The adult zebrafish retina: In vivo optical sectioning with Confocal Scanning Laser Ophthalmoscopy and Spectral-Domain Optical Coherence Tomography.

Non-invasive imaging is an invaluable diagnostic tool in ophthalmology. Two imaging devices, the scanning laser ophthalmoscope (SLO) and spectral domain optical coherence tomography (SDOCT), emerged from the clinical realm to provide research scientists with a real-time view of ocular morphology in living animals. We utilized these two independent imaging modalities in a complementary manner to perform in vivo optical sectioning of the adult zebrafish retina. Due to the very high optical power of the zebrafish lens, the confocal depth of field is narrow, allowing for detailed en face views of specific retinal layers, including the cone mosaic. Moreover, we demonstrate that both native reflectance, as well as fluorescent features observed by SLO, can be combined with axial in-depth information obtained by SDOCT. These imaging approaches can be used to screen for ocular phenotypes and monitor retinal pathology in a non-invasive manner.

The Feasibility of Spectral-Domain Optical Coherence Tomography Grading of Anterior Chamber Inflammation in a Rabbit Model of Anterior Uveitis.

PURPOSE: To determine the feasibility and accuracy of spectral-domain optical coherence tomography (SD-OCT) based grading of anterior chamber cell, using aqueous sampling as a standard, in a rabbit model of anterior uveitis. METHODS: Adult Dutch-belted rabbits were preimmunized with M. tuberculosis (Tb) H37RA antigen, 1 week prior to induction of anterior uveitis with an intracameral injection of Tb antigen. The anterior chamber was imaged with SD-OCT, followed by a slit lamp examination. Two independent, trained graders recorded their estimate of anterior chamber cell count using the Standardization of Uveitis Nomenclature (SUN) scores for each eye prior to performing an anterior chamber tap to determine the aqueous cell density using a hemocytometer. Using the aqueous cell density as a standard, correlation with SD-OCT counts were compared to those with SUN scores. RESULTS: Overall, SD-OCT correlated well with the hemocytometer counts (Spearman coefficient = 0.53, P < 0.001) compared with SUN grading and hemocytometer counts (Spearman coefficient = 0.02, P = 0.88). The correlation improved to 0.65 (P < 0.001) when we excluded eyes with corneal thickness ≥ 470 µm. Eyes with corneal thickness ≥ 470 µm exhibited the greatest degree of ocular inflammation and corneal opacity. CONCLUSIONS: In our rabbit model, SD-OCT grading of anterior chamber cell correlated significantly better with aqueous cell counts, compared to traditional slit lamp grading. Spectral-domain optical coherence tomography grading of anterior chamber cell may be a good alternative to SUN grading. Although SUN grading remains the clinical gold standard, alternative quantitative methods to assess ocular inflammation could provide insight into disease mechanism and aid in measuring treatment response.

Retinal regeneration following OCT-guided laser injury in zebrafish.

PURPOSE: Establish a focal injury/regeneration model in zebrafish using laser photocoagulation guided by optical coherence tomography (OCT). METHODS: Adult zebrafish were imaged by OCT and confocal scanning laser ophthalmoscopy (cSLO) in room air through a contact lens. Using a beam combiner, 532-nm laser photocoagulation was applied using the OCT C-scan image for targeting. Laser spots of 42 to 47 mW were delivered to the retina. At multiple intervals post injury, fish were imaged using both OCT and cSLO to follow the progression of each lesion. Histologic sections and TUNEL staining were performed to monitor the injury response. RESULTS: Round lesions (26057 ± 621 µm(2)) localized to the outer retina were successfully applied. Laser application was visualized by real-time OCT and lesions were detectable by both OCT and cSLO in vivo. Lesion size increased 1 day post lesion then decreased in size. Histologic sections showed focal areas of damage localized primarily to the outer retina. By 3 weeks, the damaged areas had regenerated and a fully laminated structure was re-established. However, subtle changes can still be detected by OCT, cSLO imaging, and histology. Infrared darkfield imaging was more sensitive than OCT at revealing subtle changes in regenerated areas. CONCLUSIONS: Optical coherence tomography-guided laser photocoagulation is a useful tool for inducing localized lesions and studying retinal regeneration in zebrafish. This novel method will allow us to characterize the cellular and molecular changes that take place at the interface between normal and damaged tissue. Regeneration can be observed using high-resolution OCT and cSLO imaging in vivo.