Image-based biomimetic modeling and its application in computer-aided tissue engineering

“…This requirement can be achieved by controlling the porosity of the structure, by providing appropriate interconnectivity inside the structure, and by selecting appropriate biocompatible materials; (2) mechanical requirement – the designed scaffold must provide structural support at the site of replacement while the tissue regenerates to occupy the space defined by the scaffold structure. Scaffold structures need to be defined to possess the required mechanical stiffness and strength of the replaced structure; and (3) anatomical requirement – it must be of an appropriate geometric size that fits in at the site of replacement [46,47].…”

“…A CATE‐based approach for biomimetic modelling and design of load‐bearing tissue scaffolds and replacement has been introduced [46–48]. This approach starts with the acquisition of non‐invasive image and the image processing of appropriate tissue region of interest, followed by a 3D reconstruction of anatomical structure using enabling image‐reconstructive and reverse‐engineering techniques, CAD of scaffold unit cells to represent various tissue anatomical and morphological features, characterization of the structural heterogeneity and mechanical properties for both tissue and designed unit cell through either analytical, numerical or quantitative CT methods in order to select candidate unit cells for final scaffold, and a final design of scaffold with specified internal architecture and anatomic compatible external geometry.…”

Computer‐aided tissue engineering: overview, scope and challenges

“…This requirement can be achieved by controlling the porosity of the structure, by providing appropriate interconnectivity inside the structure, and by selecting appropriate biocompatible materials; (2) mechanical requirement – the designed scaffold must provide structural support at the site of replacement while the tissue regenerates to occupy the space defined by the scaffold structure. Scaffold structures need to be defined to possess the required mechanical stiffness and strength of the replaced structure; and (3) anatomical requirement – it must be of an appropriate geometric size that fits in at the site of replacement [46,47].…”

“…A CATE‐based approach for biomimetic modelling and design of load‐bearing tissue scaffolds and replacement has been introduced [46–48]. This approach starts with the acquisition of non‐invasive image and the image processing of appropriate tissue region of interest, followed by a 3D reconstruction of anatomical structure using enabling image‐reconstructive and reverse‐engineering techniques, CAD of scaffold unit cells to represent various tissue anatomical and morphological features, characterization of the structural heterogeneity and mechanical properties for both tissue and designed unit cell through either analytical, numerical or quantitative CT methods in order to select candidate unit cells for final scaffold, and a final design of scaffold with specified internal architecture and anatomic compatible external geometry.…”

Computer‐aided tissue engineering: overview, scope and challenges

“…A computer-aided tissue engineering (CATE) approach [6,26,27] for modeling, design and fabrication of tissue scaffolds has been utilized in this study. The CATE approach begins with the acquisition of noninvasive image and the image processing of appropriate tissue region of interest, followed by a 3D reconstruction of anatomical structure using enabling imaging reconstructive and reverse engineering techniques (MIMICS [28] and Geomagic [29]).…”

Computer-aided characterization for effective mechanical properties of porous tissue scaffolds

Computer-Aided Process Planning for the Layered Fabrication of Porous Scaffold Matrices