WO2004019779A1 - バイタルサイン表示装置およびその方法 - Google Patents
バイタルサイン表示装置およびその方法 Download PDFInfo
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- WO2004019779A1 WO2004019779A1 PCT/JP2003/010734 JP0310734W WO2004019779A1 WO 2004019779 A1 WO2004019779 A1 WO 2004019779A1 JP 0310734 W JP0310734 W JP 0310734W WO 2004019779 A1 WO2004019779 A1 WO 2004019779A1
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- Prior art keywords
- vital sign
- display
- vital
- state
- abnormal
- Prior art date
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Classifications
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01D—MEASURING NOT SPECIALLY ADAPTED FOR A SPECIFIC VARIABLE; ARRANGEMENTS FOR MEASURING TWO OR MORE VARIABLES NOT COVERED IN A SINGLE OTHER SUBCLASS; TARIFF METERING APPARATUS; MEASURING OR TESTING NOT OTHERWISE PROVIDED FOR
- G01D7/00—Indicating measured values
- G01D7/005—Indication of measured value by colour change
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/24—Detecting, measuring or recording bioelectric or biomagnetic signals of the body or parts thereof
- A61B5/316—Modalities, i.e. specific diagnostic methods
- A61B5/318—Heart-related electrical modalities, e.g. electrocardiography [ECG]
- A61B5/339—Displays specially adapted therefor
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S128/00—Surgery
- Y10S128/905—Feedback to patient of biological signal other than brain electric signal
Definitions
- the present invention relates to a vital sign display device and a method thereof, and more particularly to a device that facilitates confirmation of a biological signal.
- Patent Document 1 Japanese Patent Application Laid-Open No. Hei 4-35 239 39 (FIG. 8).
- the technology described above it is possible to specify, for example, the time of a seizure by the event mark. That is, according to the existing technology, it is possible to obtain information as to when an abnormal value of biological information has occurred.
- An object of the present invention is to provide a vital sign display device and a method thereof capable of easily confirming biological information in view of the above requirements.
- a vital sign display device for displaying vital signs
- Judging means for judging whether or not the state of the living body indicated by the living body signal is an abnormal state based on the obtained living body signal
- the vital sign is displayed as a vital sign so that it is possible to determine whether or not the state is abnormal, and the progress of the vital sign is further confirmed so that the history of the vital sign can be confirmed.
- Vital sign display means displayed sequentially
- a user who uses the output result of the vital sign display means can easily confirm whether the living body is in a normal state or an abnormal state.
- the vital sign history is displayed continuously in chronological order so that it can be confirmed, it is possible to easily confirm, for example, when and how often an abnormal state has occurred.
- a vital sign display device for displaying vital signs
- the vital sign display device is the vital sign display device
- a vital sign or a signal generated based on the vital sign is displayed as a vital sign so that it is possible to determine whether it is abnormal, and the vital sign history is displayed so that the history of the vital sign can be confirmed.
- Vital sign display means to display continuously
- a user who uses the output result of the vital sign display means can easily confirm whether the living body is in a normal state or an abnormal state.
- the vital sign history is displayed consecutively in the order of measurement so that it can be confirmed, it is possible to easily confirm, for example, when and how often an abnormal state has occurred.
- the display of the vital signs is performed in such a manner that the vital signs are drawn in a circular shape as the vital signs progress.
- the display area of the vital sign can be prevented from being extended or enlarged according to the measurement progress. Therefore, a user who uses the output result of the vital sign display means can easily recognize the overall tendency of the vital sign.
- a vital sign display device for displaying vital signs
- the vital sign display device is the vital sign display device
- Judging means for judging whether or not the state of the living body indicated by the living body signal is an abnormal state based on the obtained living body signal
- the vital sign is displayed as a vital sign so that it can be determined whether or not the state is abnormal.
- Vital sign display means by moving the display target to
- a user who uses the output result of the vital sign display means can easily confirm whether the living body is in a normal state or an abnormal state.
- the vital sign display device of the present invention further comprises:
- Display format selection means for selecting the total display time of the display area for displaying the vital sign in association with the measurement time required for the vital sign
- the display time of the display area can be adjusted according to the required time of the vital sign measurement.
- the vital sign display device of the present invention further comprises:
- Vital sign item name display means for displaying an item name of the vital sign in association with the display of the vital sign; It is characterized by having.
- the display of the vital sign is
- the display mode is changed in the case of the abnormal state.
- the vital signs at least VPC (ventricular extrasystole) or HR (heart rate), or QT interval or S P_ ⁇ binary, include items based on any one of (blood oxygen saturation),
- the vital sign is displayed as a vital sign so that it is possible to determine whether the state of the living body indicated by the vital sign is abnormal, and the vital sign is displayed so that the history of the vital sign can be confirmed. Are displayed consecutively in the order of progress,
- a user using the vital sign display can easily confirm whether the living body is in a normal state or an abnormal state.
- the vital sign history is displayed in chronological order so that it can be confirmed, it is possible to easily confirm, for example, when and how often an abnormal state has occurred.
- Bio signal is a concept including biological information or general disease state information.
- the “biological signal” includes a value (parameter) indicating individual biological information, information expressed based on a plurality of biological information, and the like.
