Study on Manufacturing-Aid Optical Coherence Tomography

Ling Wang; Jian Hao; Zhongkun Wang; Mingen Xu

doi:10.3788/AOS202040.1111003

[1] Huang D, Swanson E, Lin C et al. Optical coherence tomography[J]. Science, 254, 1178-1181(1991).

[2] Fujimoto J, Drexler W. Introduction to optical coherence tomography[M]. ∥Drexler W, Fujimoto J G. Optical coherence tomography. Cham: Springer, 1-45(2008).

[3] Gao Y, Li Z L, Zhang J H et al. Automatic measurement method for corneal thickness of optical coherence tomography images[J]. Acta Optica Sinica, 39, 0311003(2019).

[4] Wang L, Xu M G, Zhang L L et al. Automated quantitative assessment of three-dimensional bioprinted hydrogel scaffolds using optical coherence tomography[J]. Biomedical Optics Express, 7, 894-910(2016).

[5] He Q Y, Li Z L, Wang X Z et al. Automated retinal layer segmentation based on optical coherence tomographic images[J]. Acta Optica Sinica, 36, 1011003(2016).

[6] Chen C W, Betz M W, Fisher J P et al. Macroporous hydrogel scaffolds and their characterization by optical coherence tomography[J]. Tissue Engineering Part C: Methods, 17, 101-112(2011).

[7] Tang T, Zhao C, Chen Z Y et al. Ultrahigh-resolution optical coherence tomography and its application in inspection of industrial materials[J]. Acta Physica Sinica, 64, 174201(2015).

[8] Ho S T, Hutmacher D W. A comparison of micro CT with other techniques used in the characterization of scaffolds[J]. Biomaterials, 27, 1362-1376(2006).

[9] Hagenmüller H, Kohler T, Hofmann S et al. Monitoring and quantifying formation of tissue engineered human bone in situ by micro-computed tomography[J]. Journal of Biomechanics, 39, S218(2006).

[10] Lalande C, Miraux S, Derkaoui M et al. Magnetic resonance imaging tracking of human adipose derived stromal cells within three-dimensional scaffolds for bone tissue engineering[J]. European Cells and Materials, 21, 341-354(2011).

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

[12] Rice M A, Waters K R, Anseth K S. Ultrasound monitoring of cartilaginous matrix evolution in degradable PEG hydrogels[J]. Acta Biomaterialia, 5, 152-161(2009).

[13] Xu X Q, Yu L F, Chen Z P. Optical clearing of flowing blood using dextrans with spectral domain optical coherence tomography[J]. Journal of Biomedical Optics, 13, 021107(2008).

[14] Siphanto R I, Thumma K K. Kolkman R G M, et al. Serial noninvasive photoacoustic imaging of neovascularization in tumor angiogenesis[J]. Optics Express, 13, 89-95(2005).

[15] Min E, Lee J, Vavilin A et al. Wide-field optical coherence microscopy of the mouse brain slice[J]. Optics Letters, 40, 4420-4423(2015).

[16] Yoo J, Larina I V, Larin K V et al. Increasing the field-of-view of dynamic cardiac OCT via post-acquisition mosaicing without affecting frame-rate or spatial resolution[J]. Biomedical Optics Express, 2, 2614-2622(2011).

[17] Ahdi A, Rabbani H, Vard A. A hybrid method for 3D mosaicing of OCT images of macula and optic nerve head[J]. Computers in Biology and Medicine, 91, 277-290(2017).

[18] Yang Y, Huang S Y. Retinal image mosaic base on genetic algorithm and automated blood vessel extracting approach. C]∥Proceedings of the 7th World Congress on Intelligent Control and Automation, June 25-27, 2008, Chongqing, China. New York: IEEE, 7751-7756(2008).

[19] Zhang J H, Huang Y H, Song Y C et al. Convolutional neural network-based registration for mosaicing of microscopic images[J]. Journal of Electronic Imaging, 28, 043006(2019).

[20] Xu J J. Wei, Song S Z, et al. Scalable wide-field optical coherence tomography-based angiography for in vivo imaging applications[J]. Biomedical Optics Express, 7, 1905-1919(2016).

[21] Wang Z, Potsaid B, Chen L et al. Cubic meter volume optical coherence tomography[J]. Optica, 3, 1496-1503(2016).

[22] Song S Z, Xu J J, Wang R K. Long-range and wide field of view optical coherence tomography for in vivo 3D imaging of large volume object based on akinetic programmable swept source[J]. Biomedical Optics Express, 7, 4734-4748(2016).

[23] Ngo T D, Kashani A, Imbalzano G et al. Additive manufacturing (3D printing): a review of materials, methods, applications and challenges[J]. Composites Part B: Engineering, 143, 172-196(2018).

[24] Hollister S J. Porous scaffold design for tissue engineering[J]. Nature Materials, 4, 518-524(2005).

[25] Sochol R D, Sweet E, Glick C C et al. 3D printed microfluidics and microelectronics[J]. Microelectronic Engineering, 189, 52-68(2018).

[26] Lim J H, Panda B, Pham Q C. Improving flexural characteristics of 3D printed geopolymer composites with in-process steel cable reinforcement[J]. Construction and Building Materials, 178, 32-41(2018).

[27] Si P J, Wang L, Xu M E. Tumor cell invasion imaging based on optical coherence tomography[J]. Chinese Journal of Lasers, 46, 0907003(2019).

[28] Wang L, Xu M G, Zhang L L et al. Automated quantitative assessment of three-dimensional bioprinted hydrogel scaffolds using optical coherence tomography[J]. Biomedical Optics Express, 7, 894(2016).

[29] Singh M, Wu C, Liu C H et al. Phase-sensitive optical coherence elastography at 1.5 million A-lines per second[J]. Optics Letters, 40, 2588-2591(2015).

[30] Kirk R W, Kennedy B F, Sampson D D et al. Near video-rate optical coherence elastography by acceleration with a graphics processing unit[J]. Journal of Lightwave Technology, 33, 3481-3485(2015).