21.8.12 Optical Tomography, Infrared Tomography

Chapter Contents (Back)
Infrared Tomography. Optical Tomography. Tomography. Applied to retinal analysis:
See also Retinal Images, Optical Coherence Tomography, OCT.

Schweiger, M., Arridge, S.R., Delpy, D.T.,
Application of the finite-element method for the forward and inverse models in optical tomography,
JMIV(3), No. 4, 1993, pp. 263-283. BibRef 9300

Dehghani, H.[Hamid], Arridge, S.R.[Simon R.], Schweiger, M.[Martin], Delpy, D.T.[David T.],
Optical tomography in the presence of void regions,
JOSA-A(17), No. 9, September 2000, pp. 1659-1670. 0008
BibRef

Arridge, S.R.[Simon R.], Hebden, J.C.[Jeremy C.], Schweiger, M.[Martin], Schmidt, F.E.W.[Florian E.W.], Fry, M.E.[Martin E.], Hillman, E.M.C.[Elizabeth M.C.], Dehghani, H.[Hamid], Delpy, D.T.[David T.],
A method for three-dimensional time-resolved optical tomography,
IJIST(11), No. 1, 2000, pp. 2-11. 0005
BibRef

Pineda, A.R.[Angel R.], Schweiger, M.[Martin], Arridge, S.R.[Simon R.], Barrett, H.H.[Harrison H.],
Information content of data types in time-domain optical tomography,
JOSA-A(23), No. 12, December 2006, pp. 2989-2996.
WWW Link. 0801
BibRef

Panagiotou, C.[Christos], Somayajula, S.[Sangeetha], Gibson, A.P.[Adam P.], Schweiger, M.[Martin], Leahy, R.M.[Richard M.], Arridge, S.R.[Simon R.],
Information theoretic regularization in diffuse optical tomography,
JOSA-A(26), No. 5, May 2009, pp. 1277-1290.
WWW Link. 0905
BibRef

Colak, S.B., Papaioannou, D.G., Thooft, G.W., van der Mark, M.B., Schomberg, H., Paasschens, J.C.J., Melissen, J.B.M., Vanasten, N.A.A.J.,
Tomographic Image Reconstruction from Optical Projections in Light Diffusing Media,
AppOpt(36), No. 1, January 1 1997, pp. 180-213. 9702
BibRef

Gao, F., Niu, H., Zhao, H., Zhang, H.,
The Forward and Inverse Models in Time Resolved Optical Tomography Imaging and Their Finite Element Method Solutions,
IVC(16), No. 9-10, July 1998, pp. 703-712.
Elsevier DOI 9808
BibRef

Zhu, W.W., Wang, Y., Zhang, J.,
Total Least-Squares Reconstruction with Wavelets for Optical Tomography,
JOSA-A(15), No. 10, October 1998, pp. 2639-2650. 9810
BibRef

Zhu, W.W., Wang, Y., Galatsanos, N.P., Zhang, J.,
Regularized Total Least Squares Approach for Nonconvolutional Linear Inverse Problems,
IP(8), No. 11, November 1999, pp. 1657-1661.
IEEE DOI 9911
BibRef

Zhu, W.W., Wang, Y., Galatsanos, N.P., and Zhang, J.,
Regularized Total Least Squares Reconstruction for Optical Tomographic Imaging Using Conjugate Gradient Method,
ICIP97(I: 192-195).
IEEE DOI BibRef 9700

Ye, J.C.[Jong Chul], Webb, K.J.[Kevin J.], Bouman, C.A.[Charles A.], Millane, R.P.,
Optical diffusion tomography by iterative-coordinate-descent optimization in a Bayesian framework,
JOSA-A(16), No. 10, October 1999, pp. 2400-2412. BibRef 9910

Ye, J.C.[Jong Chul], Bouman, C.A., Webb, K.J., Millane, R.P.,
Nonlinear multigrid algorithms for bayesian optical diffusion tomography,
IP(10), No. 6, June 2001, pp. 909-922.
IEEE DOI 0106
BibRef

Ye, J.C.[Jong Chul], Bouman, C.A.[Charles A.], Millane, R.P.[Rick P.], Webb, K.J.[Kevin J.],
Nonlinear Multigrid Optimization for Bayesian Diffusion Tomography,
ICIP99(II:653-657).
IEEE DOI BibRef 9900

Oh, S.S.[Seung-Seok], Bouman, C.A.[Charles A.], Webb, K.J.[Kevin J.],
Multigrid Tomographic Inversion With Variable Resolution Data and Image Spaces,
IP(15), No. 9, August 2006, pp. 2805-2819.
IEEE DOI 0608
BibRef

Oh, S.S.[Seung-Seok], Milstein, A.B., Bouman, C.A.[Charles A.], Webb, K.J.[Kevin J.],
Nonlinear multigrid inversion,
ICIP03(I: 1057-1060).
IEEE DOI 0312
BibRef