- the “vital sign” is a concept including a general one that displays on the basis of a biological signal such that it is possible to determine whether the state of the living body indicated by the biological signal is abnormal. For example, in addition to a predetermined code, symbol, or mark, or numeral, or letter, etc., which makes it possible to determine whether the biological state is a normal state or an abnormal state, the biological signal is in a normal state or an abnormal state.
- This concept includes deforming the display target or changing the color of the display target so that it is possible to determine which of the two is the case.
- Vital sign item name is a concept that includes a name that expresses items related to biological information in general. For example, a parameter name, a disease state name, a diagnosis name, or the like representing an item related to biological information is included in this concept.
- Normal condition is a concept that includes cases where it can be determined that there is no disease state, cases where the condition is correct (normal), and cases where the condition is not abnormal.
- the concept includes a case where the value representing the biological information is within a range of values when the biological condition is good, and a case where the biological information is not determined to be abnormal by a predetermined determination method.
- abnormal state is a concept that includes a case where there is a disease state based on general biological information, a state where the state is not a correct (ordinary) state, and a case where the state is not normal.
- the concept includes a case where the value representing the biological information is out of the range when the biological condition is good, and a case where the biological information is determined to be abnormal by a predetermined determination method. .
- Determining whether the condition of a living body is abnormal means “to determine the presence or absence of an abnormal state (or the degree of the abnormal state)” or “to determine the presence or absence of a normal state (or the degree of the normal state)” Or, to determine whether the condition is normal or abnormal (or the extent of those conditions).
- the “circular shape” is a concept that includes general shapes that can make a round along the shape. is there. For example, a loop shape formed by a straight line or a curve, or a combination of straight lines or curves, or a ring shape, a circle shape, a circular shape, an elliptical shape, a donut shape, a ring shape, a polygonal shape, and the like are included in this concept.
- 1A, 1B, 1C, and ID are schematic diagrams of a vital sign circle radar display according to an embodiment.
- FIG. 2 is a functional block diagram of the vital sign cycle radar device.
- FIG. 3 shows an example of a hardware configuration of a vital sign cycle radar device.
- Fig. 4 is an example of display on a vital sign cycle radar.
- Figure 5 is a graphical representation of the recorded ECG waveform data.
- FIG. 6 is a flowchart of the vital sign circle radar creation process.
- FIG. 7 is a flowchart of the abnormality determination process (for VPC).
- FIG. 8 is a flowchart of the abnormality determination process (for HR).
- FIG. 9 is a flowchart of the abnormality determination process (for QT).
- Figure 1 0 is a flowchart of the abnormality determination process (if S P_ ⁇ binary).
- FIG. 11A, FIG. 11B, and FIG. 11C are modified examples of the display display of the vital sign circle radar.
- a vital sign circle radar device as an embodiment of the “vital sign display device” according to the present invention will be described.
- the present embodiment exemplifies a process of displaying a patient's electrocardiogram data and the like as a vital sign circle radar on a display.
- the present embodiment for example, when a patient is being transported, information about when and how often an abnormal state of the patient has occurred can be easily obtained visually.
- the outline of the present embodiment, the hardware configuration of the device, the correspondence between the terms described in the claims and the embodiments will be described, and then the embodiments will be described.
- the vital sign circle radar is a display of vital signs obtained from the patient's electrocardiogram and the like.
- the vital sign circle radar device 100 that performs this display will be described later.
- This device is suitable for use in an emergency scene, in an ambulance, or in a hospital. In the embodiment, as an example, a case will be described in which an ambulance crew is used in an ambulance while a patient is being transported.
- FIG. 1 is a schematic view of a display of a vital sign cycle radar.
- Figures 1A, 1B, 1C, and 1D show, in chronological order, the presence or absence of “ventricular premature contraction (VP C)”, one of the vital signs, on the display 14.
- This shows an example of display on the circle radar 50.
- One round of the circle radar 50 corresponds to a measurement time of 20 minutes.
- the circle radar 50 moves the display point clockwise in accordance with the measurement time. Move).
- the vital sign item name is displayed in the center of the circle radar 50.
- the circle part (ring part, donut ring part) of the circle radar 50 is colored gray at the start of measurement.
- the vital sign is determined for each heartbeat, and the display point moves clockwise (see the arrow 40 in FIG. 1A).
- the color (color) of the ring part changes according to. That is, the circle radar 50 has such a display form that it is possible to determine whether the state is the normal state or the abnormal state. Specifically, when VPC has not occurred (normal state), the color is green, and when VPC has occurred (abnormal state), the color is red (“change the display mode”). In the figure, for convenience, white is displayed when no VPC occurs, and black when a VPC occurs.
- the measurement progress or the current display position can be easily visually recognized by adopting a color different from the gray color of the circle portion.
- Figure 1A shows that the current vital sign (VPC) is in a normal state.
- FIG. 1B shows a display example of the display 14 when a VPC occurs. As shown in Fig. 1B, if VPC occurs at a certain measurement time, the display point at that time is drawn in red (painting process). Specifically, Figure 1B shows that the current vital sign (VPC) is in an abnormal state.
- VPC current vital sign
- FIG. 1C shows a display example of the display 14 in a state where the measurement time has progressed further than the state shown in FIG. 1B.
