JP2004041739A - Method for displaying and printing biomagnetic field measurement data - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a highly operative display method for biomagnetic field measurement data by measuring magnetic field intensities of a plurality of measuring positions. <P>SOLUTION: The display method for the biomagnetic field measurement data uses a computer 8 having a displaying screen 8-1, measures magnetic fields generated from the body of a subject 2 with a measuring sensor at a plurality of measuring positions, and displays measurement signals on the screen. For overlapping and displaying the measuring positions and the measuring positions of the subject 2, together with the measurement data on the screen, the computer 8 selects them from the database stored therein according to the information and measurement conditions of the subject 2, and displays them on the displaying screen 8-1 together with the measurement data. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a biomagnetic field measuring apparatus suitable for measuring a magnetic field of a living body based on a current in the living body, such as a neural activity of the living brain or a cardiac muscle activity of the heart.
[0002]
[Prior art]
Conventionally, a distribution of a weak magnetic field generated from a living body is measured using a superconducting quantum interference device (hereinafter, referred to as SQUID) which is a magnetic sensor, and a position of an active current in the living body is estimated from the measurement result. A multi-channel biomagnetic imaging device for imaging the distribution, inputs a signal corresponding to the magnetic field of the active current inside the living body to a neural network, calculates a teacher signal on a computer, and estimates using the neural network. There is something to do. This is a useful device capable of estimating the position of an active current source in real time by a magnetic field generated from a living body, and capable of real-time display. As such a conventional example, for example, there is a technique described in Japanese Patent Application Laid-Open No. Hei 4-319334.
[0003]
In addition, the first-stage estimation of temporarily estimating the biological activity source from magnetic field data in a direction perpendicular to the surface of the living body, and the electrical conductivity inside the living body only in the vicinity of the position of the temporary biological activity current source The estimation is performed using the magnetic field data in three directions for the precision model that has been set.Since the precision calculation is only the position estimated in the first stage, the amount of calculation is small, and the estimation time is reduced. It was an excellent way to do it. Such a conventional example is disclosed in, for example, Japanese Patent Laid-Open Publication No. 5-146416.
[0004]
[Problems to be solved by the invention]
The former of the prior art uses a neural network in a biomagnetic imaging apparatus and relates to the principle of operation, and the disclosure of the technique is insufficient in consideration of means for solving technical problems in implementing the technique. There was a point. In addition, the latter of the conventional example is a precision model of the brain, and relates to an estimation method for estimating a biological activity current generated inside the brain. There was a problem that no specific disclosure was made.
[0005]
Therefore, a specific disclosure in a display method for displaying an estimated current source estimated by the biomagnetic measurement on a two-dimensional display will be described. The position, direction, size, and depth of the estimated current dipole are indicated by the position and direction of the arrow, and the size and depth are indicated by the size, length, and scale of the arrow. , Lightness, saturation, and hue are displayed on a two-dimensional display by two kinds of parameters. As a technique related to this, there is a technique described in JP-A-2-246926.
[0006]
However, the display method specifically disclosed above is merely a two-dimensional display, and furthermore, there is a problem that the user's convenience and visibility are not sufficiently considered. An object of the present invention is to make it easy to measure the magnetic field strength at a plurality of measurement positions, and to make it possible to compare the time characteristic diagram on the same scale as the electrocardiogram so that the inspector can read the signal data correctly. It is to provide a data display method and a printing method.
[0007]
[Means for Solving the Problems]
The configuration of the method for displaying biomagnetic field measurement data according to the present invention uses a computer equipped with a display screen, measures a magnetic field emitted from within a living body of a subject at a plurality of measurement positions with a measurement sensor, and outputs the measurement signal. Is displayed on a screen of a display device, wherein the measurement site map of the subject and the measurement position are superimposed and displayed. The method for displaying biomagnetic field measurement data according to the preceding paragraph is characterized in that the measurement site map of the subject is selected and displayed by the computer from the database according to the subject information or measurement conditions. is there.
[0008]
Another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, measures a magnetic field emitted from a living body of a subject at a plurality of measurement positions with a measurement sensor, and A method of displaying biomagnetic field measurement data for displaying a measurement signal on a screen of a display device, wherein the subject information and measurement conditions are displayed simultaneously and on the same screen.
[0009]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, and measures a magnetic field emitted from within the living body of the subject at a plurality of measurement positions with a measurement sensor, In the method of displaying biomagnetic field measurement data for displaying the measurement signal on a screen of a display device, in a case where a characteristic amount of the measurement signal is displayed in a contour diagram, the color is displayed in a different color scheme selected by the computer depending on the type of the characteristic amount. It is characterized by the following. In the method for displaying biomagnetic field measurement data according to the preceding paragraph, when the characteristic amount of the measurement signal can take both a positive value and a negative value, colors having the same chromaticity are assigned to the characteristic amounts having the same absolute value. It is assumed that.
[0010]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, and measures a magnetic field emitted from within the living body of the subject at a plurality of measurement positions with a measurement sensor, In a method of displaying biomagnetic field measurement data for displaying the measurement signal on a screen of a display device, the horizontal axis represents time, the display scale is 1/25 [sec / mm], the vertical axis is magnetic flux density, and the display scale is predetermined. It is characterized by a unit.
[0011]
The configuration of the method for printing biomagnetic field measurement data according to the present invention uses a computer having a display screen, measures a magnetic field emitted from the inside of a living body of a subject at a plurality of measurement positions with a measurement sensor, and outputs the measurement signal. In the method of printing biomagnetic field measurement data, a predetermined designation operation is performed on the display screen of claim 6, whereby the biomagnetic field measurement data displayed in claim 6 is displayed on the horizontal axis as a time-feed print scale. Is set to 1/25 [second / mm], the vertical axis is the magnetic flux density, and the magnetic flux density scale is printed in a predetermined unit.
[0012]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, and measures a magnetic field emitted from within the living body of the subject at a plurality of measurement positions with a measurement sensor, In the method of displaying biomagnetic field measurement data for displaying the measurement signal on a screen of a display device, the subject information and the signal information and a single waveform of a predetermined measurement signal of multiple channels designated by a selected channel and an auxiliary channel. The information is displayed simultaneously and on the same screen.
[0013]
Another configuration of the printing method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, measures a magnetic field emitted from a living body of the subject at a plurality of measurement positions with a measurement sensor, and A method for printing biomagnetic field measurement data for displaying a measurement signal on a screen of a display device, wherein the display screen is printed by a predetermined designation operation on the display screen.
[0014]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, and measures a magnetic field emitted from within the living body of the subject at a plurality of measurement positions with a measurement sensor, In the method of displaying biomagnetic field measurement data for displaying the measurement signal on a screen of a display device, the display screen described in the preceding paragraph, by a predetermined designation operation, a single waveform of a predetermined measurement signal of a multi-channel designated by the selected channel. Instead, a multi-channel overlapping waveform for a single time axis is displayed.
[0015]
Still another configuration of the method for printing biomagnetic field measurement data according to the present invention uses a computer having a display screen, and measures a magnetic field emitted from within a living body of a subject at a plurality of measurement positions with a measurement sensor. A method of printing biomagnetic field measurement data for displaying the measurement signal on a screen of a display device, wherein an overlapping waveform of the display screen is printed by a predetermined designation operation on the display screen described in the preceding paragraph.
[0016]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, measures a magnetic field emitted from inside the living body of the subject at a plurality of positions with a measurement sensor, In the method of displaying biomagnetic field measurement data for displaying a measurement signal on a screen of a display device, when displaying the characteristic amount of the measurement signal, the heart rate and the blood pressure are displayed together.
[0017]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, measures a magnetic field emitted from inside the living body of the subject at a plurality of positions with a measurement sensor, In the method of displaying biomagnetic field measurement data, in which a measurement signal is displayed on a screen of a display device, a gaze direction is set by a predetermined instruction operation on the screen, and a three-dimensional contour map is displayed from the measurement signal by arithmetic processing of the computer. It is characterized by doing.
[0018]
Still another configuration of the display method of the biomagnetic field measurement data according to the present invention uses a computer having a display screen, measures a magnetic field emitted from inside the living body of the subject at a plurality of positions with a measurement sensor, A display method of biomagnetic field measurement data for displaying a measurement signal on a screen of a display device, wherein a waveform display start time of the measurement signal is displayed.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
An embodiment of the present invention will be described with reference to FIGS. First, a biomagnetism measuring apparatus according to the present invention will be described with reference to FIG. FIG. 1 is a schematic configuration diagram of a biomagnetism measuring device according to an embodiment of the present invention.