Andia, B.I.[Blanca I.], Sauer, K.D.[Ken D.], Bouman, C.A.[Charles A.],
Nonlinear, Noniterative Bayesian Tomographic Image reconstruction,
ICIP99(II:668-671).
IEEE DOI BibRef 9900

Oh, S.S.[Seung-Seok], Milstein, A.B.[Adam B.], Millane, R.P., Bouman, C.A.[Charles A.], Webb, K.J.[Kevin J.],
Source-Detector calibration in three-dimensional Bayesian optical diffusion tomography,
JOSA-A(19), No. 10, October 2002, pp. 1983-1993.
WWW Link. 0210
BibRef

Cao, G., Bouman, C.A.[Charles A.], Webb, K.J.[Kevin J.],
Noniterative MAP Reconstruction Using Sparse Matrix Representations,
IP(18), No. 9, September 2009, pp. 2085-2099.
IEEE DOI 0909
BibRef

Shoari, S., Bagherzadeh, N., Goodman, D., Milner, T.E., Smithies, D.J., Nelson, J.S.,
A Parallel Algorithm for Pulsed Laser Infrared Tomography,
PRL(19), No. 5-6, April 1998, pp. 521-526. 9808
BibRef

Hielscher, A.H., Klose, A.D., Hanson, K.M.,
Gradient-based iterative image reconstruction scheme for time-resolved optical tomography,
MedImg(18), No. 3, March 1999, pp. 262-271.
IEEE Top Reference. 0110
BibRef

Klose, A.D.[Alexander D.],
Transport-theory-based stochastic image reconstruction of bioluminescent sources,
JOSA-A(24), No. 6, June 2007, pp. 1601-1608.
WWW Link. 0801
BibRef

Ntziachristos, V., Hielscher, A.H., Yodh, A.G., Chance, B.,
Diffuse optical tomography of highly heterogeneous media,
MedImg(20), No. 6, June 2001, pp. 470-478.
IEEE Top Reference. 0110
BibRef

Lasser, T., Soubret, A., Ripoll, J., Ntziachristos, V.,
Surface Reconstruction for Free-Space 360 deg Fluorescence Molecular Tomography and the Effects of Animal Motion,
MedImg(27), No. 2, February 2008, pp. 188-194.
IEEE DOI 0802
BibRef

Roy, R.[Ranadhir], Sevick-Muraca, E.M.[Eva M.],
Active constrained truncated Newton method for simple-bound optical tomography,
JOSA-A(17), No. 9, September 2000, pp. 1627-1641. 0008
BibRef

Roy, R.[Ranadhir], Thompson, A.B., Godavarty, A., Sevick-Muraca, E.M.[Eva M.],
Tomographic Fluorescence Imaging in Tissue Phantoms: A Novel Reconstruction Algorithm and Imaging Geometry,
MedImg(24), No. 2, February 2005, pp. 137-154.
IEEE Abstract. 0501
BibRef

Roy, R., Godavarty, A., Sevick-Muraca, E.M.,
Fluorescence-enhanced optical tomography using referenced measurements of heterogeneous media,
MedImg(22), No. 7, July 2003, pp. 824-836.
IEEE Abstract. 0308
BibRef

Eppstein, M.J., Fedele, F., Laible, J., Zhang, C., Godavarty, A., Sevick-Muraca, E.M.,
A comparison of exact and approximate adjoint sensitivities in fluorescence tomography,
MedImg(22), No. 10, October 2003, pp. 1215-1223.
IEEE Abstract. 0310
BibRef

Markel, V.A.[Vadim A.], Schotland, J.C.[John C.],
Inverse problem in optical diffusion tomography: I. Fourier Laplace inversion formulas,
JOSA-A(18), No. 1, April 2001, pp. 1336-1347.
WWW Link. 0106
BibRef

Markel, V.A.[Vadim A.], Schotland, J.C.[John C.],
Inverse problem in optical diffusion tomography: II. Role of boundary conditions,
JOSA-A(19), No. 3, March 2002, pp. 558-566.
WWW Link. 0204
BibRef

Markel, V.A.[Vadim A.], Mital, V.[Vivek], Schotland, J.C.[John C.],
Inverse problem in optical diffusion tomography: III. Inversion formulas and singular-value decomposition,
JOSA-A(20), No. 5, May 2003, pp. 890-902.
WWW Link. 0307
BibRef

Markel, V.A.[Vadim A.], O'Sullivan, J.A.[Joseph A.], Schotland, J.C.[John C.],
Inverse Problem in Optical Diffusion Tomography: IV. Nonlinear Inversion Formulas,
JOSA-A(20), No. 5, May 2003, pp. 903-912.
WWW Link. 0307
BibRef

