3D Bioprinting of Graphene Oxide-Incorporated Cell-laden Bone Mimicking Scaffolds for Promoting Scaffold Fidelity, Osteogenic Differentiation and Mineralization

Bioprinting is a promising technique for facilitating the fabrication of engineered bone tissues for patient-specific defect repair and for developing in vitro tissue/organ models for ex vivo tests. However, polymer-based ink materials often result in insufficient mechanical strength, low scaffold fidelity and loss of osteogenesis induction because of the intrinsic swelling/shrinking and bioinert properties of most polymeric hydrogels. In this work, we developed a novel human mesenchymal stem cell (hMSC)-laden graphene oxide (GO)/alginate/gelatin composite bioink to form 3D bone mimicking scaffolds. Our results showed that the GO composite bioinks with higher GO concentrations improved the bioprintability, scaffold fidelity, compressive modulus and cell viability. The higher GO concentration increased the cell body size and DNA content. The 1GO group had the highest osteogenic differentiation of hMSC with the upregulation of osteogenic-related gene expression at day 42. To mimic critical-sized calvarial bone defects in mice, 3D cell-laden GO defect scaffolds with complex geometries were successfully bioprinted. 1GO maintained the best scaffold fidelity and had the highest mineral volume after culturing in the bioreactor for 42 days. Finally, the 1GO bioink has been demonstrated great potential for 3D bioprinting in applications of bone model and bone tissue engineering.

[1]  R. Müller,et al.  Optimization of Mechanical Stiffness and Cell Density of 3D Bioprinted Cell-laden Scaffolds Improves Extracellular Matrix Mineralization and Cellular Organization for Bone Tissue Engineering. , 2020, Acta biomaterialia.

[2]  Jae Young Lee,et al.  Graphene oxide/alginate composites as novel bioinks for three-dimensional mesenchymal stem cell printing and bone regeneration applications. , 2019, Nanoscale.

[3]  Jianhua Zhang,et al.  Alginate dependent changes of physical properties in 3D bioprinted cell-laden porous scaffolds affect cell viability and cell morphology , 2019, Biomedical materials.

[4]  W. Świȩszkowski,et al.  3D bioprinted hydrogel model incorporating β-tricalcium phosphate for calcified cartilage tissue engineering , 2019, Biofabrication.

[5]  Po‐Yen Chen,et al.  Alginate-graphene oxide hydrogels with enhanced ionic tunability and chemomechanical stability for light-directed 3D printing , 2019, Carbon.

[6]  Ø. Arlov,et al.  Exploitation of Cationic Silica Nanoparticles for Bioprinting of Large-Scale Constructs with High Printing Fidelity. , 2018, ACS applied materials & interfaces.

[7]  A. Infante,et al.  Osteogenesis and aging: lessons from mesenchymal stem cells , 2018, Stem Cell Research & Therapy.

[8]  Akhilesh K Gaharwar,et al.  Nanoengineered Ionic-Covalent Entanglement (NICE) Bioinks for 3D Bioprinting. , 2018, ACS applied materials & interfaces.

[9]  C. Verfaillie Faculty of 1000 evaluation for Controlling shear stress in 3D bioprinting is a key factor to balance printing resolution and stem cell integrity. , 2018 .

[10]  Ruihua Ding,et al.  Graphene-based nanomaterials for drug and/or gene delivery, bioimaging, and tissue engineering. , 2017, Drug discovery today.

[11]  S. Hofmann,et al.  Flow velocity-driven differentiation of human mesenchymal stromal cells in silk fibroin scaffolds: A combined experimental and computational approach , 2017, PloS one.

[12]  Wei Zhu,et al.  3D bioprinted graphene oxide-incorporated matrix for promoting chondrogenic differentiation of human bone marrow mesenchymal stem cells , 2017 .

[13]  S. Scaglione,et al.  Enhanced mechanical performances and bioactivity of cell laden-graphene oxide/alginate hydrogels open new scenario for articular tissue engineering applications , 2017 .

[14]  Liliang Ouyang,et al.  A Generalizable Strategy for the 3D Bioprinting of Hydrogels from Nonviscous Photo‐crosslinkable Inks , 2017, Advanced materials.

[15]  Eneko Axpe,et al.  Applications of Alginate-Based Bioinks in 3D Bioprinting , 2016, International journal of molecular sciences.

[16]  S. Hofmann,et al.  The influence of curvature on three-dimensional mineralized matrix formation under static and perfused conditions: an in vitro bioreactor model , 2016, Journal of The Royal Society Interface.

[17]  Dong-Guk Shin,et al.  High-Throughput, Multi-Image Cryohistology of Mineralized Tissues. , 2016, Journal of visualized experiments : JoVE.

[18]  E. K. Toh,et al.  Osteogenic differentiation of preosteoblasts on a hemostatic gelatin sponge , 2016, Scientific Reports.

