Biomechanical behavior of diamond lattice scaffolds obtained by two different design approaches with similar porosity; a numerical investigation with FEM and CFD analysis

Abstract: Scaffolds provide a suitable environment for the bone tissue to maintain its self-healing ability and help new bone-cell formation by creating structures with similar mechanical properties to the surrounding tissue. In the modeling of the scaffolds, an optimum environment is tried to be provided by changing the geometrical properties of the cell architecture such as porosity, pore size, and specific surface area. For this purpose, different design approaches have been used in studies to change these properties… Show more

“…258 Furthermore, recent studies have revealed the effect of various designing methods of diamond lattice on penetrability, successful cell culture, proper elastic modulus, etc. 262 Following this investigation, Timercan et al prepared lattice systems of gyroid and diamond that were mechanically exible and penetrable to liquids, thus encouraging osseointegration and decreasing complexity risks, for instance, a lack of xation, device migration, and subsidence in current intervertebral fusion devices. These structures were manufactured using Ti-6Al-4V and laser powder bed fusion.…”

Effects of mechanical properties of carbon-based nanocomposites on scaffolds for tissue engineering applications: a comprehensive review

“…258 Furthermore, recent studies have revealed the effect of various designing methods of diamond lattice on penetrability, successful cell culture, proper elastic modulus, etc. 262 Following this investigation, Timercan et al prepared lattice systems of gyroid and diamond that were mechanically exible and penetrable to liquids, thus encouraging osseointegration and decreasing complexity risks, for instance, a lack of xation, device migration, and subsidence in current intervertebral fusion devices. These structures were manufactured using Ti-6Al-4V and laser powder bed fusion.…”

Effects of mechanical properties of carbon-based nanocomposites on scaffolds for tissue engineering applications: a comprehensive review

“…Li et al [ 45 ] demonstrated that the elastic modulus is 25.9 GPa when the pore size is 0.65 mm, and 14.5 GPa when the pore size is 0.5 mm, which is comparable to the elastic modulus of adult cortical bone. Karaman et al [ 46 ] conducted compression tests on different design models with 50%, 60%, 70%, 80%, and 90% porosities and found that the structural strength decreases with increasing porosity. The mechanical properties of porous materials, like their elastic modulus and yield stress, are linked to their porosity.…”

Polyether-Ether-Ketone (PEEK) and Its 3D-Printed Quantitate Assessment in Cranial Reconstruction

The effects of sheet and network solid structures of similar TPMS scaffold architectures on permeability, wall shear stress, and velocity: A CFD analysis