response to Externally Applied Heat. Oral Surg Oral Med Oral Pathol, 1965. 19: p. 515-30.
4. Bayne SC, Thompson JY, and T. DF., Dental materials., in Sturdevant's Art and Science of Operative Dentistry, T. Roberson, H.O. Heymann, and E.J. Swift, Editors. 2000, Mosby: St.Louis. p. 340-342.
5. Stewardson, D.A., et al., Thermal changes and cure depths associated with a high intensity light activation unit. Journal of Dentistry, 2004. 32: p. 643–651.
6. Aguiar, F.H., et al., Effect of polymerization modes and resin composite on the temperature rise of human dentin of different thicknesses: an in vitro study. Oper Dent, 2005. 30(5): p. 602-7.
7. da Silva, E.M., et al., Influence of the degree of dentine mineralization on pulp chamber temperature increase during resin-based composite (RBC) light-activation (PDF). J Dent, 2010. 38(4): p. 336-42.
8. Guiraldo, R.D., et al., Comparison of Silorane and Methacrylate-Based Composites on the Polymerization Heat Generated with Different Light-Curing Units and Dentin Thicknesses. Brazilian dental journal, 2013. 24(3): p. 258-262.
9. Aguiar, F.H., et al., Effect of composite resin polymerization modes on temperature rise in human dentin of different thicknesses: an in vitro study. Biomed Mater, 2006. 1(3): p. 140-3.
10. Dogan, A., et al., Temperature rise induced by various light curing units through human dentin. Dent Mater J, 2009. 28(3): p. 253-60.
11. Guiraldo, R.D., et al., Influence of light energy density on heat generation during photoactivation of dental composites with different dentin and composite thickness. J Appl Oral Sci. , 2009. 17(4): p. 289-93.
12. Rueggeberg, F., Contemporary issues in photocuring. Compend Contin Educ Dent Suppl, 1999(25): p. S4-15; quiz S73.
13. Nagel, R., Operation and diagnostic features of the VIP light. Compendium of continuing education in dentistry.(Jamesburg, NJ: 1995). Supplement, 1998(25): p. S55-9; quiz S74.
14. Mills, R.W., Blue light emitting diodes--another method of light curing? Br Dent J, 1995. 178(5): p. 169.
15. Mills, R.W., K.D. Jandt, and S.H. Ashworth, Dental composite depth of cure with halogen and blue light emitting diode technology. Br Dent J, 1999. 186(8): p. 388-91.
16. Nakamura, S., T. Mukai, and M. Senoh, High-power GaN pn junction blue-light-emitting diodes. Japanese Journal of Applied Physics, 1991. 30(12A): p. L1998.
17. Haitz R H, Craford M G, and W.R. H, Light emitting diodes. 2nd edn ed. Handbook of optics, ed. B. M1995, New York: McGraw Hill.
18. Sumikawa, D.A., et al., Microstructure of primary tooth dentin. Pediatric Dentistry, 1999. 21(7): p. 439-444.
19. Chowdhary, N., Dentin comparison in primary and permanent molars under transmitted and polarised light microscopy: An in vitro study. Journal of Indian Society of Pedodontics and Preventive Dentistry, 2010. 28(3): p. 167.
20. Nor, J.E., et al., Dentin bonding: SEM comparison of the resin-dentin interface in primary and permanent teeth. J Dent Res, 1996. 75(6): p. 1396-403.
21. Nor, J.E., et al., Dentin bonding: SEM comparison of the dentin surface in primary and permanent teeth. Pediatr Dent, 1997. 19(4): p. 246-52.
22. Shashikiran, N.D., S. Gunda, and V.V. Subba Reddy, Comparison of resin-dentine interface in primary and permanent teeth for three different durations of dentine etching. J Indian Soc Pedod Prev Dent, 2002. 20(4): p. 124-31.
23. Johnsen, D.C., Comparison of primary and permanent teeth, in Oral development and histology, J. Avery, Editor 1988, Thieme, 200. p. 180-219.
