OCT在小鼠眼底检查中的研究进展

doi:10.3760/cma.j.issn.1674-845X.2014.11.016

Abstract
Figure/Table
References (28)
Related Citation (15)

Download: PDF (792 KB) HTML (1 KB)
Export: BibTeX | EndNote (RIS)

Abstract

Spectral-domain optical coherence tomography （SD-OCT） is a method that provides depth profiles of the fundus that correlate well with histological data based on the measurement of light echo time delay. It has been used in animal experiments in recent years， especially in the study of the retina in mice. It produces a high-quality live image of mice retina in vivo. This review presents the most recent progress on the value of using OCT devices for research on image quality， biometry， retinal blood flow imaging and disease models.

Key words： Tomography,optical coherence Mice Fundus oculi

Received: 03 July 2014

Corresponding Authors: Yuan Songtao， Email： yuansongtao@vip.sina.com

	Service

	E-mail this article
	Add to my bookshelf
	Add to citation manager
	E-mail Alert
	RSS
	Articles by authors
	Sun Xinghong
	Song Qinglu
	Nie Qiao
	Yuan Songtao

Cite this article:

Sun Xinghong,Song Qinglu,Nie Qiao等. Developments in mice fundus examination using optical coherence tomography[J]. Chinese Journal of Optometry Ophthalmology and Visual science, 2014, 16(11): 701-704.

URL:

https://www.cjoovs.com/EN/10.3760/cma.j.issn.1674-845X.2014.11.016 OR https://www.cjoovs.com/EN/Y2014/V16/I11/701

