Ali Salehi - School of Mechanical Engineering, University of Tehran, Tehran, Iran
Alireza Daneshmehr - School of Mechanical Engineering, University of Tehran, Tehran, Iran
Kiyarash Aminfar - School of Mechanical Engineering, University of Tehran, Tehran, Iran

Cellular structures are broadly used because of their exclusive properties in tissue engineering. This research proposes a new method, both in design and manufacturing, to engineer their mechanical properties considering gradient material and geometrical features and evaluate the possibility of using created structures as bone implants. Schwarz-primitive surface has been utilized to design cellular structures with different porosities and unit cell sizes. A total of ۱۸ cellular structures were designed and fabricated using the SLS ۳D printer with a new unconventional approach in adjusting the settings of the machine, and their mechanical properties were extracted. The structures' internal properties were evaluated using the FESEM. Comparing the mechanical compressive test results showed that adjustments in material and geometry improved mechanical properties (such as the compressive moduli, compressive strength, and yield strength). For instance, in ۳ mm samples, the elastic modulus in material gradient and geometrical gradient structures is ۲۰% and ۷۳ % higher than the minimum values of the uniform structure. FESEM imaging revealed that adjusting the absorbed energy by powders (controlled by laser characteristics) leads to the formation of natural voids with diameters in the range of ۶ to ۱۴۴ μm for the gradient structures. Evaluation of the designed structures showed that ۶ of them (۴ uniform porosity and ۲ geometrically gradient) have mechanical behavior of the desired tissue. The research outcomes can assist in optimizing manufactured parts by SLS ۳D printers with internal and external controlled properties to obtain more desirable mechanical characteristics, especially for tissue engineering applications.

Additive Manufacturing, Cellular structures, Gradient structures, Selective Laser Sintering, Tissue Engineering, Triply periodic minimal surface