Abstract

Small animal models play an irreplaceable role in the study of ocular diseases, but the need for structural information at different stages of a disease leads to time-consuming histology, inefficient use of animals, and large variability. Our long-term objective is to develop a high throughput testing facility that provides quantitative, non-invasive, high resolution, structural imaging of animal models of ophthalmic diseases. By high throughput we mean the acquisition of images and the extraction of desired information as efficiently and rapidly as possible, thereby maximizing the scientific yield of the facility. The facility will use a novel investigator-controlled animal alignment system that allows rapid selection of the imaged retinal areas together with ultra-high resolution spectral-domain OCT (optical coherence tomography) to provide 3D retinal images. To evaluate disease-induced damage and progression and to monitor treatment effects, the cell layers of the retina will be quantified using 3D segmentation of the OCT images. This project promises to significantly reduce the number of animals needed to achieve many research objectives. Collaborating scientists using small animal models for their research will provide valuable feedback to enhance the facility's productivity.
The specific aims of the proposed research are to: 1. Design and build a novel animal alignment system together with a slit lamp biomicroscope based ultra-high resolution spectral-domain OCT and robust interchangeable optical probes for high throughput imaging of the anterior segment and retina of small animals. The animal alignment system that allows rapid selection of the imaging areas of interest. 2. Develop 3-D segmentation algorithms for (1) automatic segmentation of the RNFL of the retina and (2) automatic segmentation of the boundaries of retinal tumor. These algorithms will provide quantitative information (e.g., RNFL thickness maps and tumor volume) about the change that occurs at different stages of a disease. 3. Apply the system and algorithms to studying animal models of ocular diseases. We will first focus on three rodent models: (1) we will image changes in retinal structure in a rat glaucoma model, including changes of optic nerve and RNFL thickness at different stages of glaucoma damage; (2) We will quantitatively evaluate progression and treatment effect in a mouse model of retinoblastoma; (3) We will study the status and prognosis of a murine model of corneal transplant.

Public Health Relevance

The proposed research will provide a powerful tool that will greatly accelerate the research on ocular diseases like glaucoma, retinoblastoma, and corneal transplant. It promises not only to reduce the number of animals required but also possible longitudinal studies that are currently impossible to conduct. ? ? ?

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21EB008800-01
Application #
7512280
Study Section
Special Emphasis Panel (ZRG1-SBIB-J (90))
Program Officer
Zhang, Yantian
Project Start
2008-09-05
Project End
2008-10-31
Budget Start
2008-09-05
Budget End
2008-10-31
Support Year
1
Fiscal Year
2008
Total Cost
$26,371
Indirect Cost

  Institution

Name
University of Miami School of Medicine
Department
Ophthalmology
Type
Schools of Medicine
DUNS #
052780918
City
Coral Gables
State
FL
Country
United States
Zip Code
33146

  Publications

Ma, Teng; Zhang, Xiangyang; Chiu, Chi Tat et al. (2014) Systematic study of high-frequency ultrasonic transducer design for laser-scanning photoacoustic ophthalmoscopy. J Biomed Opt 19:16015
Zhang, Xiangyang; Zhang, Hao F; Jiao, Shuliang (2012) Optical coherence photoacoustic microscopy: accomplishing optical coherence tomography and photoacoustic microscopy with a single light source. J Biomed Opt 17:030502
Jiang, Minshan; Wu, Pei-Chang; Fini, M Elizabeth et al. (2012) Single-shot dimension measurements of the mouse eye using SD-OCT. Ophthalmic Surg Lasers Imaging 43:252-6
Zhang, Xiangyang; Zhang, Hao F; Puliafito, Carmen A et al. (2011) Simultaneous in vivo imaging of melanin and lipofuscin in the retina with photoacoustic ophthalmoscopy and autofluorescence imaging. J Biomed Opt 16:080504
Zhang, Hao F; Puliafito, Carmen A; Jiao, Shuliang (2011) Photoacoustic ophthalmoscopy for in vivo retinal imaging: current status and prospects. Ophthalmic Surg Lasers Imaging 42 Suppl:S106-15
Zhang, Xiangyang; Hu, Jianming; Knighton, Robert W et al. (2011) Dual-band spectral-domain optical coherence tomography for in vivo imaging the spectral contrasts of the retinal nerve fiber layer. Opt Express 19:19653-9
Jiao, Shuliang; Jiang, Minshan; Hu, Jianming et al. (2010) Photoacoustic ophthalmoscopy for in vivo retinal imaging. Opt Express 18:3967-72
Ruggeri, Marco; Major Jr, James C; McKeown, Craig et al. (2010) Retinal structure of birds of prey revealed by ultra-high resolution spectral-domain optical coherence tomography. Invest Ophthalmol Vis Sci 51:5789-95
Jiang, Minshan; Zhang, Xiangyang; Puliafito, Carmen A et al. (2010) Adaptive optics photoacoustic microscopy. Opt Express 18:21770-6
Zhang, Xiangyang; Jiang, Minshan; Fawzi, Amani A et al. (2010) Simultaneous dual molecular contrasts provided by the absorbed photons in photoacoustic microscopy. Opt Lett 35:4018-20

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