Tanifuji, T., Hijikata, M.,
Finite difference time domain (FDTD) analysis of optical pulse responses in biological tissues for spectroscopic diffused optical tomography,
MedImg(21), No. 2, February 2002, pp. 181-184.
IEEE Top Reference. 0204
BibRef

Zhu, W., Wang, Y., Deng, Y., Yao, Y., Barbour, R.L.,
A wavelet-based multiresolution regularized least squares reconstruction approach for optical tomography,
MedImg(16), No. 2, April 1997, pp. 210-217.
IEEE Top Reference. 0205
BibRef

Pogue, B.W., Song, X.M.[Xiao-Mei], Tosteson, T.D., McBride, T.O., Jiang, S.D.[Shu-Dong], Paulsen, K.D.,
Statistical analysis of nonlinearly reconstructed near-infrared tomographic images: part I-theory and simulations,
MedImg(21), No. 7, July 2002, pp. 755-763.
IEEE Top Reference. 0210
BibRef

Song, X.M.[Xiao-Mei], Pogue, B.W., Tosteson, T.D., McBride, T.O., Jiang, S.D.[Shu-Dong], Paulsen, K.D.,
Statistical analysis of nonlinearly reconstructed near-infrared tomographic images: part II-experimental interpretation,
MedImg(21), No. 7, July 2002, pp. 764-772.
IEEE Top Reference. 0210
BibRef

Graber, H.L., Pei, Y.L.[Ya-Ling], Barbour, R.L.,
Imaging of spatiotemporal coincident states by DC optical tomography,
MedImg(21), No. 8, August 2002, pp. 852-866.
IEEE Top Reference. 0301
BibRef

Bal, G.[Guillaume], Ren, K.[Kui],
Generalized diffusion model in optical tomography with clear layers,
JOSA-A(20), No. 12, December 2003, pp. 2355-2364.
WWW Link. 0401
BibRef

Ralston, T.S., Marks, D.L., Kamalabadi, F., Boppart, S.A.,
Deconvolution Methods for Mitigation of Transverse Blurring in Optical Coherence Tomography,
IP(14), No. 9, September 2005, pp. 1254-1264.
IEEE DOI 0508
BibRef

Marks, D.L.[Daniel L.], Ralston, T.S.[Tyler S.], Boppart, S.A.[Stephen A.],
Speckle reduction by I-divergence regularization in optical coherence tomography,
JOSA-A(22), No. 11, November 2005, pp. 2366-2371.
WWW Link. 0601
BibRef

Marks, D.L.[Daniel L.], Ralston, T.S.[Tyler S.], Carney, P.S.[P. Scott], Boppart, S.A.[Stephen A.],
Inverse scattering for rotationally scanned optical coherence tomography,
JOSA-A(23), No. 10, October 2006, pp. 2433-2439.
WWW Link. 0610
BibRef

Su, J.Z.[Jian-Zhong], Shan, H.[Hua], Liu, H.L.[Han-Li], Klibanov, M.V.[Michael V.],
Reconstruction method with data from a multiple-site continuous-wave source for three-dimensional optical tomography,
JOSA-A(23), No. 10, October 2006, pp. 2388-2395.
WWW Link. 0610
BibRef

Pantong, N.[Natee], Su, J.Z.[Jian-Zhong], Shan, H.[Hua], Klibanov, M.V.[Michael V.], Liu, H.[Hanli],
Globally accelerated reconstruction algorithm for diffusion tomography with continuous-wave source in an arbitrary convex shape domain,
JOSA-A(26), No. 3, March 2009, pp. 456-472.
WWW Link. 0903
BibRef

Schultz, L.J., Blanpied, G.S., Borozdin, K.N., Fraser, A.M., Hengartner, N.W., Klimenko, A.V., Morris, C.L., Orum, C., Sossong, M.J.,
Statistical Reconstruction for Cosmic Ray Muon Tomography,
IP(16), No. 8, August 2007, pp. 1985-1993.
IEEE DOI 0709
BibRef

Davis, B.J.[Brynmor J.], Schlachter, S.C.[Simon C.], Marks, D.L.[Daniel L.], Ralston, T.S.[Tyler S.], Boppart, S.A.[Stephen A.], Carney, P.S.[P. Scott],
Nonparaxial vector-field modeling of optical coherence tomography and interferometric synthetic aperture microscopy,
JOSA-A(24), No. 9, September 2007, pp. 2527-2542.
WWW Link. 0801
BibRef
Earlier: A1, A4, A3, A5, A6, Only:
Interferometric Synthetic Aperture Microscopy: Physics-Based Image Reconstruction from Optical Coherence Tomography Data,
ICIP07(IV: 145-148).
IEEE DOI 0709
BibRef

