Device for use in electro-biological signal measurement in the presence of a magnetic field

US 9,636,019 B2
Filed: 10/06/2011
Issued: 05/02/2017
Est. Priority Date: 10/07/2010
Status: Active Grant

First Claim

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1. A measurement device for use in an electroencephalogram (EEG) measurement performed in the presence of a magnetic field, the measurement device comprising a wiring array for connecting an electrodes arrangement comprising a plurality of EEG electrodes to an EEG monitor comprising a control unit being configured and operable to analyze neural signals received from said electrodes arrangement and generate EEG data, wherein:

the wiring array comprises a plurality of sampling lines arranged to form a first group of sampling lines arranged in a spaced-apart substantially parallel relationship extending along a first axis, at least some of said first group of sampling lines being a first group of wire bundles each comprising a plurality of first wires for connecting to a corresponding first plurality of electrodes, of said electrodes arrangement, extending along said first axis; and

a second group of sampling lines arranged in a spaced-apart substantially parallel relationship extending along a second axis, at least some of said second group of sampling lines being a second group of wire bundles each comprising a plurality of second wires for connecting to a corresponding second plurality of electrodes, of said electrodes arrangement, extending along said second axis;

wherein said first group of wire bundles intersects with said second group of wire bundles over an area of measurement locations when said wiring array is placed on a patient'"'"'s scalp, the wiring array being configured and operable for simultaneously transmitting to the EEG monitor, first and second sets of EEG measurements obtained by electrodes of said electrodes arrangement being located in said area of measurement locations when said wiring array is placed on the patient'"'"'s scalp, the first set being obtained along at least one sampling line of said first group of sampling lines and the second set being obtained across at least two different sampling lines of said second group of sampling lines, thereby enabling generation of EEG data characterized by at least one of a reduced motion artifact and a reduced gradient artifact associated with the presence of the magnetic field during the EEG measurement.

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Abstract

A device is presented for use in an EEG measurement performed in the presence of a magnetic field. The device includes a wiring array for connecting an electrodes arrangement to an electroencephalogram (EEG) monitoring device. The wiring array includes sampling lines arranged to form first and second groups of sampling lines, arranged in a spaced-apart substantially parallel relationship extending along first and second axes respectively, at least some of the sampling lines being wire bundles including a plurality of wires for connecting to a corresponding plurality of electrodes of the EEG electrodes arrangement; the first and second groups of sampling lines intersect with each other to form a net structure when placed on area of measurement. The wiring array thereby enable generation of EEG data characterized by reduced motion artifact and/or reduced gradient artifact associated with the presence of the magnetic field during the EEG measurement.

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30 Claims

1. A measurement device for use in an electroencephalogram (EEG) measurement performed in the presence of a magnetic field, the measurement device comprising a wiring array for connecting an electrodes arrangement comprising a plurality of EEG electrodes to an EEG monitor comprising a control unit being configured and operable to analyze neural signals received from said electrodes arrangement and generate EEG data, wherein:
- the wiring array comprises a plurality of sampling lines arranged to form a first group of sampling lines arranged in a spaced-apart substantially parallel relationship extending along a first axis, at least some of said first group of sampling lines being a first group of wire bundles each comprising a plurality of first wires for connecting to a corresponding first plurality of electrodes, of said electrodes arrangement, extending along said first axis; and
  
  a second group of sampling lines arranged in a spaced-apart substantially parallel relationship extending along a second axis, at least some of said second group of sampling lines being a second group of wire bundles each comprising a plurality of second wires for connecting to a corresponding second plurality of electrodes, of said electrodes arrangement, extending along said second axis;
  
