A Novel Plasma-based Bioink Stimulates Cell Proliferation and Differentiation in Bioprinted, Mineralized Constructs.

Extrusion-based bioprinting, also known as 3D bioplotting, is a powerful tool for the fabrication of tissue equivalents with spatially defined cell distribution. Even though considerable progress has been made in recent years, there is still a lack of bioinks which enable a tissue-like cell response and are plottable at the same time with good shape fidelity. Herein, we report on the development of a bioink which includes fresh frozen plasma from full human blood, and thus a donor/patient-specific protein mixture. By blending of the plasma with 3 w/v % alginate and 9 w/v % methylcellulose, a pasty bioink (plasma-alg-mc) was achieved, which could be plotted with high accuracy and furthermore allowed bioplotted mesenchymal stromal cells (MSC) and primary osteoprogenitor cells to spread within the bioink. In a second step, the novel plasma-based bioink was combined with a plottable self-setting calcium phosphate cement (CPC) to fabricate bone-like tissue constructs. The CPC/plasma-alg-mc biphasic constructs revealed open porosity over the entire time of cell culture (35 d), which is crucial for bone tissue engineered grafts. The biphasic structures could be plotted in volumetric and clinically relevant dimensions and complex shapes could be also generated, as demonstrated for a scaphoid bone model. The plasma bioink potentiated that bioplotted MSC were not harmed by the setting process of the CPC. Latest after 7 days, MSC migrated from the hydrogel to the CPC surface, where they proliferated to 20 fold of the initial cell number covering the entire plotted constructs with a dense cell layer. For bioplotted and osteogenically stimulated osteoprogenitor cells, a significantly increased alkaline phosphatase activity was observed in CPC/plasma-alg-mc constructs in comparison to plasma-free controls. In conclusion, the novel plasma-alg-mc bioink is a promising new ink for several forms of bioprinted tissue equivalents and especially gainful for the combination with CPC for enhanced, biofabricated bone-like constructs.

[1]  R. Reis,et al.  Human platelet lysate-based nanocomposite bioink for bioprinting hierarchical fibrillar structures , 2019, Biofabrication.

[2]  Geunhyung Kim,et al.  Collagen/bioceramic-based composite bioink to fabricate a porous 3D hASCs-laden structure for bone tissue regeneration , 2019, Biofabrication.

[3]  Won-Kyo Jung,et al.  Enhanced rheological behaviors of alginate hydrogels with carrageenan for extrusion-based bioprinting. , 2019, Journal of the mechanical behavior of biomedical materials.

[4]  M. Gelinsky,et al.  An improved method to isolate primary human osteocytes from bone , 2019, Biomedizinische Technik. Biomedical engineering.

[5]  Swati Midha,et al.  Advances in three‐dimensional bioprinting of bone: Progress and challenges , 2019, Journal of tissue engineering and regenerative medicine.

[6]  F. O'Brien,et al.  Pore‐forming bioinks to enable spatio‐temporally defined gene delivery in bioprinted tissues , 2019, Journal of controlled release : official journal of the Controlled Release Society.

[7]  J. Fisher,et al.  Bioprinted osteon-like scaffolds enhance in vivo neovascularization , 2019, Biofabrication.

[8]  A. Lode,et al.  3D Plotted Biphasic Bone Scaffolds for Growth Factor Delivery: Biological Characterization In Vitro and In Vivo , 2019, Advanced healthcare materials.

[9]  P. Nurden,et al.  Autologous fibrin scaffolds: When platelet- and plasma-derived biomolecules meet fibrin. , 2019, Biomaterials.

[10]  A. Lode,et al.  Investigating the effect of sterilisation methods on the physical properties and cytocompatibility of methyl cellulose used in combination with alginate for 3D-bioplotting of chondrocytes , 2019, Journal of Materials Science: Materials in Medicine.

[11]  M Gelinsky,et al.  A definition of bioinks and their distinction from biomaterial inks , 2018, Biofabrication.

[12]  A. Villa,et al.  3D Bone Biomimetic Scaffolds for Basic and Translational Studies with Mesenchymal Stem Cells , 2018, International journal of molecular sciences.

[13]  A. Lode,et al.  Bioprinting of mineralized constructs utilizing multichannel plotting of a self-setting calcium phosphate cement and a cell-laden bioink , 2018, Biofabrication.

[14]  A. Lode,et al.  A Methylcellulose Hydrogel as Support for 3D Plotting of Complex Shaped Calcium Phosphate Scaffolds , 2018, Gels.

