Objective: The purpose of this in vivo study was to determine the effect of two low-intensity laser therapy (LILT) protocols on macroscopic and microscopic parameters of experimental tooth movement. Materials and Methods: To induce experimental tooth movement in rats, 40 cN of orthodontic force was applied to the left first molars. Next, a gallium–aluminum–arsenide (Ga-Al-As) diode laser with a wavelength of 830 nm and power output of 100 mW was applied with fluence of 6000 J/cm2 on the area around the moved tooth. Two different application protocols were used in the experimental groups: one with daily irradiation and another with irradiation during early stages. Macroscopic and microscopic analyses were performed at days 2 and 7 of tooth movement. The amount of tooth movement was measured with a caliper, and tartrate-resistant acid phosphatase and picrosirius staining were used to enable identification of osteoclasts and immature collagen, respectively. Results: The amount of tooth movement did not differ between the irradiated and nonirradiated groups on days 2 and 7 of the experiment. On day 2, no difference was observed in the number of osteoclasts or the percentage of immature collagen. On day 7, there was an increase in the number of osteoclasts after daily applications of LILT, while two applications produced no significant difference from control. The amount of immature collagen on the tension side significantly increased in the nonirradiated group and when LILT was applied for only 2 d, whereas it was shown to be inhibited by daily LILT applications (p < 0.05). Conclusion: The tested LILT protocols were unable to accelerate tooth movement. Even though the number of osteoclasts increased when LILT was applied daily, the repair at the tension zone was inhibited.
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References
1.
KimY.D., KimS.S., KimS.J., KwonD.W., JeonE.S., SonW.S.2008. Low-level laser irradiation facilitates fibronectin and collagen type I turnover during tooth movement in rats. Lasers Med. Sci., 4[Epub ahead of print].
2.
KaleS., KocadereliI., AtillaP., AşanE.2004. Comparison of the effects of 1,25 dihydroxycholecalciferol and prostaglandin E2 on orthodontic tooth movement. Am. J. Orthod. Dentofacial Orthop., 125:607–614.
3.
MadanM.S., LiuZ.J., GuG.M., KingG.J.2007. Effects of human relaxin on orthodontic tooth movement and periodontal ligaments in rats. Am. J. Orthod. Dentofacial Orthop., 131:8.e1–8.e10.
4.
DavidovitchZ., FinkelsonM.D., SteigmanS., ShanfeldJ.L., MontgomeryP.C., KorostoffE.1980. Electric currents, bone remodeling, and orthodontic tooth movement. I. The effect of electric currents on periodontal cyclic nucleotides. Am. J. Orthod., 77:14–32.
5.
StarkT.M., SinclairP.M.1987. Effect of pulsed electromagnetic fields on orthodontic tooth movement. Am. J. Orthod. Dentofacial Orthop., 91:91–104.
6.
NishimuraM., ChibaM., OhashiT.et al.2008. Periodontal tissue activation by vibration: intermittent stimulation by resonance vibration accelerates experimental tooth movement in rats. Am. J. Orthod. Dentofacial Orthop., 133:572–583.
7.
KawasakiK., ShimizuN.2000. Effects of low-energy laser irradiation on bone remodeling during experimental tooth movement in rats. Lasers Surg. Med., 26:282–291.
8.
CruzD.R., KoharaE.K., RibeiroM.S., WetterN.U.2004. Effects of low-intensity laser therapy on the orthodontic movement velocity of human teeth: a preliminary study. Lasers Surg. Med., 35:117–120.
9.
LimpanichkulW., GodfreyK., SrisukN., RattanayatikulC.2006. Effects of low-level laser therapy on the rate of orthodontic tooth movement. Orthod. Craniofacial, 9:38–43.
10.
SeifiM., ShafeeiH.A., DaneshdoostS., MirM.2007. Effects of two types of low-level laser wave lengths (850 and 630 nm) on the orthodontic tooth movements in rabbits. Lasers Med. Sci., 22:261–264.
11.
FujitaS., YamaguchiM., UtsunomiyaT., YamamotoH., KasaiK.2008. Low-energy laser stimulates tooth movement velocity via expression of RANK and RANKL. Orthod. Craniofac., 11:143–155.
12.
OzawaY., ShimizuN., KariyaG., AbikoY.1998. Low-energy laser irradiation stimulates bone module formation at early stages of cell culture in rat calvarial cells. Bone, 22:347–354.
13.
KingG.J., ArcherL., ZhouD.1998. Later orthodontic appliance reactivation stimulates immediate appearance of osteoclasts and linear tooth movement. Am. J. Orthod. Dentofacial Orthop., 114:692–697.
