We present here a study of blood oxygen saturation (sO2) in the parafoveal region from healthy subjects using visible light optical coherence tomography. Sixteen eyes of the normal subjects were analyzed. The sO2 of arterioles was significantly higher than the venules’ (92.1 ± 7.1 (vol %) for arterioles, 48.4 ± 5.0 (vol %) for venules, p<0.001), indicating that VIS-OCT can be a powerful tool to investigate the retinal sO2 in parafoveal micro-vessels in pathological conditions.
To evaluate the clinical utility of Visible and near infrared optical coherence tomography (vnOCT) for glaucoma early detection, A total of 55 eyes from three groups of subjects (normal subjects, glaucoma suspects, glaucoma patients) were scanned by a custom-designed vnOCT device and Zeiss Spectralis OCT. The peripapillary retinal nerve fiber layer reflectivity in visible light OCT and the ratio between visible and NIR channel is more sensitive in separating suspect eyes from normal ones than clinical OCT thickness measurements. It could be a useful metric in early detection of glaucoma upon further longitudinally validation.
Although vis-OCT oximetry has been successfully demonstrated in vivo in human retina, it is so far limited on large vessels. To precisely locate the small vessels in depth dimension, OCTA is the natural method since it can effectively enhance the vessel contrast. In this paper, we demonstrate the first visible OCTA image in human retina, the small blood vessel can be located with high fidelity by using both the structural and angiographic contrasts. This technical advance lays a foundation for the absolute sO2 calculation in small vessels in human retina in order to assess local oxygen extraction and metabolism.
The retina, as part of the central nervous system, has distinct anatomical and structural properties for its visual function. Light scattering spectroscopy, while widely used for tissue structural characterization and disease diagnosis, has been relatively unexplored in the living retina. Recently, we have developed a fiber-based visible and near-infrared optical coherence tomography system (vnOCT) for in vivo retinal imaging, to uniquely measure a spectroscopic marker (VN ratio) sensitive to nanoscale pathological changes. In the present study, we applied vnOCT in an animal model of glaucoma (dexamethasone-induced ocular hypertension mouse) and tested the capabilities of four optical markers, VN ratio, peripapillary retinal nerve fiber layer (RNFL) thickness, total retinal blood flow, and hemoglobin oxygen saturation (sO2), for the detection of retinal ganglion cell (RGC) damage in association with ocular hypertension. We found that RNFL-RGC VN ratio and arteriovenous (A-V) sO2 are capable of detecting early retinal alteration in ocular hypertensive eyes, preceding measurable change of RNFL thickness. This study suggests a potential clinical application of vnOCT in early detection of glaucoma.
Despite the recent development of advanced ophthalmic imaging techniques, volumetric fluorescence angiography (vFA) over a large field of view is still lacking. Fundus photography techniques have significant limitations due to the lack of 3D imaging capability. Scanning laser ophthalmoscopy (SLO) and confocal SLO (cSLO) use confocal gating to remove diffused light, resulting in crisper image quality. However, the volumetric imaging of SLO requires to compile z stacks, which can be challenging and time-consuming. Adaptive optics SLO (AOSLO) allows diffraction-limited resolution in both axial and lateral resolution. This technique is limited however, by its small field of view (FOV) and also the necessity of z stacks for volumetric imaging. To fill the technical void of vFA over a large field of view (FOV), we developed a novel retinal imaging modality called oblique scanning laser ophthalmoscopy (oSLO) for in vivo volumetric fluorescence retinal imaging. By using oblique illumination and detection, oSLO essentially allows “OCT-like” cross-sectional images contributed solely by the fluorescent contrast, without the need for z stacking. We will demonstrate 3D vFA over a 30˚x30˚ FOV in vivo in mouse retina. We will further report a high-speed oSLO in imaging capillary hemodynamics. The new capability allows the calculation of capillary hematocrit and blood speed in 3D, which can be potentially valuable in diabetic retinopathy and macular degeneration.
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