[1]	Fischer MD， Zhour A， Kernstock CJ. Phenotyping of mouse models with OCT[J]. Methods Mol Biol，2013，935：79-85.
[2]	Song Q， Sun X， Nie Q， et al. A novel method of multi-parameter measurements for the mouse retina in vivo using optical coherence tomography[J]. Exp Eye Res，2014，121：66-73.
[3]	Ferguson LR， Balaiya S， Grover S， et al. Modified protocol for in vivo imaging of wild-type mouse retina with customized miniature spectral domain optical coherence tomography （SD-OCT） device[J]. Biol Proced Online，2012，14：1-6.
[4]	Zhi Z， Yin X， Dziennis S， et al. Optical microangiography of retina and choroid and measurement of total retinal blood flow in mice[J]. Biomed Opt Express，2012，3：2976-2986.
[5]	Gabriele ML， Ishikawa H， Schuman JS， et al. Reproducibility of spectral-domain optical coherence tomography total retinal thickness measurements in mice[J]. Invest Ophthalmol Vis Sci， 2010，51：6519-6523.
[6]	Liu T， Hui L， Wang Y， et al. In-vivo investigation of laser-induced choroidal neovascularization in rat using spectral-domain optical coherence tomography （SD-OCT）[J]. Graefes Arch Clin Exp Ophthalmol，2013，251：1293-1301.
[7]	Chauhan BC， Stevens KT， Levesque JM， et al. Longitudinal in vivo imaging of retinal ganglion cells and retinal thickness changes following optic nerve injury in mice[J]. PLoS One，2012，7：e40352.
[8]	Zhour A， Bolz S， Grimm C， et al. In vivo imaging reveals novel aspects of retinal disease progression in Rs1h （-/Y） mice but no therapeutic effect of carbonic anhydrase inhibition[J]. Vet Ophthalmol，2012，15：123-133.
[9]	Schmucker C， Schaeffel F. A paraxial schematic eye model for the growing C57BL/6 mouse[J]. Vision Res，2004，44：1857-1867.
[10]	Fischer MD， Huber G， Beck SC， et al. Noninvasive， in vivo assessment of mouse retinal structure using optical coherence tomography[J]. PLoS One，2009，4：e7507.
[11]	McLenachan S， Chen X， McMenamin PG， et al. Absence of clinical correlates of diabetic retinopathy in the Ins2Akita retina[J]. Clin Experiment Ophthalmol，2013，41：582-592.
[12]	Rakoczy EP， Rahman ISA， Binz N， et al. Characterization of a mouse model of hyperglycemia and retinal neovascularization[J]. Am J Pathol，2010，177：2659-2670.
[13]	Gabriele ML， Ishikawa H， Schuman JS， et al. Optic nerve crush mice followed longitudinally with spectral domain optical coherence tomography[J]. Invest Ophthalmol Vis Sci，2011，52：2250-2254.
[14]	Pennesi ME， Michaels KV， Magee SS， et al. Long-term characterization of retinal degeneration in rd1 and rd10 mice using spectral domain optical coherence tomography[J]. Invest Ophthalmol Vis Sci，2012，53：4644-4656.
[15]	Alex AF， Heiduschka P， Eter N. Retinal fundus imaging in mouse models of retinal diseases[J]. Methods Mol Biol，2013， 935：41-67.
[16]	Sham CW， Chan AM， Kwong JMK， et al. Neuronal Programmed cell death-1 ligand expression regulates retinal ganglion cell number in neonatal and adult mice[J]. J Neuroophthalmol，2012， 32：227-237.
[17]	Mohan K， Harper MM， Kecova H， et al. Characterization of structure and function of the mouse retina using pattern electroretinography， pupil light reflex， and optical coherence tomography[J]. Vet Ophthalmol，2012，15：94-104.
[18]	Ruiz A， Mark M， Jacobs H， et al. Retinoid content， visual responses， and ocular morphology are compromised in the retinas of mice lacking the retinolcbinding protein receptor， STRA6[J]. Invest Ophthalmol Vis Sci，2012，53：3027-3039.
[19]	Yang X， Chou TH， Ruggeri M， et al. A new mouse model of inducible， chronic retinal ganglion cell dysfunction not associated with cell death[J]. Invest Ophthalmol Vis Sci，2013，54：1898-1904.
[20]	Hoerster R， Muether PS， Vierkotten S， et al. In-vivo and ex-vivo characterization of laser-induced choroidal neovascularization variability in mice[J]. Graefes Arch Clin Exp Ophthalmol，2012，250：1579-1586.
[21]	Yazdanfar S， Rollins AM， Izatt JA. In vivo imaging of human retinal flow dynamics by color Doppler optical coherence tomography[J]. Arch Ophthalmol，2003，121：235-239.
[22]	Liu JJ， Grulkowski I， Kraus MF， et al. In vivo imaging of the rodent eye with swept source/Fourier domain OCT[J]. Biomed Opt Express，2013，4：351-363.
[23]	Knott EJ， Sheets KG， Zhou Y， et al. Spatial correlation of mouse photoreceptor-RPE thickness between SD-OCT and histology[J]. Exp Eye Res，2011，92：155-160.
[24]	Nakano N， Ikeda HO， Hangai M， et al. Longitudinal and simultaneous imaging of retinal ganglion cells and inner retinal layers in a mouse model of glaucoma induced by N-methyl-D-aspartate[J]. Invest Ophthalmol Vis Sci，2011，52：8754-8762.
[25]	Yang Q， Cho KS， Chen H， et al. Microbead-induced ocular hypertensive mouse model for screening and testing of aqueous production suppressants for glaucoma[J]. Invest Ophthalmol Vis Sci，2012，53：3733-3741.
[26]	Cebulla CM， Ruggeri M， Murray TG， et al. Spectral domain optical coherence tomography in a murine retinal detachment model[J]. Exp Eye Res，2010，90：521-527.
[27]	Guo C， Otani A， Oishi A， et al. Knockout of ccr2 alleviates photoreceptor cell death in a model of retinitis pigmentosa[J]. Exp Eye Res，2012，104：39-47.
[28]	Larina IV， Syed SH， Sudheendran N， et al. Optical coherence tomography for live phenotypic analysis of embryonic ocular structures in mouse models[J]. J Biomed Opt，2012，17：081410-081411.