Endodontics: Additional studies on the distribution of stresses during vertical compaction of gutta-percha in the root canal

Objective This study was designed to investigate the effect of certain pathological alterations of the dental structures (diminishing bone support, internal resorption, root perforation, periapical lesion) on stress distribution during root canal filling procedures by the warm vertical compaction technique.Design The computer stress analyses were done for a maxillary canine tooth model which was based on dimensions recovered from a human cadaveric maxilla scanned by CT.Methods The finite element method was used to calculate the stresses generated during root canal filling procedures by warm vertical compaction technique. Patterns of stress distribution associated with various alterations in dental structures were investigated. For this purpose 60 cases were simulated. The hypothetical force of 10 N is taken as a unit representation. For other magnitudes of applied force, the corresponding stresses would be scaled directly because the calculations were made for linear materials.Results and Conclusion It is found that, when diminishing bone support and internal resorption are concurrently simulated, a marked increase in stress magnitudes occur (maximum von Mises stress 5.37 N/mm2). However, these values still remain much below the most frequently reported tensile strength of dentine (50–100 N/mm2). If dentist's handwork is transformed into equivalent edge tractions on gutta-percha, then stresses in dentine, even when they are corrected for 3-kg applied force, appear to remain below fracture strengths of this material.This result leads us to conclude that when warm vertical compaction technique is skilfully performed and inadvertent undue force is not applied, a premature root fracture in a large rooted maxillary anterior tooth with straight root canal anatomy is not likely to occur, even for the unfavourable conditions simulated in our model. This result, like all results derived from modelling applications, is of course contingent upon agreement between the way in which the clinical operations are performed and the way in which they are mirrored for computer representation. We believe that the approach described here avoids the spurious stresses that have been reported in similar investigations.

[1]  W. G. Matthews,et al.  Tensile Properties of Mineralized and Demineralized Human and Bovine Dentin , 1994, Journal of dental research.

[2]  P. A. Onnink,et al.  An in vitro comparison of incomplete root fractures associated with three obturation techniques. , 1994, Journal of endodontics.

[3]  C J Burstone,et al.  Moment to force ratios and the center of rotation. , 1988, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[4]  P. Gulkan,et al.  Stress analysis during root canal filling by vertical and lateral condensation procedures: a three-dimensional finite element model of a maxillary canine tooth , 1998, British Dental Journal.

[5]  J. Nicholls,et al.  Further investigation of spreader loads required to cause vertical root fracture during lateral condensation. , 1987, Journal of endodontics.

[6]  P. Gülkan,et al.  A critical reevaluation of stresses generated during vertical and lateral condensation of gutta-percha in the root canal. , 1994, Endodontics & dental traumatology.

[7]  R. Walton,et al.  Vertical root fracture and root distortion: effect of spreader design. , 1989, Journal of endodontics.

[8]  K R Williams,et al.  Orthodontic tooth movement analysed by the Finite Element Method. , 1984, Biomaterials.

[9]  C J Burstone,et al.  Patterns of initial tooth displacements associated with various root lengths and alveolar bone heights. , 1991, American journal of orthodontics and dentofacial orthopedics : official publication of the American Association of Orthodontists, its constituent societies, and the American Board of Orthodontics.

[10]  D. Gimlin,et al.  A comparison of stresses produced during lateral and vertical condensation using engineering models. , 1986, Journal of endodontics.

[11]  W J Pertot,et al.  Young's modulus of warm and cold gutta-percha. , 1996, Endodontics & dental traumatology.

[12]  C. Yeh,et al.  Fatigue root fracture: a spontaneous root fracture in non-endodontically treated teeth , 1997, British Dental Journal.

[13]  H. Gerstein,et al.  Diagnosis and possible causes of vertical root fractures. , 1980, Oral surgery, oral medicine, and oral pathology.

[14]  V K Goel,et al.  A three-dimensional finite-element stress analysis of an endodontically prepared maxillary central incisor. , 1995, Journal of endodontics.

[15]  H. Martin,et al.  Photoelastic stress comparison of warm (Endotec) versus cold lateral condensation techniques. , 1990, Oral surgery, oral medicine, and oral pathology.

[16]  S D Yaman,et al.  Analysis of stress distribution in a vertically condensed maxillary central incisor root canal. , 1995, Journal of endodontics.

[17]  G. B. Pelleu,et al.  Vertical root fractures in curved roots under simulated clinical conditions. , 1989, Journal of endodontics.

[18]  R. G. Craig,et al.  Dental Materials: Properties and Manipulation , 1979 .

[19]  R. Walton,et al.  Vertical root fracture and dentin deformation in curved roots: the influence of spreader design. , 1990, Endodontics & dental traumatology.

[20]  J. Nicholls,et al.  An in vitro study of spreader loads required to cause vertical root fracture during lateral condensation. , 1983, Journal of endodontics.

[21]  J. Palamara,et al.  Load and strain during lateral condensation and vertical root fracture. , 1999, Journal of endodontics.

[22]  P H Jacobsen,et al.  Elastic modulus of the periodontal ligament. , 1997, Biomaterials.