[1] LIANG J ZH, WILLIAMS D R, MILLER D T. Supernormal vision and high-resolution retinal imaging through adaptive optics[J]. Journal of the Optical Society of America A, 14, 2884-2892(1997).

[2] ROORDA A, WILLIAMS D R. The arrangement of the three cone classes in the living human eye[J]. Nature, 397, 520-522(1999).

[3] JONNAL R S, RHA J, ZHANG Y, et al. In vivo functional imaging of human cone photoreceptors[J]. Optics Express, 15, 16141-16160(2007).

[4] LI K Y, ROORDA A. Automated identification of cone photoreceptors in adaptive optics retinal images[J]. Journal of the Optical Society of America A, 24, 1358-1363(2007).

[5] DUBRA A, SULAI Y, NORRIS J L, et al. Noninvasive imaging of the human rod photoreceptor mosaic using a confocal adaptive optics scanning ophthalmoscope[J]. Biomedical Optics Express, 2, 1864-1876(2011).

[6] CHUI T Y P, VANNASDALE D A, BURNS S A. The use of forward scatter to improve retinal vascular imaging with an adaptive optics scanning laser ophthalmoscope[J]. Biomedical Optics Express, 3, 2537-2549(2012).

[7] ZAYIT-SOUDRY S, DUNCAN J L, SYED R, et al. Cone structure imaged with adaptive optics scanning laser ophthalmoscopy in eyes with nonneovascular age-related macular degeneration[J]. Investigative Ophthalmology & Visual Science, 54, 7498-7509(2013).

[8] QUERQUES G, KAMAMI-LEVY C, GEORGES A, et al. Appearance of regressing drusen on adaptive optics in age-related macular degeneration[J]. Ophthalmology, 121, 611-612(2014).

[9] PAQUES M, BROLLY A, BENESTY J, et al. Venous nicking without arteriovenous contact: the role of the arteriolar microenvironment in arteriovenous nickings[J]. JAMA Ophthalmology, 133, 947-950(2015).

[10] MARTIN J A, ROORDA A. Direct and noninvasive assessment of parafoveal capillary leukocyte velocity[J]. Ophthalmology, 112, 2219-2224(2005).

[11] [11] HAN G Q. High contrast imaging study of retinal capillaries in human eyes[D]. Beijing: Changchun Institute of Optics, Fine Mechanics Physics University of Chinse Academy of Sciences, 2018: 2830. (in Chinese)

[12] FABER D J, AALDERS M C G, MIK E G, et al. Oxygen saturation-dependent absorption and scattering of blood[J]. Physical Review Letters, 93, 028102(2004).

[13] REINHOLZ F, ASHMAN R A, EIKELBOOM R H. Simultaneous three wavelength imaging with a scanning laser ophthalmoscope[J]. Cytometry Part A, 37, 165-170(1999).

[14] GRIEVE K, TIRUVEEDHULA P, ZHANG Y H, et al. Multi-wavelength imaging with the adaptive optics scanning laser ophthalmoscope[J]. Optics Express, 14, 12230-12242(2006).

[15] [15] NEWTON S I. Opticks, , A Treatise of the Reflections, Refractions, in Flections & Colours of Light[M]. 4th ed. London: G. Bell & Sons, Ltd. , 1931.

[16] WALD G, GRIFFIN D R. The change in refractive power of the human eye in dim and bright light[J]. Journal of the Optical Society of America, 37, 321-336(1947).

[17] THIBOS L N, BRADLEY A, STILL D L, et al. Theory and measurement of ocular chromatic aberration[J]. Vision Research, 30, 33-49(1990).

[18] FERNÁNDEZ E J, ARTAL P. Ocular aberrations up to the infrared range: from 632.8 to 1070 nm[J]. Optics Express, 16, 21199-21208(2008).

[19] RUCKER F J, OSORIO D. The effects of longitudinal chromatic aberration and a shift in the peak of the middle-wavelength sensitive cone fundamental on cone contrast[J]. Vision Research, 48, 1929-1939(2008).

[20] NAKAJIMA M, HIRAOKA T, HIROHARA Y, et al. Verification of the lack of correlation between age and longitudinal chromatic aberrations of the human eye from the visible to the infrared[J]. Biomedical Optics Express, 6, 2676-2694(2015).

[21] VINAS M, DORRONSORO C, CORTES D, et al. Longitudinal chromatic aberration of the human eye in the visible and near infrared from wavefront sensing, double-pass and psychophysics[J]. Biomedical Optics Express, 6, 948-962(2015).

[22] VINAS M, DORRONSORO C, GARZÓN N, et al. In vivo subjective and objective longitudinal chromatic aberration after bilateral implantation of the same design of hydrophobic and hydrophilic intraocular lenses[J]. Journal of Cataract & Refractive Surgery, 41, 2115-2124(2015).

[23] CHONG S P, ZHANG T W, KHO A, et al. Ultrahigh resolution retinal imaging by visible light OCT with longitudinal achromatization[J]. Biomedical Optics Express, 9, 1477-1491(2018).

[24] ZAWADZKI R J, CENSE B, ZHANG Y, et al. Ultrahigh-resolution optical coherence tomography with monochromatic and chromatic aberration correction[J]. Optics Express, 16, 8126-8143(2008).

[25] DUBRA A, SULAI Y. Reflective afocal broadband adaptive optics scanning ophthalmoscope[J]. Biomedical Optics Express, 2, 1757-1768(2011).

[26] JIANG X Y, KUCHENBECKER J A, TOUCH P, et al. Measuring and compensating for ocular longitudinal chromatic aberration[J]. Optica, 6, 981-990(2019).

[27] ZHENG X L, LIU R X, XIA M L, et al. Temporal properties study of ocular wave aberrations with high frequency sampling[J]. Chinese Optics, 34, 0733001(2014).

[28] MORGAN J I W, HUNTER J J, MASELLA B, et al. Light-induced retinal changes observed with high-resolution autofluorescence imaging of the retinal pigment epithelium[J]. Investigative Ophthalmology & Visual Science, 49, 3715-3729(2008).

[29] DELORI F C, WEBB R H, SLINEY D H. Maximum permissible exposures for ocular safety (ANSI 2000), with emphasis on ophthalmic devices[J]. Journal of the Optical Society of America A, 24, 1250-1265(2007).

[30] [30] Laser Institute of America. ANSI Z136.12014 American national stard f safe use of lasers[S]. lo: American National Stards Institute, 2007: 2229.

[31] LI CH, XIA M L, MU Q Q, et al. High-precision open-loop adaptive optics system based on LC-SLM[J]. Optics Express, 17, 10774-10781(2009).

[32] YANG L B, HU L F, LI D Y, et al. Determining the imaging plane of a retinal capillary layer in adaptive optical imaging[J]. Chinese Physics B, 25, 094219(2016).

[33] BURNS S A, ELSNER A E, CHUI T Y, et al. In vivo adaptive optics microvascular imaging in diabetic patients without clinically severe diabetic retinopathy[J]. Biomedical Optics Express, 5, 961-974(2014).