[0020]
In FIG. 1, a biomagnetism measuring apparatus M is installed in a magnetic shield 1 in order to remove the influence of environmental magnetic noise. The subject 2, which is a subject composed of a living body, is usually measured in a state of lying on the bed 3, but may be measured in a prone state. The subject's body plane (in the case of the chest, generally parallel to the chest wall) is assumed to be substantially parallel to the plane of the bed 3 and this plane is defined by the xy plane of the Cartesian coordinate system (x, y, z). It is assumed that they are parallel. The subject's chest is curved and tilted, but is generally parallel for ease of explanation.
[0021]
A dewar 4 filled with liquid helium (hereinafter, referred to as liquid He) as a refrigerant is disposed above the chest of the subject 2, and the dewar 4 is not shown in the drawing. A plurality of magnetic sensors (see FIG. 2) including an Interference Device (hereinafter, referred to as SQUID) and a detection coil connected to the SQUID are accommodated. The liquid He is continuously replenished from the automatic replenishing device 5 outside the magnetic shield 1.
[0022]
The output of the magnetic sensor outputs a voltage having a specific relationship with the strength of the biomagnetic field (which can also be considered as a magnetic flux density) generated from the subject 2 and detected by the detection coil, and the output is FLL ( Flux Locked loop) circuit 6. The FLL circuit 6 cancels a change in the biomagnetic field (biomagnetism) input to the SQUID via a feedback coil so as to keep the output of the SQUID constant (this is called a magnetic field lock). By converting the current flowing through the feedback coil into a voltage, a voltage output having a specific relationship with a change in the biomagnetic field signal can be obtained. Since the detection is performed via the feedback coil as described above, a weak magnetic field can be detected with high sensitivity. The output voltage from the magnetic sensor is input to an amplifier / filter / amplifier (AFA) 7, the output of which is sampled, A / D converted, and taken into a computer 8.
[0023]
The computer 8 comprises a personal computer and is equipped with appropriate software, for example, Windows (registered trademark) 95 application, 8-1 is a display unit thereof, and 8-2 is a keyboard. , And 8-3, a mouse is shown, and by these operations, the computer 8 can perform various kinds of processing, and display it on the display unit as needed.
[0024]
The mouse 8-3 is used to select a processing target by moving a cursor on the screen of the display unit 8-1. This operation can also be performed by operating the keyboard. A printer 9 is connected to the computer 8, and the contents displayed on the display unit 8-1 can be arranged on an output sheet and printed. The printer may perform color printing or black and white printing, but in the present embodiment, it is assumed that a printer capable of performing color printing is connected.
[0025]
The input gain and the output gain of the AFA 7 are adjustable, and the AFA 7 is a low-pass filter that passes a frequency signal of a first reference frequency or less, a frequency of a second reference frequency or more lower than the first reference frequency. It includes a high-pass filter that passes signals and a notch filter that cuts off the frequency of the commercial power supply. The computer 8 can perform various types of processing, and the processing results can be displayed on the display unit 8-1.
[0026]
The configuration including the computer 8 shown in FIG. 1 is an example, and the present invention is not limited to this. For example, a device provided with a display having a touch panel, or a device using a pointing device such as a trackball or a joystick instead of a mouse may be used. In some cases, a computer connected via a public telephone line may be used.
[0027]
As the SQUID, for example, a DC SQUID is used as an example. When an external magnetic field is applied to the SQUID, a DC bias current (Ibias) flows through the SQUID so that a voltage (V) corresponding to the external magnetic field is generated. When the external magnetic field is represented by a magnetic flux Φ, a characteristic curve of V with respect to Φ, that is, a Φ-V characteristic curve is given by a periodic function. Prior to the measurement, an operation is performed to adjust the offset voltage (VOFF) of the FLL circuit 6 to make the DC voltage of the Φ-V characteristic curve zero level.
[0028]
The magnetic sensor will be described with reference to FIG. FIG. 2 is a perspective view of a plurality of magnetic sensors used in the biomagnetic field measurement device of FIG. As shown in FIG. 2, a plurality of magnetic sensors 20-1 to 20-8, 21-1 to 21-8, 22-1 to 22-8, 23-1 to 23-8, and 24-1 to 24 -8, 25-1 to 25-8, 26-1 to 26-8, and 27-1 are arranged in a matrix on a biological surface, that is, a surface substantially parallel to the xy plane.
[0029]
The number of the magnetic sensors 20-1,... 27-9 is arbitrary, but in the figure, since the matrix of the magnetic sensors is composed of 8 rows and 8 columns, the number of magnetic sensors is 8 × 8 = There are 64. As shown in the drawing, each magnetic sensor is arranged such that its longitudinal direction coincides with a direction (z direction) perpendicular to the body surface, that is, the xy plane. In this example, the bed surface and the XY plane of the magnetic sensor are parallel to each other. However, in order to improve measurement accuracy, it is possible to make the magnetic sensor closer to the body to be more inclined. However, since the human body 2 as a subject is always moving, if the human body 2 is brought into close contact with the human body 2, this movement will move the detection unit, and it will be difficult to detect with high accuracy.
[0030]
The detection coils of the magnetic sensors 20-1,... 27-9 include a coil for detecting a tangential component of the biomagnetic field (a component substantially parallel to the biological surface, that is, a component parallel to the xy plane) and a normal component of the biomagnetic field. There is a coil that detects (a component orthogonal to the living body plane, that is, the xy plane). As the coil for detecting the tangential component of the biomagnetic field, two coils whose coil faces are respectively oriented in the x direction and the y direction are used, and as the coil for detecting the normal component of the biomagnetic field, the coil face is used. A coil oriented in the z direction is used.
[0031]
With reference to FIG. 3, the configuration of the sensor that detects the normal component Bz of the biomagnetic field of each magnetic sensor will be described. FIG. 3 is a perspective view of a magnetic sensor for detecting a magnetic field normal component used in the biomagnetic field measuring apparatus of FIG. In FIG. 3, coils 10 and 11 made of a superconducting wire (Ni-Ti wire) are arranged such that their coil surfaces face the z direction. This coil is composed of a combination of two coils 10 and 11 having opposite directions. The coil 10 closer to the subject 2 is a detection coil, and the coil 11 farther away is a reference coil for detecting external magnetic field noise. Is done.
[0032]
The external magnetic field noise originates from a signal source that is farther than the subject, so that the noise signal is detected by both the detection coil 10 and the reference coil 11. On the other hand, since the magnetic field signal from the subject is weak, the biomagnetic signal is detected by the detection coil 10, but the reference coil 11 is almost insensitive to the biomagnetic signal.
[0033]
For this reason, since the detection coil 10 detects the biomagnetic field signal and the external magnetic field noise signal, and the reference coil 11 detects the external magnetic field noise signal, the S / N is calculated by taking the difference between the signals detected by both coils. Measurement of a biomagnetic field with a high ratio becomes possible. These coils are connected to the input coil of the SQUID via the superconducting wire of the mounting board on which the SQUID 12 is mounted, whereby the component Bz in the normal direction of the detected biomagnetic signal is transmitted to the SQUID.
[0034]
FIG. 4 illustrates a configuration of a sensor that detects tangential components Bx and By of a biomagnetic field of each magnetic sensor. FIG. 4 is a perspective view of a magnetic sensor for detecting a tangential component of a magnetic field used in the biomagnetic field measuring device of FIG. As shown in the figure, a planar coil is used in a magnetic sensor for detecting a tangential biomagnetic field component. That is, the detection coils 10 ′ and 10 ″ and the reference coils 11 ′ and 11 ″ consist of planar coils, which are arranged on a first plane 13 and a second plane 14, respectively, which are spaced apart in the z-direction. . These coils are connected to the input coils of the mounting boards of SQUIDs 12 'and 12 "similarly to those for the normal component. Sensors for detecting these Bx components are provided on two surfaces 14, 13 of a quadrangular prism which are orthogonal to each other. And a sensor for detecting the By component, thereby forming a sensor capable of detecting the Bx component and the By component.
[0035]
The tangential components Bx and By may be obtained by partially differentiating the normal component Bz obtained by the magnetic sensor of FIG. 3 with respect to x and y in addition to the detection using the magnetic sensor shown in FIG. Good. In this case, both the tangential components Bx and By and the normal component Bz can be detected and measured by one magnetic sensor.
[0036]
FIG. 5 illustrates the positional relationship between the magnetic sensors 20-1,... 27-8 shown in FIG. FIG. 5 is an explanatory diagram of the positional relationship between the magnetic sensor and the chest in the biomagnetic field measurement device of FIG. The illustrated points represent the intersections of the rows and columns on the matrix shown in FIG. 2, that is, the measurement points of the subject 2, that is, the measurement positions. Each of these measurement positions is also called a channel. As illustrated, in this example, the body axis direction connecting the head and the leg of the subject 2 is defined as the y direction, and the lateral direction of the subject 2 is defined as the x direction.
