Abstract
We present a new development of ultrahigh speed spectral domain optical coherence tomography (SDOCT) for human retinal imaging at 850 nm central wavelength by employing two high-speed line scan CMOS cameras, each running at 250 kHz. Through precisely controlling the recording and reading time periods of the two cameras, the SDOCT system realizes an imaging speed at 500,000 A-lines per second, while maintaining both high axial resolution (~8 μm) and acceptable depth ranging (~2.5 mm). With this system, we propose two scanning protocols for human retinal imaging. The first is aimed to achieve isotropic dense sampling and fast scanning speed, enabling a 3D imaging within 0.72 sec for a region covering 4x4 mm2. In this case, the B-frame rate is 700 Hz and the isotropic dense sampling is 500 A-lines along both the fast and slow axes. This scanning protocol minimizes the motion artifacts, thus making it possible to perform two directional averaging so that the signal to noise ratio of the system is enhanced while the degradation of its resolution is minimized. The second protocol is designed to scan the retina in a large field of view, in which 1200 A-lines are captured along both the fast and slow axes, covering 10 mm2, to provide overall information about the retinal status. Because of relatively long imaging time (4 seconds for a 3D scan), the motion artifact is inevitable, making it difficult to interpret the 3D data set, particularly in a way of depth-resolved en-face fundus images. To mitigate this difficulty, we propose to use the relatively high reflecting retinal pigmented epithelium layer as the reference to flatten the original 3D data set along both the fast and slow axes. We show that the proposed system delivers superb performance for human retina imaging.
Highlights
Optical coherence tomography (OCT) [1] is known to have the capability of providing depth resolved information of biological tissue with a spatial resolution at micrometer scale [2,3]
The first generation (1g) is the time domain OCT (TDOCT) [4] that is capable of only up to ~8,000 A-lines per second, which is mainly restricted by the employment of a mechanically scanning mirror in the reference arm to provide depth-resolved axial information of the sample
The schematic of our ultrahigh speed spectral domain optical coherence tomography (SDOCT) system was illustrated in Fig. 1, in which a superluminescent diode was utilized as the light source, which provided a spectral bandwidth of 45 nm centered on 842 nm, resulting in a theoretical ~7 μm axial resolution in air
Summary
Optical coherence tomography (OCT) [1] is known to have the capability of providing depth resolved information of biological tissue with a spatial resolution at micrometer scale [2,3]. The first generation (1g) is the time domain OCT (TDOCT) [4] that is capable of only up to ~8,000 A-lines per second (with the most of systems having up to 2 kHz A-scan rate), which is mainly restricted by the employment of a mechanically scanning mirror in the reference arm to provide depth-resolved axial information of the sample With this imaging speed, it is sometimes difficult for TDOCT to achieve 3D scanning for in vivo imaging applications. The fastest retinal FDOCT system, which can maintain both the high axial resolution (~7 μm) and the ultrafast imaging speed, is reported in [34], in which the authors developed an 1-μm SSOCT system running at ~400 kilo-A-lines per second, realized by combining FDML with a multi-spots detection strategy This reported system is possible to further improve its imaging speed to 684 kHz [42]. To the best of our knowledge, this is the fastest retinal SDOCT system reported so far with a high axial resolution of less than 10 μm in air
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
