Adjusting the accuracy of PEGDA-GelMA vascular network by dark pigments via digital light processing printing

1. Moreno Madrid, AP, Vrech, SM, Sanchez, MA, et al. Advances in additive manufacturing for bone tissue engineering scaffolds. Mater Sci Eng C 2019; 100: 631–644.
Google Scholar | Crossref | Medline2. Qu, H . Additive manufacturing for bone tissue engineering scaffolds. Mater Today Commun 2020; 24: 101024.
Google Scholar | Crossref3. Gu, J, Zhang, Q, Geng, M, et al. Construction of nanofibrous scaffolds with interconnected perfusable microchannel networks for engineering of vascularized bone tissue. Bioact Mater 2021; 6(10): 3254–3268.
Google Scholar | Crossref | Medline4. Bellan, LM, Singh, SP, Henderson, PW, et al. Fabrication of an artificial 3-dimensional vascular network using sacrificial sugar structures. Soft Matter 2009; 5(7): 1354–1357.
Google Scholar | Crossref5. Zhu, W, Qu, X, Zhu, J, et al. Direct 3D bioprinting of prevascularized tissue constructs with complex microarchitecture. Biomaterials 2017; 124: 106–115.
Google Scholar | Crossref | Medline6. Camasão, DB, Mantovani, D. The mechanical characterization of blood vessels and their substitutes in the continuous quest for physiological-relevant performances. A critical review. Mater Today Bio 2021; 10: 100106.
Google Scholar | Crossref | Medline7. Li, S, Liu, YY, Liu, LJ, et al. A versatile method for fabricating tissue engineering scaffolds with a three-dimensional channel for prevasculature networks. Acs Appl Mater Inter 2016; 8(38): 25096–25103.
Google Scholar | Crossref | Medline8. Qi, J, Li, J, Zheng, S. A mosaic structure multi-level vascular network design for skull tissue engineering. Comput Biol Med 2019; 104: 70–80.
Google Scholar | Crossref | Medline9. Gold, K, Gaharwar, AK, Jain, A. Emerging trends in multiscale modeling of vascular pathophysiology: organ-on-a-chip and 3D printing. Biomaterials 2019; 196: 2–17.
Google Scholar | Crossref | Medline10. Gao, Q, Liu, Z, Lin, Z, et al. 3D bioprinting of vessel-like structures with multilevel fluidic channels. Acs Biomater Sci Eng 2017; 3(3): 399–408.
Google Scholar | Crossref | Medline11. Discher, DE, Janmey, P, Wang, Yl. Tissue cells feel and respond to the stiffness of their substrate. Science 2005; 310(5751): 1139–1143.
Google Scholar | Crossref | Medline | ISI12. Xue, D, Wang, Y, Zhang, J, et al. Projection-based 3D printing of cell patterning scaffolds with multiscale channels. Acs Appl Mater Inter 2018; 10(23): 19428–19435.
Google Scholar | Crossref | Medline13. Miller, JS, Stevens, KR, Yang, MT, et al. Rapid casting of patterned vascular networks for perfusable engineered three-dimensional tissues. Nat Mater 2012; 11(9): 768–774.
Google Scholar | Crossref | Medline | ISI14. Kolesky, DB, Truby, RL, Gladman, AS, et al. 3D bioprinting of vascularized, heterogeneous cell-laden tissue constructs. Adv Mater 2014; 26(19): 3124–3130.
Google Scholar | Crossref | Medline | ISI15. Zhao, X, Irvine, SA, Agrawal, A, et al. 3D patterned substrates for bioartificial blood vessels - The effect of hydrogels on aligned cells on a biomaterial surface. Acta Biomater 2015; 26: 159–168.
Google Scholar | Crossref | Medline16. Liu, Y, Zahedmanesh, H, Lally, C, et al. Compliance properties of a composite electrospun fibre - hydrogel blood vessel scaffold. Mater Lett 2016; 178: 296–299.
Google Scholar | Crossref17. Attalla, R, Ling, C, Selvaganapathy, P. Fabrication and characterization of gels with integrated channels using 3D printing with microfluidic nozzle for tissue engineering applications. Biomed Microdevices 2016; 18(1): 17.
