[1] [1] Giloh H, Sedat J W. Fluorescence microscopy: reduced photobleaching of rhodamine and fluorescein protein conjugates by n-propyl gallate［J］. Science,1982,217(4566):1252-1255.

[2] [2] Kreis T E, Geiger B, Schlessinger J. Mobility of microinjected rhodamine actin within living chicken gizzard cells determined by fluorescence photobleaching recovery［J］. Cell,1982,29(3):835-845.

[3] [3] Hoffmann H U, Stockem W, Gruber B. Dynamics of the cytoskeleton in Amoeba proteus: II. Influence of different agents on the spatial organization of microinjected fluorescein-labeled actin［J］. Protoplasma,1984,119:79-92.

[4] [4] Masters B R. Quantitative phase imaging of cells and tissues［J］. Journal of Biomedical Optics,2012,17(2):029901.

[5] [5] Marquet P, Rappaz B, Magistretti P J, et al. Digital holographic microscopy: a noninvasive contrast imaging technique allowing quantitative visualization of living cells with subwavelength axial accuracy［J］. Optics Letter,2005,30(5):468-470.

[6] [6] Kemper B, Langehanenberg P, Von B G. Digital holographic microscopy: A new method for surface analysis and marker-free dynamic life cell imaging［J］. Optik&Photonik,2007,2(2):41-44.

[7] [7] Park Y, Depeursinge C, Popescu G. Quantitative phase imaging in biomedicine［J］. Nature Photonics,2018,12:578-589.

[8] [8] Zheng G, Horstmeyer R, Yang C. Wide-field, high-resolution Fourier ptychographic microscopy［J］. Nature Photonics,2013,7(9):739-745.

[9] [9] Zernike F. Phase contrast, a new method for the microscopic observation of transparent objects［J］. Physica,1942,9(7):686-698.

[10] [10] Zernike F. Phase contrast, a new method for the microscopic observation of transparent objects part Ⅱ［J］. Physica,1942,9(10):974-980.

[11] [11] Nomarski G. Microinterféromètre différentiel à ondes polarisées［J］. Journal de Physique et le Radium,1955,16:S9.

[12] [12] Pluta M. Nomarski's DIC microscopy: a review［C］∥Proceedings Volume 1846, Phase Contrast and Differential Interference Contrast Imaging Techniques and Applications.Warsaw,Poland:SPIE,1994:10.

[13] [13] Li J, Chen Q, Sun J, et al. Multimodal computational microscopy based on transport of intensity equation［J］. Journal of Biomedical Optics,2016,21(12):126003.

[14] [14] Teague M R. Deterministic phase retrieval: a Green's function solution［J］. Journal of the Optical Society of America,1983,73(11):1434-1441.

[15] [15] Barone-Nugent E D, Barty A, Nugent K A. Quantitative phase-amplitude microscopy I: optical microscopy［J］. Journal of Microscopy,2002,206:194-203.

[17] [17] Zuo C, Li J, Sun J, et al. Transport of intensity equation: a tutorial［J］. Optics and Lasers in Engineering,2020,135:106187.

[18] [18] Tian X, Yu W, Meng X, et al. Real-time quantitative phase imaging based on transport of intensity equation with dual simultaneously recorded field of view［J］. Optics Letters,2016,41(7):1427-1430.

[19] [19] Gong Q, Qi W, Jing X, et al. Digital field of view correction combined dual-view transport of intensity equation method for real-time quantitative imaging［J］. Optical Engineering,2018,57(6):063102.

[20] [20] Tsinopoulos S V, Polyzos D. Scattering of He-Ne laser light by an Average-sized red blood cell［J］. Applied Optics,1999,38(25):5499-5510.

[21] [21] Park H, Hong S H, Kim K, et al. Characterizations of individual mouse red blood cells parasitized by Babesia microti using 3-D holographic microscopy［J］. Scientific Reports,2015,5:10827.

[22] [22] Wang Z, Bovik A C, Sheikh H R, et al. Image quality assessment: from error visibility to structural similarity［J］. IEEE Transaction on Image Processing,2004,13(4):600-612.

[23] [23] Paganin D, Barty A, Mcmahon P J, et al. Quantitative phase-amplitude microscopy. III. The effects of noise［J］. Journal of Microscopy,2004,214(1):51-61.