Apparatus and method for magnetic resonance measurement and mapping of electrical impedance, complex permittivity and complex conductivity as applied to detection and evaluation of sample pathology
First Claim
1. A method of detecting and evaluating sample spatially ordered pathology, comprising:
- placing an in-vivo human tissue sample to be evaluated within a magnetic resonance imaging device in proximity to a Faraday shield device, wherein the Faraday shield device comprises Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device, and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield device is configured to apply a time varying potential difference to the in-vivo human tissue sample;
applying a time varying potential difference to the Faraday shield device, so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to the main magnetic field generated by the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample; and
imaging at least one of a complex permittivity, a complex conductivity, and an electrical impedance of the in-vivo human tissue sample.
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Accused Products
Abstract
A method of measurement of or mapping the distribution of complex permittivity, complex conductivity, complex impedance, or electric loss angle during magnetic resonance imaging or analysis. The method includes applying a time-varying electric field of a Faraday shield to a sample and cross-correlating the line spectrum signal so produced with the voltage applied to the Faraday shield in a detection circuit. The method permits non-contrast magnetic resonance screening for breast cancer in vivo and/or continuous measurement of electrical characteristics of materials at variable frequencies in vitro. A system of detecting and evaluating sample pathology includes a Faraday shield device that includes parallel electrodes oriented orthogonal to the static magnetic field of a MRI device to produce a time varying electric field. A detector is coupled to the MRI device to detect at least one of a complex permittivity, a complex conductivity, and an electrical impedance of the sample.
29 Citations
36 Claims
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1. A method of detecting and evaluating sample spatially ordered pathology, comprising:
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placing an in-vivo human tissue sample to be evaluated within a magnetic resonance imaging device in proximity to a Faraday shield device, wherein the Faraday shield device comprises Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device, and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield device is configured to apply a time varying potential difference to the in-vivo human tissue sample; applying a time varying potential difference to the Faraday shield device, so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to the main magnetic field generated by the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample; and imaging at least one of a complex permittivity, a complex conductivity, and an electrical impedance of the in-vivo human tissue sample. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9)
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10. A method of detecting and evaluating sample spatially ordered pathology, comprising:
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placing a Faraday shield device within an imaging region of a magnetic resonance imaging device; placing an in-vivo human tissue sample to be evaluated in proximity to the Faraday shield device, wherein the Faraday shield device comprises Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device, said Faraday shields being disposed within a pair of compression paddles and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield device is configured to apply a time varying potential difference to the in-vivo human tissue sample; applying a time varying potential difference to the Faraday shield device, so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to the main magnetic field generated by the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample; placing at least one of a receiver coil or a transmitter-receiver coil of the magnetic resonance imaging device on or near a surface of the compression paddles; analyzing an image of the in-vivo human tissue sample produced by the magnetic resonance imaging device to detect at least one of a complex permittivity, a complex conductivity, and an electrical impedance of the in-vivo human tissue sample; and identifying focal aberrations contained only in an image produced by the magnetic resonance imaging device so as to locate pathology. - View Dependent Claims (11, 12, 13, 14)
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15. A method of imaging electrical impedance by the application of time-varying electric fields in an in-vivo human tissue sample, comprising:
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placing the in-vivo human tissue sample in a magnetic resonance imaging device; providing a detector to the magnetic resonance imaging device; providing a Faraday shield attachment in proximity to the in-vivo human tissue sample, wherein the Faraday shield attachment comprises Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device that include electrically connected parallel conducting elements and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield attachment is configured to apply a time varying potential difference to the in-vivo human tissue sample; applying a periodic potential difference across the in-vivo human tissue sample so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to the main magnetic field generated by the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample; and analyzing an image of the in-vivo human tissue sample produced by the magnetic resonance imaging device to detect an impedance of the in-vivo human tissue sample with the detector. - View Dependent Claims (16, 17)
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18. A system for detecting and evaluating sample pathology, comprising:
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a magnetic resonance imaging device configured to produce an image of an in-vivo human tissue sample, the magnetic resonance imaging device generating a main magnetic field and including at least one of a receiving coil or a transmitter-receiver coil; a Faraday shield device comprising Faraday shields that include an insulating material that insulates the in-vivo human tissue sample from the Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device, and electrically connected, substantially parallel conducting elements oriented substantially orthogonal to the main magnetic field of the magnetic resonance imaging device, whereby the Faraday shield device is configured to produce a time varying electric field in the in-vivo human tissue sample; a voltage source coupled to the conducting elements and configured to generate a periodic voltage at a frequency (Ω
