Abstract
Research in bioprinting is booming due to its potential in addressing several manufacturing challenges in regenerative medicine. However, there are still many hurdles to overcome to guarantee cell survival and good printability. For the 3D extrusion-based bioprinting, cell viability is amongst one of the lowest of all the bioprinting techniques and is strongly influenced by various factors including the shear stress in the print nozzle. The goal of this study is to quantify, by means of in silico modeling, the mechanical environment experienced by the bioink during the printing process. Two ubiquitous nozzle shapes, conical and blunted, were considered, as well as three common hydrogels with material properties spanning from almost Newtonian to highly shear-thinning materials following the power-law behavior: Alginate-Gelatin, Alginate and PF127. Comprehensive in silico testing of all combinations of nozzle geometry variations and hydrogels was achieved by combining a design of experiments approach (DoE) with a computational fluid dynamics (CFD) of the printing process, analyzed through a machine learning approach named Gaussian Process. Available experimental results were used to validate the CFD model and justify the use of shear stress as a surrogate for cell survival in this study. The lower and middle nozzle radius, lower nozzle length and the material properties, alone and combined, were identified as the major influencing factors affecting shear stress, and therefore cell viability, during printing. These results were successfully compared with those of reported experiments testing viability for different nozzle geometry parameters under constant flow rate or constant pressure. The in silico 3D bioprinting platform developed in this study offers the potential to assist and accelerate further development of 3D bioprinting.
Highlights
Bioprinting is a research-intensive field within regenerative medicine combining additive manufacturing technologies and tissue engineering concepts for reproducing functional organs and complex living tissues in the laboratory (Murphy and Atala, 2014; Ji and Guvendiren, 2017; Moroni et al, 2018b; Chen et al, 2021)
We developed an in silico framework to assess and quantify the effect of the nozzle geometry, printing pressure and material properties on the shear stress and related cell viability during extrusion-based bioprinting
To corroborate the use of shear stress as a predictor for cell survival in 3D bioprinting, we simulated a series of experimental studies reporting cell viability results for a range of printing parameters such as pressure, nozzle radius, flow rate, material properties and duration after printing
Summary
Bioprinting is a research-intensive field within regenerative medicine combining additive manufacturing technologies and tissue engineering concepts for reproducing functional organs and complex living tissues in the laboratory (Murphy and Atala, 2014; Ji and Guvendiren, 2017; Moroni et al, 2018b; Chen et al, 2021). There are still many challenges in order to guarantee cell survival and good printability (Bishop et al, 2017; Moroni et al, 2018a; Ong et al, 2018; Sánchez et al, 2020). Extrusion-based bioprinting is one of the most widely used technique in current research, because of it is simplicity and ability to print a broad array of biocompatible materials and to deposit variable and high cell densities at specific locations in the three-dimensional (3D) space (Gillispie et al, 2020). Cell viability is amongst the lowest across all the bioprinting techniques
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