JP2008178558A - Biomagnetic field measurement device - Google Patents

Abstract

A biomagnetic field measurement apparatus capable of quickly retrieving an analysis result of a portion desired by a user and capable of displaying the analysis result in a multi-window manner.
Subsequent to “data analysis”, a “multi-window display function” (step S2-1) is provided to simultaneously display a plurality of analysis results on an operation screen. The multi-window display function enables selection from “menu selection” (step S2-2) to “automatic setting display” (step S2-3) or “manual setting display” (step S2-4). When “automatic setting display” is selected, a single waveform, grid map waveform, superimposed waveform, isomagnetic field diagram, and time integration diagram are displayed side by side on one screen.
[Selection] Figure 6

Description

  The present invention analyzes a signal waveform obtained from measurement of a magnetic field of a living body caused by a current in the living body, such as a nerve activity of a living body's brain and a heart's myocardial activity, and displays the analysis result on an operation screen. The present invention relates to a magnetic field measurement apparatus.

  Using a superconducting quantum interference device (SQUID), a multi-channel (multi-channel) that measures the distribution of a weak magnetic field generated from a living body at a plurality of measurement positions, estimates the position of an active current inside the living body, and images the distribution. A biomagnetic field measurement apparatus at a measurement position is known.

  In this biomagnetic field measurement apparatus, the measurement result is displayed on the screen, and the presence or absence of a heart disease or the like is determined. As the screen display of the measurement result, as described in Patent Document 1 and Patent Document 2, there are grid map display, single waveform display, superimposed waveform display, and isomagnetic field diagram display.

  The grid map display is a method of displaying data waveforms measured at a plurality of measurement positions as rows and columns corresponding to the measurement positions. The single waveform display is a method of displaying data of a single channel for each row or column in the grid map display.

  The superimposed waveform display is a method for displaying the data of all channels or a plurality of channels in an overlapping manner. Further, the isomagnetic diagram display is a method of displaying a line formed by connecting points having the same measurement signal value.

Japanese Unexamined Patent Publication No. 2000-225099 Hei 11-104096

  However, in the prior art, since a grid map display, single waveform display, superimposed waveform display, isomagnetic field map display, etc. are displayed on the screen, for example, the progress status before and after surgery of one subject is comprehensively displayed. It was difficult to confirm on one screen.

  In addition, it is necessary to print a plurality of display screens at the time of diagnosis by the doctor. However, each of the grid map display, the single waveform display, the superimposed waveform display, and the isomagnetic field map display is displayed. It must be printed separately, resulting in about 7 to 8 sheets per subject.

  As a result, not only the output time and printing cost are required, but also a place for storing the print data has to be secured.

  An object of the present invention is to realize a biomagnetic field measurement apparatus capable of quickly searching for an analysis result of a portion desired by a user and capable of displaying the analysis result in a multi-window.

  According to the present invention, in a biomagnetic field measurement apparatus that measures a magnetic field generated from a living body of a subject using a plurality of magnetic sensors, the biomagnetic field is analyzed from measurement signals obtained from the plurality of magnetic sensors. An analysis unit that generates a plurality of types of analysis waveforms and diagrams, and a display unit that displays the plurality of types of analysis waveforms and diagrams generated by the analysis unit on a single screen.

  Preferably, the display unit displays a selection area for selecting by the operator whether the multi-window display or one of the plurality of types of analysis waveforms and diagrams is displayed on one screen. When one type of display is selected, the selected analysis waveform or diagram is displayed on the screen.

  In the biomagnetic field measurement apparatus, a biomagnetic field measurement apparatus capable of quickly searching for an analysis result of a portion desired by the user and capable of displaying the analysis result in a multi-window can be realized.

  Also, by storing the printed report format in the data storage unit, it is possible to shorten the analysis time to the next time, observe the subject before and after surgery, shorten the printing time, and reduce the printing cost. .

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  FIG. 1 is a schematic external view of a biomagnetic field measuring apparatus to which the present invention is applied. The example shown in FIG. 1 is an example in which the heart is a site of interest and the biological activity in the heart is measured using a plurality of magnetic sensors (SQUIDs) 2 mounted on the dewar 1 of the biomagnetic field device.

  During the measurement, the magnetocardiogram waveform is displayed on the monitor 4, and the analysis result is output from the printer (printing unit) 5. In order to avoid measurement failures due to magnetic field noise, the measurement is performed in the magnetic shield room 3.