- the cycle radar 50 shows the drawing of red color when the VPC occurs, and the user of the equipment can see when or how by looking at this red portion. VPC occurred frequently
- FIG. 1C shows that the current vital sign (VPC) force S is present (abnormal state) and that there is a history of several abnormal states. Also, the wider the width drawn in red, the more the abnormal state is continuous.
- VPC current vital sign
- FIG. 1D shows a display example of the display 14 when the measurement time exceeds 20 minutes. If the measurement time exceeds 20 minutes, the display point of the circle radar 50 will exceed one lap, so the display of the first lap is overwritten (the display of the first lap is deleted. In the state where the specified width after the current position of the display point is changed to gray (see symbol ID 41 in the figure ID), the same abnormality judgment as in the first lap is performed. Specifically, in Fig. 1D, the current vital sign (VPC) is not generated (normal state), and the measurement time exceeds 20 minutes (2 weeks). Eyes, or It must be at least 2 weeks), and indicates that there are several abnormal state histories in the last 20 minutes.
- VPC current vital sign
- the shape and color of the vital sign cycle radar 50 described above, and the color in a normal state or an abnormal state are examples, and can be modified by means known to those skilled in the art.
- the arrow 40 in FIG. 1 is shown for explaining the movement of the display point, and is not actually displayed on the display 14. However, the arrow 40 (or a mark similar to the arrow 40) should be displayed on the display 14 so that the moving direction or the display position of the vital sign display point is clear.
- FIG. 2 shows a functional block diagram of the vital sign circle radar device 100.
- the vital sign circle radar apparatus 100 includes a vital sign acquisition unit 2, a determination unit 3, a vital sign display unit 4, a display format selection unit 6, and a vital sign item name display unit 8.
- the biological signal acquiring means 2 acquires a biological signal.
- the determination means 3 determines whether the biological signal is in a normal state or an abnormal state.
- the vital sign display means 4 displays a vital sign indicating the determination result as a vital sign cycle radar.
- the display format selection means 6 selects a display format of the digital sign circle radar.
- the vital sign item name display means 8 displays the item name of the vital sign corresponding to the vital sign circle radar.
- FIG. 3 shows an example of a hardware configuration in which the vital sign circle radar device 100 shown in FIG. 2 is realized using a CPU.
- the vital sign circle radar device 100 has a CPU 10, an amplifier 11, an A / D converter 12, a mouse / keyboard 13, a display 14 (display device), a speaker 15, a communication interface 16, a memory 17, and a Flash.
- ROM 18 flash memory or other rewritable read-only memory capable of electrically erasing stored data; hereafter referred to as F-ROM18
- display controller 19 ECG electrode 20 (biological signal detector) It has.
- the ECG electrode 20 is an electrode for measuring a patient's cardiac current.
- the amplification amplifier 11 amplifies the cardiac current obtained by the ECG electrode 20.
- the CPU 10 controls the entire vital sign circle radar apparatus 100 in addition to a process of converting the obtained cardiac current into electrocardiogram data for representing an electrocardiogram, a process of creating a vital sign circle radar, and the like.
- the F-ROM 18 records a program for controlling the vital sign circle radar device 100.
- the memory 17 provides a work area of the CPU 10 and the like. Mouse / keyboard 13 or display controller; operation information generated by operating L 9 is input to CPU 10, and image information and audio information generated by CPU 10 are output to display 14 and speaker 15, respectively. You.
- the vital sign circle radar device 100 is connected to the blood oxygen saturation measuring device 22 (biological signal detector) via the communication interface 16.
- Blood oxygen saturation measuring device 22 is a device for measuring the S p0 2 values of the patient.
- RS-232C or the like is adopted as an example of the communication interface 16.
- the bicycle sign radar device 100 may be configured by hardware logic without using a CPU.
- the hardware configuration of the device and the configuration of the CPU can be modified by means known to those skilled in the art.
- the “electrocardiogram” described in the embodiment is obtained as a result of measuring a cardiac potential difference between two points of a patient's body. Therefore, expressions such as “measurement of an electrocardiogram” in the embodiment include a concept of measuring a cardiac potential and the like.
- the “vital sign display device” is a concept including a general device for displaying vital signs, and corresponds to, for example, the vital sign circle radar device 100 of FIG. 3 in the embodiment.
- "Biological signal acquisition means” has a function of acquiring a biological signal.
- the concept corresponds to the CPU 10 of the vital sign cycle radar device 100 that performs the process of step S609 in FIG.
- "Biological signal” is a concept including a biological signal general, in the embodiments, corresponding to the recognized value de Isseki, or S p0 2 values in FIG. 6 step S 609.
- the “judgment means” is a concept including a general one having a function of determining whether or not the state of a living body indicated by the biological signal is an abnormal state based on the obtained biological signal.
- FIG. This corresponds to the CPU 10 that performs the processing of S611 and S613.
- the “vital sign display means” is a concept including a general having a function of displaying a vital sign.
- FIG. 6 illustrates a CPU 10 that performs the processing of steps S615 and S617 or S619 and S621.
- the “display format selection means” is a concept including a general one having a function of selecting a display format.
- CPU10 “Vital sign item name display means” is a concept including general ones having a function of displaying the item names of vital signs, and corresponds to the CPU 10 performing the process of step S607 in FIG. 6 in the embodiment.
