System and method for quantifying the dynamic response of a target system
First Claim
1. A method for assessing tissue function in a subject human or animal, comprising:
- obtaining simultaneously a time series of optical tomography data from a first tissue site and a second tissue site of the subject human or animal, the first tissue site and the second tissue site being located at different areas of the subject human or animal, wherein the time series of optical tomography data from the first tissue site and the second tissue site identify temporal variations in at least one hemoglobin signal by illuminating a radiation at a wavelength at which hemoglobin is a principal absorbing species in the first and second tissues;
comparing the time series of optical tomography data from the first tissue site to the time series of corresponding optical tomography data from the second tissue site;
deriving a first time series of optical tomography images from the time series of optical tomography data from the first tissue site;
deriving a second time series of optical tomography images from the time series of optical tomography data from the second tissue site;
assessing differential responses or coordinated responses from the first tissue site and the second tissue site by determining a functional property of a vasculature through examination of said temporal variations in said at least one hemoglobin signal; and
generating a real-time 3D image based on said determining of said functional property of said vasculature, wherein image contrast is provided by employing said temporal variations in said at least one hemoglobin signal.
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Abstract
A time series of optical tomography data is obtained for a target tissue site in a human (or animal), using an optical wavelength, such as near infrared, at which hemoglobin is absorptive, to observe properties of the vasculature of the human. The data may be compared to baseline data of a corresponding tissue site, e.g., from a healthy human, or from another, corresponding tissue site of the human. For example, a suspected cancerous breast of a human may be compared to a known healthy breast to detect differences in the vasculature. Measures may be made of flow, oxygen supply/demand imbalance, and evidence of altered regulation of the peripheral effector mechanism. The function of the target tissue site may be analyzed, along with the coordinated interaction between multiple sites of the target system. A provocation may be administered to identify surrogate markers of an underlying state or process.
25 Citations
21 Claims
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1. A method for assessing tissue function in a subject human or animal, comprising:
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obtaining simultaneously a time series of optical tomography data from a first tissue site and a second tissue site of the subject human or animal, the first tissue site and the second tissue site being located at different areas of the subject human or animal, wherein the time series of optical tomography data from the first tissue site and the second tissue site identify temporal variations in at least one hemoglobin signal by illuminating a radiation at a wavelength at which hemoglobin is a principal absorbing species in the first and second tissues; comparing the time series of optical tomography data from the first tissue site to the time series of corresponding optical tomography data from the second tissue site; deriving a first time series of optical tomography images from the time series of optical tomography data from the first tissue site; deriving a second time series of optical tomography images from the time series of optical tomography data from the second tissue site; assessing differential responses or coordinated responses from the first tissue site and the second tissue site by determining a functional property of a vasculature through examination of said temporal variations in said at least one hemoglobin signal; and generating a real-time 3D image based on said determining of said functional property of said vasculature, wherein image contrast is provided by employing said temporal variations in said at least one hemoglobin signal. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
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12. A method for assessing tissue function in a subject human or animal, comprising:
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obtaining simultaneously first and second time series of optical tomography data from first and second tissue sites of the subject human or animal, the first tissue site and the second tissue site being located at different areas, wherein the first and second time series of optical tomography data from the first and second tissue sites identify temporal variations in at least one hemoglobin signal by illuminating a radiation at a wavelength at which hemoglobin is a principal absorbing species in the first and second tissues; comparing the first time series of optical tomography data to the second time series of optical tomography data to assess tissue function of the tissue site; deriving a first time series of optical tomography images from the first time series of optical tomography data; and deriving a second time series of optical tomography images from the second time series of optical tomography data; assessing differential responses or coordinated responses from the first tissue site and the second tissue site by determining a functional property of a vasculature through examination of said temporal variations in said at least one hemoglobin signal; and generating a real-time 3D image based on said determining of said functional property of said vasculature, wherein image contrast is provided by employing said temporal variations in said at least one hemoglobin signal. - View Dependent Claims (13, 14, 15, 16, 17, 18, 19)
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20. A method for assessing tissue function in a subject human or animal, comprising:
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obtaining simultaneously without using contrast agent a time series of optical tomography data from a first tissue site and a second tissue site of the subject human or animal, the first tissue site and the second tissue site being located at different areas of the subject human or animal, wherein the first and second time series of optical tomography data from the first and second tissue sites identify temporal variations in at least one hemoglobin signal by illuminating a radiation at a wavelength at which hemoglobin is a principal absorbing species in the first and second tissues; provoking a vasculature of the subject human or animal during said obtaining step using physiological maneuver, metabolic maneuver, pharmacological maneuver, dietary conditioning, or physical conditioning or combinations thereof; comparing the time series of optical tomography data from the first tissue site to a time series of corresponding optical tomography data from a second tissue site; deriving a first time series of optical tomography images from the time series of optical tomography data from the first tissue site; deriving a second time series of optical tomography images from the time series of optical tomography data from the second tissue site; assessing differential responses or coordinated responses from the first tissue site and the second tissue site by determining a functional property of said vasculature through examination of said temporal variations in said at least one hemoglobin signal; and generating a real-time 3D image based on said determining of said functional property of said vasculature, wherein image contrast is provided by employing said temporal variations in said at least one hemoglobin signal. - View Dependent Claims (21)
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Specification