Your search keyword '"Jensen OB"' showing total 2 results

1. Simultaneous dual wavelength eye-tracked ultrahigh resolution retinal and choroidal optical coherence tomography.

Author

Unterhuber A, Považay B, Müller A, Jensen OB, Duelk M, Le T, Petersen PM, Velez C, Esmaeelpour M, Andersen PE, and Drexler W

Subjects

Humans, Image Processing, Computer-Assisted, Time Factors, Choroid physiology, Eye Movements, Retina physiology, Tomography, Optical Coherence methods

Abstract

We demonstrate an optical coherence tomography device that simultaneously combines different novel ultrabroad bandwidth light sources centered in the 800 and 1060 nm regions, operating at 66 kHz depth scan rate, and a confocal laser scanning ophthalmoscope-based eye tracker to permit motion-artifact-free, ultrahigh resolution and high contrast retinal and choroidal imaging. The two wavelengths of the device provide the complementary information needed for diagnosis of subtle retinal changes, while also increasing visibility of deeper-lying layers to image pathologies that include opaque media in the anterior eye segment or eyes with increased choroidal thickness.

Published

2013

2. Fourier domain mode-locked swept source at 1050 nm based on a tapered amplifier.

Author

Marschall S, Klein T, Wieser W, Biedermann BR, Hsu K, Hansen KP, Sumpf B, Hasler KH, Erbert G, Jensen OB, Pedersen C, Huber R, and Andersen PE

Subjects

Cucumis cytology, Humans, Interferometry, Skin cytology, Spectrum Analysis, Amplifiers, Electronic, Fourier Analysis, Light, Tomography, Optical Coherence instrumentation, Tomography, Optical Coherence methods

Abstract

While swept source optical coherence tomography (OCT) in the 1050 nm range is promising for retinal imaging, there are certain challenges. Conventional semiconductor gain media have limited output power, and the performance of high-speed Fourier domain mode-locked (FDML) lasers suffers from chromatic dispersion in standard optical fiber. We developed a novel light source with a tapered amplifier as gain medium, and investigated the FDML performance comparing two fiber delay lines with different dispersion properties. We introduced an additional gain element into the resonator, and thereby achieved stable FDML operation, exploiting the full bandwidth of the tapered amplifier despite high dispersion. The light source operates at a repetition rate of 116 kHz with an effective average output power in excess of 30 mW. With a total sweep range of 70 nm, we achieved an axial resolution of 15 microm in air (approximately 11 microm in tissue) in OCT measurements. As our work shows, tapered amplifiers are suitable gain media for swept sources at 1050 nm with increased output power, while high gain counteracts dispersion effects in an FDML laser.

Published

2010