Marks, D.L.[Daniel L.], Davis, B.J.[Brynmor J.], Boppart, S.A.[Stephen A.], Carney, P.S.[P. Scott],
Partially coherent illumination in full-field interferometric synthetic aperture microscopy,
JOSA-A(26), No. 2, February 2009, pp. 376-386.
WWW Link. 0902
BibRef

Ozcan, A.[Aydogan], Bilenca, A.[Alberto], Desjardins, A.E.[Adrien E.], Bouma, B.E.[Brett E.], Tearney, G.J.[Guillermo J.],
Speckle reduction in optical coherence tomography images using digital filtering,
JOSA-A(24), No. 7, July 2007, pp. 1901-1910.
WWW Link. 0801
BibRef

Desjardins, A.E., Vakoc, B.J., Suter, M.J., Yun, S.H., Tearney, G.J., Bouma, B.E.,
Real-Time FPGA Processing for High-Speed Optical Frequency Domain Imaging,
MedImg(28), No. 9, September 2009, pp. 1468-1472.
IEEE DOI 0909
BibRef

Vakoc, B.J., Tearney, G.J.[Guillermo J.], Bouma, B.E.[Brett E.],
Statistical Properties of Phase-Decorrelation in Phase-Resolved Doppler Optical Coherence Tomography,
MedImg(28), No. 6, June 2009, pp. 814-821.
IEEE DOI 0906
noise limits use for small vessels with slower flows. BibRef

Boverman, G., Miller, E.L., Brooks, D.H., Isaacson, D., Fang, Q., Boas, D.A.,
Estimation and Statistical Bounds for Three-Dimensional Polar Shapes in Diffuse Optical Tomography,
MedImg(27), No. 6, June 2008, pp. 752-765.
IEEE DOI 0711
BibRef

Kumar, A.T.N., Raymond, S.B., Dunn, A.K., Bacskai, B.J., Boas, D.A.,
A Time Domain Fluorescence Tomography System for Small Animal Imaging,
MedImg(27), No. 8, August 2008, pp. 1152-1163.
IEEE DOI 0808
BibRef

Kolehmainen, V.[Ville], Schweiger, M.[Martin], Nissilä, I.[Ilkka], Tarvainen, T.[Tanja], Arridge, S.R.[Simon R.], Kaipio, J.P.[Jari P.],
Approximation errors and model reduction in three-dimensional diffuse optical tomography,
JOSA-A(26), No. 10, October 2009, pp. 2257-2268.
WWW Link. 0910
BibRef

Guven, M., Reilly-Raska, L., Zhou, L., Yazici, B.,
Discretization Error Analysis and Adaptive Meshing Algorithms for Fluorescence Diffuse Optical Tomography: Part I,
MedImg(29), No. 2, February 2010, pp. 217-229.
IEEE DOI 1002
BibRef

Guven, M., Zhou, L., Reilly-Raska, L., Yazici, B.,
Discretization Error Analysis and Adaptive Meshing Algorithms for Fluorescence Diffuse Optical Tomography: Part II,
MedImg(29), No. 2, February 2010, pp. 230-245.
IEEE DOI 1002
BibRef

Zhou, L., Yazici, B.,
Discretization Error Analysis and Adaptive Meshing Algorithms for Fluorescence Diffuse Optical Tomography in the Presence of Measurement Noise,
IP(20), No. 4, April 2011, pp. 1094-1111.
IEEE DOI 1103
BibRef

Guven, M., Yazici, B., Kwon, K.[Kiwoon], Giladi, E., Intes, X.,
Discretization error based mesh generation for diffuse optical tomography,
AIPR05(146-151).
IEEE DOI 0510
BibRef

Son, I.Y.[Il-Young], Guven, M., Xavier Intes, B.Y.,
A 2-level domain decomposition algorithm for inverse diffuse optical tomography,
ICIP04(V: 3315-3318).
IEEE DOI 0505
BibRef

Guven, M., Yazici, B., Intes, X., Chance, B.,
An adaptive multigrid algorithm for region of interest diffuse optical tomography,
ICIP03(II: 823-826).
IEEE DOI 0312
BibRef

Guven, M., Yazici, B., Intes, X., Chance, B.,
Hierarchical Bayesian algorithm for diffuse optical tomography,
AIPR05(140-145).
IEEE DOI 0510
BibRef

Kauffmann, C., Motreff, P., Sarry, L.,
In Vivo Supervised Analysis of Stent Reendothelialization From Optical Coherence Tomography,
MedImg(29), No. 3, March 2010, pp. 807-818.
IEEE DOI 1003
BibRef

Wang, Y.L.[Ying-Li], Liang, Y.M.[Yan-Mei], Xu, K.H.[Kuan-Hong],
Signal processing for sidelobe suppression in optical coherence tomography images,
JOSA-A(27), No. 3, March 2010, pp. 415-421.
WWW Link. 1003
BibRef