- FIG. 4 shows a display example displayed by the vital sign circle radar creation processing by the CPU 10.
- the display 14 includes a vital sign circle radar 50 as a vital sign circle radar, a vital sign circle radar 50 as a VPC (Ventricular Extrasystole), and a vital sign circle radar 51 as a heart rate (HR) (heart rate).
- vital signs circle radar 53 vital signs circle radar 52, S p0 2 values of QT (QT interval) is displayed.
- these VPC, HR, QT, from among S P_ ⁇ 2 is set to be displayed only those selected in advance by the user as a vital signs capacitors one Kurureda.
- Each of these vital sign circle radars has a "1. vital sign circle
- the vital sign status is displayed as described in “Relay display overview.” Specifically, in the case of a no-fat sign circle radar, the display point moves as the measurement time of the biological signal elapses. If the living body is in an abnormal state (the biological signal is an abnormal value), an abnormal display 60 (red) is displayed as a vital sign, while if the living body is in a normal state (the biological signal is a normal value), the vital sign is displayed. Normal display 6 2 (green) is displayed.
- VPC, HR, QT is exemplified as an item of vital signs to be selected by the user.
- four S p 0 2 value is not limited to, items of vital signs to be employed, It can be modified by means known to those skilled in the art.
- VPC as vital signs mono- Kurureda to view a combination of VPC and S P_ ⁇ binary, or the four other vital signs of the items (e.g., abnormal increase of ST)
- a circle radar may be displayed.
- the user of the vital sign circle radar apparatus 100 can intuitively and easily obtain information about when or how often the abnormality of the biological signal has occurred. be able to.
- the CPU 10 of the vital sign circular radar device 100 is connected to the ECG electrode 20 attached to the patient's body by the ECG electrode 20 and the amplification amplifier 11. Then, the electrocardiogram is measured to extract the electrocardiogram waveform and the recognition value data of the electrocardiogram waveform.
- 1 2 lead ECG is from several to 10 several These are the 12 patterns of ECG that can be obtained by attaching electrodes to a living body. This recognition value data is used for determining an abnormality of a biological signal in the embodiment.
- the Sp 2 value is measured by the blood oxygen saturation measuring device 22.
- the CPU 10 accepts the input of the recognition value data and the SpO2 value thereof and displays them as a vital sign circle radar.
- the CPU 10 continuously records digital data (electrocardiographic waveform data) obtained via the ECG electrode 20 in the memory 17 (or F-ROM 18) for each of the 12 leads.
- Fig. 5 schematically shows the recorded electrocardiographic waveform data for one lead in the form of a graph (vertical axis: potential (voltage), horizontal axis: time). As shown in FIG.
- the CPU 10 determines R (R potential or R wave height), T (T Potential or T wave height), Q (Q potential or Q wave height), ST (ST level), QT (QT interval), and RR (RR interval) are extracted and stored in memory 17 (or F — Record on ROM18).
- R R potential or R wave height
- T T Potential or T wave height
- Q Q potential or Q wave height
- ST ST level
- QT QT interval
- RR RR interval
- (1) Recognition of one heartbeat After sampling the electrocardiogram waveform data (potential value or voltage value) for a predetermined time, the R wave, which is a local maximum component exceeding a predetermined threshold, and ( Recognize the next R wave and recognize the RR interval as one heartbeat. At this time, the T-wave component (frequency lower than the R-wave), which is a maximum value other than the R-wave, may be removed using a local filter.
- P wave The maximum value that exists 200 to 300 ms e c (milliseconds) before the position of the R wave is recognized as the P wave.
- Q wave The minimum value that exists immediately before the position of the R wave is recognized as the Q wave.
- T wave The maximum value existing between the R wave and the next R wave is recognized as the T wave.
- CPU 10 of the vital signs mono- Kurureda device 100 illustrating an example of creating a vital signs circle radar based on the electrocardiogram and S P_ ⁇ binary patients.
- This vital sign circle radar creation processing is performed in units of one heartbeat.
- the sampling frequency of the ECG data is, for example, any of 125, 250, 500, and 1000 Hz.
- the vital sign circle radar creation processing may be performed in units other than one heartbeat or in predetermined time units.
- the unit of the vital sign circle radar creation processing and the sampling frequency of the electrocardiogram data can be changed by means known to those skilled in the art.
- the CPU 10 of the vital sign circle radar device 100 performs the input processing of the vital sign item selected by the user (step S601).
- the CPU 10 performs an input process of the scheduled measurement required time (corresponding to “measurement required time”) selected by the user (step S603).
- the CPU 10 may output an interactive interface on the display 14 to receive the user input by inputting the vital sign item and the scheduled measurement required time, or separately from this. It may be set as a specification of a bi-sign lane circle radar device.
- the vital signs item "VPC, HR, QT, S P_ ⁇ binary" eyes and 4 Section of, at the scheduled time required for measurement as "20 minutes" in advance of the vital signs circle radar device 100 F- R_ ⁇ _M18 It has been set.
- the CPU 10 draws the circle radar on the display 14 based on the vital sign item input in step S601 and the scheduled measurement required time input in step S603 (step S605).
