Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender

Yıl: 2019 Cilt: 9 Sayı: 1 Sayfa Aralığı: 30 - 40 Metin Dili: İngilizce DOI: 10.5577/intdentres.2019.vol9.no1.5 İndeks Tarihi: 01-04-2020

Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender

Öz:
Aim: The aim of this study was to demonstrate the anatomical structureof pulp chamber, measure the volume of the total pulp chambers in mm3and evaluate the pulp chamber volume changes by age and genderstatistically in mandibular and maxillary first molars by means of CBCT.Methodology: In our study, CBCT examinations of patients between theages of 7-18 years, which were carried out due to different reasons wereevaluated retrospectively. The CBCT images of healthy total of 160 lowerand upper right permanent first molar teeth were selected randomly andthe volumes of the total pulp chamber were measured in mm3 with the 3DSlicer software program. We analyzed the collected data with statisticalanalysis methods and we evaluated whether there was any differencebetween the patients grouped according to the age in respect of volumechanges in the total pulp chamber and whether there was any differencebetween the mean volume values and gender of the patients within thesame group.Results: Comparison of the volume measurements of the lower and upperfirst permanent molar teeth between the groups showed that the volumevalues of the total pulp chamber decreased depending on the age (p<0.05).Regarding gender, volume decrease related to age was statistically moresignificant among females. We determined in all age groups except age 7-9 group that the volume value of the total pulp chamber of the upperpermanent first molar teeth was statistically higher than the volume valueof the total pulp chamber of the lower permanent first molar teeth(p<0,05).Conclusions: We believe that CBCT is an easy and conservative methodfor the 3D-imaging of the pulp chamber, volume measurement andexamination of the dimensional changes of the total pulp chamberdepending on deposition of secondary dentin.
Anahtar Kelime:

Konular: Diş Hekimliği
Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık
  • 1. Ketterl W. Age-induced Changes in the Teeth and Their Attachment Apparatus. Int Dent J. 1983;33(3):262-71.
  • 2. Boushell LW, Sturdevant JR. Clinical Significance of Dental Anatomy, Histology, Physiology, and Occlusion. In: Heymann HO, Swift EJ, Ritter AV, editors. Sturdevant's Art & Science of Operative Dentistry. 6 ed. St. Louis: Mosby; 2013. p. 1-40.
  • 3. Zilberman U, Smith P. Sex-and age-related differences in primary and secondary dentin formation. Adv Dent Res. 2001;15(1):42-5. (Crossref)
  • 4. Nancy A. Dentin-Pulp Complex. In: Rudolp P, Alvis K, editors. Ten Cate's Oral Histology Development, Structure and Function. 6 ed. St.Louis: Mosby; 2003. p. 192-239.
  • 5. Özçobanoğlu G, Durutürk L. Süt Dişlerinde Pulpa ve Dentinin Histolojik Yapısal Özellikleri. Acta Odontologica Turcica. 2013;30(2):99-109.
  • 6. Rai B, Anand S. Secondary Dentin for Age Determination. The Internet Journal of Forensic Science. 2007;2(1):9. (Crossref)
  • 7. Goldberg M, Lasfargues J-J. Pulpo-dentinal Complex Revisited. J Dent. 1995;23(1):15-20. (Crossref)
  • 8. Smith AJ, Cassidy N, Perry H, Begue-Kirn C, Ruch JV, Lesot H. Reactionary Dentinogenesis. The International journal of developmental biology. 1995;39(1):273-80.
  • 9. Pinchi V, Pradella F, Buti J, Baldinotti C, Focardi M, Norelli GA. A New Age Estimation Procedure Based on the 3D CBCT Study of the Pulp Cavity and Hard Tissues of the Teeth for Forensic purposes: A Pilot Study. J Forensic Leg Med. 2015;36:150-7. (Crossref)
  • 10. Linde A, Goldberg M. Dentinogenesis. Crit Rev Oral Biol Med. 1993;4(5):679-728. (Crossref)
  • 11. Çelik EU, Yıldız G, Katırcı G. Sklerotik Dentine Bağlanma. EÜ Dişhek Fak Derg. 2009;30:61-74.