  FIG. 2 is an operation explanatory diagram from data measurement to printing in one embodiment of the present invention. In FIG. 2, the data processing unit performs data measurement processing 6 of a minute magnetic field emitted from the heart using a plurality of magnetic sensors 2.

  Data measured by the data measurement process 6 is converted into digital data by a data converter (not shown), and then collected in a raw data file 7 in the database 15.

  The data processed by the data measurement process 6 is subjected to a data analysis process 8 by a data analysis processing unit. During the data analysis process 8, an averaging process is performed using the raw data collected in the raw data file 7. 9 is performed.

  Here, the averaging process is a process of performing addition processing for each heartbeat in the collected cardiac magnetic field signal to obtain a smooth waveform with reduced noise.

  The measurement data subjected to the averaging process 9 is stored in the averaging data file 10 in the database (data storage unit) 15 and subjected to a data transfer process or the like in the data service center 16 described later. Various displays can be displayed on the screen using the averaging data.

  The data subjected to the data analysis process 8 is displayed on the display screen unit 12 and is stored in the database 15 as the analysis result 11. Further, a plurality of screens displayed on the display screen unit 12 or a selected screen among them is subjected to the printing process 14. The displayed screen is stored in the database 15 as the display screen 13.

  FIG. 3 is a diagram illustrating an isomagnetic field diagram which is an example of a selection screen output to the display screen unit 12. In FIG. 3, the information display area on the left side of the screen includes subject information 17 (name, date of birth, etc.) and data information 18 (data type, data ID, date of measurement) to be measured. Etc.).

  The center of the screen is a measurement screen display area 19, and the measured magnetocardiogram waveform (isomagnetic field diagram) is displayed on the screen. On the right side 20 of the screen, an operation area in which various conditions related to magnetocardiography measurement can be set by operating a cursor such as a mouse or a keyboard is displayed.

  In the upper part, a channel (any one of a plurality of magnetic sensors) of the magnetic sensor 2 can be designated, and a heart waveform in the channel is displayed on the screen. As other functions, the measurement time displayed on the screen, the magnetic field strength, and the like can be changed by the cursor operation 21.

  Next, selection of an analysis result display method will be described with reference to FIGS.

  Here, the present invention is characterized by having a multi-window display function and freely selecting and displaying the analysis result. The multi-window display function is to display the analysis result display method by combining the number of divisions, the arrangement, the color, and the like.

  Data analysis is intended to obtain information necessary for diagnosis by displaying various types of waveforms and diagrams, and selecting various types of waveforms and diagrams by selecting a menu on the screen. Can be displayed automatically. The report format display includes a plurality of analysis results, subject IDs, date and time, comments, etc., and the waveform can be displayed in color.

  In this way, data can be identified and managed based on the contents included in the report format. In addition, the color of the report makes it easier to see the contents of the report.

  FIG. 4 is a schematic flowchart of display screen selection. In FIG. 4, if “single waveform display” is selected in the menu selection from “data analysis” (step S1-1), a single waveform display screen is displayed (steps S1-2 and S1-7). .

  In addition, if “superimpose waveform display” is selected in the menu selection (step S1-1) from “data analysis”, a superposition waveform screen is displayed (S1-3, S1-7), and the menu from “data analysis” is displayed. If “grid map display” is selected in the selection (step S1-1), a grid map waveform screen is displayed (steps S1-4 and S1-7).

  In addition, if “isomagnetic field diagram” is selected in the menu selection (step S1-1) from “data analysis”, an isomagnetic field diagram screen is displayed (steps S1-5 and S1-7), and “data analysis” is displayed. When “Time integral diagram” is selected in the menu selection (step S1-1), a time integral diagram screen is displayed (steps S1-5 and S1-7).

  By selecting a screen display menu, various types of waveforms and diagrams can be selectively displayed. However, if it does not have the same function to display various analysis data on the data display screen, it will be necessary to change the display screen each time it is judged necessary for diagnosis, or to analyze it individually. The result must be printed.

  That is, in order to display the analysis result in the same way as the other analysis results, it is necessary to improve the display method.

  FIG. 5 is a diagram for explaining the operation of multi-window display. As shown in FIG. 5, a “multi-window display function” (step S2-1) is newly provided following “data analysis”, and a plurality of analysis results are simultaneously displayed on the operation screen.