- the scheduled measurement required time is set as the entire display time of one circle of the circle radar (corresponding to “all display time”).
- Draw a circle radar In the embodiment, as an example, the “overall display time” is set to the same time as the scheduled measurement required time. However, the present invention is not limited to this, and the time obtained by adding a predetermined time to the scheduled measurement required time is automatically set as “overall display time”. You may make it.
- the CPU 10 displays the vital sign name in the center of the circle radar (step S607). Specifically, for example, if the by-night sign item is Sp 2 and the total display time is 20 minutes, the CPU 10 draws one circle radar on the display 14 and displays “Sp ⁇ 2 "(see circle radar 53 in Figure 4).
- CPU 10 performs the process of acquiring recognition value data and S p 0 2 values (Fig. 6 step S 609). Specifically, CPU 10 via the ECG electrodes 20 and the blood oxygen saturation measuring device 22 or the like, records the recognition value data and S p0 2 values in the memory 17 (or F -ROM18). The CPU 10 determines whether or not recognition value data for one heartbeat has been acquired (step S610), and if not acquired, repeats the processing of step S609. Fig. 6 The processing after step S611 is the contents of the vital sign circle radar creation processing program corresponding to one heartbeat. Therefore, during the measurement of the biological information, the execution of the vital sign circle radar creation processing program shown from step S611 in FIG. 6 is repeated for each heartbeat.
- the CPU 10 performs an abnormality determination process based on the data (step S611). In embodiments, it performed VPC, HR, QT, from among S p0 2 value, the abnormality determination process for vital sign items input in step S 6 01.
- step S611 the CPU 10 executes a subroutine of abnormality determination processing of a vital sign item selected by the user in advance.
- CPU 10 as the abnormality determination processing, the processing in the case of VPC illustrated in each flow one chart of FIG. 10 in the case of FIG. 9, S P_ ⁇ binary in the case of FIG. 8, QT in the case of FIG. 7, HR Execute. The details of these abnormality determination processes will be described later.
- the CPU 10 performs the following rendering processing on the display 14 in accordance with the result of the abnormality determination processing for each vital sign.
- the CPU 10 determines whether or not it is determined that the vital sign is abnormal by the vital sign abnormality determination processing (step S613). If normal, CP U10 calculates a drawing area for the vital sign (step S619), and draws green in the drawing area (step S621) (see normal display 62 in FIG. 4).
- step S613 determines whether the state is abnormal. If it is determined in step S613 that the state is abnormal, the CPU 10 calculates a drawing area for the vital sign (step S615), and draws red in the drawing area. (Step S617) (Refer to error display 60 in Fig. 4). The calculation of the drawing area is the same as that in the normal state.
- step S623 the CPU 10 determines whether or not the biosine measurement processing has been completed. If it is determined that the processing has not been completed, the CPU 10 proceeds to step S609. Repeat the process. On the other hand, if it is determined that the vital sign measurement processing has ended, the CPU 10 ends the processing.
- step S611 when there are a plurality of vital signs for which the CPU 10 performs the abnormality determination processing, the processing from step S613 to step S623 is performed on the plurality of vital signs, and then the step S623 is performed.
- the abnormality determination process performed by the CPU 10 in step S611 of FIG. 6 will be described.
- Abnormality determination process respectively, process monument shown in each flow one chart of FIG. 10 when the case is the case of VP C in FIG. 8, QT in the case of FIG. 7, HR in FIG. 9, S P_ ⁇ binary ' Ital sign abnormality determination processing means) is executed.
- the CPU 10 recognizes the recognition value data recorded in the memory 17 (or the F-ROM 18) and other data necessary for the abnormality determination (for each abnormality determination process item, (Detailed description) is used.
- FIG. 7 is a flowchart of the VPC abnormality determination process.
- VPC Vehicle premature In the embodiment, the abnormal determination of contraction
- Abnormal state when the patient is in a state of ventricular extrasystole
- normal state when the patient does not have a ventricular extrasystole state.
- the CPU 10 of the vital sign circle radar device 100 determines whether or not there is a P wave based on the recognition value data recorded in the memory 17 (or the F-ROM 18) (FIG. 7, step S701). Specifically, for example, the CPU 10 determines whether or not the local maximum (P-wave) exists at a position 200 to 300 ms ec before the position of the R-wave for all of the 12 leads, and determines at least one or more. If there is a P-wave in the guidance, it is determined that “P-wave exists”.
- the CPU 10 sets the determination result to “normal state” (step S707).
- the CPU 10 determines whether the main direction of the QRS wave is the same as the direction of the T wave (step S703). Specifically, for example, in at least 6 or more of the 12 leads, the CPU 10 sets the sign (plus or minus) of the value of the R potential (or R wave height) (for example, mV: millivolt) and the T potential ( If the sign of the value of (or T wave height) is the same, it is determined that "the main direction of the QRS wave and the direction of the T wave are the same.”
- the CPU 10 determines whether or not the RR interval exceeds 80% of the average RR interval of the normal waveform. (Step S705). Specifically, the CPU 10 calculates, for example, the average value of the RR interval (unit: ms ec (milliseconds)) of all 12 leads for one heartbeat currently being determined, for all the 12 leads. If the RR interval exceeds 80% of the average value of the RR interval for the past 5 minutes (excluding the RR interval value for abnormal waveforms), the RR interval exceeds 80% of the average RR interval of the normal waveform Is determined.