  • 12. Luukko K, Kettunen P, I F, Berggreen E. Structure and Functions of the Dentin-Pulp Complex. In: Hargreaves KM, Cohen S, editors. Cohen's Pathways of the Pulp. 10 ed. St. Louis: Mosby Elsevier; 2012. p. 452-503. (Crossref)
  • 13. Venskutonis T, Plotino G, Juodzbalys G, Mickevičienė L. The importance of cone-beam computed tomography in the management of endodontic problems: a review of the literature. J Endod. 2014;40(12):1895-901. (Crossref)
  • 14. Azim AA, Azim KA, Deutsch AS, Huang GT-J. Acquisition of Anatomic Parameters Concerning Molar Pulp Chamber Landmarks Using Cone-beam Computed Tomography. J Endod. 2014;40(9):1298-302. (Crossref)
  • 15. Ge Z, Yang P, Li G, Zhang J, Ma X. Age Estimation Based on Pulp Cavity/Chamber Volume of 13 Types of Tooth from Cone Beam Computed Tomography Images. Int J Legal Med. 2016;130:1159-67. (Crossref)
  • 16. Porto LVMG, da Silva Neto JC, dos Anjos Pontual A, Catunda RQ. Evaluation of Volumetric Changes of Teeth in a Brazilian Population by Using Cone Beam Computed Tomography. J Forensic Leg Med. 2015;36:4-9. (Crossref)
  • 17. Bodrumlu E, Cicek E, Dundar C. Age and Sex-related Differences of Pulp Chamber Size in Mandibular Second Molars. Indian J Dent Res. 2013;24(6):742. (Crossref)
  • 18. Chandler NP, Pitt Ford TR, Monteith BD. Coronal Pulp Size in Molars: A Study of Bitewing Radiographs. Int Endod J. 2003;36(11):757-63. (Crossref)
  • 19. Laçin N, Aytuğar E, Veli İ. Cone-beam computed tomography evaluation of bifid mandibular canal. Int Dent Res 2018;8(2):78- 83. (Crossref)
  • 20. Aktuna Belgin C, Adiguzel O, Bud M, Colak M, Akkus Z. Mandibular Buccal Bone Thickness In Southeastern Anatolian People: A Cone-Beam Computed Tomography Study. Int Dent Res 2017;7:6-12. (Crossref)
  • 21. Venkatesh S, Ajmera S, Ganeshkar SV. Volumetric Pulp Changes After Orthodontic Treatment Determined by Cone-beam Computed Tomography. J Endod. 2014;40(11):1758-63. (Crossref)
  • 22. Jagannathan N, Neelakantan P, Thiruvengadam C, Ramani P, Premkumar P, Natesan A, et al. Age Estimation in an Indian Population Using Pulp/tooth Volume Ratio of Mandibular Canines Obtained from Cone Beam Computed Tomography. J Forensic Odontostomatol. 2011;29(1):1-6.
  • 23. Laçin N, Tatar B, Veli İ, Adıgüzel A. Evaluation of medial lingual foramen with cone-beam computed tomography in a Turkish adult population. Int Dent Res 2018;8(3):139-43. (Crossref)
  • 24. Şahin FÜ, Topuz Ö. Diş Hekimliği Araştırmalarında Mikrobilgisayarlı Tomografi Uygulamaları. Acta Odontologica Turcica. 2014;31(2):114. (Crossref)
  • 25. Agematsu H, Someda H, Hashimoto M, Matsunaga S, Abe S, Kim H, et al. Three-dimensional Observation of Decrease in Pulp Cavity Volume Using Micro-CT: Age-related Change. The Bulletin of Tokyo Dental College. 2010;51(1):1-6. (Crossref)
  • 26. Iwaka Y. Three-dimensional Observation of the Pulp Cavity of Mandibular First Molars by Micro-CT. J Oral Biosci. 2006;48(2):94-102. (Crossref)
  • 27. Oi T, Saka H, Ide Y. Three‐dimensional Observation of Pulp Cavities in the Maxillary First Premolar Tooth Using Micro‐CT. Int Endod J. 2004;37(1):46-51. (Crossref)
  • 28. Dragan OC, Farcaşanu AŞ, Câmpian RS, Turcu RVF. Human Tooth and Root Canal Morphology Reconstruction Using Magnetic Resonance Imaging. Clujul Medical. 2016;89(1):137. (Crossref)