24. Loney, R.W. and R.B. Price, Temperature transmission of high-output light-curing units through dentin. Oper Dent, 2001. 26(5): p. 516-20.
25. Tjan, A.H. and J.R. Dunn, Temperature rise produced by various visible light generators through dentinal barriers. J Prosthet Dent, 1988. 59(4): p. 433-8.
26. Jakubinek, M.B., et al., Temperature excursions at the pulp–dentin junction during the curing of light-activated dental restorations. dental materials, 2008. 24: p. 1468-1476.
27. Knezevic, A., et al., Degree of conversion and temperature rise during polymerization of composite resin samples with blue diodes. J Oral Rehabil, 2001. 28(6): p. 586-91.
28. Vandewalle, K.S., et al., Thermal emission and curing efficiency of LED and halogen curing lights. Oper Dent, 2005. 30(2): p. 257-64.
29. Miyazaki, M., et al., Evaluation of curing units used in private dental offices. Operative dentistry, 1997. 23(2): p. 50-54.
30. Uhl, A., et al., The influence of storage and indenter load on the Knoop hardness of dental composites polymerized with LED and halogen technologies. dental materials, 2004. 20(1): p. 21-28.
31. Mills, R.W., et al., High power light emitting diode (LED) arrays versus halogen light polymerization of oral biomaterials: Barcol hardness, compressive strength and radiometric properties. Biomaterials, 2002. 23(14): p. 2955-63.
32. Stahl, F., et al., Light-emitting diode (LED) polymerisation of dental composites: flexural properties and polymerisation potential. Biomaterials, 2000. 21(13): p. 1379-85.
33. Ozturk, B., et al., Temperature rise during adhesive and resin composite polymerization with various light curing sources. Oper Dent, 2004. 29(3): p. 325-32.
34. Jandt, K., et al., Depth of cure and compressive strength of dental composites cured with blue light emitting diodes (LEDs). dental materials, 2000. 16(1): p. 41-47.
35. Leonard, D.L., Critical appraisal. Light-emitting-diode curing lights-revisited. J Esthet Restor Dent, 2007. 19(1): p. 56-62.
36. Kraemer, N., et al., Light curing of resin-based composites in the LED era. Am J Dent, 2008. 21(3): p. 135-142.
37. Guiraldo, R.D., et al., Influence of the light curing unit and thickness of residual dentin on generation of heat during composite photoactivation. J Oral Sci, 2008. 50(2): p. 137-42.
38. Summitt, J.B., J.W. Robbins, and T.J. Hilton, Fundamentals of Operative Dentistry: A Contemporary Approach. Third Edition ed2006: Quintessence Publishing Cot Inc.
39. Durey, K., A. Santini, and V. Miletic, Pulp chamber temperature rise during curing of resin-based composites with different light-curing units. Prim Dent Care, 2008. 15(1): p. 33-8.
40. Hirayama A, Yamada M, and M. K., An electron microscope study on dentinal tubules of human deciduous teeth. . Shikwa Gakuho, 1992. 86: p. 1021-1031.
41. Aguilar, F., et al., Histological Characteristics of Dentine in Permanent and Deciduous Teeth and their Clinic Significance. Preliminary Study, in Argentine Society of Dental Research 2007 2007.
42. Agematsu, H., et al., Scanning electron microscopic observations of microcanals and continuous zones of interglobular dentin in human deciduous incisal dentin. Bull Tokyo Dent Coll, 1990. 31(2): p. 163-73.
43. Bordin-Aykroyd, S., J. Sefton, and E. Davies, In vitro bond strengths of three current dentin adhesives to primary and permanent teeth. dental materials, 1992. 8(2): p. 74-78.
44. Hirayama, A., [Experimental analytical electron microscopic studies on the quantitative analysis of elemental concentrations in biological thin specimens and its application to dental science]. Shika gakuho. Dental science reports, 1990. 90(8): p. 1019-1036.