Abstract
Three-dimensional (3D) bioplotting has been widely used to print hydrogel scaffolds for tissue engineering applications. One issue involved in 3D bioplotting is to achieve the scaffold structure with the desired mechanical properties. To overcome this issue, various numerical methods have been developed to predict the mechanical properties of scaffolds, but limited by the imperfect representation of one key feature of scaffolds fabricated by 3D bioplotting, i.e., the penetration or fusion of strands in one layer into the previous layer. This paper presents our study on the development of a novel numerical model to predict the elastic modulus (one important index of mechanical properties) of 3D bioplotted scaffolds considering the aforementioned strand penetration. For this, the finite element method was used for the model development, while medium-viscosity alginate was selected for scaffold fabrication by the 3D bioplotting technique. The elastic modulus of the bioplotted scaffolds was characterized using mechanical testing and results were compared with those predicted from the developed model, demonstrating a strong congruity between them. Once validated, the developed model was also used to investigate the effect of other geometrical features on the mechanical behavior of bioplotted scaffolds. Our results show that the penetration, pore size, and number of printed layers have significant effects on the elastic modulus of bioplotted scaffolds; and also suggest that the developed model can be used as a powerful tool to modulate the mechanical behavior of bioplotted scaffolds.
Highlights
IntroductionOne aim of tissue engineering is to develop tissue/organ substitutes or scaffolds, based on the principles of biology and engineering, for the repair or replacement of damaged tissues and organs [1,2]
One aim of tissue engineering is to develop tissue/organ substitutes or scaffolds, based on the principles of biology and engineering, for the repair or replacement of damaged tissues and organs [1,2].For this, scaffolds, typically of a three-dimensional (3D) porous structure made from biomaterials, play an important role in supporting and/or promoting cell growth, tissue regeneration, and transport of nutrients and wastes
A novel finite element model, by taking into account of the penetration of strands in in one layer into the previous layer, was developed to represent and predict the mechanical one layer into the previous layer, was developed to represent and predict the mechanical properties of properties of scaffolds fabricated by the 3D bioplotting technique
Summary
One aim of tissue engineering is to develop tissue/organ substitutes or scaffolds, based on the principles of biology and engineering, for the repair or replacement of damaged tissues and organs [1,2]. Scaffolds, typically of a three-dimensional (3D) porous structure made from biomaterials, play an important role in supporting and/or promoting cell growth, tissue regeneration, and transport of nutrients and wastes. Design and fabrication of scaffolds have proven to be a challenging task [3]. One important issue in the design and fabrication of scaffolds is achieving the desired mechanical properties to match those of tissue at the site of implantation.
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