- step S707 If it is determined that the RR interval exceeds 80% of the average RR interval of the normal waveform, the CPU 10 performs the process of step S707. On the other hand, if it is determined that the RR interval does not exceed 80% of the average RR interval of the normal waveform, the CPU 10 Is set to "abnormal state" (step S709).
- the CPU 10 performs the processing from step S613 in FIG. 6 based on the determination result obtained in the processing of step S707 or step S709.
- FIG. 8 is a flowchart of the HR (heart rate) abnormality determination process.
- the abnormality determination of the HR is defined as “abnormal state” when the heart rate is equal to or smaller than a predetermined number or equal to or larger than a predetermined number, and is set as “normal state” otherwise.
- the CPU 10 calculates an average RR interval (unit: sec (second)) for all 12 leads for one heartbeat currently being determined, and calculates the heart rate by calculating the 60Z average RR interval. Get number data.
- the CPU 10 determines whether or not the heart rate is 50 (beats / minute) or less (bradycardia) (step S801 in FIG. 8). If the CPU 10 determines that the heart rate is 50 or less, the CPU 10 sets the determination result to “abnormal state” (step S805). On the other hand, when determining that the heart rate is not less than 50, the CPU 10 determines whether the heart rate is 100 or more (tachycardia) (step S803).
- step S805 If it is determined that the heart rate is 100 or more, the CPU 10 performs the process of step S805. On the other hand, when determining that the heart rate is not 100 or more, the CPU 10 sets the determination result to “normal state” (step S807).
- the CPU 10 performs the processing from step S613 in FIG. 6 on the basis of the determination result obtained in the processing of step S805 or step S807.
- FIG. 9 is a flowchart of QT (QT interval) abnormality determination processing.
- the QT abnormality determination is defined as “abnormal state” when the QTc value obtained by correcting the QT interval value is equal to or smaller than a predetermined number or equal to or larger than a predetermined number, and is “normal state” otherwise. I decided to.
- the CPU 10 obtains, for example, QTc value data obtained by averaging the QT c values of all 12 leads for one heartbeat currently being determined. .
- the QT interval value is obtained, for example, on the electrocardiogram by the interval between the position of the Qb point obtained based on the Q wave and the position of the Te point obtained based on the T wave.
- QTc value CPU10 For example, it is calculated by dividing the QT interval value by RR (root RR, square root of RR interval).
- the CPU 10 determines whether or not the QTc interval is equal to or longer than 0.46 seconds (Step S901 in FIG. 9). When determining that the QTc interval is 0.46 seconds or more (QT extension), the CPU 10 sets the determination result to “abnormal state” (step S905). On the other hand, when determining that the QTc interval is not longer than 0.46 seconds, the CPU 10 determines whether the QTc interval is not longer than 0.34 seconds (step S903).
- step S905 If it is determined that the QTc interval is 0.34 seconds or less (QT shortening), the CPU 10 performs the process of step S905. On the other hand, when determining that the QTc interval is not less than 0.34 seconds, the CPU 10 sets the determination result to “normal state” (step S907).
- the CPU 10 performs the processing from step S613 in FIG. 6 based on the determination result obtained in the processing of step S905 or step S907.
- FIG. 10 is a flowchart of the S p ⁇ 2 value abnormality determination process.
- the abnormal determination of S p0 2 values in embodiments, Sp_ ⁇ 2 value is the "abnormal state" to the predetermined value or less, and that a "normal state” to otherwise.
- CPU10 performs the following determination using S p0 2 values recorded in the memory 17 (or F- ROM 18).
- the CPU 10 determines whether or not the value of Sp ⁇ 2 is 90% or less (Step S101 in FIG. 10). When the S P_ ⁇ binary is equal to or less than 90%, CPU 10 sets the determination result to "abnormal state" (step S 103). On the other hand, if the Sp_ ⁇ 2 value is determined not less 90%, CPU 10 is a determination result to "normal state” (step S 105).
- the CPU 10 performs the processing from step S613 in FIG. 6 on the basis of the determination result obtained in the processing of step S103 or step S105.
- step S613 in FIG. 6 the abnormality determination process is repeated for all the vital sign items input in step S601, and thereafter, The drawing process after the process of step S613 is repeated for all vital sign items in order.
- the drawing process is completed for all vital sign items, the vital sign circle radar creation process for one heartbeat is completed.
- the algorithm of the vital sign circle radar creation processing described as the embodiment is not limited to this, and other embodiments may be adopted.
- the abnormality determination process and the rendering process are performed for each vital sign item.
- the colors and the like provided are examples, and these can be modified by means known to those skilled in the art.
- the variation of the drawing process relates to labor saving of the drawing process. Specifically, if the CPU 10 determines that the state is normal in step S 6 13 in FIG. 6, the CPU 10 does not perform the drawing process from step S 6 19 for each determination, and When the determination of the state is continued for, for example, 5 seconds or more, the processing from step S 6 19 is performed. On the other hand, if it is determined in step S613 of FIG. 6 that the state is abnormal, drawing processing from step S615 is performed for each determination.