[19]  D. Kelly,et al.  3D Bioprinting of Developmentally Inspired Templates for Whole Bone Organ Engineering , 2016, Advanced healthcare materials.

[20]  Jesper Gantelius,et al.  3D Bioprinting of Tissue/Organ Models. , 2016, Angewandte Chemie.

[21]  James J. Yoo,et al.  A 3D bioprinting system to produce human-scale tissue constructs with structural integrity , 2016, Nature Biotechnology.

[22]  T. Scheibel,et al.  Strategies and Molecular Design Criteria for 3D Printable Hydrogels. , 2016, Chemical reviews.

[23]  Horst Fischer,et al.  Controlling Shear Stress in 3D Bioprinting is a Key Factor to Balance Printing Resolution and Stem Cell Integrity , 2016, Advanced healthcare materials.

[24]  Zhengfang Yi,et al.  A Bifunctional Biomaterial with Photothermal Effect for Tumor Therapy and Bone Regeneration , 2016 .

[25]  S. Agarwal,et al.  Removal of hazardous dyes-BR 12 and methyl orange using graphene oxide as an adsorbent from aqueous phase , 2016 .

[26]  A. Khademhosseini,et al.  Hydrogels 2.0: improved properties with nanomaterial composites for biomedical applications , 2015, Biomedical materials.

[27]  S. Hsu,et al.  3D bioprinting of neural stem cell-laden thermoresponsive biodegradable polyurethane hydrogel and potential in central nervous system repair. , 2015, Biomaterials.

[28]  Wei Sun,et al.  The influence of printing parameters on cell survival rate and printability in microextrusion-based 3D cell printing technology , 2015, Biofabrication.

[29]  Chengtie Wu,et al.  Graphene-oxide-modified β-tricalcium phosphate bioceramics stimulate in vitro and in vivo osteogenesis , 2015 .

[30]  Suck Won Hong,et al.  Reduced graphene oxide-coated hydroxyapatite composites stimulate spontaneous osteogenic differentiation of human mesenchymal stem cells. , 2015, Nanoscale.

[31]  Sajini Vadukumpully,et al.  Graphene oxide nanoflakes incorporated gelatin–hydroxyapatite scaffolds enhance osteogenic differentiation of human mesenchymal stem cells , 2015, Nanotechnology.

[32]  B. Hong,et al.  Covalent conjugation of mechanically stiff graphene oxide flakes to three-dimensional collagen scaffolds for osteogenic differentiation of human mesenchymal stem cells , 2015 .

[33]  S. Hofmann,et al.  Effect of fetal bovine serum on mineralization in silk fibroin scaffolds. , 2015, Acta biomaterialia.

[34]  Jing Yu,et al.  Supramolecular hybrid hydrogel based on host-guest interaction and its application in drug delivery. , 2014, ACS Applied Materials and Interfaces.

[35]  T. Hyeon,et al.  Dual Roles of Graphene Oxide in Chondrogenic Differentiation of Adult Stem Cells: Cell‐Adhesion Substrate and Growth Factor‐Delivery Carrier , 2014 .

[36]  Meik Neufurth,et al.  Engineering a morphogenetically active hydrogel for bioprinting of bioartificial tissue derived from human osteoblast-like SaOS-2 cells. , 2014, Biomaterials.

[37]  A. Simchi,et al.  Flexible bactericidal graphene oxide–chitosan layers for stem cell proliferation , 2014 .

[38]  Mikaël M. Martino,et al.  Growth Factors Engineered for Super-Affinity to the Extracellular Matrix Enhance Tissue Healing , 2014, Science.

[39]  S. Senafi,et al.  Differentiation Capacity of Mouse Dental Pulp Stem Cells into Osteoblasts and Osteoclasts , 2014, Cell journal.

[40]  Ralph Müller,et al.  Tunable hydrogel composite with two-step processing in combination with innovative hardware upgrade for cell-based three-dimensional bioprinting. , 2014, Acta biomaterialia.

[41]  Vinayak Sant,et al.  Graphene-based nanomaterials for drug delivery and tissue engineering. , 2014, Journal of controlled release : official journal of the Controlled Release Society.

[42]  A. Khademhosseini,et al.  Cell‐laden Microengineered and Mechanically Tunable Hybrid Hydrogels of Gelatin and Graphene Oxide , 2013, Advanced materials.

[43]  W. Duan,et al.  Role of surface charge and oxidative stress in cytotoxicity and genotoxicity of graphene oxide towards human lung fibroblast cells , 2013, Journal of applied toxicology : JAT.

[44]  Jie Yin,et al.  Mechanically strong graphene oxide/sodium alginate/polyacrylamide nanocomposite hydrogel with improved dye adsorption capacity , 2013 .

