Litcius/Paper detail

Extending Single Cell Bioprinting from Femtosecond to Picosecond Laser Pulse Durations

Jun Zhang, Yasemin Geiger, F. Sotier, Sasa Djordjevic, Denitsa Docheva, Stefanie Sudhop, Hauke Clausen‐Schaumann, H. Huber

2021Micromachines13 citationsDOIOpen Access PDF

Abstract

Femtosecond laser pulses have been successfully used for film-free single-cell bioprinting, enabling precise and efficient selection and positioning of individual mammalian cells from a complex cell mixture (based on morphology or fluorescence) onto a 2D target substrate or a 3D pre-processed scaffold. In order to evaluate the effects of higher pulse durations on the bioprinting process, we investigated cavitation bubble and jet dynamics in the femto- and picosecond regime. By increasing the laser pulse duration from 600 fs to 14.1 ps, less energy is deposited in the hydrogel for the cavitation bubble expansion, resulting in less kinetic energy for the jet propagation with a slower jet velocity. Under appropriate conditions, single cells can be reliably transferred with a cell survival rate after transfer above 95% through the entire pulse duration range. More cost efficient and compact laser sources with pulse durations in the picosecond range could be used for film-free bioprinting and single-cell transfer.

Topics & Concepts

FemtosecondPicosecondMaterials scienceLaserUltrashort pulsePulse (music)OpticsPulse durationOptoelectronicsJet (fluid)BubblePhysicsDetectorMechanicsThermodynamicsLaser Material Processing Techniques3D Printing in Biomedical ResearchCellular Mechanics and Interactions