  In addition, the multi-window display function can be selected from "menu selection" (step S2-2) to "automatic setting display" (multi-window display) (step S2-3) or "manual setting display" (one type display) (step S2- 4) can be selected.

  FIG. 6 is a diagram showing a display screen when “automatic setting display” is selected. As shown in FIG. 6, a single waveform, a grid map waveform, a superimposed waveform, an isomagnetic field diagram, and a time integration diagram are displayed side by side in one screen.

  FIG. 7 is a diagram showing a display screen when “manual setting display” is selected. The example shown in FIG. 7 is the case of an isomagnetic field diagram, and the isomagnetic field diagram previously measured by the same subject and the isomagnetic field diagram measured this time are displayed on the same screen.

  In the example shown in FIGS. 6 and 7, the subject information and data information also shown in FIG. 3 are displayed on the left side of the screen (S2-5 in FIG. 5). A scroll bar (time setting unit) is displayed in the lower part of the screen, and the measurement time of each analysis result can be set by operating this scroll bar.

  As another common function, the magnetic field strength of the isomagnetic field diagram and the time integration diagram can be changed from the text box (S2-6 in FIG. 5).

  Here, in the case of automatic setting display, the layout of a single waveform, grid map waveform, superimposed waveform, isomagnetic field diagram, and time integration diagram is fixed. In this case, the subject's data list is displayed on the screen, and when the subject whose analysis results are to be displayed is selected from the data list screen, the analysis results (single waveform, grid map waveform, superimposed waveform) are automatically displayed. , Isomagnetic field diagram, time integration diagram) are displayed. Thereby, an analysis result can be displayed on one screen at a time.

  When it is desired to enlarge and display only a certain analysis result, the user can click on the display screen to move to the analysis screen and perform the analysis again. Thereby, the time which analysis time requires can be shortened.

  On the other hand, in the case of manual setting display, the number of displayed analysis results, arrangement, color, etc. can be selected. For example, as shown in FIG. 7, when it is desired to grasp the progress status of a subject before and after the operation, the previous analysis result and the current analysis result are selected from the subject list screen and displayed on the same screen. Can be displayed.

  As a result, since both results can be compared, the diagnosis time by the doctor can also be shortened (S2-7 in FIG. 5).

  Next, the relationship between the data service center 16 and the biomagnetic field measurement device will be described.

  The definition of the data service center will be described with reference to FIG. The data service center 16 is connected to a plurality of biomagnetic field measurement devices 22 in the inspection facility 23 via a network 26, and the measurement results 24 in each biomagnetic field measurement device 22 are tabulated and classified to perform statistical management. Is an institution.

  The biomagnetic field measurement device 22 includes a communication unit that performs two-way communication with the data service center 16. The data service center 16 integrates measurement results obtained from the biomagnetic field measurement device 22 and subject attribute information. A database 27 for collecting information 24 is included.

  Database 27 receives information 24 from device 22. Information received in the database 27 is divided into a data storage area 28 and a data analysis profile 29 and stored in units of facilities, and is classified and stored by age, sex, case, and period.

  When the user inputs the user ID 25 to the biomagnetic field measurement device 22, the user can access the history information of the data service center 16. Further, the measurement results from the plurality of received biomagnetic field measurement devices 22 are statistically analyzed by age, sex, case, and period, and the tendency and the pattern are transmitted to each device 22 side and stored in the device 22. .

  When the measurement result is not automatically analyzed, the analysis is supported via the network 26, and the analysis result is distributed into the device 22 via the network 26.

  Next, the operation of the data service center 16 will be further described with reference to FIG.

  In FIG. 9, in step S <b> 3-1, information obtained by associating the result measured from the examination facility 23 with the subject attribute information is transmitted to the data service center 16 via the network 26.

  Next, in step S <b> 3-2, data from the biomagnetic device 22 installed in each examination facility 23 is stored on the database 27 in the data service center 16.

  In step S3-3, measurement results and subject attribute information are accumulated on the database 27 in the center 16. Next, in step S3-4, the information obtained in step S3-3 is divided into each waveform and each subject attribute information. Subsequently, in step S3-5, the analysis result is notified from the center 16 to the biomagnetic field measurement device 22, and the history information of the data information stored in the center 16 is browsed in step S3-6.

  Finally, in step S3-7, the history information 29 is transmitted to the biomagnetic field measurement device 22.

  As described above, by performing the steps S3-1 to S3-7, the user can obtain the statistical evaluation of the analysis result in a short time via the analysis support system by the external organization. In addition, the analysis result and the subject information can be centrally managed, so that the data can be continuously viewed. Furthermore, data operation becomes easy by identifying and managing the analysis results.