Lee, O., Kim, J.M., Bresler, Y., Ye, J.C.,
Compressive Diffuse Optical Tomography: Noniterative Exact Reconstruction Using Joint Sparsity,
MedImg(30), No. 5, May 2011, pp. 1129-1142.
IEEE DOI 1105
BibRef

Tian, F., Niu, H., Khan, B., Alexandrakis, G., Behbehani, K., Liu, H.,
Enhanced Functional Brain Imaging by Using Adaptive Filtering and a Depth Compensation Algorithm in Diffuse Optical Tomography,
MedImg(30), No. 6, June 2011, pp. 1239-1251.
IEEE DOI 1101
BibRef

Sung, Y.J.[Yong-Jin], Dasari, R.R.[Ramachandra R.],
Deterministic regularization of three-dimensional optical diffraction tomography,
JOSA-A(28), No. 8, August 2011, pp. 1554-1561.
WWW Link. 1108
BibRef

Liu, X., Liu, F., Zhang, Y., Bai, J.B.,
Unmixing Dynamic Fluorescence Diffuse Optical Tomography Images With Independent Component Analysis,
MedImg(30), No. 9, September 2011, pp. 1591-1604.
IEEE DOI 1109
BibRef

Liu, X., Zhang, B., Luo, J., Bai, J.B.,
4-D Reconstruction for Dynamic Fluorescence Diffuse Optical Tomography,
MedImg(31), No. 11, November 2012, pp. 2120-2132.
IEEE DOI 1211
BibRef

Cheddad, A., Svensson, C., Sharpe, J., Georgsson, F., Ahlgren, U.,
Image Processing Assisted Algorithms for Optical Projection Tomography,
MedImg(31), No. 1, January 2012, pp. 1-15.
IEEE DOI 1201
BibRef

Bonfert-Taylor, P.[Petra], Leblond, F.[Frederic], Holt, R.W.[Robert W.], Tichauer, K.[Kenneth], Pogue, B.W.[Brian W.], Taylor, E.C.[Edward C.],
Information loss and reconstruction in diffuse fluorescence tomography,
JOSA-A(29), No. 3, March 2012, pp. 321-330.
WWW Link. 1203
BibRef

Zhu, S.P.[Shou-Ping], Dong, D.[Di], Birk, U.J., Rieckher, M., Tavernarakis, N., Qu, X.C.[Xiao-Chao], Liang, J.[Jimin], Tian, J.[Jie], Ripoll, J.,
Automated Motion Correction for In Vivo Optical Projection Tomography,
MedImg(31), No. 7, July 2012, pp. 1358-1371.
IEEE DOI 1208
BibRef

Gao, Y., Wang, K., Jiang, S., Liu, Y., Ai, T., Tian, J.,
Bioluminescence Tomography Based on Gaussian Weighted Laplace Prior Regularization for In Vivo Morphological Imaging of Glioma,
MedImg(36), No. 11, November 2017, pp. 2343-2354.
IEEE DOI 1711
BibRef
And: Corrections: MedImg(37), No. 7, July 2018, pp. 1733-1733.
IEEE DOI 1808
BibRef
And: Corrections: MedImg(37), No. 9, September 2018, pp. 2161-2161.
IEEE DOI 1809
Image reconstruction, In vivo, Mice, Numerical models, Phantoms, Tomography, Tumors, Bioluminescence tomography, brain, multi-modality, fusion BibRef

Yin, D.[Daiqiang], Gu, Y.[Ying], Xue, P.[Ping],
Speckle-constrained variational methods for image restoration in optical coherence tomography,
JOSA-A(30), No. 5, May 2013, pp. 878-885.
WWW Link. 1305
BibRef

Chan, A.C., Lam, E.Y., Srinivasan, V.J.,
Comparison of Kasai Autocorrelation and Maximum Likelihood Estimators for Doppler Optical Coherence Tomography,
MedImg(32), No. 6, 2013, pp. 1033-1042.
IEEE DOI 1307
optical tomography BibRef

Chan, A.C., Srinivasan, V.J., Lam, E.Y.,
Maximum Likelihood Doppler Frequency Estimation Under Decorrelation Noise for Quantifying Flow in Optical Coherence Tomography,
MedImg(33), No. 6, June 2014, pp. 1313-1323.
IEEE DOI 1407
Coherence BibRef

Fang, L.Y.[Le-Yuan], Li, S.T.[Shu-Tao], McNabb, R.P., Nie, Q.[Qing], Kuo, A.N., Toth, C.A., Izatt, J.A., Farsiu, S.,
Fast Acquisition and Reconstruction of Optical Coherence Tomography Images via Sparse Representation,
MedImg(32), No. 11, 2013, pp. 2034-2049.
IEEE DOI 1312
biomedical optical imaging BibRef