  • 29. Falakaloglu S, Veis A. Determining the size of the mental foramen: A cone-beam computed tomography study. Int Dent Res 2017;7:20-25. (Crossref)
  • 30. Cangul S, Adiguzel O. Cone-Beam Three-Dimensional Dental Volumetric Tomography in Dental Practice. Int Dent Res 2017;7:62-70. (Crossref)
  • 31. Sharawy WW, Ahmed HMA. Endodontic management of a three rooted mandibular third molar with a dilacerated distal root and close approximation to the inferior alveolar canal: A case report. Int Dent Res 2017;7:42-45. (Crossref)
  • 32. Laçin N, Tatar B, Veli İ, Aytuğar E. Mandibuler Retromolar Kanal ve Foramenin Konik Işınlı Bilgisayarlı Tomografi ile Değerlendirilmesi. Journal of Harran University Medical Faculty 2019;16(1):139-142. (Crossref)
  • 33. Laçin N, Aytuğar E, Veli İ. Cone Beam Computed Tomography evaluation of bifid mandibular condyle in a Turkish population. Yeditepe J Dent. 2019; 15(2): 209-212. (Crossref)
  • 34. Adıgüzel Ö, Kaya S, Yiğit Özer S, Değer Y, Göncü Başaran E, Yavuz İ. Three-dimensional Finite Element Analysis of Endodontically Treated Tooth Restored with Carbon and Titanium Posts. Int Dent Res 2011;2:55-59. (Crossref)
  • 35. Elias E, Liao J, Jara H, Watanabe M, Nadgir R, Sakai Y, et al. Quantitative MRI Analysis of Craniofacial Bone Marrow in Patients with Sickle Cell Disease. American Journal of Neuroradiology. 2013;34(3):622-7. (Crossref)
  • 36. Morris VC, Murray MP, DeLancey JO, Ashton‐Miller JA. A Comparison of the Effect of Age on Levator Ani and Obturator Internus Muscle Cross‐sectional Areas and Volumes in Nulliparous Women. Neurourol Urodyn. 2012;31(4):481-6. (Crossref)
  • 37. Irimia A, Chambers MC, Alger JR, Filippou M, Prastawa MW, Wang B, et al. Comparison of Acute and Chronic Traumatic Brain Injury Using Semi-automatic Multimodal Segmentation of MR Volumes. J Neurotrauma. 2011;28(11):2287-306. (Crossref)
  • 38. Xu X, Chen X, Zhang J, Zheng Y, Sun G, Yu X, et al. Comparison of the Tada Formula With Software Slicer Precise and Low-Cost Method for Volume Assessment of Intracerebral Hematoma. Stroke. 2014;45(11):3433-5. (Crossref)
  • 39. Nardelli P, Khan KA, Corvò A, Moore N, Murphy MJ, Twomey M, et al. Optimizing Parameters of an Open-Source Airway Segmentation Algorithm Using Different CT Images. Biomedical engineering online. 2015;14(1):1. (Crossref)
  • 40. Rytlewski JA, Geuss LR, Anyaeji CI, Lewis EW, Suggs LJ. Threedimensional Image Quantification as a New Morphometry Method for Tissue Engineering. Tissue Engineering Part C: Methods. 2012;18(7):507-16. (Crossref)
  • 41. Frisardi G, Chessa G, Barone S, Paoli A, Razionale A, Frisardi F. Integration of 3D Anatomical Data Obtained by CT Imaging and 3D Optical Scanning for Computer Aided Implant Surgery. BMC Med Imaging. 2011;11(1):1-7. (Crossref)
  • 42. Marković A, Mišić T, Calvo‐Guirado JL, Delgado‐Ruíz RA, Janjić B, Abboud M. Two‐Center Prospective, Randomized, Clinical, and Radiographic Study Comparing Osteotome Sinus Floor Elevation with or without Bone Graft and Simultaneous Implant Placement. Clin Implant Dent Relat Res. 2015:1-9. (Crossref)
  • 43. Smith TM, Olejniczak AJ, Tafforeau P, Reid DJ, Grine FE, Hublin J. Molar Crown Thickness, Volume, and Development in South African Middle Stone Age Humans. South African Journal of Science. 2006;102(11/12):513.
