Integrated 3D bioprinting-based geometry-control strategy for fabricating corneal substitutes

The shortage of donor corneas is a severe global issue, and hence the development of corneal alternatives is imperative and urgent. Although attempts to produce artificial cornea substitutes by tissue engineering have made some positive progress, many problems remain that hamper their clinical application worldwide. For example, the curvature of tissue-engineered cornea substitutes cannot be designed to fit the bulbus oculi of patients. To overcome these limitations, in this paper, we present a novel integrated three-dimensional (3D) bioprinting-based cornea substitute fabrication strategy to realize design, customized fabrication, and evaluation of multi-layer hollow structures with complicated surfaces. The key rationale for this method is to combine digital light processing (DLP) and extrusion bioprinting into an integrated 3D cornea bioprinting system. A designable and personalized corneal substitute was designed based on mathematical modelling and a computer tomography scan of a natural cornea. The printed corneal substitute was evaluated based on biomechanical analysis, weight, structural integrity, and fit. The results revealed that the fabrication of high water content and highly transparent curved films with geometric features designed according to the natural human cornea can be achieved using a rapid, simple, and low-cost manufacturing process with a high repetition rate and quality. This study demonstrated the feasibility of customized design, analysis, and fabrication of a corneal substitute. The programmability of this method opens up the possibility of producing substitutes for other cornea-like shell structures with different scale and geometry features, such as the glomerulus, atrium, and oophoron.

[1]  Bin Zhang,et al.  High-resolution 3D Bioprinting System for Fabricating Cell-laden Hydrogel Scaffolds with High Cellular Activities , 2017 .

[2]  Bo Chen,et al.  Ex vivo construction of an artificial ocular surface by combination of corneal limbal epithelial cells and a compressed collagen scaffold containing keratocytes. , 2010, Tissue engineering. Part A.

[3]  Isabelle Brunette,et al.  Stable corneal regeneration four years after implantation of a cell-free recombinant human collagen scaffold. , 2014, Biomaterials.

[4]  Miguel Alaminos,et al.  Construction of a complete rabbit cornea substitute using a fibrin-agarose scaffold. , 2006, Investigative ophthalmology & visual science.

[5]  Ali Khademhosseini,et al.  A perspective on 3D bioprinting in tissue regeneration , 2018, Bio-design and manufacturing.

[6]  Bin Zhang,et al.  3D bioprinting for artificial cornea: Challenges and perspectives. , 2019, Medical engineering & physics.

[7]  Dong-Woo Cho,et al.  Characterization of cornea-specific bioink: high transparency, improved in vivo safety , 2019, Journal of tissue engineering.

[8]  Xia Li,et al.  Multi-length scale bioprinting towards simulating microenvironmental cues , 2018, Bio-Design and Manufacturing.

[9]  Kyunga Na,et al.  Effect of solution viscosity on retardation of cell sedimentation in DLP 3D printing of gelatin methacrylate/silk fibroin bioink , 2017 .

[10]  David L Kaplan,et al.  Silk film biomaterials for cornea tissue engineering. , 2009, Biomaterials.

[11]  K. Meek,et al.  Corneal structure and transparency , 2015, Progress in Retinal and Eye Research.

[12]  Gilles Thuret,et al.  Global Survey of Corneal Transplantation and Eye Banking. , 2016, JAMA ophthalmology.

[13]  R. D. Watkins,et al.  THE OPTICAL SYSTEM OF THE EYE , 1970 .

[14]  Peter Szurman,et al.  Decellularization of porcine corneas and repopulation with human corneal cells for tissue‐engineered xenografts , 2012, Acta ophthalmologica.

[15]  Warren S. Grundfest,et al.  THz and mm-Wave Sensing of Corneal Tissue Water Content: Electromagnetic Modeling and Analysis , 2015, IEEE Transactions on Terahertz Science and Technology.

[16]  Bing-Hong Wang,et al.  Effects of corneal thickness distribution and apex position on postoperative refractive status after full-bed deep anterior lamellar keratoplasty , 2018, Journal of Zhejiang University-SCIENCE B.

[17]  Y. S. Zhang,et al.  Three-dimensional bioprinting of gelatin methacryloyl (GelMA) , 2018, Bio-Design and Manufacturing.

[18]  A. Khademhosseini,et al.  Cell-laden microengineered pullulan methacrylate hydrogels promote cell proliferation and 3D cluster formation. , 2011, Soft matter.

[19]  P. Kiely,et al.  The Mean Shape of the Human Cornea , 1982 .

[20]  Steven E. Wilson,et al.  Cellular and extracellular matrix modulation of corneal stromal opacity. , 2014, Experimental eye research.

[21]  J. Mehta,et al.  Corneal bioprinting utilizing collagen-based bioinks and primary human keratocytes. , 2019, Journal of biomedical materials research. Part A.

[22]  David L Kaplan,et al.  Human corneal limbal epithelial cell response to varying silk film geometric topography in vitro. , 2012, Acta biomaterialia.

[23]  Che J. Connon,et al.  3D bioprinting of a corneal stroma equivalent , 2018, Experimental eye research.

[24]  W A Douthwaite,et al.  Mathematical models of the general corneal surface , 1993, Ophthalmic & physiological optics : the journal of the British College of Ophthalmic Opticians.

[25]  Seiichi Funamoto,et al.  In vivo evaluation of a novel scaffold for artificial corneas prepared by using ultrahigh hydrostatic pressure to decellularize porcine corneas , 2009, Molecular vision.

[26]  Jodhbir S. Mehta,et al.  Plastic Compressed Collagen as a Novel Carrier for Expanded Human Corneal Endothelial Cells for Transplantation , 2012, PloS one.