) creating a current in the in-vivo human tissue sample essentially orthogonal to the main magnetic field of the magnetic resonance device; anda detector configured to analyze an image of the in-vivo human tissue sample produced by the magnetic resonance imaging device to detect one of a complex permittivity, a complex conductivity, and an electrical impedance of the in-vivo human tissue sample. - View Dependent Claims (19, 20, 21, 22, 23, 24, 25, 26, 27, 28)
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29. A system for imaging the electrical impedance of an in-vivo human tissue sample, comprising:
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a magnetic resonance imaging device; a Faraday shield attachment adapted to be placed within the magnetic resonance imaging device and disposed in proximity to the in-vivo human tissue sample, wherein the Faraday shield attachment comprises Faraday shields, oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device, that include electrically connected conducting elements oriented substantially parallel to each other and substantially orthogonal to a main magnetic field of the magnetic resonance imaging device and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield attachment is configured to apply a time varying potential difference to the in-vivo human tissue sample; a voltage source coupled to the conducting elements of the Faraday shield attachment and configured to apply a periodic potential difference across the in-vivo human tissue sample so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to the main magnetic field of the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample; and a detector coupled to the magnetic resonance imaging device to analyze an image of the in-vivo human tissue sample produced by the magnetic resonance imaging device to detect a value corresponding to an electrical impedance of the in-vivo human tissue sample. - View Dependent Claims (30)
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31. A method of detecting and evaluating sample spatially ordered pathology, comprising:
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placing an in-vivo tissue sample that is a human breast to be evaluated within a magnetic resonance imaging device and into a Faraday shield device, wherein the Faraday shield device comprises Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device and an insulating material that insulates the breast from the Faraday shields, whereby the Faraday shield device is configured to apply a time varying potential difference to the breast; applying to the Faraday shield device a time varying potential difference having a phase modulating frequency, so as to create a time varying electric field in the breast and a time varying current field in the breast essentially orthogonal to the main magnetic field of the magnetic resonance imaging device that periodically varies a phase of spins within the breast; and imaging the distribution of at least one of a complex permittivity and an electrical impedance of the breast at the phase modulating frequency. - View Dependent Claims (32, 33)
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34. A system for detecting and evaluating sample spatially ordered pathology, comprising:
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a magnetic resonance imaging device; means for applying a time varying potential difference to a Faraday shield device disposed in proximity to an in-vivo human tissue sample, so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to a main magnetic field generated by the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample, wherein the Faraday shield device comprises Faraday shields oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield device is configured to apply a time varying potential difference to the in-vivo human tissue sample; and means for imaging at least one of a complex permittivity, a complex conductivity, and an electrical impedance of the in-vivo human tissue sample.
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35. A system for imaging electrical impedance by the application of time-varying electric fields in an in-vivo human tissue sample, comprising:
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a magnetic resonance imaging device comprising a detector; a Faraday shield attachment adapted to be disposed in proximity to the in-vivo human tissue sample within the magnetic resonance imaging device, wherein the Faraday shield attachment comprises Faraday shields, oriented so as not to significantly affect a radio frequency field generated within the magnetic resonance imaging device, that include electrically connected conducting elements substantially parallel to each other and an insulating material that insulates the in-vivo human tissue sample from the Faraday shields, whereby the Faraday shield attachment is configured to apply a time varying potential difference to the in-vivo human tissue sample; means for applying a periodic potential difference to the Faraday shield attachment across the in-vivo human tissue sample so as to create a time varying electric field in the in-vivo human tissue sample and a local time varying current field in the in-vivo human tissue sample essentially orthogonal to a main magnetic field generated by the magnetic resonance imaging device which results in a periodic aberration in a local magnetic field that periodically varies a phase of spins within the in-vivo human tissue sample; and means for analyzing an image of the in-vivo human tissue sample produced by the magnetic resonance imaging device to detect an electrical impedance of the in-vivo human tissue sample with the detector.
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36. A system for detecting and evaluating sample spatially ordered pathology in an in-vivo breast tissue, comprising:
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a magnetic resonance imaging device; a Faraday shield device in proximity to the breast tissue, the Faraday shield device comprising Faraday shields oriented so as not to interfere with a radio frequency field generated within the magnetic resonance imaging device and an insulating material that insulates the breast tissue from the Faraday shields; means for applying to the Faraday shield device a time varying potential difference having a phase modulating frequency, so as to create a time varying electric field in the breast tissue and a time varying current field in the breast tissue essentially orthogonal to a main magnetic field generated by the magnetic resonance imaging device that periodically varies a phase of spins within the breast tissue, whereby the Faraday shield device is configured to apply a time varying potential difference to the breast tissue; and means for imaging the distribution of at least one of a complex permittivity and an electrical impedance of the breast at the phase modulating frequency.
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Specification