Abstract: An exemplary system, method, and computer-accessible medium for generating an image(s) of an three-dimensional anatomical flow map(s) can include receiving an optical coherence tomography (“OCT”) signal(s), splitting the OCT signal(s) into a plurality of subspectra, averaging the plurality of subspectra, and generating the image(s) of the three-dimensional anatomical flow map(s) based on the averaged subspectra. The OCT signal(s) can be a swept-source OCT signal. The OCT signal(s) can be split into the subspectra based on a Hamming window. The Hamming distance window can be optimized to minimize a nearest side lobe for each of the subspectra. A position of at least one of the subspectra can be shifted prior to averaging the subspectra. The position of all but one of the subspectra can be shifted prior to averaging the subspectra.

Abstract: An exemplary system, method, and computer-accessible medium for generating an image(s) of an three-dimensional anatomical flow map(s) can include receiving an optical coherence tomography (“OCT”) signal(s), splitting the OCT signal(s) into a plurality of subspectra, averaging the plurality of subspectra, and generating the image(s) of the three-dimensional anatomical flow map(s) based on the averaged subspectra. The OCT signal(s) can be a swept-source OCT signal. The OCT signal(s) can be split into the subspectra based on a Hamming window. The Hamming distance window can be optimized to minimize a nearest side lobe for each of the subspectra. A position of at least one of the subspectra can be shifted prior to averaging the subspectra. The position of all but one of the subspectra can be shifted prior to averaging the subspectra.

Abstract: The present invention provides a method of imaging blood vessels or blood flow in blood vessels in an animal comprising: (i) injecting a lipid solution into the bloodstream of the animal; (ii) imaging the blood vessels by an imaging method; and (iii) calculating the blood flow velocity in the blood vessels.

Abstract: The present invention provides a method of imaging blood vessels or blood flow in blood vessels in an animal comprising: (i) injecting a lipid solution into the bloodstream of the animal; (ii) imaging the blood vessels by an imaging method; and (iii) calculating the blood flow velocity in the blood vessels.

Abstract: In general, in one aspect, the invention features a method that includes using an optical coherence tomography system to acquire a plurality of frames of a sample where each frame includes optical information about the composition of the sample through a section of the sample. The method further includes averaging over two or more of the frames to provide an image of the section of the sample where successive frames of the two or more frames are acquired with a time lapse of 0.05-0.7 seconds. Embodiments of the method may have unique advantages for endoscopic subcellular imaging. For example, they can enable subcellular imaging with low-NA optics (e.g., NA=0.25 or less) while providing morphological imaging of the underlying tissue up to 0.6 mm without focal tracking.

Abstract: In general, in one aspect, the invention features a method that includes using an optical coherence tomography system to acquire a plurality of frames of a sample where each frame includes optical information about the composition of the sample through a section of the sample. The method further includes averaging over two or more of the frames to provide an image of the section of the sample where successive frames of the two or more frames are acquired with a time lapse of 0.05-0.7 seconds. Embodiments of the method may have unique advantages for endoscopic subcellular imaging. For example, they can enable subcellular imaging with low-NA optics (e.g., NA=0.25 or less) while providing morphological imaging of the underlying tissue up to 0.6 mm without focal tracking.

Abstract: A system and method for an endoscopic optical coherence tomography (OCT) system based on a CMOS-MEMS mirror to facilitate lateral light scanning. The laser scanning scope, adapted to the instrument channel of a commercially-available endoscopic sheath, allows for the real-time cross-sectional imaging of living biological tissue via direct endoscopic visual guidance. A conventional rod lens imaging system may be used for the visual guidance. The MEMS mirror is preferably actuated using either or both of a thermal-mechanical or electrostatic actuation system. More than one MEMS micromirror may be used in a single system for 3D imaging.