Abstract
We present the first, most compact, ultrahigh-resolution, high-speed, distal scanning optical coherence tomography (OCT) endoscope operating at 800 nm. Achieving high speed imaging while maintaining an ultrahigh axial resolution is one of the most significant challenges with endoscopic OCT at 800 nm. Maintaining an ultrahigh axial resolution requires preservation of the broad spectral bandwidth of the light source throughout the OCT system. To overcome this critical limitation we implemented a distal scanning endoscope with diffractive optics to minimize loss in spectral throughput. In this paper, we employed a customized miniature 900 µm diameter DC micromotor fitted with a micro reflector to scan the imaging beam. We integrated a customized diffractive microlens into the imaging optics to reduce chromatic focal shift over the broad spectral bandwidth of the Ti:Sapphire laser of an approximately 150 nm 3dB bandwidth, affording a measured axial resolution of 2.4 µm (in air). The imaging capability of this high-speed, ultrahigh-resolution distal scanning endoscope was validated by performing 3D volumetric imaging of mouse colon in vivo at 50 frames-per-second (limited only by the A-scan rate of linear CCD array in the spectral-domain OCT system and sampling requirements). The results demonstrated that fine microstructures of colon could be clearly visualized, including the boundary between the absorptive cell layer and colonic mucosa as well the crypt patterns. Furthermore, this endoscope was employed to visualize morphological changes in an enterotoxigenic Bacteriodes fragilis (ETBF) induced colon tumor model. We present the results of our feasibility studies and suggest the potential of this system for visualizing time dependent morphological changes associated with tumorigenesis on murine models in vivo.
Highlights
In vitro endoscopic optical coherence tomography (OCT) was first demonstrated 20 years ago using a single-mode optical fiber and a gradient-index (GRIN) lens to deliver and collect backscattered light to and from the sample [1]
Most compact, ultrahigh-resolution, high-speed, distal scanning optical coherence tomography (OCT) endoscope operating at 800 nm
The imaging capability of this high-speed, ultrahigh-resolution distal scanning endoscope was validated by performing 3D volumetric imaging of mouse colon in vivo at 50 frames-per-second
Summary
In vitro endoscopic OCT was first demonstrated 20 years ago using a single-mode optical fiber and a gradient-index (GRIN) lens to deliver and collect backscattered light to and from the sample [1]. Most endoscopic OCT systems have been implemented at 1300 nm, with the best achievable axial resolution limited to 5-20 μm (in air) [9,10,11]. Success has been limited due to the engineering challenges for OCT endoscopes at this wavelength range. Two major challenges are: 1) correcting chromatic aberration in the imaging micro-optics for the broad spectral range and 2) implementing a scanning mechanism for high-speed imaging. Our group recently addressed the first challenge by engineering a diffractive endoscope [15, 16]. We demonstrated proof-of-concept that off-the-shelf miniature diffractive optics is able to partially compensate chromatic aberration. In this paper we present new customized diffractive optics capable of compensating the chromatic aberration throughout the entire spectral bandwidth of the light source
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