[15]  Ali Khademhosseini,et al.  Patient‐Specific Bioinks for 3D Bioprinting of Tissue Engineering Scaffolds , 2018, Advanced healthcare materials.

[16]  R. Hudák,et al.  Implantation of a 3D-printed titanium sternum in a patient with a sternal tumor , 2018, World Journal of Surgical Oncology.

[17]  J Malda,et al.  Assessing bioink shape fidelity to aid material development in 3D bioprinting , 2017, Biofabrication.

[18]  Petra J. Kluger,et al.  Bone matrix production in hydroxyapatite-modified hydrogels suitable for bone bioprinting , 2017, Biofabrication.

[19]  Jos Malda,et al.  Double printing of hyaluronic acid/poly(glycidol) hybrid hydrogels with poly(ε-caprolactone) for MSC chondrogenesis , 2017, Biofabrication.

[20]  F. Melchels,et al.  Proposal to assess printability of bioinks for extrusion-based bioprinting and evaluation of rheological properties governing bioprintability , 2017, Biofabrication.

[21]  Thomas Bley,et al.  Green bioprinting: extrusion-based fabrication of plant cell-laden biopolymer hydrogel scaffolds , 2017, Biofabrication.

[22]  Qing Li,et al.  Biofabrication: A Guide to Technology and Terminology. , 2017, Trends in biotechnology.

[23]  R. Aebersold,et al.  The Human Plasma Proteome Draft of 2017: Building on the Human Plasma PeptideAtlas from Mass Spectrometry and Complementary Assays. , 2017, Journal of proteome research.

[24]  Eben Alsberg,et al.  * Three-Dimensional Bioprinting of Polycaprolactone Reinforced Gene Activated Bioinks for Bone Tissue Engineering. , 2017, Tissue engineering. Part A.

[25]  David Kilian,et al.  Three-dimensional bioprinting of volumetric tissues and organs , 2017 .

[26]  T Ahlfeld,et al.  Development of a clay based bioink for 3D cell printing for skeletal application , 2017, Biofabrication.

[27]  B. Nies,et al.  Strontium(II) and mechanical loading additively augment bone formation in calcium phosphate scaffolds , 2017, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[28]  Liang Zhao,et al.  Engineering bone regeneration with novel cell-laden hydrogel microfiber-injectable calcium phosphate scaffold. , 2017, Materials science & engineering. C, Materials for biological applications.

[29]  Anja Lode,et al.  Three‐dimensional plotting of a cell‐laden alginate/methylcellulose blend: towards biofabrication of tissue engineering constructs with clinically relevant dimensions , 2017, Journal of tissue engineering and regenerative medicine.

[30]  S. Catros,et al.  Layer-by-layer bioassembly of cellularized polylactic acid porous membranes for bone tissue engineering , 2017, Journal of Materials Science: Materials in Medicine.

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

[32]  Léa J Pourchet,et al.  Human Skin 3D Bioprinting Using Scaffold‐Free Approach , 2017, Advanced healthcare materials.

[33]  Diego Velasco,et al.  3D bioprinting of functional human skin: production and in vivo analysis , 2016, Biofabrication.

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

[35]  R. Truckenmüller,et al.  Controlling Growth and Osteogenic Differentiation of Osteoblasts on Microgrooved Polystyrene Surfaces , 2016, PloS one.

[36]  Horst Fischer,et al.  Bioprinting Organotypic Hydrogels with Improved Mesenchymal Stem Cell Remodeling and Mineralization Properties for Bone Tissue Engineering , 2016, Advanced healthcare materials.

[37]  J. Sheng,et al.  Three decades of research on angiogenin: a review and perspective. , 2016, Acta biochimica et biophysica Sinica.

[38]  Mark A. Skylar-Scott,et al.  Three-dimensional bioprinting of thick vascularized tissues , 2016, Proceedings of the National Academy of Sciences.

[39]  Pamela Habibovic,et al.  Calcium phosphates in biomedical applications: materials for the future? , 2016 .

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

[41]  D. Kenkel,et al.  Bioprinting Complex Cartilaginous Structures with Clinically Compliant Biomaterials , 2015 .

[42]  Berthold Nies,et al.  3D plotting of growth factor loaded calcium phosphate cement scaffolds. , 2015, Acta biomaterialia.

[43]  A. Sauaia,et al.  Plasma is the physiologic buffer of tissue plasminogen activator-mediated fibrinolysis: rationale for plasma-first resuscitation after life-threatening hemorrhage. , 2015, Journal of the American College of Surgeons.

[44]  Aldo R Boccaccini,et al.  Evaluation of an alginate–gelatine crosslinked hydrogel for bioplotting , 2015, Biofabrication.

