Temperature variations in pulp chamber: an in vitro comparison between ultrasonic and rotating instruments in tooth preparation.

Q3 Medicine

Minerva stomatologica Pub Date : 2020-02-01 DOI:10.23736/S0026-4970.19.04279-1

D. Baldi, J. Colombo, M. Robiony, M. Menini, Elisa Bisagni, P. Pera

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引用次数: 5

Abstract

BACKGROUND The purpose of this study was to analyze pulpal temperature increase generated by prosthodontic margin repositioning and finishing with ultrasonic and rotating instruments. The temperature changes recorded were also correlated with the residual dentin thickness. METHODS A sample of 32 human extracted molars was selected. The teeth were endodontically treated and prepared with prosthetic round chamfer preparation. Then, they were inserted in plaster cubes up to the cement-enamel junction, leaving the apical portion pervious for inserting the thermocouple probe. The conventional technique, which involves the use of a high-speed contra-angle handpiece, was compared with an ultrasonic method (Crown Prep, Mectron, Carasco, Italy). For margin repositioning and finishing, two walls were randomly selected for each tooth: one was included in the test group and cut with the piezoelectric instrument (Multipiezo Touch TipHolder DB2, Mectron, Carasco, Italy), the other one was inserted in the control group and cut with the high speed contra-angle handpiece (Kavo, Biberach, Germany). To standardize the operator-dependent parameters, it was used a mechanical arm controlled by a computer.These parameters were the pressure exerted on the dental wall, the cutting length and the time required for margin repositioning and finishing. For both test and control group, test phase consisted in a first stage of margin repositioning using an ultrasound tip or a diamond bur with a greater granulometry (120 μm for the ultrasound tip and 125 μm for the diamond bur), followed by a second finishing step conducted by an ultrasound tip or a diamond bur with smaller granulometry (60 μm for the ultrasound tip and 30 μm for the diamond bur). During these stages the intrapulpal temperature was recorded thanks to a thermocouple. Before and after these steps, the thickness of the remaining dental walls was measured with a caliber. RESULTS The average pulpal temperature increase was 5,03°C with a standard deviation of 0,98 for the ultrasonic preparation (test group) and 3,55°C with a standard deviation of 0,95 for the conventional technique (control group). The difference was statistically significant (p value < 0,001). However, neither of the instruments reached the critical level of 5.5°C reported in the literature. The mean initial dentin thicknesses was 1,82 mm (S.D. 0,47) for the control group and 1,59 mm (S.D. 0,54) for the test group but the analysis of the residual dentin thicknesses revealed a greater reduction of the walls worked up with high speed contra-angle handpiece (mean 0,9 mm, S.D. 0,5), which was therefore more aggressive than the ultrasonic instrument (mean 1,1 mm, S.D 0,5). A very weak negative correlation was present between the thickness of the wall at baseline and the increment of temperature. CONCLUSIONS Within limitations of this study, temperature increasing of ultrasonic instruments shows a statistical difference related to rotary ones. But, as literature shows, the ultrasonic advantages are margin precision, preservation of soft tissues and reduction of operating times. Furthermore, in relation with results of this study, they could be considered safe for pulp vitality because the increase in pulpal temperature is similar to traditional instruments and it doesn't exceed the critical level of 5,5°C.

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牙髓腔内温度变化:超声与旋转器械在牙体预备中的比较。

背景本研究的目的是分析超声和旋转器械对修复边缘重新定位和修整引起的牙髓温度升高。记录的温度变化也与残留牙本质厚度相关。方法选取32颗人类磨牙标本。对牙齿进行了牙髓治疗，并用人工圆倒角制剂进行了制备。然后，将其插入石膏立方体中，直至水泥-搪瓷连接处，使顶端部分可渗透，以便插入热电偶探针。将涉及使用高速反角度手持件的传统技术与超声波方法（Crown Prep，Mectron，Carasco，意大利）进行了比较。对于边缘重新定位和修整，每个牙齿随机选择两个壁：一个被纳入试验组，并用压电仪器（Multipiezo Touch TipHolder DB2，Mectron，Carasco，Italy）切割，另一个被插入对照组，并使用高速反角手持件（Kavo，Biberach，Germany）切割。为了使操作员相关参数标准化，使用了由计算机控制的机械臂。这些参数是施加在牙壁上的压力、切割长度以及边缘重新定位和精加工所需的时间。对于试验组和对照组，试验阶段均包括第一阶段的边缘重新定位，使用具有更大粒度的超声尖端或金刚石钻头（超声尖端为120μm，金刚石钻头为125μm），然后通过具有较小粒度的超声尖端或金刚石钻头（超声尖端为60μm，金刚石钻头为30μm）进行第二精加工步骤。在这些阶段，由于热电偶的作用，记录了硫酸盐内部的温度。在这些步骤之前和之后，用口径测量剩余牙壁的厚度。结果超声制剂（试验组）的平均牙髓温度升高为5.03°C，标准偏差为0.98；常规技术（对照组）的牙髓温度平均升高为3.55°C，标的偏差为0.95。差异具有统计学意义（p值<0.001）。然而，这两种仪器都没有达到文献中报道的5.5°C的临界水平。对照组和试验组的平均初始牙本质厚度分别为1.82 mm（S.D.0.47）和1.59 mm（S.D.0,54），但对残余牙本质厚度的分析显示，使用高速斜角手柄（平均0.9 mm，S.D.0,5）时，牙本质壁的减少更大，因此比超声波仪器（平均1.1 mm，S.D 0,5）更具攻击性。基线时的壁厚与温度增量之间存在非常弱的负相关性。结论在本研究的局限性范围内，超声波仪器的温度升高显示出与旋转式仪器相关的统计差异。但是，正如文献所示，超声波的优点是边缘精确、保存软组织和减少手术时间。此外，根据这项研究的结果，它们可以被认为对牙髓活力是安全的，因为牙髓温度的升高与传统仪器相似，并且没有超过5.5°C的临界水平。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Minerva stomatologica DENTISTRY, ORAL SURGERY & MEDICINE-

CiteScore

1.50

自引率

0.00%

发文量

期刊介绍： The journal Minerva Stomatologica publishes scientific papers on dentistry and maxillo-facial surgery. Manuscripts may be submitted in the form of editorials, original articles, review articles, case reports, therapeutical notes, special articles and letters to the Editor. Manuscripts are expected to comply with the instructions to authors which conform to the Uniform Requirements for Manuscripts Submitted to Biomedical Editors by the International Committee of Medical Journal Editors (www.icmje.org). Articles not conforming to international standards will not be considered for acceptance.