Google Scholar | Crossref | Medline18. Wang, K, Zhu, M, Li, T, et al. Improvement of cell infiltration in electrospun polycaprolactone scaffolds for the construction of vascular grafts. J Biomed Nanotechnol 2014; 10(8): 1588–1598.
Google Scholar | Crossref | Medline19. Norotte, C, Marga, FS, Niklason, LE, et al. Scaffold-free vascular tissue engineering using bioprinting. Biomaterials 2009; 30(30): 5910–5917.
Google Scholar | Crossref | Medline | ISI20. Kesari, P, Xu, T, Boland, T. Layer-by-layer printing of cells and its application to tissue engineering. MRS Online Proc Libr 2004; 845(1): 5–11.
Google Scholar21. Homan, KA, Kolesky, DB, Skylar-Scott, MA, et al. Bioprinting of 3D convoluted renal proximal tubules on perfusable chips. Sci Rep-uk 2016; 6(1): 34845.
Google Scholar | Crossref | Medline22. Kirkpatrick, CJ, Fuchs, S, Unger, RE. Co-culture systems for vascularization — Learning from nature. Adv Drug Deliver Rev 2011; 63(4): 291–299.
Google Scholar | Crossref | Medline23. Wang, Y, Yu, Z, Mei, D, et al. Fabrication of micro-wavy patterned surfaces for enhanced cell culturing. Proced CIRP 2017; 65: 279–283.
Google Scholar | Crossref24. Kankala, RK, Zhu, K, Li, J, et al. Fabrication of arbitrary 3D components in cardiac surgery: from macro-, micro- to nanoscale. Biofabrication 2017; 9(3): 032002.
Google Scholar | Crossref | Medline25. Shin, S, Kwak, H, Hyun, J. Melanin nanoparticle-incorporated silk fibroin hydrogels for the enhancement of printing resolution in 3D-projection stereolithography of poly(ethylene glycol)-tetraacrylate bio-ink. Acs Appl Mater Inter 2018; 10(28): 23573–23582.
Google Scholar | Crossref | Medline26. Liang, R, Gu, Y, Wu, Y, et al. Lithography-based 3D bioprinting and bioinks for bone repair and regeneration. Acs Biomater Sci Eng 2021; 7(3): 806–816.
Google Scholar | Crossref | Medline27. Sun, AX, Lin, H, Beck, AM, et al. Projection stereolithographic fabrication of human adipose stem cell-incorporated biodegradable scaffolds for cartilage tissue engineering. Front Bioeng Biotech 2015; 3: 115.
Google Scholar | Crossref | Medline28. Lin, H, Zhang, D, Alexander, PG, et al. Application of visible light-based projection stereolithography for live cell-scaffold fabrication with designed architecture. Biomaterials 2013; 34(2): 331–339.
Google Scholar | Crossref | Medline | ISI29. Zhang, Q, Weng, S, Hamel, CM, et al. Design for the reduction of volume shrinkage-induced distortion in digital light processing 3D printing. Extreme Mech Lett 2021; 48: 101403.
Google Scholar | Crossref30. Kowsari, K, Zhang, B, Panjwani, S, et al. Photopolymer formulation to minimize feature size, surface roughness, and stair-stepping in digital light processing-based three-dimensional printing. Addit Manuf 2018; 24: 627–638.
Google Scholar31. Tumbleston, JR, Shirvanyants, D, Ermoshkin, N, et al. Continuous liquid interface production of 3D objects. Science 2015; 347(6228): 1349–1352.
Google Scholar | Crossref | Medline32. Li, Y, Mao, Q, Li, X, et al. High-fidelity and high-efficiency additive manufacturing using tunable pre-curing digital light processing. Addit Manuf 2019; 30: 100889.
Google Scholar33. Zissi, S, Bertsch, A, Jézéquel, JY, et al. Stereolithography and microtechniques. Microsyst Tech 1995; 2(1): 97–102.
Google Scholar | Crossref34. Gong, H, Bickham, BP, Woolley, AT, et al. Custom 3D printer and resin for 18 μm × 20 μm microfluidic flow channels. Lab Chip 2017; 17(17): 2899–2909.
Google Scholar | Crossref | Medline35. Gong, H, Beauchamp, M, Perry, S, et al. Optical approach to resin formulation for 3D printed microfluidics. Rsc Adv 2015; 5(129): 106621–106632.