[45]  B. Duan,et al.  3D bioprinting of heterogeneous aortic valve conduits with alginate/gelatin hydrogels. , 2013, Journal of biomedical materials research. Part A.

[46]  Seungmi Ryu,et al.  Culture of neural cells and stem cells on graphene , 2013, Tissue Engineering and Regenerative Medicine.

[47]  B. Hong,et al.  Biomedical applications of graphene and graphene oxide. , 2013, Accounts of chemical research.

[48]  Sook Hee Ku,et al.  Myoblast differentiation on graphene oxide. , 2013, Biomaterials.

[49]  Mei-Chin Chen,et al.  Electrically conductive nanofibers with highly oriented structures and their potential application in skeletal muscle tissue engineering. , 2013, Acta biomaterialia.

[50]  Yongxiang Luo,et al.  Hierarchical mesoporous bioactive glass/alginate composite scaffolds fabricated by three-dimensional plotting for bone tissue engineering , 2012, Biofabrication.

[51]  Omid Akhavan,et al.  Size-dependent genotoxicity of graphene nanoplatelets in human stem cells. , 2012, Biomaterials.

[52]  Yan Peng Liu,et al.  Fluorinated Graphene for Promoting Neuro‐Induction of Stem Cells , 2012, Advanced materials.

[53]  Wei Wang,et al.  Alginate/graphene oxide fibers with enhanced mechanical strength prepared by wet spinning , 2012 .

[54]  H. Sakata,et al.  Enhancement of the transport and dielectric properties of graphite oxide nanoplatelets‐polyvinyl alcohol composite showing low percolation threshold , 2012 .

[55]  C. Shao,et al.  Simultaneous Reduction and Surface Functionalization of Graphene Oxide for Hydroxyapatite Mineralization , 2012 .

[56]  Moon Gyu Sung,et al.  Enhanced Differentiation of Human Neural Stem Cells into Neurons on Graphene , 2011, Advanced materials.

[57]  S. Sampath,et al.  Graphene and graphene oxide as effective adsorbents toward anionic and cationic dyes. , 2011, Journal of colloid and interface science.

[58]  Chwee Teck Lim,et al.  Origin of enhanced stem cell growth and differentiation on graphene and graphene oxide. , 2011, ACS nano.

[59]  Y. Morsi,et al.  Parametric analysis of shape changes of alginate beads , 2011 .

[60]  Sook Hee Ku,et al.  Graphene–Biomineral Hybrid Materials , 2011, Advanced materials.

[61]  G. Pastorin,et al.  Graphene for controlled and accelerated osteogenic differentiation of human mesenchymal stem cells. , 2011, ACS nano.

[62]  C. Fan,et al.  Protein corona-mediated mitigation of cytotoxicity of graphene oxide. , 2011, ACS nano.

[63]  J. Nam,et al.  Fibronectin-carbon-nanotube hybrid nanostructures for controlled cell growth. , 2011, Small.

[64]  G. Wallace,et al.  Mechanically Strong, Electrically Conductive, and Biocompatible Graphene Paper , 2008 .

[65]  Peter X Ma,et al.  Maintaining dimensions and mechanical properties of ionically crosslinked alginate hydrogel scaffolds in vitro. , 2008, Journal of biomedical materials research. Part A.

[66]  David L. Kaplan,et al.  Non-Invasive Time-Lapsed Monitoring and Quantification of Engineered Bone-Like Tissue , 2007, Annals of Biomedical Engineering.

[67]  Martin Schuler,et al.  Systematic study of osteoblast and fibroblast response to roughness by means of surface-morphology gradients. , 2007, Biomaterials.

[68]  Ralph Müller,et al.  Control of in vitro tissue-engineered bone-like structures using human mesenchymal stem cells and porous silk scaffolds. , 2007, Biomaterials.

[69]  Ibrahim T. Ozbolat,et al.  Current advances and future perspectives in extrusion-based bioprinting. , 2016, Biomaterials.

[70]  D. Mooney,et al.  Alginate: properties and biomedical applications. , 2012, Progress in polymer science.

[71]  Cindy Liu high throughput , 2009 .

[72]  Timothy A. Miller,et al.  The effect of biomimetic apatite structure on osteoblast viability, proliferation, and gene expression. , 2005, Biomaterials.

[73]  Y. Kuboki,et al.  Osteoblast-related gene expression of bone marrow cells during the osteoblastic differentiation induced by type I collagen. , 2001, Journal of biochemistry.

[74]  G. Skjåk-Bræk,et al.  Alginate as immobilization matrix for cells. , 1990, Trends in biotechnology.

[75]  V C Mow,et al.  Variations in the intrinsic mechanical properties of human articular cartilage with age, degeneration, and water content. , 1982, The Journal of bone and joint surgery. American volume.