Fang, L.Y.[Le-Yuan], Li, S.T.[Shu-Tao], Cunefare, D., Farsiu, S.,
Segmentation Based Sparse Reconstruction of Optical Coherence Tomography Images,
MedImg(36), No. 2, February 2017, pp. 407-421.
IEEE DOI 1702
Dictionaries BibRef

Prakash, J., Dehghani, H., Pogue, B.W., Yalavarthy, P.K.,
Model-Resolution-Based Basis Pursuit Deconvolution Improves Diffuse Optical Tomographic Imaging,
MedImg(33), No. 4, April 2014, pp. 891-901.
IEEE DOI 1404
Biomedical optical imaging BibRef

Mozumder, M.[Meghdoot], Tarvainen, T.[Tanja], Kaipio, J.P.[Jari P.], Arridge, S.R.[Simon R.], Kolehmainen, V.[Ville],
Compensation of Modeling Errors Due to Unknown Domain Boundary in Diffuse Optical Tomography,
JOSA-A(31), No. 8, August 2014, pp. 1847-1855.
DOI Link 1408
Inverse problems
See also Compensation of Modelling Errors Due to Unknown Domain Boundary in Electrical Impedance Tomography. BibRef

Xu, D.[Daguang], Huang, Y.[Yong], Kang, J.U.[Jin U.],
Real-time dispersion-compensated image reconstruction for compressive sensing spectral domain optical coherence tomography,
JOSA-A(31), No. 9, September 2014, pp. 2064-2069.
DOI Link 1410
Digital image processing BibRef

Chen, C.[Chen], Tian, F.[Fenghua], Liu, H.[Hanli], Huang, J.Z.[Jun-Zhou],
Diffuse Optical Tomography Enhanced by Clustered Sparsity for Functional Brain Imaging,
MedImg(33), No. 12, December 2014, pp. 2323-2331.
IEEE DOI 1412
biomedical optical imaging BibRef

Mohajerani, P., Tzoumas, S., Rosenthal, A., Ntziachristos, V.,
Optical and Optoacoustic Model-Based Tomography: Theory and current challenges for deep tissue imaging of optical contrast,
SPMag(32), No. 1, January 2015, pp. 88-100.
IEEE DOI 1502
acoustic tomography BibRef

Kafieh, R., Rabbani, H., Selesnick, I.,
Three Dimensional Data-Driven Multi Scale Atomic Representation of Optical Coherence Tomography,
MedImg(34), No. 5, May 2015, pp. 1042-1062.
IEEE DOI 1505
Adaptive optics BibRef

Mohanan, K.P., Nandakumaran, A.K., Roy, D., Vasu, R.M.,
Ultrasound-modulated optical tomography: direct recovery of elasticity distribution from experimentally measured intensity autocorrelation,
JOSA-A(32), No. 5, May 2015, pp. 955-963.
DOI Link 1505
Image reconstruction techniques BibRef

Fang, L.Y.[Le-Yuan], Li, S.T.[Shu-Tao], Kang, X.D.[Xu-Dong], Izatt, J.A., Farsiu, S.,
3-D Adaptive Sparsity Based Image Compression With Applications to Optical Coherence Tomography,
MedImg(34), No. 6, June 2015, pp. 1306-1320.
IEEE DOI 1506
eye BibRef

Lee, O., Tak, S., Ye, J.C.,
A Unified Sparse Recovery and Inference Framework for Functional Diffuse Optical Tomography Using Random Effect Model,
MedImg(34), No. 7, July 2015, pp. 1602-1615.
IEEE DOI 1507
Analytical models BibRef

Scott, G.G., Coats, B.,
Microstructural Characterization of the Pia-Arachnoid Complex Using Optical Coherence Tomography,
MedImg(34), No. 7, July 2015, pp. 1452-1459.
IEEE DOI 1507
Animals BibRef

Uttam, S.[Shikhar], Liu, Y.[Yang],
Fourier phase in Fourier-domain optical coherence tomography,
JOSA-A(32), No. 12, December 2015, pp. 2286-2306.
DOI Link 1601
Fourier optics and signal processing BibRef

Smith, G.T., Dwork, N., O'Connor, D., Sikora, U., Lurie, K.L., Pauly, J.M., Ellerbee, A.K.,
Automated, Depth-Resolved Estimation of the Attenuation Coefficient From Optical Coherence Tomography Data,
MedImg(34), No. 12, December 2015, pp. 2592-2602.
IEEE DOI 1601
Attenuation BibRef

Powell, S., Arridge, S.R., Leung, T.S.,
Gradient-Based Quantitative Image Reconstruction in Ultrasound-Modulated Optical Tomography: First Harmonic Measurement Type in a Linearised Diffusion Formulation,
MedImg(35), No. 2, February 2016, pp. 456-467.
IEEE DOI 1602
Adaptive optics BibRef