Google Scholar | Crossref | Medline36. Li, Y, Mao, Q, Yin, J, et al. Theoretical prediction and experimental validation of the digital light processing (DLP) working curve for photocurable materials. Addit Manuf 2021; 37: 101716.
Google Scholar37. Gentry, SP, Halloran, JW. Absorption effects in photopolymerized ceramic suspensions. J Eur Ceram Soc 2013; 33(10): 1989–1994.
Google Scholar | Crossref38. Gentry, SP, Halloran, JW. Light scattering in absorbing ceramic suspensions: Effect on the width and depth of photopolymerized features. J Eur Ceram Soc 2015; 35(6): 1895–1904.
Google Scholar | Crossref39. Zhao, Z, Wu, D, Chen, HS, et al. Indentation experiments and simulations of nonuniformly photocrosslinked polymers in 3D printed structures. Addit Manuf 2020; 35: 101420.
Google Scholar40. Karalekas, D, Aggelopoulos, A. Study of shrinkage strains in a stereolithography cured acrylic photopolymer resin. J Mater Process Tech 2003; 136(1): 146–150.
Google Scholar | Crossref41. Chakraborty, S, Gourain, V, Benz, M, et al. Droplet microarrays for cell culture: effect of surface properties and nanoliter culture volume on global transcriptomic landscape. Mater Today Bio 2021; 11: 100112.
Google Scholar | Crossref | Medline42. Kuang, X, Wu, J, Chen, K, et al. Grayscale digital light processing 3D printing for highly functionally graded materials. Sci Adv 2019; 5(5): eaav5790.
Google Scholar | Crossref | Medline43. Zhao, Z, Wu, J, Mu, X, et al. Desolvation induced origami of photocurable polymers by digit light processing. Macromolecular Rapid Commun 2017; 38(13): 1600625.
Google Scholar | Crossref44. Choi, JW, Wicker, RB, Cho, SH, et al. Cure depth control for complex 3D microstructure fabrication in dynamic mask projection microstereolithography. Rapid Prototyping J 2009; 15(1): 59–70.
Google Scholar | Crossref45. Lee, K-W, Wang, S, Fox, BC, et al. Poly(propylene fumarate) bone tissue engineering scaffold fabrication using stereolithography: effects of resin formulations and laser parameters. Biomacromolecules 2007; 8(4): 1077–1084.
Google Scholar | Crossref | Medline46. Sun, A, He, X, Ji, X, et al. Current research progress of photopolymerized hydrogels in tissue engineering. Chin Chem Lett 2021.
Google Scholar47. Nichol, JW, Koshy, ST, Bae, H, et al. Cell-laden microengineered gelatin methacrylate hydrogels. Biomaterials 2010; 31(21): 5536–5544.
Google Scholar | Crossref | Medline | ISI48. Shie, M-Y, Lee, J-J, Ho, CC, et al. Effects of gelatin methacrylate bio-ink concentration on mechano-physical properties and human dermal fibroblast behavior. Polymers 2020; 12(9): 1930.
Google Scholar | Crossref49. Lin, CC . Recent advances in crosslinking chemistry of biomimetic poly(ethylene glycol) hydrogels. Rsc Adv 2015; 5(50): 39844–39853.
Google Scholar | Crossref | Medline50. Presser, C . Absorption coefficient measurements of particle-laden filters using laser heating: validation with nigrosin. J Quant Spectrosc Radiat Transf 2012; 113(8): 607–623.
Google Scholar | Crossref51. Kondo, Y, Sahu, L, Kuwata, M, et al. Stabilization of the Mass Absorption Cross Section of Black Carbon for Filter-Based Absorption Photometry by the use of a Heated Inlet. Aerosol Sci Tech 2009; 43(8): 741–756.
Google Scholar | Crossref52. Yang, Q, Li, J, Wang, X, et al. Dual-emission color-controllable nanoparticle based molecular imprinting ratiometric fluorescence sensor for the visual detection of Brilliant Blue. Sensors Actuators B: Chem 2019; 284: 428–436.
Google Scholar | Crossref53. Khoshakhlagh, P, Bowser, DA, Brown, JQ, et al. Comparison of visible and UVA phototoxicity in neural culture systems micropatterned with digital projection photolithography. J Biomed Mater Res A 2019; 107(1): 134–144.
Google Scholar | Crossref |

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