Add to ORKGIntroduction: To date only single in vitro engineered tissues are transferred to clinical approaches due to todays inability to fabricate suitable, artifical vascular systems. Combining inkjet printing with high-resolution multiphoton polymerization (MPP) enables us to generate branched, tubular systems with diameters << 1 mm. New synthetic polymers were tailored to match the needs of the technical building process and the elastic properties of blood vessels. The polymers were biofunctionalized to achieve a close coating with endothelial cells (ECs). Experimental Methods: Based on numerical simulations, branched tubular scaffolds were fabricated by combining inkjet printing and MPP. Precursor polymers, cross linking agent, photo initiators ...
3D bioprinting is currently used for developing oncological research models such as organ-on-chip or...
[[abstract]]The microvascular network is a simple but critical system that is responsible for a rang...
The inability to adequately vascularize tissues in vivo or in vitro currently limits the development...
Free-form fabrication techniques, often referred to as ‘3D printing’, are currently tested with rega...
Clinically, large diameter artery defects (diameter larger than 6 mm) can be substituted by unbiodeg...
In this work, a novel strategy was developed to fabricate prevascularized cell-layer blood vessels i...
Blood vessel reconstruction is still an elusive goal for the development of in vitro models as well ...
Blood vessel reconstruction is still an elusive goal for the development of in vitro models as well ...
In order to fabricate a large-volume bioengineered tissue, building vasculature is the most importan...
Complicated vessels pervade almost all body tissues and influence the pathophysiology of the human b...
This project investigated the technical feasibility of creating an adherent layer of endothelial cel...
Despite the technological advances of the last decades, drug development remains a lengthy and costl...
The microvascular network is a simple but critical system that is responsible for a range of importa...
[[abstract]]Although various research efforts have been made to produce a vascular-like network stru...
To engineer tissues with clinically relevant dimensions by three-dimensional bioprinting, an extende...
3D bioprinting is currently used for developing oncological research models such as organ-on-chip or...
[[abstract]]The microvascular network is a simple but critical system that is responsible for a rang...
The inability to adequately vascularize tissues in vivo or in vitro currently limits the development...
Free-form fabrication techniques, often referred to as ‘3D printing’, are currently tested with rega...
Clinically, large diameter artery defects (diameter larger than 6 mm) can be substituted by unbiodeg...
In this work, a novel strategy was developed to fabricate prevascularized cell-layer blood vessels i...
Blood vessel reconstruction is still an elusive goal for the development of in vitro models as well ...
Blood vessel reconstruction is still an elusive goal for the development of in vitro models as well ...
In order to fabricate a large-volume bioengineered tissue, building vasculature is the most importan...
Complicated vessels pervade almost all body tissues and influence the pathophysiology of the human b...
This project investigated the technical feasibility of creating an adherent layer of endothelial cel...
Despite the technological advances of the last decades, drug development remains a lengthy and costl...
The microvascular network is a simple but critical system that is responsible for a range of importa...
[[abstract]]Although various research efforts have been made to produce a vascular-like network stru...
To engineer tissues with clinically relevant dimensions by three-dimensional bioprinting, an extende...
3D bioprinting is currently used for developing oncological research models such as organ-on-chip or...
[[abstract]]The microvascular network is a simple but critical system that is responsible for a rang...
The inability to adequately vascularize tissues in vivo or in vitro currently limits the development...