Page 204 - IJB-9-1

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International Journal of Bioprinting 3D bioprinting of tissue with carbon nanomaterials

alcohol) and solubilized extracellular matrix towards 61. Kang MS, Song S-J, Cha JH, et al., 2020, Increased
cartilage engineering. Int J Mol Sci, 22:3901. neuritogenesis on ternary nanofiber matrices of PLCL and
laminin decorated with black phosphorus. J Ind Eng Chem,
46. Ouyang L, Highley CB, Sun W, et al., 2017, A generalizable
strategy for the 3D bioprinting of hydrogels from nonviscous 92:226–235.
photo-crosslinkable inks. Adv Mater, 29:1604983. 62. Raja IS, Kang MS, Kim KS, et al., 2020, Two-dimensional
theranostic nanomaterials in cancer treatment: State of the
47. Bertlein S, Brown G, Lim KS, et al., 2017, Thiol-ene clickable
gelatin: A platform bioink for multiple 3D biofabrication art and perspectives. Cancers, 12:1657.
technologies. Adv Mater, 29:1703404. 63. Raja IS, Lee JH, Hong SW, et al., 2021, A critical review on
48. Wang SJ, Zhang ZZ, Jiang D, et al., 2016, Thermogel-coated genotoxicity potential of low dimensional nanomaterials. J
poly(ε-caprolactone) composite scaffold for enhanced Hazard Mater, 409:124915.
cartilage tissue engineering. Polymers, 8:200. 64. Mahor A, Singh PP, Bharadwaj P, et al., 2021, Carbon-based
49. Zhang K, Xue K, Loh XJ, 2021, Thermo-responsive nanomaterials for delivery of biologicals and therapeutics: A
hydrogels: From recent progress to biomedical applications. cutting-edge technology. C, 7:19.
Gels, 7:77. 65. Perkins BL, Naderi N, 2016, Carbon nanostructures in bone
50. Iglesias-Mejuto A, García-González CA, 2022, 3D-printed, tissue engineering. Open Orthop J, 10:877–899.
dual crosslinked and sterile aerogel scaffolds for bone tissue 66. Rauti R, Musto M, Bosi S, et al., 2019, Properties and behavior
engineering. Polymers, 14:1211. of carbon nanomaterials when interfacing neuronal cells:
51. Mora-Boza A, Włodarczyk-Biegun MK, Del Campo A, et al., How far have we come? Carbon, 143:430–446.
2019, Glycerylphytate as an ionic crosslinker for 3D printing 67. Kang MS, Lee JH, Hong SW, et al., 2021, Nanocomposites
of multi-layered scaffolds with improved shape fidelity and for enhanced osseointegration of dental and orthopedic
biological features. Biomater Sci, 8:506–516. implants revisited: Surface functionalization by carbon
52. Olmos-Juste R, Alonso-Lerma B, Pérez-Jiménez R, et al., 2021, nanomaterial coatings. J Compos Sci, 5:23.
3D printed alginate-cellulose nanofibers based patches for local 68. Kang MS, Jang HJ, Lee SH, et al., 2021, Potential of carbon-
curcumin administration. Carbohydr Polym, 264:118026. based nanocomposites for dental tissue engineering and
53. Howell DW, Peak CW, Bayless KJ, et al., 2018, 2D regeneration. Materials, 14:5104.
nanosilicates loaded with proangiogenic factors stimulate 69. Li Q, Song J, Besenbacher F, et al., 2015, Two-dimensional
endothelial sprouting. Adv Biosyst, 2:1800092. material confined water. Acc Chem Res, 48:119–127.
54. Bendtsen ST, Quinnell SP, Wei M, 2017, Development of a 70. Yu D, Goh K, Wang H, et al., 2014, Scalable synthesis
novel alginate-polyvinyl alcohol-hydroxyapatite hydrogel of hierarchically structured carbon nanotube-graphene
for 3D bioprinting bone tissue engineered scaffolds. J fibres for capacitive energy storage. Nat Nanotechnol,
Biomed Mater Res Part A, 105:1457–1468. 9:555–562.
55. Bonnelye E, Chabadel A, Saltel F, et al., 2008, Dual effect of 71. Liu Y, Dong X, Chen P, 2012, Biological and chemical sensors
strontium ranelate: Stimulation of osteoblast differentiation based on graphene materials. Chem Soc Rev, 41:2283–2307.
and inhibition of osteoclast formation and resorption in
vitro. Bone, 42:129–138. 72. Raja IS, Vedhanayagam M, Preeth DR, et al., 2021,
Development of two-dimensional nanomaterials based
56. Jeong WY, Kang MS, Lee H, et al., 2021, Recent trends in electrochemical biosensors on enhancing the analysis of
photoacoustic imaging techniques for 2D nanomaterial- food toxicants. Int J Mol Sci, 22:3277.
based phototherapy. Biomedicines, 9:80.
73. Shin YC, Bae J-H, Lee JH, et al., 2022, Enhanced
57. Yu D, Goh K, Wang H, et al., 2014, Scalable synthesis of
hierarchically structured carbon nanotube–graphene fibres osseointegration of dental implants with reduced graphene
for capacitive energy storage. Nat Nanotechnol, 9:555–562. oxide coating. Biomater Res, 26:11.
74. Vedhanayagam M, Raja IS, Molkenova A, et al., 2021,
58. Rueda-Gensini L, Serna JA, Cifuentes J, et al., 2021,
Graphene oxide-embedded extracellular matrix-derived Carbon dots-mediated fluorescent scaffolds: Recent trends
hydrogel as a multiresponsive platform for 3D bioprinting in image-guided tissue engineering applications. Int J Mol
applications. Int J Bioprint, 7:353. Sci, 22:5378.
59. Raja IS, Song SJ, Kang MS, et al., 2019, Toxicity of zero- and 75. Kang MS, Lee H, Jeong S, et al., 2022, State of the art in carbon
one-dimensional carbon nanomaterials. Nanomaterials, nanomaterials for photoacoustic imaging. Biomedicines,
9:1214. 10:1374.
60. Shin YC, Song SJ, Jeong SJ, et al., 2018, Graphene-based 76. Konios D, Stylianakis MM, Stratakis E, et al., 2014,
nanocomposites as promising options for hard tissue Dispersion behaviour of graphene oxide and reduced
regeneration. Adv Exp Med Biol, 1078:103–117. graphene oxide. J Colloid Interface Sci, 430:108–112.

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