14.
TaweechaisupapongS., SrisukN., NimitpornsukoC., VattraphoudesT., RattanayatikulC., GodfreyK.2005. Evening primrose oil effects on osteoclasts during tooth movement. Angle Orthod., 75:356–361.
15.
Vandevska-RadunovicV., KristiansenA.B., HeyeraasK.J., KvinnslandS.1994. Changes in blood circulation in teeth and supporting tissues incident to experimental tooth movement. Eur. J. Orthod., 16:361–369.
16.
RetamosoL.B., Da CunhaT.D.E.M., KnopL.A., ShintcovskR.L., TanakaO.M.2009. Organization and quantification of the collagen fibers in bone formation during orthodontic tooth movement. Micron, 40:827–830.
17.
Garavello-FreitasI., BaranauskasV., JoazeiroP.P., PadovaniC.R., Dal Pai-SilvaM., Da Cruz-HöflingM.A.2003. Low-power laser irradiation improves histomorphometrical parameters and bone matrix organization during tibia wound healing in rats. J. Photochem. Photobiol. B., 70:81–89.
18.
RenY., MalthaJ.C., Kuijpers-JagtmanA.M.2004. The rat as a model for orthodontic tooth movement—a critical review and a proposed solution. Eur. J. Orthod., 26:483–490.
19.
KaruT.1999. Primary and secondary mechanisms of action of visible to near-IR radiation on cells. J. Photochem. Photobiol. B., 49:1–17.
20.
SaitoS., ShimizuN.1997. Stimulatory effects of low-power laser irradiation on bone regeneration in midpalatal suture during expansion in the rat. Am. J. Orthod. Dentofacial Orthop., 111:525–532.
21.
CoombeA.R., HoC.T.G., DarendelilerM.A.et al.2001. The effects of low laser irradiation on osteoblastic cells. Clin. Orthod. Res., 4:3–14.
22.
HoureldN.N., AbrahamseH.2008. Laser light influences cellular viability and proliferation in diabetic-wounded fibroblast cells in a dose- and wavelength-dependent manner. Lasers Med. Sci., 23:11–18.
23.
DrevenšekM., SprogarS., BorasI., DrevensekG.2006. Effects of endothelin antagonist tezosentan on orthodontic tooth movement in rats. Am. J. Orthod. Dentofacial Orthop., 129:555–558.
24.
HalleenJ.M., TiitinenS.L., YlipahkalaH., FagerlundK.M., VäänänenH.K.2006. Tartrate-resistant acid phosphatase 5b (TRACP 5b) as a marker of bone resorption. Clin. Lab., 52:499–509.
25.
AiharaN., YamaguchiM., KasaiK.2006. Low-energy irradiation stimulates formation of osteoclast-like cells via RANK expression in vitro. Lasers Med. Sci., 21:24–33.
26.
NicolauR.A., JorgettiV., RigauJ., PachecoM.T.T., ReisL.M., ZângaroR.A.2003. Effect of low-power GaAlAs laser (660 nm) on bone structure and cell activity: an experimental animal study. Lasers Med. Sci., 18:89–94.
27.
KaruT.I., KolyakovS.F.2005. Exact action spectra for cellular responses relevant to phototherapy. Photomed. Laser Surg., 23:355–361.
28.
MundyG.R.1999. Bone Remodeling and Its Disorders, 2nd. London: Martin Dunitz Ltd.
29.
WangH., LiX., WuZ., WeiY., LuoZ.2008. The effect on the extracellular matrix of the deep fascia in response to leg lengthening. BMC Musculoskelet. Disord., 9:101.
30.
JunqueiraL.C., Assis FigueiredoM.T., TorloniH., MontesG.S.1986. Differential histologic diagnosis of osteoid. Study on human osteosarcoma collagen by the histochemical picrosirius-polarization method. J. Pathol., 148:189–196.
31.
Almeida-LopesL., RigauJ., ZângaroR.A., Guidugli-NetoJ., JaegerM.M.2001. Comparison of the low level laser therapy effects on cultured human gingival fibroblasts proliferation using different irradiance and same fluence. Lasers Surg. Med., 29:179–184.
32.
NgG.Y., FungD.T., LeungM.C., GuoX.2004. Ultrastructural comparison of medial collateral ligament repair after single or multiple applications of GaAlAs laser in rats. Lasers Surg. Med., 35:317–323.
33.
VernaC., ZaffeD., SicilianiG.1999. Histomorphometric study of bone reactions during orthodontic tooth movement in rats. Bone, 24:371–379.
