Investigating wall shear stress and the static pressure in bone scaffolds: a study of porosity and fluid flow dynamics.

In bone tissue engineering, scaffolds are crucial as they provide a suitable structure for cell proliferation. Transporting Dulbecco's Modified Eagle Medium (DMEM) to the cells and regulating the scaffold's biocompatibility are both controlled by the dynamics of the fluid passing through the scaffold pores. Scaffold design selection and modeling are thus important in tissue engineering to achieve successful bone regeneration.

Evaluating the Feasibility of Short Dental Implants as Alternatives to Long Dental Implants in Mandibular Bone: A Finite Element Study.

This study uses finite element analysis to investigate the potential application of shorter dental implants as a substitute for longer implants in the lower jaw (mandible). FEA allows the evaluation of the stress patterns around the implant-bone interface, a critical factor for successful osseointegration. Ten models were generated, encompassing five long (L1-L5) and five short implant models (S1-S5) with variations in diameter and length.

Evaluate the effect of bone density variation on stress distribution at the bone-implant interface using numerical analysis.

The current study aims to comprehend how different bone densities affect stress distribution at the bone-implant interface. This will help understand the behaviour and help predict success rates of the implant planted in different bone densities. The process of implantation involves the removal of bone from a small portion of the jawbone to replace either a lost tooth or an infected one and an implant is inserted in the cavity made as a result.

A mathematical approach to estimate micro-displacement of a dental implant using electromagnetic Frequency Response Analysis.

The aim of this paper is to formulate a mathematical model of dental prosthetic using single degree of freedom (SDOF) to assess the micro-displacement under electromagnetic excitation. Using Finite Element Analysis (FEA) and values from literature, stiffness and damping values of the mathematical model were estimated. For ensuring the successful implantation of dental implant system, monitoring of primary stability in terms of micro-displacement is crucial.

Strain based in vitro analysis of dental implant using artificial bone model and validation by numerical technique.

Background/purpose: Dental implant fails due to mechanical failure of the implant contribute to about 10-15 % of implant failures. It is necessary to prevent the design failure of the implant since it leads to bone loss which further leads to complications in reimplantation. This makes it important to test the design of a dental implant using FEM and in vitro testing before its application.

Influence of surface coatings on the stress distribution by varying friction contact at implant-bone interface using finite element analysis.

The present work aims to evaluate the effect of various surface coatings of titanium dental implants by varying the friction coefficient (µ) at the interface between the dental implant and jawbone using finite element analysis (FEA) methods and to provide a comparative analysis between the various surface coatings and implant designs. An accurate model of the dental implant prosthetics consisting of the hard (cortical) and the soft (cancellous) bone, with the various titanium dental implant designs was modelled using a 3D CAD software, and the FE mesh model was generated using HyperMesh 13.0.