Study of gelatin as an effective energy absorbing layer for laser bioprinting

Laser-induced forward transfer printing, also commonly known as laser printing, has been widely implemented for three-dimensional bioprinting due to its unique orifice-free nature during printing. However, the printing quality has the potential to be further improved for various laser bioprinting ap...

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Bibliographic Details
Published in:Biofabrication 2017-06, Vol.9 (2), p.024103-024103
Main Authors: Xiong, Ruitong, Zhang, Zhengyi, Chai, Wenxuan, Chrisey, Douglas B, Huang, Yong
Format: Article
Language:English
Subjects:
Animals
Bioprinting - instrumentation
Bioprinting - methods
Cell Survival - physiology
cell viability
DNA Damage
energy absorbing layer
Equipment Design
gelatin
Gelatin - chemistry
laser printing
Lasers
Mice
NIH 3T3 Cells
Printing, Three-Dimensional
three-dimensional bioprinting
Tissue Engineering - instrumentation
Tissue Engineering - methods
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Summary:Laser-induced forward transfer printing, also commonly known as laser printing, has been widely implemented for three-dimensional bioprinting due to its unique orifice-free nature during printing. However, the printing quality has the potential to be further improved for various laser bioprinting applications. The objectives of this study are to investigate the feasibility of using gelatin as an energy absorbing layer (EAL) material for laser bioprinting and its effects on the quality of printed constructs, bioink printability, and post-printing cell viability and process-induced DNA damage. The gelatin EAL is applied between the quartz support and the coating of build material, which is to be printed. Printing quality can be improved by EAL-assisted laser printing when using various alginate solutions (1%, 2%, and 4%) and cell-laden bioinks (2% alginate and 5 × 106 cells ml−1 in cell culture medium). The required laser fluence is also reduced due to a higher absorption coefficient of gelatin gel, in particular when to achieve the best printing type/quality. The post-printing cell viability is improved by ∼10% and DNA double-strand breaks are reduced by ∼50%. For all the build materials investigated, the gelatin EAL helps reduce the droplet size and average jet velocity.
ISSN:1758-5090
1758-5090
DOI:10.1088/1758-5090/aa74f2