Design of vascular tree for organ bioprinting

Abstract Organ printing is a variant of the biomedical application of additive manufacturing (rapid prototyping) technology or layer-by-layer additive biofabrication of 3D tissue and organ constructs using self-assembled tissue spheroids as building blocks. Bioengineering of perfusable intraorgan branched vascular trees incorporated into 3D tissue constructs is essential for the survival of bioprinted thick 3D tissues and organs. In order to design the optimal ‘blueprint’ for digital bioprinting of intraorgan branched vascular trees, the coefficients of tissue retraction associated with post-printing vascular tissue spheroid fusion and remodeling must be determined and incorporated into the original CAD. Using living tissue spheroids assembled into ring-like and tube-like vascular tissue constructs, the coefficient of tissue retraction has been experimentally evaluated. It has been shown that the internal diameter of ring-like and the height of tubular-like tissue constructs are significantly reduced during tissue spheroid fusion. During the tissue fusion process, the individual tissue spheroids also change their shape from ball-like to a conus-like form. A simple formula for the calculation of the necessary number of tissue spheroids for biofabrication of ring-like structures of desirable diameter has been deduced. These data provide sufficient information to design optimal CAD for bioprinted branched vascular trees of different human organs desirable final geometry and size.

[1]  Brendon M. Baker,et al.  Rapid casting of patterned vascular networks for perfusable engineered 3D tissues , 2012, Nature materials.

[2]  Vladimir Mironov,et al.  Towards organ printing: engineering an intra-organ branched vascular tree , 2010, Expert opinion on biological therapy.

[3]  Ricardo Femat,et al.  A model for renal arterial branching based on graph theory. , 2010, Mathematical biosciences.

[4]  Vladimir Mironov,et al.  Organ printing: promises and challenges. , 2008, Regenerative medicine.

[5]  Jess G Snedeker,et al.  A novel concept for scaffold-free vessel tissue engineering: self-assembly of microtissue building blocks. , 2010, Journal of biotechnology.

[6]  Karoly Jakab,et al.  Tissue engineering by self-assembly and bio-printing of living cells , 2010, Biofabrication.

[7]  Alexander Sasov,et al.  Micro-CT of corrosion casts for use in the computer-aided design of microvasculature. , 2009, Tissue engineering. Part C, Methods.

[8]  Hod Lipson,et al.  Fab@Home: the personal desktop fabricator kit , 2007 .

[9]  Vladimir Mironov,et al.  Organ printing: tissue spheroids as building blocks. , 2009, Biomaterials.

[10]  Alexei Sourin,et al.  Function representation in geometric modeling: concepts, implementation and applications , 1995, The Visual Computer.

[11]  Hod Lipson,et al.  Construction and adaptation of an open source rapid prototyping machine for biomedical research purposes—a multinational collaborative development , 2009 .

[12]  Hod Lipson,et al.  Design and analysis of digital materials for physical 3D voxel printing , 2009 .

[13]  V. Mironov,et al.  Designer ‘blueprint’ for vascular trees: morphology evolution of vascular tissue constructs , 2009 .