Stress Distribution in Cortical Bone around the Basal Implant – A Finite Element Analysis

Roy, Anip Kumar; Dixit, Nivedita; Punde, Prashant; Sinha, Koshika Tondon; Jalaluddin, Mohammad; Kumar, Ashish

doi:10.4103/jpbs.jpbs_679_20

Cited by 1 publication

(1 citation statement)

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“…61 Bone strength is directly related to bone density 62 as bone material density (BMD) 63 is used to determine the risk of fracture of bone and, indirectly, the stress shielding effect 33 in the bone. Considering the geometrical conditions of the basal dental implants 18,19 compressive load of 200 N 33 applied on the top surface of the implant, and maximum von Mises stress are observed at the implant neck, 64 followed by the shaft of the implant which is similar to the previous study done on the dental implant. 19 Von Mises strain analysis (Figure 7) is performed for the bone-implant assembly for normal, hard, and soft bone conditions.…”

Section: Resultssupporting

confidence: 82%

Design of patient specific basal dental implant using Finite Element method and Artificial Neural Network technique

Choudhury

Rana

Chakraborty

et al. 2022

Proc Inst Mech Eng H

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The bone conditions of mandibular bone vary from patient to patient, and as a result, a patient-specific dental implant needs to be designed. The basal dental implant is implanted in the cortical region of the bone since the top surface of the bone narrows down because of aging. Taguchi designs of experiments technique are used in which 25 optimum solid models of basal dental implants are modeled with variable geometrical parameters, viz. thread length, diameter, and pitch. In the solid models the implants are placed in the cortical part of the 3D models of cadaveric mandibles, that are prepared from CT data using image processing software. Patient-specific bone conditions are varied according to the strong, weak, and normal basal bone. A compressive force of 200 N is applied on the top surface of these implants and using finite element analysis software, the microstrain on the peri-implant bone ranges from 1000 to 4000 depending on the various bone conditions. According to the finite element data, it can be concluded that weak bone microstrain is comparatively high compared with normal and strong bone conditions. A surrogate artificial neural network model is prepared from the finite element analysis data. Surrogate model assisted genetic algorithm is used to find the optimum patient-specific basal dental implant for a better osseointegration-friendly mechanical environment.

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