Quantitative optoacoustic tomography with enhanced contrast
First Claim
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1. An optoacoustic imaging system for producing images of one or more objects in a body, configured to perform the steps of:
- a) illuminating a body using pulses of electromagnetic radiation thereby generating a distribution of absorbed thermal energy under conditions of temporal pressure confinement within a volume of a resolution of interest;
b) detecting temporally resolved profiles of optoacoustic pressure signals generated within the volume of interest using one or more ultrasonic transducers;
c) processing the detected optoacoustic pressure signals to determine a value of absorbed electromagnetic energy;
d) determining a probability for each sample of the processed optoacoustic pressure signals to be received from a direction relative to each transducer using a radial backprojection algorithm; and
e) applying a maximum angular amplitude probability (MAAP) algorithm effective to use directional information of the received optoacoustic signals relative to the transducer receiving the signal thereby reconstructing the high-contrast optoacoustic images of the body showing location, shape and true brightness of one or more objects within the body, thereby producing high-contrast optoacoustic images of the volume of interest; and
f) fitting each reconstructed arc with a polynomial function and calculating the second derivative to determine exact boundaries of one or more objects for quantitative analysis of the reconstructed high-contrast optoacoustic images.
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Abstract
Provided herein is an optoacoustic imaging system configured to produce images of one or more objects in a body using at least a maximum angular amplitude probability algorithm to reconstruct the optoacoustic images of the body. In addition the optoacoustic imaging system may be configured to produce 3D maps from the reconstructed optoacoustic images of the body. Also, provided is a method for diagnosing a pathophysiological condition characterized by abnormal optical properties of tissues in a body from maps so produced.
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Citations
19 Claims
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1. An optoacoustic imaging system for producing images of one or more objects in a body, configured to perform the steps of:
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a) illuminating a body using pulses of electromagnetic radiation thereby generating a distribution of absorbed thermal energy under conditions of temporal pressure confinement within a volume of a resolution of interest; b) detecting temporally resolved profiles of optoacoustic pressure signals generated within the volume of interest using one or more ultrasonic transducers; c) processing the detected optoacoustic pressure signals to determine a value of absorbed electromagnetic energy; d) determining a probability for each sample of the processed optoacoustic pressure signals to be received from a direction relative to each transducer using a radial backprojection algorithm; and e) applying a maximum angular amplitude probability (MAAP) algorithm effective to use directional information of the received optoacoustic signals relative to the transducer receiving the signal thereby reconstructing the high-contrast optoacoustic images of the body showing location, shape and true brightness of one or more objects within the body, thereby producing high-contrast optoacoustic images of the volume of interest; and f) fitting each reconstructed arc with a polynomial function and calculating the second derivative to determine exact boundaries of one or more objects for quantitative analysis of the reconstructed high-contrast optoacoustic images. - View Dependent Claims (2, 3, 4, 5)
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6. An optoacoustic imaging system for producing maps of one or more objects in a body, configured to perform the steps of:
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a) illuminating the body with pulses of electromagnetic radiation thereby producing a homogeneous distribution of an energy fluence within any given plane inside the body perpendicular to the direction of the incident beam of the electromagnetic radiation; b) detecting temporally resolved profiles of resulting optoacoustic signals using an array of ultrawide-band ultrasonic transducers with transducer directivity of about 0 to about 2π
steradians and with an angular aperture of the army of about 0 and 4π
steradians;c) amplifying and digitally recording the temporally resolved signals using an electronic data acquisition system; d) filtering all digitally recorded signals from noise while keeping the profiles of the optoacoustic signals unaltered; e) optimally processing the temporally resolved signals to convert bipolar pressure signals into monopolar signals f) reconstructing optoacoustic images of the body using a radial backprojection algorithm effective to determine a probability for each sample of an optoacoustic signal to be received from a direction relative to the transducer; g) applying a maximum angular amplitude probability algorithm effective to use information on the direction of the received optoacoustic signals relative to the transducer thereby reconstructing high-contrast optoacoustic images of the body showing location and shape of the one or more objects; h) fitting each reconstructed arc with a polynomial function and calculating the second derivative to determine exact boundaries of one or more objects; i) assigning each of the determined objects inside the body with an unknown absorption coefficient; j) using each sample of the integral of the temporally resolved optoacoustic profiles received by each transducer to solve a linear regression model of unknown absorbtion coefficients with regression coefficients related to determined sizes of the objects; and k) plotting the optoacoustic map based on determined absorption coefficients of the one or more objects inside the body. - View Dependent Claims (7, 8, 9, 10)
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11. An optoacoustic imaging system for diagnosing a pathophysiological condition characterized by abnormal optical properties of tissues in a body, configured to perform the steps of:
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a) obtaining temporally resolved profiles of acoustic signals generated by one or more objects associated with the pathophysiological condition within a body upon illumination thereof with electromagnetic radiation; b) applying at least a maximum angular amplitude probability algorithm to the profiles to determine optical absorption coefficients of the one or more objects to reconstruct high-contrast optoacoustic images of the body; and c) plotting an optoacoustic map based on the determined optical absorption coefficients of one or more objects showing a location thereof inside the body thereby diagnosing the pathophysiological condition. - View Dependent Claims (12, 13, 14, 15, 16, 17, 18, 19)
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Specification