[0037]
FIG. 28 is a measurement signal diagram of a biomagnetic field at each measurement position shown in FIG. This measurement result shows the time-varying biomagnetic field waveform obtained by performing the above-described processing based on the signal detected by the magnetic sensor corresponding to each measurement position for each corresponding channel in the matrix. Things. In this example, since each channel is provided at a position where the magnetic field generated by the heart muscle can be detected, the waveform in FIG. 28 shows a magnetocardiogram waveform. As shown in FIG. 28, a case where the measurement data measured for each channel is displayed corresponding to the position for each channel is called a grid map display. 28 (a), (b), and (c) show magnetocardiogram waveforms of the tangent component Bx, the tangential component By, and the tangent component Bz, respectively.
[0038]
FIG. 29 is a magnetocardiogram waveform diagram of the tangential component Bx measured for two channels in the biomagnetic field measurement signal of FIG. The solid line shows the magnetocardiogram waveform of one channel, and the dotted line shows the magnetocardiogram waveform of another channel. The time zone T1 during which the ventricle of the heart is depolarized, that is, the time of each waveform peak in the systolic QRS wave is shown as tQ, tR, and tS, respectively. The time period of the T wave, which is the diastole of the heart, is indicated as T2. When displaying the measured data, in addition to the grid map display, displaying single channel data for each row or column is called single waveform display, and data for all channels or multiple channels is superimposed. Is displayed as overlapped waveform display.
[0039]
The calculator 8 further processes the magnetocardiogram waveform obtained by taking in the output voltage from the magnetic sensor, for example, averaging processing, isomagnetic map, and time integral chart creation processing. It is stored in a storage device and can be displayed on a display unit by a predetermined operation as needed. For example, referring to FIG. 29, a point in time when the rising portion of the QRS wave matches the threshold SL by a predetermined time (tOFF), and when a predetermined time T3 has elapsed from the point in time t1 The data up to t2 is added a predetermined number of times. This is averaging (averaging), and the predetermined time T3 is called an averaging time, and tOFF is called an offset time.
[0040]
Further, the magnetocardiogram waveform data may be integrated over a predetermined time range. A map formed by connecting points having the same time integration value is called a time integration diagram. A map formed by connecting points having the same magnetocardiogram waveform signal value is called an isomagnetic diagram. FIG. 30 shows an isomagnetic field diagram at a specific time interval corresponding to the measurement signal of FIG. 28, and shows an example of a sampling cycle every 20 msec. It goes without saying that it can be changed.
[0041]
Since each channel is roughly set, the distance between the isomagnetic lines, that is, the magnetic field intensity difference is set in advance, and linear interpolation is performed between the channels to draw the isomagnetic lines, so that the isomagnetic lines more suitable for diagnosis can be obtained. You can make a diagram. 29, the time from the time t1 to the peak position (tR) of the QRS wave in the time characteristic of the signal data detected by each sensor is called a propagation time, A map created by connecting points of equal time is called a propagation time diagram. The time point t1 may be further determined by detecting a peak position time point of the QRS wave and using this time point as a reference.
[0042]
Further, the setting level of the threshold value SL can be changed. The time point t1 may be based on the time point when the falling part of the QRS wave matches the threshold value SL. The measured biomagnetic field signal is generated by an electrophysiological phenomenon in the living body, and its source is approximated by a current dipole model, and the current dipole of the magnetic field source is synthesized on the isomagnetic line. It can be displayed and is called magnetic field source display. The isomagnetic diagram, the time integration diagram, and the propagation time diagram are reconstructed in correspondence with the plane on which the sensors are arranged. It can be reconstructed as a mapping.
[0043]
From the registration of the subject 2 to the data measurement, analysis display and printing of the data measurement are performed by a series of operations while viewing the display screen on the display unit 8-1. Give an explanation. In FIG. 1, the analysis charts described above are all created by the computer 8 equipped with appropriate software for the measurement and data analysis of the biomagnetic signal. At the time of this creation, a display screen of a desired layout can be obtained by operating the screen on the display unit 8-1, the keyboard unit 8-2, and the mouse 8-3.
[0044]
FIG. 6 shows a screen of a desired basic layout displayed on the display 8-1 shown in FIG. FIG. 6 is a basic configuration diagram of a screen displayed on a display unit of the biomagnetic field measurement device of FIG. As shown in the figure, a title bar 801, a menu bar 802, and a tool bar 803, on which icons are arranged, are arranged in the upper part of the display screen of FIG. I have.
[0045]
Each of the above units can be considered as a display area or area. These arrangements are commonly displayed on the operation screen for other processing purposes, for example, processing for registration and readout of a subject, measurement of a magnetic field, analysis of measurement data, and the like. This increases ease of use and reduces the time for measurement and processing.
[0046]
The central portion of the basic screen includes an examinee information section 804 arranged in order from left to right, an analysis data section 805 for displaying analysis data such as a diagram and a waveform, and an operation area section 806. It is arranged. The lower part is a status bar 807, which is a message bar part 807-1 for displaying a guide message for the next operation arranged on the left side and a date and time display part 807 arranged on the right side thereof. -2. Note that the message bar section 807-1 and the date and time display 807-2 may be one display area. In addition, each of the above-described units indicates a schematic location, and detailed illustrations are omitted in each case.
[0047]
In the basic screen in this example, the title bar section 801 that always displays the name of this system at the top, a menu bar section 802 that performs basic operations of this system, and the frequency of use of the menu bar section 802 Since the tool bar section 803 capable of high-level operation is arranged, the user does not need to search the operation area every time the operation screen changes, and if the user always looks at the top of the operation screen, the currently operating system can be operated. You can know. In addition, assuming that the human is reading the text at the top of the screen, it is clear that this is the first place to look, so by providing the basic items in the operation of this system at the top, , Has improved usability in a natural way.
[0048]
At the center of the screen, an analysis data section 805, which is the main body of the operation screen, is provided in the center to improve the visibility, and on the right side, an operation area section unique to the operation screen is provided. By providing the 806, the arrangement of the operation screen and the operation unit in the right-hand operation is the same as that of the right-hand operation, so that the operation can be performed without discomfort. Therefore, even if this operation screen is adopted as an operation screen with a touch panel, care is taken so that the right hand operating the operation area section 806 does not hinder the analysis data section 805.
[0049]
Similarly, a subject information section 804 having only a confirmation function is provided on the left side of the analysis data section 805. The subject information section 804 displays information on the subject under measurement or information on data under data analysis and information on the subject, so that the subject under measurement or the signal under data analysis is always displayed. You can perform operations while checking the data. In addition, since the left position is the farthest position in the right hand operation, consideration is made so as not to affect the visibility of the display even if it is adopted in an operation screen with a touch panel.
[0050]
As shown in FIG. 10, the analysis data section 805 and the operation area section 806 are replaced by the subject list and the data list of the subject only when the subject list is displayed. When the subject list screen is displayed on the subject information section 804, information on the subject on which the cursor is placed is always displayed in the subject list on the screen. When analysis data such as a diagram or a waveform is displayed in the analysis data unit 805 as shown in FIGS. 12 to 14 and the like, the displayed analysis data is obtained. The information about the subject is displayed at all times.
[0051]
Thus, the relationship between the displayed analysis data and the subject from which the analysis data has been obtained can be clearly known. As described above, in the operation screen of this system, the subject information section 804 is always displayed at the fixed position (the left side in the figure) of the operation screen, as in the menu section 802. It is not necessary to search the subject information area every time the operation screen is changed, and can be known by always looking at a predetermined position (left side) of the operation screen.
[0052]
As shown in FIGS. 12 to 14, the title bar 801 displays the name of the frame, specifically, the name "Multichannel MCG System". Since the “Multichannel MCG System” is unclear in the drawing, it is shown outside the screen. The same applies to the following drawings. In the operation area 806, operation elements such as buttons and text boxes are arranged.
[0053]
A menu section 802 is a section for selecting an operation menu, and includes a “file (F)”, a “subject list (L)”, a “data measurement (Q)”, a “data analysis (Q)”. A), "option (O)" and "help (H)", and are arranged in the order of operation.
[0054]
With reference to FIG. 7, the contents of each operation menu in the menu section 802 on the screen will be described. FIG. 7 is an explanatory diagram of an operation menu in a menu bar portion of an operation screen displayed on the display unit of the biomagnetic field measurement device in FIG. In FIG. 7, the contents of these menus are displayed as pull-down menus by designating and clicking the corresponding menu buttons on the cursor of the pointer device (hereinafter simply referred to as "click"). For this reason, when the operation menu is not required, only the keywords for calling the respective menus are compactly displayed on the menu section 802. Therefore, the keywords required for each operation such as the analysis data section and the operation area section are required. The display area can be set wider.
