Cellular-resolution, extended depth of focus optical coherence tomography catheter toward in vivo cardiovascular imaging (Conference Presentation)

Optical coherence tomography (OCT) has been a useful clinical tool for diagnosing coronary artery disease through a flexible catheter, but its full promise relies on resolving cellular and sub-cellular structures in vivo. Previously, visualizing cellular structures through an imaging catheter is not possible due to limited depth of focus (DOF) of a tightly focused Gaussian beam: typically, a Gaussian beam with 2-3 μm resolution has a DOF within 100 μm, which is not sufficient for in vivo catheter imaging. Therefore, we developed a self-imaging wavefront division optical system that generates a coaxially-focused multimode (CAFM) beam with a DOF that is approximately one order of magnitude longer than that of a Gaussian beam. In this study, we present a high-resolution, extended DOF catheter based on self-imaging wavefront division optics. The catheter generates a CAFM beam with a lateral resolution of 3 μm and a DOF close to 2 mm. To correct the aberration introduced by catheter sheath, we incorporated a cylindrical prism to compensate the sheath astigmatism. When the catheter is incorporated into a micro-resolution OCT (μOCT) system with rotational scanning mechanics, cellular-resolution cross-sectional images of the coronary artery wall can be obtained. The device serves as an important step toward characterizing cellular and sub-cellular structures in vivo for coronary artery disease diagnosis.