  wherein said first group of wire bundles intersects with said second group of wire bundles over an area of measurement locations when said wiring array is placed on a patient'"'"'s scalp, the wiring array being configured and operable for simultaneously transmitting to the EEG monitor, first and second sets of EEG measurements obtained by electrodes of said electrodes arrangement being located in said area of measurement locations when said wiring array is placed on the patient'"'"'s scalp, the first set being obtained along at least one sampling line of said first group of sampling lines and the second set being obtained across at least two different sampling lines of said second group of sampling lines, thereby enabling generation of EEG data characterized by at least one of a reduced motion artifact and a reduced gradient artifact associated with the presence of the magnetic field during the EEG measurement.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 17, 18, 19, 20)
- - 2. The measurement device of claim 1, wherein said second axis is substantially perpendicular to said first axis.
  - 3. The measurement device of claim 1, wherein the wiring array is in the form of a net structure that is (a) configured for connecting said EEG monitor to the electrodes arrangement, wherein the electrodes of the electrodes arrangement are capable of being positioned along a patient'"'"'s scalp according to the International 10-20 system;
    - or (b) configured for connecting said EEG monitor to the electrodes arrangement, wherein at least some electrodes of the electrodes arrangement are capable of being joined to the patient'"'"'s head in one of the following manners;
      
      non-invasively placed on the patient'"'"'s scalp, semi-invasively joined to the patient'"'"'s head epidural region, and invasively joined to the patient'"'"'s head subdural region.
  - 4. The measurement device of claim 1, wherein at least some of the sampling lines are configured for being removably connectable to the electrodes, thereby allowing for a replacement of at least some of the electrodes between scans.
  - 5. The measurement device of claim 1, wherein at least one of said first and second groups of sampling lines comprises at least two sub-groups, wherein sampling lines of the at least two sub-groups are arranged in an alternating fashion such that any two adjacent sampling lines belonging to said first or second group belong respectively to different sub-groups of said first or second group.
  - 6. The measurement device of claim 1, further comprising:
    - at least one of an MRI scanner for imaging the patient'"'"'s brain or a Transcranial Magnetic Stimulation (TMS) coil device configured and operable to produce a changing magnetic field to cause activity in the patient'"'"'s brain;
      
      an EEG monitor comprising a control unit; and
      
      an electrodes arrangement;
      
      said wiring array being connected between the EEG monitor and the electrodes, said electrodes being configured for being placed at predetermined locations on the patient'"'"'s scalp and for detecting a neural signal when placed on the patient'"'"'s scalp; and
      
      said wiring array being thereby configured for relaying said neural signals to the EEG monitor for analysis of said neural signal and generation of EEG data.
  - 7. The measurement device of claim 6, having one of the following configurations:
    - (i) at least one of said sampling lines is configured to connect to a pair of electrodes of said electrodes arrangement; and
      
      (ii) the electrode arrangement comprises a reference electrode, a first electrode configured to obtain a first bipolar measurement with the reference electrode, and a second electrode configured to obtain a second bipolar measurement with the reference electrode, the first and second electrodes being both connected to one of the sampling lines, said EEG data generated at the EEG monitor being a combination of said first and second bipolar measurements and being indicative of a signal between the first and second electrodes.
  - 8. The measurement device of claim 6, wherein the measurement device comprises the TMS coil device and the magnetic field is a changing magnetic field generated by the TMS coil device.
  - 9. The device of claim 6, wherein said control unit is configured and operable for receiving the EEG data and selecting therefrom data pieces, and analyzing said data pieces for recognizing and suppressing at least one of a motion artifact and gradient artifact.
  - 10. The measurement device of claim 9, wherein said selecting of said data pieces comprises selecting a first sub-set of measurements from said first set of measurements between a first group of electrode pairs of said first plurality of electrodes, and selecting a second sub-set of measurements from said second set of measurements between a second group of electrode pairs of said second plurality of electrodes.
  - 11. The measurement device of claim 10, wherein said control unit is configured and operable for analyzing the selected data pieces by:
    - applying to said first and second sub-sets a separation algorithm to jointly decompose the selected data pieces of the first and second sub-sets of signal measurements into a plurality of components;
      
      comparing an effect of at least some of said plurality of components on each of the first and second sub-sets of measurements; and
      