[0055]
Then, when an operation menu is required, the keywords arranged in accordance with the operation procedure can be displayed by selecting from the menu bar section 802, and the operation can be instructed. At this time, since the keywords are arranged according to an arrangement of characters (from left to right), the operation can be instructed in a natural manner.
[0056]
In FIG. 7, in the pull-down menu of "File (F)", a page layout dialog box (not shown) is opened, "Page layout (U)" for setting a page layout, and "Page layout (U)" before printing. The items include "Preview (V)" for preview, "Print (P)" for printing data, and "End (X) of magnetocardiographic system" for terminating Multichannel MCGSystem.
[0057]
The pull-down menu of the "subject list (L)" includes items of "subject list (L)", "subject deletion (P)", and "data deletion (D)". When "Examinee list (L)" in the pull-down menu is clicked, an examinee list screen shown in FIG. 10 is displayed.
[0058]
"Delete subject (P)" in the pull-down menu is for deleting the subject on which the cursor is placed in the subject list on the subject list screen of FIG. When it is clicked, a confirmation dialog box (not shown) for confirming whether to delete the file is opened, and when the deletion is necessary, a button "OK" in the dialog box is clicked. To cancel the deletion, the user clicks the "Cancel" button. When a subject is deleted, all data in the data list for that subject is also deleted.
[0059]
"Data deletion (D)" is the data displayed on the lower part of the screen among the data on the subject on which the cursor is placed in the subject list on the subject list screen of FIG. Click to delete the examiner's data, and when it is clicked, a confirmation dialog box (not shown) opens to confirm whether or not to delete the data. A button "OK" in the box is clicked, and a button "Cancel" is clicked to cancel the deletion.
[0060]
The pull-down menu of “Data measurement (Q)” includes items of “FLL adjustment (F)” and “Data measurement (Q)”. When "FLL adjustment (F)" in the pull-down menu is selected, the bias current Ibias and the offset voltage VOFF of the FLL circuit 6 are automatically adjusted according to the flow of FIG. When the FLL adjustment is being executed, the contents of the operation screen are not updated and the input from the user is not accepted at all until the FLL adjustment is completed. When the adjustment of the FLL is completed, the state returns to the state before the execution of the FLL adjustment. When "Data measurement (Q)" is clicked, a data measurement screen including a grid map (FIG. 12) is displayed.
[0061]
The pull-down menu of "Data analysis (A)" is "Single waveform display (W)", "Overlap waveform display (M)", "Grid map display (G)", "Equimagnetic field diagram (B)" , "Time integral diagram (T)" and "propagation time diagram (P)". When “single waveform display (W)” is clicked, a single waveform display character screen (FIG. 18) is displayed. When “overlap waveform display (M)” is clicked, a superimposed waveform operation screen (FIG. 20) is displayed. When "grid map display (G)" is clicked, a grid map operation screen (FIG. 21) is displayed.
[0062]
Also, when the “isomagnetic diagram (B)” is clicked, the isomagnetic diagram screen (FIG. 23) is displayed. When the “time integral diagram (T)” is clicked, the time integral diagram screen (FIG. 27) is displayed. When "Propagation time diagram (P)" is clicked, a propagation time diagram screen (FIG. 26) is displayed.
[0063]
The pull-down menu of “Option (O)” includes “Magnetic field source display (S)”, “Line mode (L)”, “Fill mode (F)”, and “3D display setting (D)”. When "display magnetic field source (S)" is clicked, a current dipole estimated to have generated a magnetic field measured when displaying the isomagnetic diagram is indicated by an arrow on the isomagnetic diagram. The “line mode (L)” and the “fill mode (F)” specify display of only contour lines and display of filling between contour lines when displaying a contour map, and are mutually exclusive. You. When "3D display setting (D)" is clicked, a dialog box for setting a line of sight for three-dimensionally displaying the contour map opens, and an input from the operator is accepted.
[0064]
The "Help (H)" pull-down menu includes "Contents (C)", "Search by keyword (S)", and "Version information (A)". Used to present a table of contents, search for topics in keywords, and open a version dialog box.
[0065]
The tool bar section 803 includes “print” (808), “print preview” (809), “subject list” (810), “data measurement” (811), “system adjustment” (812), "Single waveform display" (813), "Overlap waveform display" (814), "Grid map @ waveform display" (815), "Equimagnetic field diagram" (816), "Time integration diagram" (817), "Propagation" An icon “time diagram” (818) is arranged. These are not shown in detail, but are linked to menu functions, and frequently used items can be selected from pull-down menu items.
[0066]
That is, “print” (808) is “print (P)” of the file (F), “print preview” (809) is “print preview (V)” of the “file (F)”, and “ "List of subjects" (810) is "subject list (L)" of "subject list (L)", "data measurement" (811) is "data measurement (Q)" of "data measurement (Q)", " “System adjustment” (812) is “FLL adjustment (F)” of “Data measurement (Q)”, and “Single waveform display” (813) is “Single waveform display (W)” of “Data analysis (A)”. "," Overlap waveform display "(814) is" overlay waveform display "of" data analysis (A) ", and" grid map waveform display "(815) is" grid map waveform display of data analysis (A) ". "And" isomagnetic diagram "(816) are" isomagnetic diagram "of" data analysis (A) ", The “time integration diagram” (817) corresponds to the “time integration diagram” of “data analysis (A)”, and the “propagation time diagram” (818) corresponds to the “propagation time diagram” of “data analysis (A)”. I have.
[0067]
As described above, a menu linked to an icon can be selected by simply clicking the icon. Therefore, operations that are frequently used can be easily operated simply by clicking on the icon adjacent to the analysis data section 805. Therefore, compared to the operation of the menu section 802, the operation can be easily recognized. It can be operated with easy icons. The icon may be selected by the user, or may be automatically displayed on the toolbar 803 according to the frequency of use (the number of times).
[0068]
Hereinafter, the system operation will be described with reference to the flowchart of FIG. FIG. 8 is a flowchart showing an operation in the biomagnetic field measuring apparatus of FIG. A series of descriptions of system adjustment, subject selection and registration, data measurement, and data analysis will be described in detail with reference to FIGS.
[0069]
In FIG. 8, when the power of the computer 8 is turned on (S-1), the operating system is started up, and a program start icon incorporated in the computer is displayed on the display unit 8-1 (S-). 2). When a program of the Multichannel MCG System is selected from the icons (S-3), an operation screen is displayed and operation becomes possible.
[0070]
When the MCG system starts up, the operation screen as described above is displayed. In the system according to the present example, the subject list screen shown in FIG. 10 is displayed as an initial screen (S-4). This is because the relationship between the subject and the measurement or analysis data of the subject is extremely important, and the system manages data using subject information as keywords. In other words, measurement data and analysis data cannot be managed without subject information.
[0071]
Therefore, in this system, on the subject list screen, first, when the subject is registered or registered, the subject is specified. If there is measurement data, specify the target data. It is to be noted that an operation screen for waiting time at system startup may be provided prior to the subject list screen, and an operation screen serving as a table of contents of the present system may be provided.
[0072]
A series of operations from registration of the subject to measurement of the data of the registered subject and analysis of the measured data are performed on an operation screen displayed on the display 8-1. It is performed while watching. Therefore, before describing the series of operations, the layout of the operation screen will be described first. The subject list screen shown in FIG. 10 will be described. FIG. 10 is a subject list screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. The left side is occupied by the subject information section. The subject list is displayed at the top of the entire right side, and the data list is displayed at the bottom. Items in the subject list include ID (subject ID number), name, registration date (date of data registration), number of measurements (number of times data measurement was performed), date of birth , Age, height, weight, comments (comments on the subject), and the like.
[0073]
The subject list on the upper right side can be scrolled by the vertical scroll bar, and the items of the subject list can be scrolled by the horizontal (horizontal) scroll bar. can do. The row of the selected subject is highlighted.
[0074]
The items in the data list relating to the selected subject include the ID, the type of data (raw data or averaging), or the sampling interval (when data measurement is performed). (Sampling interval in milliseconds), sampling time (seconds), classification (disease classification information), Date and Time (date and time when data was measured), comments (data Comments).
[0075]
The data list can be scrolled with a vertical scroll bar, and the data list item can be scrolled with a horizontal (horizontal) scroll bar. The selected line of data is highlighted. According to this subject list screen, information of each subject is displayed on the subject list in one line. As a result, the information of the subjects arranged vertically can be clearly separated, so that the discriminability can be improved. For example, the erroneous operation of selecting another subject by mistake can be reduced. it can.
[0076]
The information of each subject can be scrolled by a horizontal (horizontal) scroll bar, and the information of the selected subject is vertically arranged for each item in a vertically long subject information section. Therefore, visibility is not impaired.
