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Journal of Peking University(Health Sciences) ›› 2019, Vol. 51 ›› Issue (6): 1124-1129. doi: 10.19723/j.issn.1671-167X.2019.06.026

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Effects of different methods on drying root canal by near-field microwave detection system

Jia-sha WANG1,Pei-yu WANG2,Yu-hong LIANG1,()   

  1. 1. Department of Cariology and Endodontology,Peking University School and Hospital of Stomatology & National Clinical Research Center for Oral Diseases & National Engineering Laboratory for Digital and Material Technology of Stomatology & Beijing Key Laboratory of Digital Stomatology, Beijing 100081, China
    2. State Key Laboratory for Turbulence and Complex Systems, College of Engineering, Peking University, Beijing 100871, China
    3. Department of Stomatology, Peking University International Hospital, Beijing 102206, China
  • Received:2017-12-06 Online:2019-12-18 Published:2019-12-19
  • Contact: Yu-hong LIANG E-mail:leungyuhong@sina.com

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Abstract:

Objective: To set up near-field microwave detection system, to evaluate the accuracy of measuring water and to compare the effects of different methods on drying root canal.Methods: Known and quantitative distilled water in Eppendorf tube and root canal was detected by near-field microwave detection system which was set up first. The microwave reflection coefficient was recorded so as to evaluate the accuracy of the measuring water. 12 single-rooted mandibular premolar teeth with apical matureness and a curvature less than 10° were decoronated, leaving roots 14 mm in length. After instrumentation to F3, the root canals were air-dried and injected with 10 μL distilled water each. Then all the root canals were assigned to 4 groups (n=12) according to different methods on root canal drying. Near-field microwave detection system was used to detect the change of water after air-drying and root canal drying so as to evaluate the effects of different root canal drying methods: (1) negative control group, the canals were injected with 10 μL distilled water and no root canal drying method was performed; (2) paper points drying experimental group, four #60 paper points were used to blot-dry the middle and upper part of the canal, followed by #40 paper points blot-drying the apical area. The above step was repeated with the tip of paper point that appeared with no water under microscope as finished; (3) 95% (volume fraction) ethanol drying experimental group, after the distilled water was removed with paper points (similar to paper points experimental group), 10 μL 95% ethanol was injected into the canal and was left in place for 10 s, then paper points were used to dry the canal; (4) 70% (volume fraction) isopropyl alcohol drying experimental group, after the distilled water was removed with paper points (similar to paper points experimental group), 10 μL 70% isopropyl alcohol was injected into the canal and was left in place for 10 s, then paper points were used to dry the canal. The linear correlation analysis was used to test the accuracy of the measuring water by near-field microwave detection method and physical measurement. The Pearson correlation coefficient was calculated based on the data. The effects of different methods on drying root canal were analyzed by Chi square test.Results: The R 2 for the microwave reflection coefficient and the physical measurement of the water in Eppendorf tube and root canal were 0.991 and 0.970. The microwave reflection coefficient in all the experimental groups showed significant difference (P<0.05). After drying with paper points, the residual water was the most, and the microwave reflection coefficient was the highest: 0.023. While after 70% isopropyl alcohol drying root canal, the residual water was the least with the microwave reflection coefficient 0.006, showing that the effect of drying was the best.Conclusion: Near-field microwave detection system could detect the change of water in root canal. The effect of root canal drying by 70% isopropyl alcohol was superior to 95% ethanol and paper points.

Key words: Root canal obturation, Near-field microwaves, Water, Bicuspid

CLC Number: 

  • R781.3

Figure 1

The physical view of near-field microwave detection"

Figure 2

The schematic diagram and physical view of self-made cavity mould"

Figure 3

The relationship between the microwave reflection coefficient and the physical measurement of water in Eppendorf tube"

Figure 4

The relationship between the microwave reflection coefficient and the physical measurement of water in root canal"

Figure 5

The critical value of water in near-field microwave detection system"

Figure 6

The microwave reflection coefficient of residual water after different drying methods on root canal ETOH, ethanol; IPA, isopropyl alcohol."

