Finite element analysis (FEA) of stress distribution in platform-switched short dental implants

The distribution of stress on short platform switched dental implants is of interest. Hence, the mandibular posterior molar area was modelled using a three-dimensional finite element method (FEM) with a continuous 1.5 mm cortical bone thickness and an inner cancellous bone core. The implants used in the study were 5 mm long, 4.5 mm wide and 3.5 mm wide at the abutments. 120 N of force was applied in both the vertical and oblique (20° and 35°) directions to create a realistic simulation. ANSYS Workbench was generated for each model. Von Mises stress was assessed in the cortical and cancellous bones at varying depths. Ten noded tetrahedron elements with three degrees of freedom per node were employed to interpret translations on the x, y, and z axes. The stress-based biomechanical behaviour of platform switched short osseo-integrated implants varied across all 5 positions in FEM simulations, based on the depth of implant placement, the direction of applied force, and the shape of the bone. Data shows that opposite forces to the vertical forces caused more damage. Thus, the implantation of subcrestal implants resulted in reduced stress on the cortical and cancellous bone.


Background:
Dental implants are frequently utilised to replace lost teeth [1].Oral implants cannot be successful unless there is sufficient bone volume and density [2].The way that pressures are absorbed by the surrounding bone has a major role in whether a dental implant succeeds or fails [3].Depending on the implant's shape, the contact between it and the bone varies [2, 4].These implants should be placed 1 to 2 mm below the bone crest [2].Radiographic scans performed after a 5-year follow-up revealed that patients using the platform-switching approach had not displayed the resorption pattern.A dental implant is considered short if its length is less than 8 mm [5].Numerous techniques, including strain gauges, photo-elastic models and finite element analysis (FEA), have been employed to examine the connection among loading, implant design, and peri-implant bone remodelling [2].All of the structure's components have their stress and deflection properly computed [6-9].Finite element model (FEM) design provides information on stress and strain in bone and implants structures and facilitates the clear understanding of concepts for clinical applications involving any animals or humans [2].Therefore, it is of interest to evaluate finite element analysis of stress distribution in platformswitched short dental implants.

Materials and Methods:
This investigation was carried out at the department of oral implantology.The mandibular posterior molar region was modelled using a three-dimensional finite element method (FEM) with a consistently thick 1.5 mm cortical bone and an inner core of cancellous bone.The implants used in the study were 5 mm long, 4.5 mm wide and 3.5 mm wide at the abutments.120 N of force was applied in both the axial and oblique (20° and 35°) directions to create a realistic simulation.Every model was created with Ansys Workbench.Von Mises stress was assessed in both cancellous and cortical bone at varying depths.To interpret translations on the x, y, and z axes, ten noded tetrahedron elements with three degrees of freedom per node were employed.The model was constructed using homogeneous, linearly elastic, and isotropic materials.Table 1 shows elastic features that have been reported in the literature.These investigations use fixed boundary conditions finite element modelling of the mandibular posterior area.The boundary condition is the use of power and control.The node on the muscle attachment where the boundary conditions were restricted was the external oblique line, which ran buccally to the lingual side of the mylohyoid ridge.The FEM assumed that the bone implant interface had an optimal fit between the implant and bone.Each model represents the loaded and osseointegrated state.

Results:
Cortical bone displayed higher stress in an oblique direction in the von Mises stress assessment for 0.5 mm subcrestal implants (35c).When cancellous bone is implanted subcrestally, lowstress values are seen.The lowest stress was recorded by implants positioned 1.5 mm subcrestally at 0 c.This was followed by an increase in stress oblique forces at 35 c.Similar to cortical bone, cancelous bone shows maximal stress in an oblique direction (35c) for subcrestal implants.The cortical bone displayed the largest stress concentration in an oblique orientation at 2 mm subcrestally, regardless of the force's angulation.At the equicrestal location, the cancellous bone had the greatest stress and the cortical bone experienced the least stress, regardless of the angulation of the load.Conversely, at the 1.5 mm subcrestal position in the subcreasatal position, the cancellous bone has the least stress, while the cortical bone experiences the most stress (Table 2).

Conclusion
Data shows that the mandibular posterior area is a suitable location for implant placement.Further, the cortical bone is under the maximum stress at the 0.5 mm subcrestal position for the cortical bone and the 1.5 mm subcrestal position for the cancellous bone, respectively.

Table 1 :
Mechanical characteristics of titanium and bone utilised in this study

Table 2 :
[10]mean von Mises stress generated in the cortical and cancellous bone under a vertical and oblique load of 120 N Tapered implants raised the stress on the crestal bone when loaded as shown by Rasouli-Ghahroudi et al.[12].Platform switching reduced the amount of stress that was transferred to the crestal bone in both tapered and parallel wall implants[12].Further, the tapered implant shape actually raises the stress on the crestal bone[13].In terms of the bone, all three models had the cortical bone around the implant's cervical location as the site of the largest von Mises stress[11].Platform-switching implants offer an affordable, straightforward, and dependable biomechanical alternative[10].It should be noted that the use of a single-piece implant to get over the difficulty of implant internal design modelling in two-piece implants is a bottleneck.
Discussion:Crestal bone loss plays a significant role in deciding the implant's long-term prognosis.This can be avoided if the annual vertical bone loss surrounding an implant stays below 0.2 mm and does not surpass 2 mm in the first year.By doing this, the implant's biological breadth will be preserved [9].Successful oral implants require adequate bone volume and density.The arch location is often a good indicator of bone quality [2].Tomar et al.