[0077]
In this case, the visibility may be further improved by enabling the data list items of each subject to move forward and backward (left and right). Further, by displaying the information of each subject on one line, many subjects can be seen at a time, so that the number of times of scrolling with the vertical scroll bar can be reduced.
[0078]
Further, the data can be displayed in the lower data list by a simple operation of simply placing the cursor on the subject list to be selected from the subject list and clicking on the subject list to be selected. In addition, since the subject list and the data list are arranged vertically, movement of the line of sight can be reduced, so that the relevance can be easily recognized.
[0079]
The size of the data list can be freely changed by a simple operation of moving the cursor to the upper part of the area and dragging the data list. Therefore, the size of the data list can be freely adjusted according to the number of data lists. Can be set.
[0080]
A row of a desired subject is selected from the subject list on the subject list screen (S-5). Thereafter, the flow is branched into three in the menu (S-6). According to one of the branches, the item "End of magnetocardiography (X)" in the menu "File (F)" is selected, and in this case, end processing such as closing the operation screen is performed (S). -7), whereby the system is shut down (S-8). Thereafter, the power of the computer 8 is turned off (S-9), and all the operations are terminated.
[0081]
According to another branch, data analysis (S-11) and data measurement (S-12) are performed. The data analysis is performed in the menu "Data analysis (A)", "single waveform display (W)", "overlap waveform display (M)", "grid map display (G)", " This can be executed by selecting any one of the following items: isomagnetic diagram (B), time integration diagram (T), and propagation time diagram (P).
[0082]
Further, data measurement can be executed by selecting a submenu "Measurement panel (P)" in a menu "Data measurement (Q)". When another subject or another data is selected, the process returns to S-4 by selecting the item “subject list (L)” in the menu “subject list (L)”. Will be. The details of the subject selection in step S-5, the data analysis in step S-11, and the data analysis in step S-12 will be described in more detail below with reference to FIGS. You.
[0083]
FIG. 9 shows the flow of subject selection in step S-5 in FIG. FIG. 9 is a flowchart for selecting a subject in the flowchart of FIG. The flow of the subject selection branches depending on whether or not the information of the subject to be selected is already registered in the system. If the information on the subject to be selected has not been registered (YES in S-5-1), the cursor on the subject list in FIG. Move to the last line (S-5-2). The last line is always prepared as a blank line to add and register new subject information. Subsequently, each column of the subject information is input to the blank line using the keyboard 8-2 (S-5-3).
[0084]
When data is entered in the last blank line of the subject list for registration of subject information, a new blank line is added below that line for the next registration. If new subject information is to be continuously registered, the cursor may be shifted one line down and input one after another. If the input of all the subject information to be input is not completed (S-5-4), the process returns to the above (S-5-2). select.
[0085]
When the subject information to be selected has already been registered (NO in S-5-1) and when the input of the subject information has been completed (YES in S-5-4) Specifies the subject information to be selected from the subject list by clicking the button of the mouse 8-3 (S-5-5).
[0086]
In this example, multiple input data or operation instructions to be input are displayed, such as by displaying a pull-down menu on the operation screen, excluding character input such as the subject's name and address, and the mouse is selected from among the selection targets. The input operation is performed by instructing the user to click on the specific object. Thus, most operations can be performed by mouse operation, so that a comfortable operation environment can be provided to an operator who is not accustomed to the keyboard, and input / operation time can be reduced.
[0087]
As for the plurality of selection targets in the pull-down menu, selection targets that can be input / operated in this device or its input / operation state are set and displayed in advance, so that erroneous input / erroneous operation can be reduced. Further, in this embodiment, since the cursor can be positioned on the input area and the input can be performed via the keyboard, the degree of freedom of the input by the operator is secured.
[0088]
In this example, it is assumed that a character is input using a keyboard. However, a keyboard dialog may be displayed at the time of input, and the input may be performed by operating the mouse with a mouse. Further, a handwriting input dialog may be displayed and handwriting input may be performed by operating the mouse. Further, a touch panel may be provided on the display unit, and input / operation may be performed on a screen via a fingertip or an input pen. Thus, the operability of input / operation can be remarkably improved.
[0089]
FIG. 11 shows the flow of data measurement in step S-12 in FIG. FIG. 11 is a flowchart of data measurement in the flowchart of FIG. First, a grid map of the magnetocardiogram waveform is displayed as an initial screen as shown in FIG. 12 (S-12-1). FIG. 12 is an all-channel data measurement screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. In FIG. 12, in the operation area portion, operations for channel selection and ON / OFF of the waveform monitor can be respectively performed, and further, indicates whether measurement is performed from the front or the back of the subject. It is possible to set the direction, the signal sampling conditions, and the scale of the waveform display.
[0090]
The channels consist of 64 8 × 8 channels, and all channels can be selected by clicking the “Select All Channels” button or by dragging the channel matrix diagonally from end to end. Also, by dragging the channel matrix in units of rows or columns, channels can be selected in units of rows or columns.
[0091]
In any case, the magnetocardiogram waveform of the selected channel is displayed in the analysis data section. In the case of selection in units of rows or columns, the selection is displayed as shown in FIG. FIG. 13 is a data measurement screen displayed on the display unit of the biomagnetic field measurement apparatus in FIG. 1 and selected in units of rows or columns. In this case, the selected waveform is enlarged to the full scale on the time axis and displayed.
[0092]
That is, when all 64 channels are selected, as shown in FIG. 12, the analysis data portion is divided into upper, lower, left, and right (cells) to give priority to the display of all channels. As shown in FIG. 13, the analysis data portion is divided into upper and lower parts to form a familiar graph form in which the time axis is left and right, thereby giving a display form in which visibility is prioritized.
[0093]
As for the monitoring of the waveform, when the "ON" button (middle right) is pressed, the acquisition of the signal and the updating of the waveform are repeated at a specified time, for example, from 0.5 sec to 2 sec. The magnetocardiographic signal is monitored. When the “OFF” button is pressed, the updating of the waveform is stopped. For the FLL, by clicking the “Lock” button or the “Unlock” button, the magnetic field lock can be performed on the 64 SQUID sensors, and the lock can be released. In this case, if one “Lock” or “Unlock” button is pressed, the state is maintained until the other button is pressed. This avoids an unselected malfunction state.
[0094]
For the sampling time (measurement time) and interval (scale), click the corresponding text box with an inverted black triangle to open a pull-down menu of selectable numerical values and select the desired number from the pull-down menu. can do. The selectable numbers are, for example, 1 sec, 5 sec, 10 sec, 30 sec, 1 min and 2 min for the time, and 0.1 msec, 0.5 msec, 1.0 msec, 2.0 msec, 4.0 msec, for the intervals, for example. They are 5.0 msec and 10.0 msec. The time may be selected from about 1 sec to about 24 h as needed.
[0095]
In the illustrated "scale" box, "time" is the time scale in msec units, that is, the horizontal scale, and "signal" is the scale of the A / D converted signal. , I.e., the vertical scale. For these, similarly to the selection of the sampling time and interval, a desired numerical value is selected from a pull-down menu opened by clicking the corresponding text box.
[0096]
As the channels, in addition to the 64 channels, for example, 16 auxiliary channels may be prepared, and an electrocardiographic waveform may be obtained in the auxiliary channels. At the bottom of FIG. 26, the waveform of the tenth channel as a reference channel is displayed, which is the electrocardiographic waveform obtained on the tenth channel among the auxiliary channels. The magnetocardiogram waveform generally contains magnetic noise, while the electrocardiogram waveform does not contain such noise. FIG. 26 is a diagram of a propagation time display screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG.
[0097]
Therefore, by comparing the displayed magnetocardiogram waveform with the electrocardiogram waveform of the reference channel, information as to whether or not the magnetocardiogram waveform contains magnetic noise can be obtained. Of course, the electrocardiographic waveform may be obtained from any of the regular 64 channels instead of the auxiliary channel. In addition, an electroencephalogram, an electroencephalogram, a blood flow waveform, a blood pressure waveform, or the like may be used. Further, the electrocardiographic waveform of the pregnant woman and the magnetocardiographic waveform of the fetus may be compared.
[0098]
As the reference waveform, not only a reference waveform of one channel but also a reference waveform of a plurality of channels may be displayed. Further, the reference channel may be used to input not only a signal from a living body but also various control signals for maintenance or the like.
[0099]
In the subject information section (804 in FIG. 6) of the data measurement operation screens of FIGS. 12 and 13, the measurement part 76 displayed under the subject information (ID and the like) is the measurement of the subject. It shows the positional relationship between a part and a measurement point. The positional relationship between the measurement site and the measurement points of the subject is determined by the physique of the subject such as age, height, weight, and gender, and the measurement direction of the chest surface or back.