- the reference time (5 seconds or more) of the drawing process in the above-described normal state is an example, and may be changed according to the length of the entire display time of the circle radar.
- the user of the vital sign circle radar device 100 can easily confirm and determine the state of the vital sign of the patient.
- a predetermined time interval for example, the latest one minute, etc.
- a trend graph that displays a value of a biological signal (parameter) is displayed, or a time graph of the latest time is displayed. It was common to display biological signals sequentially. In this case, there is one problem that it is difficult to confirm the history of the abnormality of the biological signal.
- the vital sign display method employs a circle radar 50 or the like that can cover the entire transport time of the patient by the ambulance (generally, about 15 minutes or about 20 minutes). (See Fig. 4), the history of vital signs can be easily checked. Therefore, the user of the vital sign circle radar device 100 can easily visually recognize information about when and how often the biosignal abnormality has occurred.
- the user since the vital signs are displayed by the circle radar 50 or the like, the user needs relatively little movement of the visual field to grasp the overall state of each vital sign, Another advantage is that it is easy to check the status of vital signs over time.
- the vital sign is displayed by a vital sign radar which can determine whether it is normal or abnormal
- the original data of the vital sign is displayed (for example, the fluctuation of a value such as a heart rate is displayed in a graph).
- a vital sign radar which can determine whether it is normal or abnormal
- the original data of the vital sign is displayed (for example, the fluctuation of a value such as a heart rate is displayed in a graph).
- the value (parameter) of the biological signal is changed to a vital sign display form (radar display) that can determine whether the state is a normal state or an abnormal state.
- radar display a vital sign display form
- the user can intuitively grasp the abnormal state of the living body (the presence or absence of an abnormal value of the biological signal).
- the vital sign circle radar device 100 displays the state of the heartbeat in a predetermined symbol (ma
- the heart rate information display means that displays information related to heart rate by changing the display format.
- the CPU 10 blinks the heart mark in response to the beating of the heart being measured.
- the user can confirm that the vital sign circle radar device 100 is operating normally and can grasp the state of the heartbeat of the patient.
- the sound for example, pitch sound
- the speaker 15 may be output from the speaker 15 in accordance with the beating of the heart together with or instead of the blinking of the mark.
- the vital sign circle radar device 100 is used when the ECG electrode 20 attached to the patient's body comes off during the vital sign circle radar creation process, or when a trouble occurs in the vital sign circle radar creation process.
- Display a predetermined warning (“Warning signal output means that outputs a warning signal when the vital sign cannot be determined”).
- the CPU 10 displays a warning message such as “electrode disconnection” in the display area of the “diagnosis information” on the display 14.
- the CPU 10 may change the color of the whole or part of the display to alert the user, or output a warning sound (alarm sound, etc.). You can.
- FIG. 4 illustrates the vital sign display by the vital sign circle radar device 100, but the present invention is not limited to this.
- a display method as shown in FIG. 11 may be employed. Hereinafter, an outline of each display method will be described.
- Fig. 11 A shows vital signs displayed with a bar-shaped radar.
- the figure shows an example in which a radar 70 such as a VPC is displayed on the display 14. Specifically, the display point moves from the left side of the screen to the right side of the screen as the patient's vital signs are measured.
- the display method of the normal state and the abnormal state is the same as in the above-described embodiment. Further, the total display time of the bar-shaped radar may be determined according to the measurement required time selected by the user.
- Fig. 11B shows vital signs displayed by loop radar (ring radar, donut radar).
- the figure shows an example in which a radar 80 such as a Sp ⁇ binary value is displayed on the display 14.
- a radar 80 such as a Sp ⁇ binary value
- the position at the start of measurement is moved. Specifically, the display point 83 at the start of measurement moves clockwise as the measurement progresses, while the display point 82 for the current measurement time (the latest measurement time) It is located in the upper center.
- a predetermined mark is displayed outside the radar 80 as an abnormal display 84 indicating an abnormal state, thereby distinguishing the display form from the normal state display method.
- Figure 11C shows vital signs as lines.
- the figure shows an example in which the VPC line 90 is displayed on the display 14. Specifically, the display point 91 moves clockwise from the upper center of the screen as the patient's vital signs are measured. In the case of an abnormal state, the abnormal display 92 or 93 indicating the abnormal state is displayed on the line 90.
- the example in which the vital signs are displayed on the display 14 has been described as the “vital sign display means”.
- a vital sign is displayed on a memory card,
- vitamin sign display described in the claims is a concept including general output of vital signs that can be visually recognized. For example, this concept includes a sign that is displayed on a display, a sign that is output as a hard copy, or a sign that is output by facsimile.
- the corresponding display point is drawn in red. See
- the following display method may be adopted.
- the first variation of the abnormal state display is a method of blinking the blinking display point of the abnormal state.
- the abnormality display 60 in FIG. 4 may be blinked in red or the like.
- a second variation of the abnormal state display is a method of changing the display mode according to the level of the abnormal value. Specifically, the level of abnormalities (including severity or severity, etc.) of outliers is ranked (ranked), and the colors of the display points (for example, saturation, lightness, hue, etc.) are determined according to the levels. Etc.) may be changed.
- the chart below illustrates the leveling of outliers in the case of heart rate (HR).