Shulga, D., Morozov, O., Hunziker, P.,
A Tensor B-Spline Approach for Solving the Diffusion PDE With Application to Optical Diffusion Tomography,
MedImg(36), No. 4, April 2017, pp. 972-982.
IEEE DOI 1704
Adaptive optics BibRef

Shulga, D., Morozov, O., Hunziker, P.,
Solving 3-D PDEs by Tensor B-Spline Methodology: A High Performance Approach Applied to Optical Diffusion Tomography,
MedImg(37), No. 9, September 2018, pp. 2115-2125.
IEEE DOI 1809
Splines (mathematics), Tensile stress, Finite element analysis, Kernel, Tomography, Brain modeling, Biomedical optical imaging, tensor BibRef

Cao, Y.H.[Yi-Hui], Liu, C.[Chao], Jin, Q.H.[Qin-Hua], Chen, Y.D.[Yun-Dai], Yin, Q.Y.[Qin-Ye], Li, J.A.[Jian-An], Zhao, W.[Wei],
Automatic Bifurcation angle calculation in intravascular optical coherence tomography images,
ICIVC17(650-654)
IEEE DOI 1708
Bifurcation, Fitting, Image resolution, Optical imaging, Optical variables measurement, bifurcation angle calculation, intravascular optical coherence tomography, main vessel, side, branch BibRef

Jamaludin, J., Rahim, R.A., Rahiman, M.H.F.[M. H. Fazul], Rohani, J.M.[J. Mohd],
Analysis on the Effect of Sensor Views in Image Reconstruction Produced by Optical Tomography System Using Charge-Coupled Device,
IP(27), No. 4, April 2018, pp. 1689-1696.
IEEE DOI 1802
CCD image sensors, image reconstruction, image resolution, optical tomography, OPT system, charge-coupled device, sensor views BibRef

Elliott, M.R., Kim, D., Molony, D.S., Morris, L., Samady, H., Joshi, S., Timmins, L.H.,
Establishment of an Automated Algorithm Utilizing Optical Coherence Tomography and Micro-Computed Tomography Imaging to Reconstruct the 3-D Deformed Stent Geometry,
MedImg(38), No. 3, March 2019, pp. 710-720.
IEEE DOI 1903
Image reconstruction, Geometry, Phantoms, Computed tomography, Mathematical model, biomechanics BibRef

Yoo, J.J.[Jae-Jun], Sabir, S.[Sohail], Heo, D.C.[Du-Chang], Kim, K.H.[Kee Hyun], Wahab, A.[Abdul], Choi, Y.S.[Yoon-Seok], Lee, S.I.[Seul-I], Chae, E.Y.[Eun Young], Kim, H.H.[Hak Hee], Bae, Y.M.[Young Min], Choi, Y.W.[Young-Wook], Cho, S.R.[Seung-Ryong], Ye, J.C.[Jong Chul],
Deep Learning Diffuse Optical Tomography,
MedImg(39), No. 4, April 2020, pp. 877-887.
IEEE DOI 2004
Optical imaging, Nonlinear optics, Optical scattering, Mathematical model, Neural networks, Photonics, Deep learning, convolution framelets BibRef

Cai, M., Zhang, Z., Shi, X., Yang, J., Hu, Z., Tian, J.,
Non-Negative Iterative Convex Refinement Approach for Accurate and Robust Reconstruction in Cerenkov Luminescence Tomography,
MedImg(39), No. 10, October 2020, pp. 3207-3217.
IEEE DOI 2010
Image reconstruction, Imaging, Mathematical model, Shape, Slabs, Iterative methods, Luminescence, tumor BibRef

Kazanci, H.O.[Huseyin Ozgur],
Differential photon waves imaging,
IJIST(31), No. 2, 2021, pp. 718-728.
DOI Link 2105
differential photon waves imaging (DPWI), diffuse optic imaging (DOI) methodology, diffuse optic tomography (DOT) BibRef

Kovács, P.[Péter], Lehner, B.[Bernhard], Thummerer, G.[Gregor], Mayr, G.[Günther], Burgholzer, P.[Peter], Huemer, M.[Mario],
Surfing Virtual Waves to Thermal Tomography: From model- to deep learning-based reconstructions,
SPMag(39), No. 1, January 2022, pp. 55-67.
IEEE DOI 2201
Heating systems, Computational modeling, Imaging, Photothermal effects, Computational efficiency, Spatial resolution BibRef

Abhishek, A.[Anuj], Strauss, T.[Thilo], Khan, T.[Taufiquar],
An Optimal Bayesian Estimator for Absorption Coefficient in Diffuse Optical Tomography,
SIIMS(15), No. 2, 2022, pp. 797-821.
DOI Link 2206
BibRef