[0100]
In this example, as shown in FIG. 14, drawing information indicating the positional relationship between the measurement site and the measurement point of the subject is represented by the sex, measurement direction, physique information such as height and weight, and measurement direction of the subject. It is installed in the computer 8 as a database that can be pulled out. FIG. 14 is a database for generating a measurement site map of the subject displayed in the subject information section on the basic operation screen of FIG.
[0101]
In order to extract information from the database, physique information such as height and weight of the subject list of FIG. 10, gender of the subject list, the age calculated from the date of birth and the date of measurement, and FIG. Information such as the “direction” of the measurement in FIG. 13 is used. When measuring cardiac magnetism, since the positional relationship between the body surface and the heart inside the body greatly varies from individual to individual, it is also conceivable to add a parameter representing the positional relationship between the figure representing the subject and the measurement site. In addition, a medical image such as a photographic image or an MRI at the time of measurement of the subject can be synthesized as the subject part.
[0102]
Returning to the description of the flowchart of FIG. A monitor channel is selected and specified (S-12-2). When the lock button of the FLL is pressed, the magnetic field of all SQUIDs is locked (step S-12-3). In this state, the sampling time and signal, which are the measurement parameters, are set, and the measurement direction of the subject is set (step S-12-4). When the measurement direction of the subject is input, a measurement site map of the subject is extracted from the measurement site database of FIG. 13 from the subject information in the subject list of FIG. 10 and the input measurement direction, and FIG. A subject site map is displayed on the subject information display unit 804 (see FIG. 6) in FIG.
[0103]
For these settings, standard setting values prepared in advance or conditions previously set in the biomagnetic field measuring apparatus can be used, and can be omitted from the next time. As a result, it is not necessary to set the conditions every time, so that the setting time can be reduced. The setting condition may be recorded with a name or the like and can be called.
[0104]
When the "start" button in the "measurement" box is pressed, data measurement starts (step S-12-5). When the measurement is started, the displayed signal waveform is fixed as it is. When the measurement is completed, the collected data is displayed and confirmed. That is, the screen display shown in FIG. 15 is made, and the waveform is confirmed (S-12-6). Thereafter, the necessity of storing the data is determined (S-12-7). If the data needs to be stored, the menu "File (F)"-"Save (S)" is selected and the signal is stored. Is added to the subject's data list. If storage is not required, it is not stored (S-12-8).
[0105]
Thereafter, it is determined whether or not measurement is necessary again, including the case where storage is not required (S-12-10). If necessary, a monitor channel is selected and “Data measurement (Q)” menu item “ Data measurement (Q)] item is selected (S-12-2) and the above steps are repeated, and if not necessary, all the steps of data measurement are completed. 15 is a waveform confirmation screen displayed at the end of measurement on the display unit, where Fig. 15 shows an example in which a channel in the second column is selected as a channel.
[0106]
In FIG. 15, at the bottom of the analysis data section, there is a scroll bar-262 in which the scroll box 261 moves. The scroll box 261 is movable between the left and right ends of the scroll bar-262, and the width w of the scroll box 261 represents a time scale. The time width between the left and right ends of the scroll bar-262 represents the measurement time, and therefore, the displayed waveform is a portion of the waveform generated during the measurement time corresponding to the time scale w of the scroll box 261. 5 is an enlarged waveform of FIG.
[0107]
Accordingly, the operator indicates how long (the width of the scroll box 261) the waveform currently displayed in the analysis data unit 805 in the measurement time (the width of the scroll bar-262), Since it is possible to grasp at a glance whether the waveform indicates the first half or the second half of the measurement time, the visibility can be improved. Since an accurate display start time is required to reproduce the waveform display at another occasion, it is displayed to the left of the scroll bar 262.
[0108]
Further, since the position of the scroll box 261 and the waveform of the analysis data section 805 are linked, the display area of the analysis data section 805 can be moved by moving the cursor while dragging the cursor to the scroll box 261. A waveform for a predetermined time may be viewed. In this way, the scroll bar-262 can be treated as a table of contents, for example, the waveform of a predetermined time can be easily confirmed, and the measurement contents can be confirmed in detail.
[0109]
FIG. 16 is a flowchart of the data analysis in step S-11 in FIG. FIG. 16 is a flowchart of data analysis in the flowchart of FIG. In the data analysis, various kinds of waveforms and diagrams are displayed to obtain information necessary for diagnosis. In the "data analysis (A)" menu shown in FIG. By making a selection, (S-11-1) various types of waveforms and diagrams can be selectively displayed.
[0110]
That is, if "single waveform display (W)" of "data analysis (A)" is selected, the single waveform screen shown in FIG. 17 is displayed (S-11-2), and "data analysis (W)" is displayed. If "A) (superimposed waveform display (M)" is selected, the superimposed waveform screen shown in FIG. 20 is displayed (S-11-3), and "grid map display (data analysis (A)") is displayed. G) is selected, the grid map waveform screen shown in FIG. 21 is displayed in (S-11-4), and if "Data analysis (A)" is selected, "Equimagnetic field map (B)" is selected. When the isomagnetic diagram screen shown in FIGS. 22, 23, and 24 is (S-11-5) and “Propagation time diagram (P)” of “Data analysis (A)” is selected, FIG. When the propagation time diagram screen shown is (S-11-6) and "time analysis diagram (T)" of "data analysis (A)" is selected, the time integration diagram screen shown in FIG. In -11-7), are respectively displayed. If "End (X) of magnetocardiographic system" of "File (F)" is selected, the system is ended.
[0111]
If the icons 813 to 818 arranged on the toolbar 803 in FIG. 6 are clicked on the respective screens, the display screen of the waveform or diagram designated by the click is displayed instead. In the flowchart of FIG. 16, in S-11-1, the branch portion is set to “branch by menu or icon” instead of being described only by “branch by menu”.
[0112]
Therefore, according to this example, various analysis data can be obtained by simply clicking the icon buttons 813 to 818 in the toolbar unit 803 without selecting a menu in the flowchart of FIG. And operability can be improved by reducing erroneous operations.
[0113]
The time waveform display screens shown in FIGS. 17, 20, and 21 will be described. 17 is a single waveform screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. 1, FIG. 20 is a superimposed waveform screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. 1, and FIG. 3 is a grid map screen displayed on a display unit of one biomagnetic field measurement apparatus. In the illustrated operation area, the magnetic flux density in the “scale” box is the value of the full scale on the plus side and the minus side with reference to the zero level (the unit is picotesla (pT)). The value is selected in the pull-down menu that is opened by clicking the triangular black button in that text box.
[0114]
In FIGS. 22 to 24, 26 and 27, by clicking a radio box in the “display component” box, the waveform of the normal component or the waveform of the tangent component can be selected and displayed on the screen.
[0115]
According to the single waveform display screen shown in FIG. 17, it is possible to compare the shapes and sizes of the waveforms of the channels arranged and displayed vertically in the analysis data section. Similarly, according to the superimposed waveform display screen of FIG. 20, the single waveforms arranged vertically as shown in FIG. 17 are displayed in an overlapping manner, and the shapes and sizes of the waveforms can be compared. When the “Print (P)” item of the “File (F)” menu in the menu bar section 802 is displayed while the single waveform display screen shown in FIG. 17 is displayed, the report shown in FIG. 18 is output. You. FIG. 18 is a print report of the single waveform display of FIG. In this report, the subject information 74, the signal information 75, and the measurement site 76 correspond to the information displayed on the single waveform display screen of FIG.
[0116]
A part of the magnetic field waveform 51 printed in FIG. 18 in detail is shown in FIG. FIG. 19 is a diagram showing a scale of the print output of the magnetocardiogram waveform of FIG. This magnetocardiogram waveform is made compatible with an electrocardiogram which is often used. In the report shown in FIG. 18, nine magnetic field waveforms are printed, and each magnetic field waveform 51 is drawn on the grid pattern shown in FIG. This lattice pattern is composed of squares of 1 mm in length and width, and the squares are grouped into 5 pieces in length and width, and the boundaries are drawn by thick lines. The horizontal axis in FIG. 19 represents the time axis, one square of 1 mm square represents 0.04 seconds, the vertical axis represents the magnetic flux density, and one square is 1 [pT] (picotesla). .
[0117]
With reference to FIG. 22, the color-coded display of the isomagnetic lines displayed on the display unit of the biomagnetic field measuring apparatus in FIG. 1 will be described. FIG. 22 is an isomagnetic diagram displayed on the display unit of the biomagnetic field measuring apparatus in FIG. 1. In FIG. 22, a vertically elongated magnetic field strength index box 310 is arranged at the right end of the analysis data section. The magnetic field strength index box is divided into twelve sections having different colors. This is to improve visual (color) recognizability by distinguishing the magnetic field intensity range indicated by each stripe pattern on the isomagnetic diagram screen shown in FIG. 22 by the type of color. It is.