  As described above, in the present invention, the data service center 16 collectively manages the measurement data of the subject measured by the plurality of biomagnetic field measurement devices 22 to statistically analyze the presence or absence of a disease or the like. The history information can be accessed from any of the biomagnetic field measurement devices 22 connected to the data service center.

1 is a schematic external view of a biomagnetic field measurement apparatus to which the present invention is applied. It is operation explanatory drawing from the data measurement in one Embodiment of this invention to printing. It is a figure which shows the isomagnetic-field diagram which is an example of the screen output to a display screen part. It is a schematic flowchart of the display screen selection in this invention. It is operation | movement explanatory drawing of the multiwindow display in this invention. It is a figure which shows the display screen at the time of selecting "automatic setting display" in this invention. It is a figure which shows the display screen at the time of selecting "manual setting display" in this invention. It is explanatory drawing of the data service center in this invention. It is explanatory drawing of the data service center in this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Dewar gantry, 2 ... Magnetic sensor (SQUID), 3 ... Magnetic shield room, 4 ... Monitor (PC), 5 ... Printer, 6 ... Data measurement process, 7 ... Raw data file, 8 ... Data analysis process, 9 ... Averaging process, 10 ... Averaging data file, 11 ... Analysis result, 12 ... Display screen part, 13 ... -Display screen data, 14 ... Printing process, 15 ... Database (inside the biomagnetic field measuring device), 16 ... Data service center (external organization), 17 ... Subject information area, 18 ... -Data information area, 19 ... Meter display screen (measurement screen), 20 ... Operation part area, 21 ... Cursor operation area, 22 ... Biomagnetic field measuring device, 23 ... Examination 24 ... Measurement result and subject information 25 ... User ID 26 ... Network 27 ... Database (data service center) 28 ... Data storage area (in the data service center) , 29 ... Analysis profile (in the data service center)

Claims (9)

In a biomagnetic field measurement apparatus that measures a magnetic field generated from within the living body of a subject using a plurality of magnetic sensors,
Analyzing a biomagnetic field from measurement signals obtained from the plurality of magnetic sensors, and generating a plurality of types of analysis waveforms and diagrams;
A display unit that displays a plurality of types of analysis waveforms and diagrams generated by the analysis unit on a single screen, and
A biomagnetic field measurement apparatus comprising: The biomagnetic field measurement apparatus according to claim 1,
The said display part displays the subject information from which the measurement signal was obtained with the said multi-window display on one screen, The biomagnetic field measuring device characterized by the above-mentioned. The biomagnetic field measurement apparatus according to claim 2, wherein
The said display part displays the said multi-window display, the subject information from which the measurement signal was obtained, the subject ID, the date, and the comment on one screen. The biomagnetic field measurement apparatus according to claim 2 or 3,
The display unit includes a time setting unit for an operator to set the time when the analysis waveform and the diagram displayed in the multi-window are obtained, and a part of the analysis waveform and the diagram displayed in the multi-window is displayed. A biomagnetic field measurement apparatus, wherein when the operator gives an instruction, the indicated part is enlarged and displayed. In claim 4,
The display unit displays a selection area on the screen for selecting by the operator whether to display the multi-window display or one of the plurality of types of analysis waveforms and diagrams on one screen. A biomagnetic field measurement apparatus that displays the selected analysis waveform or diagram on the screen when one type of display is selected.   The biomagnetic field measurement apparatus according to any one of claims 2 to 5, wherein the display unit displays a selection area of the subject on a screen, and an analysis waveform and a diagram of the subject selected by the operator. Is displayed on a screen. In the biomagnetic field measurement apparatus according to any one of claims 2 to 6,
A biomagnetic field measurement apparatus comprising a printing unit for printing the content displayed on the display screen. The biomagnetic field measurement apparatus according to claim 7,
A biomagnetic field measurement apparatus comprising: a data storage unit for storing display screen data printed by the printing unit according to age, sex, measurement period, and medical history of a subject. The biomagnetic field measurement apparatus according to claim 8, wherein
Based on a plurality of subject magnetic field measurement information, a data service center that statistically analyzes the subject biomagnetic field information and a communication unit that performs bidirectional communication, the information analyzed by the data service center A biomagnetic field measurement apparatus which is stored in a data storage unit.

Images