Zhang, X.X.[Xuan-Xuan], Cao, X.[Xu], Zhang, P.[Peng], Song, F.[Fan], Zhang, J.[Jiulou], Zhang, L.[Lin], Zhang, G.L.[Guang-Lei],
Self-Training Strategy Based on Finite Element Method for Adaptive Bioluminescence Tomography Reconstruction,
MedImg(41), No. 10, October 2022, pp. 2629-2643.
IEEE DOI 2210
Image reconstruction, Neural networks, Mathematical models, Tomography, Photonics, Deep learning, Biomedical imaging, self-training BibRef


Yuan, B.Z.[Bing-Zhi], Tamaki, T., Kushida, T., Raytchev, B., Kanedal, K., Mukaigawa, Y., Kubo, H.,
Layered optical tomography of multiple scattering media with combined constraint optimization,
FCV15(1-6)
IEEE DOI 1506
Hessian matrices BibRef

Akashi, R., Nagahara, H., Mukaigawa, Y., Taniguchi, R.I.,
Scattering tomography using ellipsoidal mirror,
FCV15(1-5)
IEEE DOI 1506
medical image processing BibRef

Anantrasirichai, N., Nicholson, L.[Lindsay], Morgan, J.E.[James E.], Erchova, I.[Irina], Achim, A.[Alin],
Adaptive-weighted bilateral filtering for optical coherence tomography,
ICIP13(1110-1114)
IEEE DOI 1402
Adaptive optics BibRef

Rodrigues, P.[Pedro], Guimarăes, P.[Pedro], Araújo, A.[Adérito], Barbeiro, S.[Sílvia], Bernardes, R.[Rui],
Explicit and Semi-implicit Complex-Diffusion Schemes for Optical Coherence Tomography Despeckling,
ICIAR13(282-289).
Springer DOI 1307
BibRef

Serranho, P., Maduro, C., Santos, T., Cunha-Vaz, J., Bernardes, R.,
Synthetic OCT data for image processing performance testing,
ICIP11(401-404).
IEEE DOI 1201
Optical Coherence Tomography BibRef

Xu, L.[Lei], Stojkovic, B.[Branislav], Ding, H.[Hu], Song, Q.[Qi], Wu, X.D.[Xiao-Dong], Sonka, M.[Milan], Xu, J.H.[Jin-Hui],
Faster Segmentation Algorithm for Optical Coherence Tomography Images with Guaranteed Smoothness,
MLMI11(308-316).
Springer DOI 1109
BibRef

Brady, S.P.[Spencer P.], Do, M.N.[Minh N.], Bhargava, R.[Rohit],
Reconstructing FT-IR spectroscopic imaging data with a sparse prior,
ICIP09(829-832).
IEEE DOI 0911
Fourier Transform Infrared. Long acquisition times. Large storage. BibRef

Qin, C.H.[Cheng-Hu], Tian, J.[Jie], Yang, X.[Xin], Liu, K.[Kai], Feng, J.C.[Jin-Chao], Yan, G.R.[Guo-Rui], Zhu, S.P.[Shou-Ping], Xu, M.[Min],
An adaptive meshless method for spectrally resolved bioluminescence tomography,
ICIP09(2541-2544).
IEEE DOI 0911
BibRef

Niroumand, A.M., Bnooks, D.H., Shafai, B.,
Diffuse optical tomography using a linear matrix inequality algorithm in an admissible solution approach,
ICIP03(I: 577-580).
IEEE DOI 0312
BibRef

Ruminski, J.[Jacek], Kaczmarek, M.[Mariusz], Nowakowski, A.[Antoni],
Medical Active Thermography: A New Image Reconstruction Method,
CAIP01(274 ff.).
Springer DOI 0210
BibRef

Milosevic, M.[Milos], Schwartzkopf, W.C.[Wade C.], Milner, T.E.[Thomas E.], Evans, B.L.[Brian L.], Bovik, A.C.[Alan C.],
Low-Complexity Velocity Estimation in High-Speed Optical Doppler Tomography Systems,
ICIP99(II:658-662).
IEEE DOI BibRef 9900

Marks, D.L.[Daniel L.], Munson, Jr., D.C.[David C.], Stack, R.[Ronald], Brady, D.J.[David J.],
Three-Dimensional Surface Reconstruction of Optical Lambertian Objects Using Cone-Beam Tomography,
ICIP99(II:663-667).
IEEE DOI BibRef 9900

Pierson, R.E., Chen, E.Y., Bishop, K.P., McMackin, L.,
Evaluating effective resolution of an optical tomographic imaging system using a narrow-band correlation metric,
ICIP96(III: 535-538).
IEEE DOI 9610
BibRef

Antonov, V., Dolgobrodov, S., Gusev, V.,
The optical tomographic method in medicine,
ICIP95(I: 622-624).
IEEE DOI 9510
BibRef

Chapter on Medical Applications, CAT, MRI, Ultrasound, Heart Models, Brain Models continues in
Medical Applications -- Brain, Cortex Applications .


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