[0118]
That is, the center position 311 in the longitudinal direction of the magnetic field strength index box 310 is a position where the magnetic field strength is zero, and the sections above the center position are referred to as the first to sixth sections in order from the center position. Thus, for example, the first section has a magnetic field intensity range of 0 to 2 pT, the second section has a magnetic field intensity range of 24 pT, the third section has a magnetic field intensity range of 4 to 6 pT, and the fourth section has a magnetic field intensity range of 6 to 8 pT. The fifth section corresponds to a field strength range of 8 to 10 pT, and the sixth section corresponds to a field strength range of 10 to 12 pT.
[0119]
The same applies to the section below the center position. However, a section above the center position indicates a plus direction magnetic field strength, and a section below the center position indicates a minus direction magnetic field strength. The isomagnetic diagram shown in FIG. 22 is displayed in different colors according to the magnetic field strength in accordance with the definition of the correspondence between the magnetic field strength range and the color in the magnetic field strength index box 310. In addition, as a color, the plus side of the magnetic field strength may be a warm color system, the minus side may be a cool color system, and the center may be yellow. Thereby, the strength of the magnetic field can be recognized in color, so that the visibility can be improved.
[0120]
In this example, the propagation time diagram of FIG. 26 and the time integration diagram of FIG. 27 described later also display the characteristic amount of the biomagnetism by the same contour diagram, and thus are displayed in the same color scheme as the above-mentioned contour map. And the displayed characteristic amount is difficult to understand, the color scheme is changed according to the displayed characteristic amount as described below.
[0121]
The colors displayed on the screen are generated by combining three colors of RGB, that is, red, green and blue. The intensity of each color of RGB is represented by 0 to 100. For example, when the RGB value is (0,0,0), it is black, when (100,100,100) is white, (100,0,0) is completely red. , RGB values are (50, 0, 0), the brightness is red, which is half of (100, 0, 0). At this time, in this example, the maximum value of the isomagnetic diagram is (100, 20, 20) bright red, the minimum value is (40, 40, 100) violet blue, and the 0 value is (100, 100, 20). 90), and in the time integration diagram, they are respectively red (100, 20, 67) close to pink, blue containing (20, 57, 100) green, and (90, 100, 90) , The maximum value of the propagation time diagram is bright red of (100, 20, 20), and the 0 value is light gray of (97, 97, 97) (the 0 value is the minimum value in the propagation time diagram). . The color of the characteristic amount between the maximum value and the zero value or the intermediate value between the minimum value and the zero value is obtained by linearly storing between the maximum value RGB value and the zero value RGB value.
[0122]
According to the above color scheme, a color corresponding to a characteristic amount having the same absolute value is a warm color system in the case of a positive value and a cool color system in the case of a negative value, but has the same chromaticity. Here, the chromaticity is the brightness of gray that has the same appearance as that of the color, and the chromaticity being equal means that those colors are similarly conspicuous.
[0123]
Since the positive value and the negative value have almost the same value range in the isomagnetic diagram and the time integral diagram, the positive and negative chromaticities are aligned to give the same appearance depending on the strength of the characteristic amount. It will be easier to understand. Also, when the display contents are displayed on a black-and-white display device or printed by a black-and-white laser printer, characteristic values with the same absolute value are printed in gray with the same darkness, so the distribution of the characteristic values can be accurately determined. Can be read.
[0124]
According to this example, since the magnetic field strength index box 310 is provided near the analysis data section, the color to be compared, that is, the color added to the map and the predetermined color of the magnetic field strength index box 310 are viewed from the viewpoint. Since the movement can be confirmed while comparing the movement without greatly moving, the relationship between the level of the magnetic field and the color can be clearly determined. In this embodiment, the magnetic field strength index box 310 is provided at the right end of the analysis data section, but may be provided near the analysis data section, for example, at the upper, lower, or left side.
[0125]
In FIG. 22, “number of maps” in the “reconstruction parameter” box indicates the number of isomagnetic maps to be displayed, and “maximum value” indicates both ends of the magnetic field strength index box 310. The term “interval” corresponding to the magnetic field strength means a magnetic field range corresponding to the length of each section in the magnetic field strength index box 310. The value can be selected by clicking the triangle or inverted triangle button in the corresponding text box.
[0126]
The ECG waveform of the reference channel and two map time selection cursors 311 and 312 are displayed at the bottom of the analysis data section. A division line having the same interval is displayed between the two map time selection cursors 311 and 312, and the number of the division lines matches the number of maps selected by the map number selection.
[0127]
In addition, the two map time selection cursors 311 and 312 can move their positions independently in the left-right direction. If the movement changes the distance between the cursors, the space between the dividing lines also changes. The intervals between the dividing lines are always equal. Of course, each division line may be provided with a cursor and individually set one by one.
[0128]
In FIG. 22, the number of displayed isomagnetic maps is 16, but these diagrams are diagrams at the time when the dividing line on the waveform of the reference channel is located. The time is also displayed so that the user can know what time the map is. This allows the operator to indicate the extent (the width of the two cursors 311 and 312) in the analysis time (the width of the waveform of the reference channel) in the map currently displayed in the analysis data section. Since it is possible to grasp at a glance where the range indicated by the map is within the analysis time, visibility can be improved.
[0129]
Further, the range indicated by the map can be set by simply moving the two cursors with a mouse operation, so that the operation is easy. Furthermore, if the interval between the dividing lines is freely set, various analysis environments can be provided to the operator, for example, by making the questionable part dense and the other part sparse.
[0130]
Another isomagnetic diagram will be described with reference to FIG. FIG. 23 is another isomagnetic diagram displayed on the display unit of the biomagnetic field measuring apparatus in FIG. 1. Further, when the check box of the “current direction” in the operation area at the right end of FIG. 23 is clicked to display a check mark, an arrow is displayed on the isomagnetic diagram. The isomagnetic map on which the arrow is displayed is called an allo-map. For the arrows, the position indicates the position of the channel (position of the magnetic sensor), the length indicates the strength of the magnetic field, and the direction indicates the direction of the current when the direction of the magnetic field is converted into the direction of the current. I have.
[0131]
In addition, the isomagnetic map can be displayed as a two-dimensional contour map and a three-dimensional stereoscopic view shown in FIG. 24, and can be displayed by switching the display method of the operation area 806 using 2D and 3D radio buttons. can do. That is, when the 2D radio button is pressed, the two-dimensional contour map shown in FIGS. 22 and 23 is displayed as the isomagnetic map. When the 3D radio button is pressed, the three-dimensional view shown in FIG. 24 is displayed. FIG. 24 is yet another isomagnetic diagram displayed on the display unit of the biomagnetic field measuring apparatus of FIG.
[0132]
With reference to FIG. 25, a description will be given of a viewing direction setting dialog for synthesizing a three-dimensional three-dimensional view. FIG. 25 is a dialog box diagram for setting the viewing direction of the three-dimensional display of the isomagnetic map. In FIG. 25, the 3D display setting dialog is opened by selecting and clicking the “3D display setting (D)” item of the “option (O)” menu of the menu bar section 803 with the mouse 8-3.
[0133]
Normally, the three-dimensional view of the isomagnetic diagram is obtained by placing the subject 2 on the bed 3 and setting the subject 2 at a measurable position below the dual 4 in the biomagnetic field measuring apparatus system of FIG. It is easy to comprehend what is created at an angle that stands on the right side of the examiner and looks down from the vicinity of the waist to the chest of the examinee. However, depending on the installation conditions of the magnetically shielded room 1, the bed 3 and the dewar 4 may be installed symmetrically, and the angle for synthesizing the three-dimensional view in order to check the unevenness of the three-dimensional view is required. Must be configurable.
[0134]
At the top of the setting dialog for the 3D (three-dimensional) display, an arrangement diagram of the dur 4 and the bed 3 is shown, and shows how the angle of the line of sight is defined. A text box for receiving two angle parameters for determining the line-of-sight direction is arranged in the lower part. The value input in the setting dialog shown in FIG. 25 is effective in subsequent operations unless changed by the same operation.
[0135]
The propagation time operation will be described with reference to FIG. FIG. 26 is a propagation time display screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. In FIG. 26, the start position of the propagation time can be changed by changing the position of the cursor 321 moving on the reference waveform, and the position of the cursor 321 can be changed using the mouse with the mouse. It is possible by dragging. Similarly, the display of the propagation time diagram can be switched between the two-dimensional contour display and the three-dimensional stereoscopic display by using the 2D and 3D radio buttons in the isomagnetic diagram.
