Add to ORKGA differential phase contrast (DPC) method is validated for in vivo human retinal and choroidal vasculature visualization using high-speed swept-source optical coherence tomography (SS-OCT) at 1060 nm. The vasculature was identified as regions of motion by creating differential phase variance (DPV) tomograms: multiple B-scans were collected of individual slices through the retina and the variance of the phase differences was calculated. DPV captured the small vessels and the meshwork of capillaries associated with the inner retina in en face images over 4 mm^2 in a normal subject. En face DPV images were capable of capturing the microvasculature and regions of motion through the inner retina and choroid
We demonstrate the feasibility of our newly developed phase stabilized high-speed (100 kHz A-scans/s...
Phase variance-based motion contrast imaging is demonstrated using a spectral domain optical coheren...
We present in vivo volumetric images of human retinal micro-circulation using Fourier-domain optical...
A differential phase contrast (DPC) method is validated for in vivo human retinal and choroidal vasc...
Human retinal and choroidal vasculature was visualized by a differential phase-contrast (DPC) method...
We demonstrate an intensity-based motion sensitive method, called differential logarithmic intensity...
We present high-speed Fourier-domain optical coherence tomography (Fd-OCT) with the phase variance b...
Detailed visualization of microvascular changes in the human retina is clinically limited by the cap...
Purpose: Phase-variance optical coherence tomography (PV-OCT) provides volumetric imaging of the re...
PURPOSE. To test the hypothesis that a novel phase-contrast optical coherence tomography (OCT) syste...
We present recent developments from a phase variance based motion contrast method of retinal vascula...
We evaluate methods to visualize human retinal micro-circulation in vivo by standard intensity-based...
Purpose. To demonstrate the application of phase-variance optical coherence tomography (pvOCT) for c...
Purpose. To investigate the retinal and choroidal vascular pattern, structure, and thickness using h...
Purpose. To test the hypothesis that a novel phase-contrast optical coherence tomography (OCT) syste...
We demonstrate the feasibility of our newly developed phase stabilized high-speed (100 kHz A-scans/s...
Phase variance-based motion contrast imaging is demonstrated using a spectral domain optical coheren...
We present in vivo volumetric images of human retinal micro-circulation using Fourier-domain optical...
A differential phase contrast (DPC) method is validated for in vivo human retinal and choroidal vasc...
Human retinal and choroidal vasculature was visualized by a differential phase-contrast (DPC) method...
We demonstrate an intensity-based motion sensitive method, called differential logarithmic intensity...
We present high-speed Fourier-domain optical coherence tomography (Fd-OCT) with the phase variance b...
Detailed visualization of microvascular changes in the human retina is clinically limited by the cap...
Purpose: Phase-variance optical coherence tomography (PV-OCT) provides volumetric imaging of the re...
PURPOSE. To test the hypothesis that a novel phase-contrast optical coherence tomography (OCT) syste...
We present recent developments from a phase variance based motion contrast method of retinal vascula...
We evaluate methods to visualize human retinal micro-circulation in vivo by standard intensity-based...
Purpose. To demonstrate the application of phase-variance optical coherence tomography (pvOCT) for c...
Purpose. To investigate the retinal and choroidal vascular pattern, structure, and thickness using h...
Purpose. To test the hypothesis that a novel phase-contrast optical coherence tomography (OCT) syste...
We demonstrate the feasibility of our newly developed phase stabilized high-speed (100 kHz A-scans/s...
Phase variance-based motion contrast imaging is demonstrated using a spectral domain optical coheren...
We present in vivo volumetric images of human retinal micro-circulation using Fourier-domain optical...