      recognizing at least one specific component which has an effect on said second sub-set of measurements that is larger than the effect on said first sub-set of measurements, and labeling said at least one specific component as an artifact-affected component.
  - 12. The measurement device of claim 9, wherein the said selecting of said data pieces comprises selecting at least a set of signal measurements between a group of electrode pairs of at least one of said first and second plurality of electrodes.
  - 13. The device of claim 12, wherein:
    - the control unit is configured and operable to select the set of signal measurements by selecting a first sub-set of signal measurements from said first set of measurements obtained between a first group of electrode pairs of said first plurality of electrodes, and by selecting a second sub-set of the signal measurements from said second set of measurements obtained between a second group of electrode pairs of said second plurality of electrodes.
  - 14. The measurement device of claim 1, further comprising the EEG monitor comprising the control unit, wherein said control unit is configured and operable to compare said first and second sets of EEG measurements to separate EEG data indicative of neural signals from EEG data indicative of at least one of a motion artifact and a gradient artifact.
  - 17. A cap configured for being worn by a patient during an electroencephalogram (EEG) measurement performed in the presence of a magnetic field, the cap comprising the measurement device of claim 1.
  - 18. The cap of claim 17, further comprising:
    - an electrically non-conductive headpiece, comprising;
      
      an inner surface, configured for being fitted to the patient'"'"'s head;
      
      an outer surface carrying said wiring array; and
      
      a plurality of apertures, each said aperture being configured for being traversed by a portion of one of said electrodes for connecting to one of said wires.
  - 19. The cap of claim 18, wherein said headpiece comprises fasteners located on said outer surface and configured for fastening said wiring array to said headpiece.
  - 20. The cap of claim 18, wherein said headpiece is made of a stretchable material, for closely fitting the scalp of the patient.

15. A net structure configured for being placed on a patient'"'"'s scalp in an electroencephalogram (EEG) measurement performed in the presence of a magnetic field, the net structure comprising a wiring arrangement, which comprises first and second groups of sampling lines including first and second wire bundles and extending along first and second axes respectively, the first and second wire bundles intersecting over an area of measurement locations when placed on the patient'"'"'s scalp, each group comprising a plurality of spaced-apart substantially parallel sampling lines configured for transmitting EEG signals from a respective plurality of spaced-apart EEG measurement locations, to read EEG data from the measurement locations via the first and second groups of sampling lines, while decreasing at least one of a motion artifact and a gradient artifact generated in the EEG measurement.

16. A cap configured for being worn by a patient in an electroencephalogram (EEG) measurement performed in the presence of a magnetic field, the cap carrying a wiring arrangement, which comprises first and second groups of sampling lines including first and second wire bundles respectively, and extending along first and second axes, the first and second wire bundles intersecting over an area of measurement when placed on a patient'"'"'s scalp, each group comprising a plurality of spaced-apart substantially parallel sampling lines, each sampling line being configured for transmitting EEG signals from a respective plurality of spaced-apart EEG measurement locations, to simultaneously read EEG data from the measurement locations along one or more of the first wire bundles and across at least two of the second wire bundles, thereby decreasing at least one of a motion artifact and a gradient artifact generated in the EEG measurement.

21. A method for performing an electroencephalogram (EEG) measurement in the presence of a magnetic field, the method comprising:
- providing an electrode arrangement comprising a plurality of EEG electrodes, capable of being joined to a patient'"'"'s head;
  
  providing an EEG monitor comprising a control unit being configured and operable to analyze neural signals received from said electrodes arrangement and generate EEG data;
  
  connecting said plurality of EEG electrodes to the EEG monitor, using a wiring array comprising;
  
  a first group of sampling lines arranged in a spaced-apart substantially parallel relationship extending along a first axis, at least some of said first group of sampling lines being a first group of wire bundles, each of said first group of wire bundles comprising a plurality of first wires for connecting to a corresponding first plurality of electrodes of said plurality of EEG electrodes; and
  
  a second group of sampling lines arranged in a spaced-apart substantially parallel relationship extending along a second axis, at least some of said second group of sampling lines being a second group of wire bundles, each of said second group of wire bundles comprising a plurality of second wires for connecting to a corresponding second plurality of electrodes, of said plurality of EEG electrodes, extending along said second axis;
  
  wherein said second group of wire bundles intersects with said first group of wire bundles to form a net structure over an area of measurement locations on the patient'"'"'s head;
  
  measuring simultaneously first and second neural signals using electrodes located in said area of measurement locations, the first neural signal being obtained along one or more sampling lines of said first group and the second neural signal being obtained across different sampling lines of said second group;
  
  transmitting said first and second neural signals to said EEG monitor via said wiring array; and
  
