Method and apparatus for the non-invasive measurement of tissue function and metabolism by determination of steady-state fluorescence anisotropy
First Claim
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1. A non-destructive method of evaluating the functional capacity of a living human tissue in situ in an intact living human being, comprising:
- (a) non-destructively imaging a first resting steady-state fluorescence anisotropy map of said tissue within a latency period of metabolic change in response to a stimulus that changes metabolism and function by the following steps;
(i) irradiating the tissue with continuous linearly polarized light sufficient to cause endogenous lipoamide dehydrogenase (LipDH) to fluoresce within the latency period of metabolic change to light, and capturing the fluorescence emission prior to the excitation light causing the tissue to change its metabolism;
(ii) resolving the emitted fluorescence from said LipDH into vector components parallel and perpendicular to the plane of the exciting polarized light;
(iii) calculating the steady-state fluorescence anisotropy (A) of said LipDH from the resolved vector components; and
(iv) constructing a steady-state fluorescence anisotropy map image of said tissue;
(b) non-destructively imaging a second stimulated steady-state fluorescence anisotropy map of said tissue for a second metabolic or functional state by the following steps;
(i) irradiating the tissue with continuous linearly polarized light sufficient to cause endogenous LipDH to fluoresce after the latency period of metabolic change to light, and capturing the fluorescence emission after the stimulus has caused the tissue to change its metabolism; and
(ii) repeating parts (ii), (iii) and (iv) of step (a);
(c) determining the functional capacity of the tissue by subtracting point by point or pixel by pixel the first resting steady-state fluorescence anisotropy image from the second stimulated steady-state fluorescence anisotropy image, over the entire imaged field or within areas of interest; and
(d) comparing the functional capacity of the tissue under evaluation to a database of normal metabolic levels obtained from control tissue similarly determined by steps a-c to reveal dysfunctional areas in the tissue under evaluation.
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Abstract
A non-invasive measurement of biological tissue reveals information about the function of that tissue. Polarized light is directed onto the tissue, stimulating the emission of fluorescence, due to one or more endogenous fluorophors in the tissue. Fluorescence anisotropy is then calculated. Such measurements of fluorescence anisotropy are then used to assess the functional status of the tissue, and to identify the existence and severity of disease states. Such assessment can be made by comparing a fluorescence anisotropy profile with a known profile of a control.
43 Citations
12 Claims
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1. A non-destructive method of evaluating the functional capacity of a living human tissue in situ in an intact living human being, comprising:
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(a) non-destructively imaging a first resting steady-state fluorescence anisotropy map of said tissue within a latency period of metabolic change in response to a stimulus that changes metabolism and function by the following steps; (i) irradiating the tissue with continuous linearly polarized light sufficient to cause endogenous lipoamide dehydrogenase (LipDH) to fluoresce within the latency period of metabolic change to light, and capturing the fluorescence emission prior to the excitation light causing the tissue to change its metabolism; (ii) resolving the emitted fluorescence from said LipDH into vector components parallel and perpendicular to the plane of the exciting polarized light; (iii) calculating the steady-state fluorescence anisotropy (A) of said LipDH from the resolved vector components; and (iv) constructing a steady-state fluorescence anisotropy map image of said tissue; (b) non-destructively imaging a second stimulated steady-state fluorescence anisotropy map of said tissue for a second metabolic or functional state by the following steps; (i) irradiating the tissue with continuous linearly polarized light sufficient to cause endogenous LipDH to fluoresce after the latency period of metabolic change to light, and capturing the fluorescence emission after the stimulus has caused the tissue to change its metabolism; and (ii) repeating parts (ii), (iii) and (iv) of step (a); (c) determining the functional capacity of the tissue by subtracting point by point or pixel by pixel the first resting steady-state fluorescence anisotropy image from the second stimulated steady-state fluorescence anisotropy image, over the entire imaged field or within areas of interest; and (d) comparing the functional capacity of the tissue under evaluation to a database of normal metabolic levels obtained from control tissue similarly determined by steps a-c to reveal dysfunctional areas in the tissue under evaluation. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12)
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Current AssigneeCellview Imaging Inc.
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Original AssigneeRalph Zuckerman
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InventorsZuckerman, Ralph
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Primary Examiner(s)Weber, Jon P
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Assistant Examiner(s)SINGH, SATYENDRA K
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Application NumberUS11/624,820Publication NumberTime in Patent Office1,873 DaysField of SearchNoneUS Class Current435/4CPC Class CodesA61B 5/0071 by measuring fluorescence e...A61B 5/14546 for measuring analytes not ...A61B 5/1455 using optical sensors, e.g....A61B 5/14555 specially adapted for the e...A61B 5/14556 by fluorescence A61B5/14555...A61B 5/4842 Monitoring progression or s...A61B 5/7246 using correlation, e.g. tem...A61B 5/7278 Artificial waveform generat...G01N 2021/6484 Optical fibresG01N 21/6445 Measuring fluorescence pola...G01N 21/645 Specially adapted construct...G01N 2201/0683 Brewster plate; polarisatio...G01N 2201/12 Circuits of general importa...
