Laser assisted cell printing.

Computer assisted biofabrication of fully functional living tissue for regenerative medicine involves generation of complex three-dimensional constructs consisting of living cells and biomaterials. Laser BioPrinting (LaBP) based on laser-induced forward-transfer provides unique possibilities for the deposition of different living cells and biomaterials in a well-defined 3D structure. LaBP can be applied to generate scaffold-free 3D cell systems through a layer-by-layer technique by combining cell solutions with materials that are able to form stable gels. Also, it is used to precisely populate scaffolds with different cells and different cell densities. It was proven that printed cells are not affected by the laser printing procedure and that a differentiation of printed stem cells is not induced. Thus, LaBP is demonstrated as a promising tool for the ex vivo generation of tissue replacements.

Adipogenic differentiation of laser-printed 3D tissue grafts consisting of human adipose-derived stem cells.

Laser-assisted bioprinting (LaBP) allows the realization of computer-generated 3D tissue grafts consisting of cells embedded in a hydrogel environment. In this study, human adipose-derived stem cells (hASCs) were printed in a free-scalable 3D grid pattern by means of LaBP. We demonstrate that neither the proliferation ability nor the differentiation behaviour of the stem cells was affected by the LaBP procedure. Furthermore, the 3D grafts were differentiated down the adipogenic lineage pathway for 10 days. We verify by quantitative assessments of adipogenic markers that the 3D grafts resemble cell lineages present in natural adipose tissue. Additionally, we provide the proof that even pre-differentiated hASCs could be utilized for the generation of 3D tissue grafts. These results indicate that the biofabrication of living grafts resembling their complex native origin is within reach.

Laser printing of cells into 3D scaffolds.

One of the most promising approaches in tissue engineering is the application of 3D scaffolds, which provide cell support and guidance in the initial tissue formation stage. The porosity of the scaffold and internal pore organization influence cell migration and play a major role in its biodegradation dynamics, nutrient diffusion and mechanical stability. In order to control cell migration and cellular interactions within the scaffold, novel technologies capable of producing 3D structures in accordance with predefined design are required. The two-photon polymerization (2PP) technique, used in this report for the fabrication of scaffolds, allows the realization of arbitrary 3D structures with submicron spatial resolution. Highly porous 3D scaffolds, produced by 2PP of acrylated poly(ethylene glycol), are seeded with cells by means of laser-induced forward transfer (LIFT). In this laser printing approach, a propulsive force, resulting from laser-induced shock wave, is used to propel individual cells or cell groups from a donor substrate towards the receiver substrate. We demonstrate that with this technique printing of multiple cell types into 3D scaffolds is possible. Combination of LIFT and 2PP provides a route for the realization of 3D multicellular tissue constructs and artificial ECM engineered on the microscale.