Publications in Scientific Journals:

M. Tromayer, A. Dobos, P. Gruber, A. Ajami, R. Dedic, A. Ovsianikov, R. Liska:
"A biocompatible diazosulfonate initiator for direct encapsulation of human stem cells via two-photon polymerization";
Polymer Chemistry, 9 (2018), 22; 3108 - 3117.

English abstract:
Direct cell encapsulation is a powerful tool for fabrication of biomimetic 3D cell culture models in vitro.
This method allows more precise recapitulation of the natural environment and physiological functions of
cells compared to classical 2D cultures. In contrast to seeding cells on prefabricated scaffolds, cell encapsulation
offers benefits regarding high initial cell loading, uniformity of cell distribution and more defined
cell-matrix contact. Two-photon polymerization (2PP) based 3D printing enables the precise engineering
of cell-containing hydrogel constructs as tissue models. Two-photon initiators (2PIs) specifically developed
for this purpose still exhibit considerable cyto- and phototoxicity, impairing the viability of encapsulated
cells. This work reports the development of the first cleavable diazosulfonate 2PI DAS, largely overcoming
these limitations. The material was characterized by standard spectroscopic methods, white light
continuum two-photon absorption cross-section measurements, and its photosensitization of cytotoxic
singlet oxygen was compared to the well-established 2PI P2CK. When DAS is used at double concentration
to compensate for the lower two-photon cross section, its performance in 2PP-printing of hydrogels
is similar to P2CK based on structuring threshold and structure swelling measurements. PrestoBlue
metabolic assay showed vastly improved cytocompatibility of DAS in 2D. Cell survival in 3D direct encapsulation
via 2PP was up to five times higher versus P2CK, further demonstrating the excellent biocompatibility
of DAS and its potential as superior material for laser-based biofabrication.

Direct cell encapsulation, fabrication of biomimetic 3D cell culture models in vitro, high initial cell loading, uniformity of cell distribution and more defined cell-matrix contact, 3D printing

"Official" electronic version of the publication (accessed through its Digital Object Identifier - DOI)

Electronic version of the publication:

Created from the Publication Database of the Vienna University of Technology.