Constant linear velocity spiral scanning for real time 4D OCT with visualization in virtual reality (Conference Presentation)

J. Li, O. Carrasco-Zevallos, Moseph Jackson-Atogi, M. Draelos, C. Viehland, B. Keller, R. McNabb, A. Kuo, J. Izatt
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Abstract

High speed optical coherence tomography (OCT) systems with A-scan rates greater than 100 kHz allow for 4D visualizations in applications such as intraoperative OCT. However, traditional triangle or sawtooth waveforms used to drive galvanometer scanners often have frequency content that exceeds the bandwidth of the scanners, leading to distorted scans. Sinusoidal waveforms used to drive resonant scanners also lead to distorted scans due to the nonlinear scan velocity. Additionally, with raster scan patterns, the scanner needs time to stop and reverse direction in between B-scans, leading to significant acquisition dead time. Continuous scan patterns such as constant frequency spiral scanning or Lissajous scanning no longer have acquisition dead times, but suffer from non-uniform sampling across the imaging plane. We previously introduced constant linear velocity (CLV) spiral scanning as a novel scan pattern to maximize the data acquisition efficiency of high speed OCT systems. While this continuous scan pattern has no acquisition dead time and produces more uniform sampling compared to raster scanning, it required significant processing time. We introduce a processing pipeline implemented using CUDA in C++, which drastically reduces the amount of processing time needed, allowing real time visualization of 4D OCT data. To demonstrate its potential utility, we used CLV scanning with a 100 kHz swept-source OCT system to image retinas of enucleated porcine eyes undergoing mock ophthalmic surgery movements. Additionally, we rendered these volumes in virtual reality (VR) in real time, allowing for interactive manipulation and sectioning.
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恒线速度螺旋扫描实时四维OCT与虚拟现实可视化(会议报告)
a扫描速率大于100 kHz的高速光学相干断层扫描(OCT)系统允许在术中OCT等应用中实现4D可视化。然而,用于驱动振镜扫描仪的传统三角形或锯齿波形通常具有超过扫描仪带宽的频率内容,导致扫描失真。由于扫描速度的非线性,用于驱动共振扫描仪的正弦波也会导致扫描畸变。此外,对于光栅扫描模式,扫描仪需要时间在b扫描之间停止和反转方向,导致显著的采集死区时间。连续扫描模式,如恒频螺旋扫描或Lissajous扫描不再有采集死时间,但在成像平面上受到不均匀采样的影响。我们之前介绍了恒线速度(CLV)螺旋扫描作为一种新的扫描模式,以最大限度地提高高速OCT系统的数据采集效率。虽然与光栅扫描相比,这种连续扫描模式没有采集死区时间,并且产生更均匀的采样,但它需要大量的处理时间。我们介绍了一个使用CUDA在c++中实现的处理管道,这大大减少了所需的处理时间,允许4D OCT数据的实时可视化。为了证明其潜在的实用性,我们使用CLV扫描和100 kHz扫描源OCT系统来对正在进行模拟眼科手术运动的去核猪眼睛的视网膜进行成像。此外,我们在虚拟现实(VR)中实时渲染这些体量,允许交互式操作和切片。
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