OCT-Based Improvement of Geometrical Controllability of 3D-Bioprinted Porous Hydrogel Scaffolds

Wang Ling; Zhang Lielie; Zhou Qingqing; Xu Ming′en

doi:10.3788/cjl201643.0607001

[1] van Bael S, Chai Y C, Truscello S, et al.. The effect of pore geometry on the in vitro biological behavior of human periosteum-derived cells seeded on selective laser-melted Ti6Al4V bone scaffolds[J]. Acta Biomaterials, 2012, 8(7): 2824-2834.

[2] Billiet T, Vandenhaute M, Schelfhout J, et al.. A review of trends and limitations in hydrogel-rapid prototyping for tissue engineering[J]. Biomaterials, 2012, 33(26): 6020-6041.

[3] Liu Feng, Zhang Renji, Yan Yongnian, et al.. Rapid prototyping of gelatin/sodium alginate tissue engineering scaffolds[J]. Journal of Tsinghua University (Science and Technology), 2006, 46(8): 1357-1360.

[4] Mironov V, Kasyanov V, Markwald R R. Organ printing: From bioprinter to organ biofabrication line[J]. Current Opinion in Biotechnology, 2011, 22(5): 667-673.

[5] Xu M E, Wang X H, Yan Y N, et al.. An cell-assembly derived physiological 3D model of the metabolic syndrome, based on adipose-derived stromal cells and a gelatin/alginate/fibrinogen matrix[J]. Biomaterials, 2010, 31(22): 3868-3877.

[6] Yan Y N, Wang X H, Pan Y, et al.. Fabrication of viable tissue-engineered constructs with 3D cell-assembly technique[J]. Biomaterials, 2005, 26(29): 5864-5871.

[7] Fedorovich N E, Dewijn J R, Verbout A J, et al.. Three-dimensional fiber deposition of cell-laden, viable, patterned constructs for bone tissue printing[J]. Tissue Engineering Part A, 2008, 14(1): 127-133.

[8] Wang X H, Yan Y N Y, Pan Y, et al.. Generation of three-dimensional hepatocyte/gelatin structures with rapid prototyping system[J]. Tissue Engineering, 2006, 12(1): 83-90.

[9] Shim J H, Kim J Y, Park M, et al.. Development of a hybrid scaffold with synthetic biomaterials and hydrogel using solid freeform fabrication technology[J]. Biomaterials, 2011, 3(3): 034102.

[10] Wang Ling, Tu Pei, Shi Ran, et al.. Quantitative evaluation of three-dimensional bio-printed hydrogel scaffolds by optical coherence tomography[J]. Chinese J Lasers, 2015, 42(8): 0804003.

[11] Xu M E, Li Y, Suo H, et al.. Fabricating a pearl/PLGA composite scaffold by the low-temperature deposition manufacturing technique for bone tissue engineering[J]. Biofabrication, 2010, 2(2): 025002.

[12] Wang Ling, Zhu Hailong, Tu Pei, et al.. High-speed three-dimensional swept source optical coherence tomography system based on LabVIEW[J]. Chinese J Lasers, 2014, 41(7): 0704001.

[13] Appel A A, Anastasio M A, Larson J C, et al.. Imaging challenges in biomaterials and tissue engineering[J]. Biomaterials, 2013, 34(28): 6615-6630.

[14] Guo Xin, Wang Xiangzhao, Bu Peng, et al.. Effects of scattering on spectral shape and depth resolution in Fourier domain optical coherence tomography[J]. Acta Optica Sinica, 2014, 34(1): 0117001.

[15] Billiet T, Gevaert E, Schryver T D, et al.. The 3D printing of gelatin methacrylamide cell-laden tissue-engineered constructs with high cell viability[J]. Biomaterials, 2014, 35(1): 49-62.

[16] Khalil S, Nam J, Sun W. Multi-nozzle deposition for construction of 3D biopolymer tissue scaffolds[J]. Rapid Prototyping Journal, 2005, 11(1): 9-17.

CLP Journals