摘要
Extrusion-based 3D bioprinting is a direct deposition approach used to create three-dimensional(3D)tissue scaffolds typically comprising hydrogels.Hydrogels are hydrated polymer networks that are chemically or physically cross-linked.Often,3D bioprinting is performed in air,despite the hydrated nature of hydrogels and the potential advantage of using a liquid phase to provide cross-linking and otherwise functionalize the hydrogel.In this work,we print gelatin alginate hydrogels directly into a cross-linking solution of calcium chloride and investigate the influence of nozzle diameter,distance between nozzle and surface,calcium chloride concentration,and extrusion rate on the dimensions of the printed hydrogel.The hydrogel layer height was generally found to increase with increasing extrusion rate and nozzle distance,according to the increased volume extruded and the available space,respectively.In addition,the hydrogel width was generally found to increase with decreasing nozzle distance and cross-linking concentration corresponding to confinement-induced spreading and low crosslinking regimes,respectively.Width/height ratios of^1 were generally achieved when the nozzle diameter and distance were comparable above a certain cross-linking concentration.Using these relationships,biocompatible 3D multilayer structures were successfully printed directly into calcium chloride cross-linking solution.
基金
the Ministry of Higher Education of Saudi Arabia under the King Abdullah Scholarship Program(IR10133)
Enterprise Ireland(CF-2016-0389-P)
the European Union’sHorizon 2020 research and innovation program under Marie Sklodowska-Curie Grant Agreement No.644175
Science Foundation Ireland(13/TIDA/B2701)
This project was co-funded by the European Regional Development Fund(ERDF)under Ireland’s European Structural and Investment Funds Programmes 2014–2020.