  • 44. Shaw L, Jones A. Morphological Considerations of the Dental Pulp Chamber from Radiographs of Molar and Premolar Teeth. J Dent. 1984;12(2):139-45. (Crossref)
  • 45. Khojastepour L, Rahimizadeh N, Khayat A. Morphologic Measurements of Anatomic Landmarks in Pulp Chambers of Human First Molars: a Study of Bitewing Radiographs. Iranian endodontic journal. 2008;2(4):147-51.
  • 46. Tsatsoulis IN, Filippatos CG, Floratos SG, Kontakiotis EG. Estimation of Radiographic Angles and Distances in Coronal Part of Mandibular Molars: A Study of Panoramic Radiographs Using EMAGO Software. European journal of dentistry. 2014;8(1):90. (Crossref)
  • 47. Zaher JF, Fawzy IA, Habib SR, Ali MM. Age Estimation from Pulp/tooth Area Ratio in Maxillary Incisors Among Egyptians Using Dental Radiographic Images. J Forensic Leg Med. 2011;18(2):62-5. (Crossref)
  • 48. Hietala E-L, Larmas M, Salo T. Localization of Estrogen- Receptor-Related Antigen in Human Odontoblasts. J Dent Res. 1998;77(6):1384-7. (Crossref)
  • 49. Jukić S, Prpić-Mehičić G, Talan-Hranilovć J, Miletić I, Šegović S, Anić I. Estrogen Receptors in Human Pulp Tissue. Oral Surgery, Oral Medicine, Oral Pathology, Oral Radiology, and Endodontology. 2003;95(3):340-4. (Crossref)
  • 50. Fanibunda K. A Method of Measuring the Volume of Human Dental Pulp Cavities. Int Endod J. 1986;19(4):194-7. (Crossref)
APA AÇIKLAR KAVAS A, TÜMEN E (2019). Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. , 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
Chicago AÇIKLAR KAVAS Anıl,TÜMEN EMİN CANER Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. (2019): 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
MLA AÇIKLAR KAVAS Anıl,TÜMEN EMİN CANER Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. , 2019, ss.30 - 40. 10.5577/intdentres.2019.vol9.no1.5
AMA AÇIKLAR KAVAS A,TÜMEN E Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. . 2019; 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
Vancouver AÇIKLAR KAVAS A,TÜMEN E Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. . 2019; 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
IEEE AÇIKLAR KAVAS A,TÜMEN E "Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender." , ss.30 - 40, 2019. 10.5577/intdentres.2019.vol9.no1.5
ISNAD AÇIKLAR KAVAS, Anıl - TÜMEN, EMİN CANER. "Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender". (2019), 30-40. https://doi.org/10.5577/intdentres.2019.vol9.no1.5
APA AÇIKLAR KAVAS A, TÜMEN E (2019). Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. International Dental Research, 9(1), 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
Chicago AÇIKLAR KAVAS Anıl,TÜMEN EMİN CANER Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. International Dental Research 9, no.1 (2019): 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
MLA AÇIKLAR KAVAS Anıl,TÜMEN EMİN CANER Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. International Dental Research, vol.9, no.1, 2019, ss.30 - 40. 10.5577/intdentres.2019.vol9.no1.5
AMA AÇIKLAR KAVAS A,TÜMEN E Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. International Dental Research. 2019; 9(1): 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
Vancouver AÇIKLAR KAVAS A,TÜMEN E Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender. International Dental Research. 2019; 9(1): 30 - 40. 10.5577/intdentres.2019.vol9.no1.5
IEEE AÇIKLAR KAVAS A,TÜMEN E "Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender." International Dental Research, 9, ss.30 - 40, 2019. 10.5577/intdentres.2019.vol9.no1.5
ISNAD AÇIKLAR KAVAS, Anıl - TÜMEN, EMİN CANER. "Volumetric pulp chambers measurements in mandibular and maxillary permanent first molar using cone-beam computed tomography by age and gender". International Dental Research 9/1 (2019), 30-40. https://doi.org/10.5577/intdentres.2019.vol9.no1.5