[1] Deng L Z, Wei B, He P et al. A Geant4-based Monte Carlo study of a benchtop multi-pinhole X-ray fluorescence computed tomography imaging[J]. International Journal of Nanomedicine, 13, 7207-7216(2018).
[3] Takeda T, Wu J, Lwin T T et al. X-ray fluorescent CT imaging of cerebral uptake of stable-iodine perfusion agent iodoamphetamine analog IMP in mice[J]. Journal of Synchrotron Radiation, 16, 57-62(2009).
[4] Yang Q, Deng B, Lü W W et al. Nondestructive imaging of elements distribution in biomedical samples by X-ray fluorescence computed tomography[J]. Spectroscopy and Spectral Analysis, 31, 2753-2757(2011).
[6] Deng B, Yang Q, Du G H et al. The progress of X-ray fluorescence computed tomography at SSRF[J]. Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions With Materials and Atoms, 305, 5-8(2013).
[7] Fu G, Meng L J, Eng P et al. Experimental demonstration of novel imaging geometries for X-ray fluorescence computed tomography[J]. Medical Physics, 40, 061903(2013).
[8] Li L, Zhang S Y, Li R Z et al. Full-field fan-beam X-ray fluorescence computed tomography with a conventional X-ray tube and photon-counting detectors for fast nanoparticle bioimaging[J]. Optical Engineering, 56, 043106(2017).
[10] Ahmed M F, Yasar S, Cho S H. A Monte Carlo model of a benchtop X-ray fluorescence computed tomography system and its application to validate a deconvolution-based X-ray fluorescence signal extraction method[J]. IEEE Transactions on Medical Imaging, 37, 2483-2492(2018).
[11] Ma Z Z, Jiang S H, Luo B B et al. Influence of detection angle on the quality of pencil-beam X-ray fluorescence CT[J]. Laser & Optoelectronics Progress, 57, 161103(2020).
[12] Ji D J, Qu G R, Hu C H et al. Contrast enhancement method based on synchrotron radiation CT image reconstruction[J]. Laser & Optoelectronics Progress, 57, 221024(2020).
[13] Chen L, Xu J, Li W J et al. Experimental research of monochromatic X-ray microscopy[J]. High Power Laser and Particle Beams, 32, 25-30(2020).
[14] Larsson J C, Vogt C, Vågberg W et al. High-spatial-resolution X-ray fluorescence tomography with spectrally matched nanoparticles[J]. Physics in Medicine & Biology, 63, 164001(2018).
[15] Noo F, Clackdoyle R, Mennessier C et al. Analytic method based on identification of ellipse parameters for scanner calibration in cone-beam tomography[J]. Physics in Medicine and Biology, 45, 3489-3508(2000).
[16] Khoury R, Bonissent A, Clémens J C et al. A geometrical calibration method for the PIXSCAN micro-CT scanner[J]. Journal of Instrumentation, 4, P07016(2009).
[17] Wein W, Ladikos A, Baumgartner A. Self-calibration of geometric and radiometric parameters for cone-beam computed tomography. [C]//11th International Meeting on Fully Three-Dimensonal Image Reconstruction in Radiology and Nuclear Medicine, October 27, 2011, Munchen, Germany. Munchen: hgpu. org, 2, 1-4(2011).
[18] Kyriakou Y, Lapp R M, Hillebrand L et al. Simultaneous misalignment correction for approximate circular cone-beam computed tomography[J]. Physics in Medicine and Biology, 53, 6267-6289(2008).
[19] Kingston A M, Sakellariou A, Sheppard A P et al. An auto-focus method for generating sharp 3D tomographic images[J]. Proceedings of SPIE, 7804, 78040J(2010).
[20] Chen M Y, Xi Y, Cong W X et al. X-ray CT geometrical calibration via locally linear embedding[J]. Journal of X-ray Science And Technology, 24, 241-256(2016).
[21] Roweis S T, Saul L K. Nonlinear dimensionality reduction by locally linear embedding[J]. Science, 290, 2323-2326(2000).
[22] Cheong S K, Jones B L, Siddiqi A K et al. X-ray fluorescence computed tomography (XFCT) imaging of gold nanoparticle-loaded objects using 110 kVp x-rays[J]. Physics in Medicine and Biology, 55, 647-662(2010).
