Three-dimensional bioprinting of complex cell laden alginate hydrogel structures

Different bioprinting techniques have been used to produce cell-laden alginate hydrogel structures, however these approaches have been limited to 2D or simple three-dimension (3D) structures. In this study, a new extrusion based bioprinting technique was developed to produce more complex alginate hydrogel structures. This was achieved by dividing the alginate hydrogel cross-linking process into three stages: primary calcium ion cross-linking for printability of the gel, secondary calcium cross-linking for rigidity of the alginate hydrogel immediately after printing and tertiary barium ion cross-linking for long-term stability of the alginate hydrogel in culture medium. Simple 3D structures including tubes were first printed to ensure the feasibility of the bioprinting technique and then complex 3D structures such as branched vascular structures were successfully printed. The static stiffness of the alginate hydrogel after printing was 20.18 ± 1.62 KPa which was rigid enough to sustain the integrity of the complex 3D alginate hydrogel structure during the printing. The addition of 60 mM barium chloride was found to significantly extend the stability of the cross-linked alginate hydrogel from 3 d to beyond 11 d without compromising the cellular viability. The results based on cell bioprinting suggested that viability of U87-MG cells was 93 ± 0.9% immediately after bioprinting and cell viability maintained above 88% ± 4.3% in the alginate hydrogel over the period of 11 d.

[1]  D. Cho,et al.  Bioprinting of a mechanically enhanced three-dimensional dual cell-laden construct for osteochondral tissue engineering using a multi-head tissue/organ building system , 2012 .

[2]  H. Fischer,et al.  Three-dimensional printing of stem cell-laden hydrogels submerged in a hydrophobic high-density fluid , 2012, Biofabrication.

[3]  Ivan Donati,et al.  Effect of Ca2+, Ba2+, and Sr2+ on alginate microbeads. , 2006, Biomacromolecules.

[4]  Barry Merriman,et al.  U87MG Decoded: The Genomic Sequence of a Cytogenetically Aberrant Human Cancer Cell Line , 2010, PLoS genetics.

[5]  Hod Lipson,et al.  Increased mixing improves hydrogel homogeneity and quality of three-dimensional printed constructs. , 2011, Tissue engineering. Part C, Methods.

[6]  Yu Qian,et al.  Curcumin Enhances the Radiosensitivity of U87 Cells by Inducing DUSP-2 Up-Regulation , 2015, Cellular Physiology and Biochemistry.

[7]  Liliang Ouyang,et al.  Three-dimensional printing of Hela cells for cervical tumor model in vitro , 2014, Biofabrication.

[8]  Dongsheng Liu,et al.  Rapid formation of a supramolecular polypeptide-DNA hydrogel for in situ three-dimensional multilayer bioprinting. , 2015, Angewandte Chemie.

[9]  F. Guillemot,et al.  Controlling laser-induced jet formation for bioprinting mesenchymal stem cells with high viability and high resolution , 2014, Biofabrication.

[10]  Sarit B. Bhaduri,et al.  Drop-on-demand printing of cells and materials for designer tissue constructs , 2007 .

[11]  Xi Chen,et al.  Three-dimensional bioprinting of embryonic stem cells directs highly uniform embryoid body formation , 2015, Biofabrication.

[12]  Yong Huang,et al.  Alginate gelation-induced cell death during laser-assisted cell printing , 2014, Biofabrication.

[13]  Makoto Nakamura,et al.  Development of a three-dimensional bioprinter: construction of cell supporting structures using hydrogel and state-of-the-art inkjet technology. , 2009, Journal of biomechanical engineering.

[14]  S. Hollister Porous scaffold design for tissue engineering , 2005, Nature materials.

[15]  I. Fichtner,et al.  Radiosensitisation of U87MG brain tumours by anti-epidermal growth factor receptor monoclonal antibodies , 2009, British Journal of Cancer.

[16]  Jason A. Spector,et al.  High-Fidelity Tissue Engineering of Patient-Specific Auricles for Reconstruction of Pediatric Microtia and Other Auricular Deformities , 2013, PloS one.

[17]  Shintaroh Iwanaga,et al.  Three-dimensional inkjet biofabrication based on designed images , 2011, Biofabrication.

[18]  G. Prestwich,et al.  Photocrosslinkable hyaluronan-gelatin hydrogels for two-step bioprinting. , 2010, Tissue engineering. Part A.

[19]  L. Koch,et al.  Laser printing of cells into 3D scaffolds , 2010, Biofabrication.

[20]  John R. Tumbleston,et al.  Continuous liquid interface production of 3D objects , 2015, Science.

[21]  Ryan B. Wicker,et al.  Stereolithography of Three-Dimensional Bioactive Poly(Ethylene Glycol) Constructs with Encapsulated Cells , 2006, Annals of Biomedical Engineering.

[22]  V Mironov,et al.  Biofabrication: a 21st century manufacturing paradigm , 2009, Biofabrication.

[23]  T. Boland,et al.  Human microvasculature fabrication using thermal inkjet printing technology. , 2009, Biomaterials.

[24]  Jaesung Park,et al.  Development of a hybrid scaffold with synthetic biomaterials and hydrogel using solid freeform fabrication technology , 2011, Biofabrication.

[25]  Wei Sun,et al.  Three-dimensional in vitro cancer models: a short review , 2014, Biofabrication.

[26]  Alan Faulkner-Jones,et al.  Bioprinting of human pluripotent stem cells and their directed differentiation into hepatocyte-like cells for the generation of mini-livers in 3D , 2015, Biofabrication.

[27]  B N Chichkov,et al.  Adipogenic differentiation of laser-printed 3D tissue grafts consisting of human adipose-derived stem cells , 2011, Biofabrication.

[28]  Wei Sun,et al.  Bioprinting endothelial cells with alginate for 3D tissue constructs. , 2009, Journal of biomechanical engineering.

[29]  F. Guillemot,et al.  Laser assisted bioprinting of engineered tissue with high cell density and microscale organization. , 2010, Biomaterials.

[30]  A. Ueno,et al.  Cell patterning through inkjet printing of one cell per droplet. , 2012, Biofabrication.

[31]  K H Kang,et al.  Rapid 3D printing of anatomically accurate and mechanically heterogeneous aortic valve hydrogel scaffolds , 2012, Biofabrication.

[32]  Feng Xu,et al.  Engineering three-dimensional cell mechanical microenvironment with hydrogels , 2012, Biofabrication.

[33]  D. Cho,et al.  3D printing of composite tissue with complex shape applied to ear regeneration , 2014, Biofabrication.

[34]  A. Schambach,et al.  Skin tissue generation by laser cell printing , 2012, Biotechnology and bioengineering.

[35]  Alan Faulkner-Jones,et al.  Development of a valve-based cell printer for the formation of human embryonic stem cell spheroid aggregates , 2013, Biofabrication.

[36]  Jos Malda,et al.  A Printable Photopolymerizable Thermosensitive p(HPMAm‐lactate)‐PEG Hydrogel for Tissue Engineering , 2011 .

[37]  K H Kang,et al.  Quantitative optimization of solid freeform deposition of aqueous hydrogels , 2013, Biofabrication.

[38]  James J. Yoo,et al.  Hybrid printing of mechanically and biologically improved constructs for cartilage tissue engineering applications , 2012, Biofabrication.

[39]  M. Ringnér,et al.  Exosomes reflect the hypoxic status of glioma cells and mediate hypoxia-dependent activation of vascular cells during tumor development , 2013, Proceedings of the National Academy of Sciences.