Lochmatter D, Steineck M, Brauchli L
Department of Orthodontics and Pedodontics, University of Basel, Hebelstr. 3, 4056, Basel, Switzerland.
J Orofac Orthop. 2012 Apr;73(2):104-15. doi: 10.1007/s00056-011-0067-7. Epub 2012 Mar 3.
Since their introduction in 1945, tooth positioners have been used to treat a range of malpositions. Although the original appliance was made of natural rubber, today's tooth positioners are fabricated from various elastic, transparent materials. It was the aim of this study to evaluate the forces and moments produced by current positioners on various upper canine malpositions.
Seven positioners of different materials were tested on 11 upper canine malpositions: 0.25, 0.5, 1 mm supraposition; 0.25, 0.5, 1 mm infraposition; 5°, 10°, 20° mesiorotation; 5° mesioinclination, 5° buccal root torque. We measured forces and moments in vitro after bite closure by 0.5 mm, and opening by 1 mm using a three-dimensional robotic device. All measurements were taken in a temperature-controlled environment at 36 °C.
The forces and moments measured at the canine varied greatly among the different positioners, with the thermoformed EVA positioner showing much greater forces and moments in almost all malpositions. At initial closure, we observed intrusive forces of 6-32 N for suprapositions, 0-11 N intrusive forces for infrapositions, 0-20 Nmm for mesiorotations, 6-12 Nmm for mesioinclinations, and - 23 Nmm to 5 Nmm for buccal root torque. All positioners were most effective on suprapositioned teeth. Very low or negligible correctional forces and moments in conjunction with all infrapositions and 5° with rotation were noted. Labial root torque led to unpredictable moments.
Positioner material plays a major role in delivering forces to the teeth. However, tooth positioners did not induce corrective forces in all the malpositions tested. Clinically relevant correctional forces or moments in conjunction with all suprapositions, rotations of 10° and 20° as well as mesial tipping of the canine were observed.
自1945年问世以来,牙齿定位器已被用于治疗一系列牙齿错位。尽管最初的矫治器由天然橡胶制成,但如今的牙齿定位器是由各种弹性透明材料制成。本研究旨在评估当前定位器对各种上颌尖牙错位产生的力和力矩。
在11种上颌尖牙错位情况上测试了7种不同材料的定位器:0.25、0.5、1毫米的重叠;0.25、0.5、1毫米的低位;5°、10°、20°的近中旋转;5°的近中倾斜、5°的颊根转矩。使用三维机器人装置在咬合关闭0.5毫米后和打开1毫米后在体外测量力和力矩。所有测量均在36℃的温度控制环境中进行。
不同定位器在尖牙处测量的力和力矩差异很大,热成型EVA定位器在几乎所有错位情况下显示出大得多的力和力矩。在初始关闭时,我们观察到重叠情况下的侵入力为6 - 32牛,低位情况下的侵入力为0 - 11牛,近中旋转情况下为0 - 20牛·毫米,近中倾斜情况下为6 - 12牛·毫米,颊根转矩情况下为 - 23牛·毫米至5牛·毫米。所有定位器对上颌重叠牙最有效。对于所有低位情况和5°旋转,观察到非常低或可忽略不计的矫正力和力矩。唇根转矩导致不可预测的力矩。
定位器材料在向牙齿传递力方面起主要作用。然而,牙齿定位器并非在所有测试的错位情况下都能产生矫正力。观察到与所有重叠、10°和