  analyzing said first and second neural signals and yielding EEG data being characterized by at least one of a reduced motion artifact and a reduced gradient artifact.
- View Dependent Claims (22, 23, 24, 25, 26, 27, 28, 29, 30)
- - 22. The method of claim 21, comprising:
    - processing said EEG data to calculate an amplitude and an orientation of said neural signals.
  - 23. The method of claim 21, wherein said measuring of said first neural signal comprises measuring between a reference electrode and one or more electrodes of said first plurality of electrodes.
  - 24. The method of claim 23, wherein said measuring of each of said first and second neural signals comprises measuring the neural signal between the reference electrode and at least some of said electrodes of said electrodes arrangement;
    - andwherein said yielding of EEG data comprises combining data indicative of two measurements taken between said reference electrode and respectively a first and a second electrode of said first plurality of electrodes being connected to the same sampling line to thereby provide combined EEG data, such that said combined EEG data is indicative of a neural signal between said first and second electrodes.
  - 25. The method of claim 21, wherein said magnetic field is a constant magnetic field generated by a magnetic resonance imaging scanner, or a changing magnetic field generated by a transcranial magnetic stimulation coil device.
  - 26. The method of claim 21, further comprising selecting from the EEG data, data pieces, analyzing the selected data pieces and recognizing and suppressing at least one of a motion artifact and a gradient artifact generated in the EEG measurement.
  - 27. The method of claim 26, wherein:
    - said analyzing of the selected data pieces comprises;
      
      applying to said first and second neural signals a separation algorithm to jointly decompose said selected data pieces into a plurality of components;
      
      comparing an effect of at least some of said plurality of components on each of the first and second neural signals; and
      
      recognizing at least one specific component from said plurality of components which has an effect on said second neural signal that is larger than an effect on said first neural signal, and labeling said at least one specific component as a motion artifact-affected component or a gradient artifact-affected component.
  - 28. The method of claim 27, wherein:
    - said comparing comprises;
      
      determining a first value indicative of the effect of said at least one specific component on said first neural signal, and a second value indicative of the effect of said at least one specific component on said second neural signal;
      
      calculating a relation between said first and second values; and
      
      comparing said relation to a predetermined threshold; and
      
      whereinsaid recognizing at least one specific component comprises identifying said at least one specific component as one of the motion artifact-affected component or the gradient artifact-affected component, according to said comparison between said relation and said predetermined threshold.
  - 29. The method of claim 26, wherein:
    - said analyzing of the selected data pieces comprises;
      
      applying to said selected data pieces a separation algorithm to decompose said data into a plurality of components;
      
      for each of at least some of said plurality of components, selecting at least three electrodes from said first or second plurality of electrodes, such that two of said at least three electrodes are connected to different sampling lines; and
      
      for each of at least some of said plurality of components, calculating gradients of each component along respective sides of a polygon defined by said electrodes and analyzing said gradients.
  - 30. The method of claim 21, comprising:
    - positioning at least one of said first and second groups of sampling lines such that the at least one of said first and second groups of sampling lines comprises at least two sub-groups of the sampling lines,wherein sampling lines of the sub-groups are positioned in an alternating fashion such that any two adjacent sampling lines belonging to said first or second group belong respectively to different sub-groups of said first or second group.

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Current Assignee
The Medical Research, Infrastructure And Health Services Fund Of The Tel Aviv Medical Center
Original Assignee
The Medical Research, Infrastructure And Health Services Fund Of The Tel Aviv Medical Center
Inventors
Hendler, Talma, Medvedovsky, Mordekhay, Zhdanov, Andrey, Klovatch, Ilana, Fahoum, Firas
Primary Examiner(s)
Cwern, Jonathan
Assistant Examiner(s)
Gillman, Amelie R

Application Number

US13/878,297
Publication Number

US 20130204122A1
Time in Patent Office

2,035 Days
Field of Search
US Class Current
CPC Class Codes

A61B 2562/222   Electrical cables or leads ...

A61B 5/0055   by applying suction

A61B 5/291   for electroencephalography ...

A61B 5/369   Electroencephalography [EEG...

Device for use in electro-biological signal measurement in the presence of a magnetic field

First Claim

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Device for use in electro-biological signal measurement in the presence of a magnetic field

First Claim

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Specification

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