[0136]
FIG. 27 illustrates a time integral diagram operation. FIG. 27 is a time integration display screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. FIG. 27 shows two time integration diagrams and one difference diagram. The “difference display” of the propagation time diagram can be easily displayed by clicking a check box and displaying a check mark. When the "differential display" is checked, four cursors 331 to 334 appear on the reference waveform, and two time integration diagrams are displayed on the upper left and right, and a difference diagram is displayed on the lower left as shown. .
[0137]
The two time integral diagrams integrate the magnetocardiogram waveform over a time range of 100 msec to 140 msec and 180 msec to 240 msec set using the cursors 331 and 332 and the cursors 333 and 334 on the reference waveform, respectively. Based on the values, the respective time ranges can be changed by dragging the cursors 331 and 332 and the cursors 333 and 334, respectively, using a mouse.
[0138]
The difference diagram represents the difference between the two time integral diagrams. If there is no check mark, only two cursors (for example, the cursors 331 and 332) appear for the cursor, and only one time integration diagram is displayed for the time integration diagram. Of course, the integration time can be changed by changing the position of the cursor. As described above, according to this example, by clicking the check mark for “differential display”, two sets of cursors for prompting the next operation are displayed, so that the operation time can be shortened without giving any confusing operation. The time range can be easily set by moving the two sets of cursors with a mouse, so that operability can be improved. The display of the time integral diagram and the isomagnetic diagram can be similarly switched between the two-dimensional contour display and the three-dimensional stereoscopic display by the 2D and 3D radio buttons.
[0139]
【The invention's effect】
As described in detail above, according to the configuration of the present invention, it is easy to measure the magnetic field strength at a plurality of measurement positions, and the time characteristic diagram is used on the same scale as the electrocardiogram so that the examiner can correctly read the signal data. It is possible to provide a display method and a printing method of biomagnetic field measurement data that are comparable and have good operability.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of a biomagnetic field measuring apparatus according to an embodiment of the present invention.
FIG. 2 is a perspective view of a plurality of magnetic sensors used in the biomagnetic field measurement device of FIG.
FIG. 3 is a perspective view of a magnetic sensor for detecting a normal component of a magnetic field used in the biomagnetic field measuring apparatus of FIG. 1;
FIG. 4 is a perspective view of a magnetic sensor for detecting a tangential component of a magnetic field used in the biomagnetic field measuring device of FIG. 1;
FIG. 5 is an explanatory diagram of a positional relationship between a magnetic sensor and a chest of a subject in the biomagnetic field measuring apparatus in FIG. 1;
FIG. 6 is a basic configuration diagram of a display screen displayed on a display unit of the biomagnetic field measurement device in FIG. 1;
FIG. 7 is an explanatory diagram of an operation menu in a menu section of a display screen on the display unit of the biomagnetic field measuring apparatus of FIG. 1;
FIG. 8 is a flowchart showing an operation in the biomagnetic field measuring apparatus of FIG. 1;
9 is a flowchart for selecting a subject in the flowchart of FIG. 8;
FIG. 10 is a subject list screen displayed on a display unit of the biomagnetic field measuring apparatus of FIG. 1;
FIG. 11 is a flowchart of data measurement in the flowchart of FIG.
FIG. 12 is a data measurement screen of all channels displayed on the display unit of the biomagnetic field measurement apparatus of FIG. 1;
FIG. 13 is a data measurement screen in row units or column units displayed on the display unit of the biomagnetic field measurement apparatus in FIG. 1;
14 is a database for generating a measurement site map of a subject displayed in a subject information section on the basic display screen of FIG. 6;
FIG. 15 is a waveform confirmation screen displayed on the display unit of the biomagnetic field measurement apparatus in FIG. 1 at the end of measurement.
FIG. 16 is a flowchart of data analysis in the flowchart of FIG. 8;
FIG. 17 is a single waveform screen displayed on a display unit of the biomagnetic field measuring apparatus in FIG. 1;
FIG. 18 is a print report showing the single waveform display of FIG. 17;
FIG. 19 is a diagram showing a scale of a print output for outputting a magnetocardiogram waveform in FIG. 18;
FIG. 20 is a superimposed waveform screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. 1;
FIG. 21 is a grid map screen displayed on the display unit of the biomagnetic field measuring apparatus of FIG. 1;
FIG. 22 is an isomagnetic diagram displayed on the display unit of the biomagnetic field measuring apparatus in FIG. 1;
FIG. 23 is another isomagnetic diagram displayed on the display unit of the biomagnetic field measuring apparatus in FIG. 1;
FIG. 24 is yet another isomagnetic diagram displayed on the display unit of the biomagnetic field measuring apparatus of FIG. 1;
FIG. 25 is a diagram illustrating a dialog box for setting a line-of-sight direction of a three-dimensional display of the isomagnetic diagram.
FIG. 26 is a propagation time display screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. 1;
FIG. 27 is a time integration display screen displayed on the display unit of the biomagnetic field measurement apparatus of FIG. 1;
28 is a biomagnetic field measurement signal diagram of each measurement site shown in FIG.
29 is a magnetocardiogram waveform diagram of tangential components for two channels in the biomagnetic field measurement signal of FIG. 28.
30 is an isomagnetic diagram for each specific time corresponding to the biomagnetic field measurement signal of FIG. 28;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Magnetic shield room, 2 ... Examinee, 3 ... Bed, 4 ... Dewar, 5 ... Automatic supply device, 6 ... FLL circuit, 7 ... Amplifier / filter / amplifier, 8 ... Computer, 8-1 ... display unit, 8-2 ... keyboard, 8-3 ... mouse, 20-1 to 20-8, 21-1 to 21-8, 22-1 to 22-8, 23-1 to 23- 8, 24-1 to 24-8, 25-1 to 25-8, 26-1 to 26-8 and 27-1 to 27-8 ... magnetic sensors, 10, 10 'and 10 "and 11, 11' and 11 "coil, 12, 12 'and 12" SQUID, 13 and 14 sensor, 30 chest, 261 scroll box, 262 scroll bar, 263 display start time, 271 threshold -Sol, 273-275 ... Slider cursor, 311, 312 and 331-334 Cursor 801 title bar section 802 menu section section 803 tool bar section 804 subject information section 805 analysis data section 806 operation area section 808 Status bar section, 807-1: message bar section, 807-2: date and time display section, 808 to 814 ... icons.

Claims (7)

Using a computer with a display screen, the magnetic field emitted from the body of the subject is measured at a plurality of measurement positions with a measurement sensor, in the display method of biomagnetic measurement data to display the measurement signal on the screen, A method for displaying biomagnetic field measurement data, wherein said subject information and measurement conditions are displayed simultaneously and on the same screen. Using a computer with a display screen, the magnetic field emitted from the body of the subject is measured at a plurality of measurement positions with a measurement sensor, in the display method of biomagnetic measurement data to display the measurement signal on the screen, A method for displaying biomagnetic field measurement data, characterized in that when the characteristic amount of the measurement signal is displayed in a contour diagram, it is displayed in a different color scheme selected by the computer depending on the type of the characteristic amount. 3. The method for displaying biomagnetic field measurement data according to claim 2, wherein when the characteristic amount of the measurement signal can take both a positive value and a negative value, colors having the same chromaticity are assigned to the characteristic amounts having the same absolute value. A method for displaying biomagnetic field measurement data, characterized in that: Using a computer with a display screen, the magnetic field emitted from the body of the subject is measured at a plurality of measurement positions with a measurement sensor, in the display method of biomagnetic measurement data to display the measurement signal on the screen, Displaying a single waveform of the subject information and signal information and a multi-channel measurement signal designated by a selected channel and auxiliary information on an auxiliary channel simultaneously and on the same screen. . Using a computer with a display screen, the magnetic field emitted from within the living body of the subject is measured at a plurality of measurement positions with a measurement sensor, and in the biomagnetic field measurement data printing method of displaying the measurement signal on the screen, 5. A method for printing biomagnetic field measurement data, wherein the display screen according to claim 4 is printed by a specified operation on the display screen according to claim 4. Using a computer with a display screen, the magnetic field emitted from the body of the subject is measured at a plurality of measurement positions with a measurement sensor, in the display method of biomagnetic measurement data to display the measurement signal on the screen, 5. The display screen according to claim 4, wherein, instead of a single waveform of the multi-channel measurement signal specified by the selected channel, a multi-channel overlapping waveform for a single time axis is displayed on the screen by a predetermined specification operation. Characteristic display method of biomagnetic field measurement data. Using a computer with a display screen, the magnetic field emitted from within the living body of the subject is measured at a plurality of measurement positions with a measurement sensor, and in the biomagnetic field measurement data printing method of displaying the measurement signal on the screen, 7. A method for printing biomagnetic field measurement data, comprising printing an overlapping waveform on the display screen by a predetermined designation operation on the display screen according to claim 6.

Images