[1] 高学军, 岳林, 董艳梅 , 等. 牙体牙髓病学[M]. 2版. 北京: 北京大学医学出版社, 2013: 387.
[2] Wong Y, Spencer P . Continuing etching of an all-in-one adhesive in wet dentin tubules[J]. J Dent Res, 2005,84(4):350-354.
[3] Hasselgren G . The prognosis for endodontic treatment of obliterated root canals[J]. J Endod, 1988,14(11):565-567.
[4] Bence RW . Handbook of clinical endodontics[M]. London: Mosby, 1980.
[5] Nagas E, Uyanik MO, Eymirli A , et al. Dentin moisture conditions affect the adhesion of root canal sealers[J]. J Endod, 2012,38(2):240-244.
[6] Stevens RW, Strother JM, Mcclanahan SB . Leakage and sealer penetration in smear-free dentin after a final rinse with 95% ethanol[J]. J Endod, 2006,32(8):785-788.
[7] Gibby SG, Wong Y, Kulild JC , et al. Novel methodology to eva-luate the effect of residual moisture on epoxy resin sealer/dentine interface: a pilot study[J]. Int Endod J, 2011,44(3):236-244.
[8] Roggendorf MJ, Ebert J, Petschelt A , et al. Influence of moisture on the apical seal of root canal fillings with five different types of sealer[J]. J Endod, 2007,33(1):31-33.
[9] 黎粤华, 李靖宇 . 基于微波技术的温室作物含水量检测[J]. 森林工程, 2013(3):90-92.
[10] 杨厚荣, 罗友哲, 陈小英 . 微波雷达水分传感器应用于有耗介质水分测量研究[J]. 计测技术, 2010(S1):52-56.
[11] Takeyama T, Nikawa Y. Diagnosis of dental caries using millimeter wave reflection[C]// Asia Pacific Microwave Conference. Europe: Microwave Conference, 2009: 1196-1199.
[12] Komabayashi T, Zhu Q, Jiang J , et al. A rapid nondestructive method for root dentin moisture measurements: in vitro pilot study[J]. Oral Surg Oral Medo, 2009,107(3):e107-e111.
[13] Pane ES, Palamara JEA, Messer HH . Critical evaluation of the push-out test for root canal filling materials[J]. J Endod, 2013,39(5):669-673.
[14] Tay FR, Pashley DH, Yoshiyama M . Two modes of nanoleakage expression in single-step adhesives[J]. J Dent Res, 2002,81(7):472-476.
[15] Zoughi R . Microwave non-destructive testing and evaluation principles[M]. Berlin: Springer Science & Business Media, 2012.
[16] Pozar DM . Microwave engineering[M]. USA: John Wiley & Sons, 2009.
[17] 周在杞 . 微波检测技术[M]. 北京: 化学工业出版社, 2008.
[18] Sacilik K, Tarimci C, Colak A . Moisture content and bulk density dependence of dielectric properties of safflower seed in the radio frequency range[J]. J Food Eng, 2007,78(4):1111-1116.
[19] Krupka J . Frequency domain complex permittivity measurements at microwave frequencies[J]. Meas Sci Technol, 2006,17(6):R55.
[20] McKeown MS, Trabelsi S, Tollner EW , et al. Dielectric spectroscopy measurements for moisture prediction in Vidalia onions[J]. J Food Eng, 2012,111(3):505-510.
[21] Wang PY, Zhou L . Near-field microwave identification and quantitative evaluation of liquid ingress in honeycomb sandwich structures[J]. NDT & E Int, 2016(83):32-37.
[22] Gao M, Tang J, Johnson JA , et al. Dielectric properties of ground almond shells in the development of radio frequency and microwave pasteurization[J]. J Food Eng, 2012,112(4):282-287.
[23] Stuchly SS . Dielectric properties of some granular solids containing water[J]. J Microwave Power, 1970,5(2):62-68.
[24] Engel GT, Goodell GG , McClanahan SB. Sealer penetration and apical microleakage in smear-free dentin after a final rinse with either 70% isopropyl alcohol or Peridex[J]. J Endod, 2005,31(8):620-623.
[25] 邢其毅, 徐瑞秋, 裴伟伟 , 等. 基础有机化学[M]. 4版. 北京: 北京大学出版社, 2016: 7.
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