[45]  P. Gatenholm,et al.  3D Bioprinting Human Chondrocytes with Nanocellulose-Alginate Bioink for Cartilage Tissue Engineering Applications. , 2015, Biomacromolecules.

[46]  T. Scheibel,et al.  Biofabrication of cell-loaded 3D spider silk constructs. , 2015, Angewandte Chemie.

[47]  M. Gelinsky,et al.  Formation of osteoclasts on calcium phosphate bone cements and polystyrene depends on monocyte isolation conditions. , 2015, Tissue engineering. Part C, Methods.

[48]  J. Malda,et al.  Development and characterisation of a new bioink for additive tissue manufacturing. , 2014, Journal of materials chemistry. B.

[49]  A. Lode,et al.  A novel strontium(II)-modified calcium phosphate bone cement stimulates human-bone-marrow-derived mesenchymal stem cell proliferation and osteogenic differentiation in vitro. , 2013, Acta biomaterialia.

[50]  S. Samavedi,et al.  Calcium phosphate ceramics in bone tissue engineering: a review of properties and their influence on cell behavior. , 2013, Acta biomaterialia.

[51]  Yongxiang Luo,et al.  Well-ordered biphasic calcium phosphate-alginate scaffolds fabricated by multi-channel 3D plotting under mild conditions. , 2013, Journal of materials chemistry. B.

[52]  B. Nies,et al.  Properties of injectable ready-to-use calcium phosphate cement based on water-immiscible liquid. , 2013, Acta biomaterialia.

[53]  Johannes E. Schindelin,et al.  Fiji: an open-source platform for biological-image analysis , 2012, Nature Methods.

[54]  J Malda,et al.  Bioprinting of hybrid tissue constructs with tailorable mechanical properties , 2011, Biofabrication.

[55]  G. Duda,et al.  Toward biomimetic materials in bone regeneration: functional behavior of mesenchymal stem cells on a broad spectrum of extracellular matrix components. , 2010, Journal of biomedical materials research. Part A.

[56]  Sergey V. Dorozhkin,et al.  Calcium Orthophosphates as Bioceramics: State of the Art , 2010, Journal of functional biomaterials.

[57]  Alessandro Sannino,et al.  Biodegradable Cellulose-based Hydrogels: Design and Applications , 2009, Materials.

[58]  Matthias Schieker,et al.  Introducing a single-cell-derived human mesenchymal stem cell line expressing hTERT after lentiviral gene transfer , 2008, Journal of cellular and molecular medicine.

[59]  J. C. Rau,et al.  Serpins in thrombosis, hemostasis and fibrinolysis , 2007, Journal of thrombosis and haemostasis : JTH.

[60]  P. Koolwijk,et al.  Fibrin structure and wound healing , 2006, Journal of thrombosis and haemostasis : JTH.

[61]  G. Lowe,et al.  Plasma fibrinogen , 2004, Annals of clinical biochemistry.

[62]  M. Gelinsky,et al.  Proliferation and differentiation of osteoblasts on Biocement D modified with collagen type I and citric acid. , 2004, Journal of biomedical materials research. Part B, Applied biomaterials.

[63]  A. Lode,et al.  Strontium-modified premixed calcium phosphate cements for the therapy of osteoporotic bone defects. , 2018, Acta biomaterialia.

[64]  Barry J Doyle,et al.  Characterisation of hyaluronic acid methylcellulose hydrogels for 3D bioprinting. , 2018, Journal of the mechanical behavior of biomedical materials.

[65]  Yvonne Förster,et al.  Design and Fabrication of Complex Scaffolds for Bone Defect Healing: Combined 3D Plotting of a Calcium Phosphate Cement and a Growth Factor-Loaded Hydrogel , 2016, Annals of Biomedical Engineering.

[66]  C. Mantzoros,et al.  The role of leptin in regulating bone metabolism. , 2015, Metabolism: clinical and experimental.

[67]  P. Dubruel,et al.  The 3D printing of gelatin methacrylamide cell-laden tissue-engineered constructs with high cell viability. , 2014, Biomaterials.

[68]  Cynthia A. Reinhart-King,et al.  Matrix Stiffness: A Regulator of Cellular Behavior and Tissue Formation , 2012 .

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

[70]  Birgit Glasmacher,et al.  Laser printing of stem cells for biofabrication of scaffold-free autologous grafts. , 2011, Tissue engineering. Part C, Methods.

[71]  P. Salenius A study of the pH and buffer capacity of blood, plasma and red blood cells. , 1957, Scandinavian journal of clinical and laboratory investigation.