3D Printing of a Double Network Hydrogel with a Compression Strength and Elastic Modulus Greater than those of Cartilage.

This article demonstrates a two-step method to 3D print double network hydrogels at room temperature with a low-cost ($300) 3D printer. A first network precursor solution was made 3D printable via extrusion from a nozzle by adding a layered silicate to make it shear-thinning. After printing and UV-curing, objects were soaked in a second network precursor solution and UV-cured again to create interpenetrating networks of poly(2-acrylamido-2-methylpropanesulfonate) and polyacrylamide. By varying the ratio of polyacrylamide to cross-linker, the trade-off between stiffness and maximum elongation of the gel can be tuned to yield a compression strength and elastic modulus of 61.9 and 0.44 MPa, respectively, values that are greater than those reported for bovine cartilage. The maximum compressive (93.5 MPa) and tensile (1.4 MPa) strengths of the gel are twice that of previous 3D printed gels, and the gel does not deform after it is soaked in water. By 3D printing a synthetic meniscus from an X-ray computed tomography image of an anatomical model, we demonstrate the potential to customize hydrogel implants based on 3D images of a patient's anatomy.

[1]  Albert C. Chen,et al.  Depth‐dependent confined compression modulus of full‐thickness bovine articular cartilage , 1997, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

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

[3]  Nupura S. Bhise,et al.  Direct-write bioprinting of cell-laden methacrylated gelatin hydrogels , 2014, Biofabrication.

[4]  J. Lewis,et al.  3D Bioprinting of Vascularized, Heterogeneous Cell‐Laden Tissue Constructs , 2014, Advanced materials.

[5]  K. Dehaven Decision-making factors in the treatment of meniscus lesions. , 1990, Clinical orthopaedics and related research.

[6]  H J Helminen,et al.  Comparison of the equilibrium response of articular cartilage in unconfined compression, confined compression and indentation. , 2002, Journal of biomechanics.

[7]  Qiuming Wang,et al.  A Robust, One‐Pot Synthesis of Highly Mechanical and Recoverable Double Network Hydrogels Using Thermoreversible Sol‐Gel Polysaccharide , 2013, Advanced materials.

[8]  Joon Hyung Park,et al.  Three-dimensional printing of complex biological structures by freeform reversible embedding of suspended hydrogels , 2015, Science Advances.

[9]  Y. Osada,et al.  Biomechanical properties of high-toughness double network hydrogels. , 2005, Biomaterials.

[10]  Shannon E Bakarich,et al.  Extrusion printing of ionic-covalent entanglement hydrogels with high toughness. , 2013, Journal of materials chemistry. B.

[11]  T. Wright,et al.  Evaluation of a porous polyurethane scaffold in a partial meniscal defect ovine model. , 2010, Arthroscopy : the journal of arthroscopic & related surgery : official publication of the Arthroscopy Association of North America and the International Arthroscopy Association.

[12]  Geoffrey M Spinks,et al.  Three-dimensional printing fiber reinforced hydrogel composites. , 2014, ACS applied materials & interfaces.

[13]  Sailing He,et al.  Rapid Fabrication of Complex 3D Extracellular Microenvironments by Dynamic Optical Projection Stereolithography , 2012, Advanced materials.

[14]  T. Kurokawa,et al.  A novel double-network hydrogel induces spontaneous articular cartilage regeneration in vivo in a large osteochondral defect. , 2009, Macromolecular bioscience.

[15]  I. McDermott Meniscal tears, repairs and replacement: their relevance to osteoarthritis of the knee , 2011, British Journal of Sports Medicine.

[16]  Shiren Wang,et al.  3D printing of an extremely tough hydrogel , 2015 .

[17]  Hon Fai Chan,et al.  3D Printing of Highly Stretchable and Tough Hydrogels into Complex, Cellularized Structures , 2015, Advanced materials.

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

[19]  Jian Ping Gong,et al.  Why are double network hydrogels so tough , 2010 .

[20]  Koichi Masuda,et al.  Tensile mechanical properties of bovine articular cartilage: Variations with growth and relationships to collagen network components , 2003, Journal of orthopaedic research : official publication of the Orthopaedic Research Society.

[21]  Jennifer L. West,et al.  Three‐Dimensional Biochemical and Biomechanical Patterning of Hydrogels for Guiding Cell Behavior , 2006 .

[22]  J. Steadman,et al.  Meniscal regeneration with copolymeric collagen scaffolds , 1992, The American journal of sports medicine.

[23]  Geoffrey D Abrams,et al.  Trends in Meniscus Repair and Meniscectomy in the United States, 2005-2011 , 2013, The American journal of sports medicine.

[24]  T. Kurokawa,et al.  Double‐Network Hydrogels with Extremely High Mechanical Strength , 2003 .

[25]  Stuart R. Stock,et al.  Hyperelastic “bone”: A highly versatile, growth factor–free, osteoregenerative, scalable, and surgically friendly biomaterial , 2016, Science Translational Medicine.

[26]  Robert F. Shepherd,et al.  Direct‐Write Assembly of 3D Hydrogel Scaffolds for Guided Cell Growth , 2009 .

[27]  Xuanhe Zhao,et al.  Multi-scale multi-mechanism design of tough hydrogels: building dissipation into stretchy networks. , 2014, Soft matter.

[28]  Pieter Buma,et al.  Synthetic meniscus replacement: a review , 2013, International Orthopaedics.

[29]  P. Buma,et al.  Effect on Tissue Differentiation and Articular Cartilage Degradation of a Polymer Meniscus Implant , 2008, The American journal of sports medicine.

[30]  M R Wisnom,et al.  The compressive strength of articular cartilage , 1998, Proceedings of the Institution of Mechanical Engineers. Part H, Journal of engineering in medicine.

[31]  M. Carmont,et al.  Meniscal scaffolds: early experience and review of the literature. , 2012, The Knee.