- the abnormal level is large, for example, by performing a process of increasing the saturation of “red” in the abnormal display 60 (see FIG. 4) and displaying it ( Function as "vital sign abnormality level display means"), it is possible to provide more detailed abnormality information to the user.
- the change in the display mode according to the level of the abnormal value is not limited to the above, and for example, the size of the display point may be changed.
- Figure 11 As shown in C, the abnormal display 93 can indicate that the abnormal level is low, and the abnormal display 92 with a larger circle indicates that the abnormal level is high.
- the vital sign circle radar device 100 performs both the measurement of the electrocardiogram and the display of the vital sign circle radar, but the functions may be configured by two or more separate devices.
- Such devices include a device that measures ECG and outputs ECG data, and a device that displays vital sign cycle radar based on the input ECG data. ) May be adopted.
- measurement processing of the electrocardiogram S P_ ⁇ 2 value measurement processing, the abnormality determination process, the configuration in which perform their vital signs display processing (the number of devices, combinations), CPU configuration, etc., means known to those skilled in the art Can be deformed.
- CPU 10 of the vital signs circle radar device 100 although Gyotsu failure judgment S p0 2 values in accordance with the flowchart of FIG. 10, not limited thereto, blood oxygen saturation measuring device 22 CPUs make abnormal judgments and the results of the judgments (corresponding to “Signals generated based on biological signals”. For example, normal signals or abnormal signals, or normal signals or abnormal signals are included. ) May be passed to the CPU 10.
- a peripheral device other than the blood oxygen saturation measuring device 22 may be connected to the vital sign cycle radar device 100.
- a blood pressure measurement device may be connected to the vital sign circle radar device 100 as a peripheral device, and "Blood Pressure (BP)" may be displayed as a vital sign.
- the vital sign circle radar device 100 is used in an ambulance.However, the present invention is not limited to this, and the vital sign circle radar device 100 can be carried at an emergency medical site, or installed at home and home. For medical use, Can be widely used for living organisms including animals.
- devices with the same function as the vital sign circle radar device 100 will be installed in the driver's seat of automobiles and trains, cockpits of airplanes, etc., to prevent the possibility of serious accidents due to attacks such as myocardial infarction. It can also be used for daily health care by installing it on toilet seats and the like. At this time, the ECG electrode 20 and the like need to be installed at a site where the body of the subject must come into contact, for example, a handle, a toilet seat, a handrail, or the like.
- the program for operating the CPU 10 is stored in the F-ROM 18, but this program is read from the CD-ROM in which the program is stored and installed on a hard disk or the like! You just need to do it.
- programs such as a DVD-ROM, a flexible disk (FD), and an IC card may be installed from a computer-readable recording medium.
- programs can be downloaded using communication lines. Also, by installing the program from the CD-ROM, the program stored in the CD-ROM is not indirectly executed by the computer, but the program stored in the CD-ROM is directly It may be made to execute it.
- Computer-executable programs include those that can be directly executed by simply installing them, as well as those that need to be converted to another form (for example, those that have been compressed for a while). Decompression etc.), and also include those that can be executed in combination with other module parts.
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Abstract
Description
Claims
Priority Applications (4)
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US10/525,747 US7371214B2 (en) | 2002-08-27 | 2003-08-26 | Vital sign display device and method thereof |
AU2003257703A AU2003257703A1 (en) | 2002-08-27 | 2003-08-26 | Vital sign display and its method |
JP2004532702A JP4376784B2 (ja) | 2002-08-27 | 2003-08-26 | バイタルサイン表示装置およびその作動方法 |
EP03791278A EP1547518A4 (en) | 2002-08-27 | 2003-08-26 | VITAL LABEL DISPLAY AND ITS METHOD |
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JP2002/246627 | 2002-08-27 | ||
JP2002246627 | 2002-08-27 |
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US (1) | US7371214B2 (ja) |
EP (1) | EP1547518A4 (ja) |
JP (1) | JP4376784B2 (ja) |
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- 2003-08-26 WO PCT/JP2003/010734 patent/WO2004019779A1/ja active Application Filing
- 2003-08-26 EP EP03791278A patent/EP1547518A4/en not_active Ceased
- 2003-08-26 CN CNB038202360A patent/CN100396235C/zh not_active Expired - Fee Related
- 2003-08-26 AU AU2003257703A patent/AU2003257703A1/en not_active Abandoned
- 2003-08-26 US US10/525,747 patent/US7371214B2/en not_active Expired - Fee Related
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Cited By (7)
Publication number | Priority date | Publication date | Assignee | Title |
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JP2010538728A (ja) * | 2007-09-12 | 2010-12-16 | コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ | アラーム及び動向付け機能を有するqt間隔監視システム |
JP2009291606A (ja) * | 2008-06-03 | 2009-12-17 | General Electric Co <Ge> | 健康状態インジケータを備えた患者監視システム |
US8696565B2 (en) | 2008-06-03 | 2014-04-15 | General Electric Company | Patient monitoring system with health status indicator |
US10426350B2 (en) | 2012-03-07 | 2019-10-01 | Ziteo, Inc. | Methods and systems for tracking and guiding sensors and instruments |
JP2014168579A (ja) * | 2013-03-04 | 2014-09-18 | Nippon Koden Corp | 表示装置、および表示装置の制御プログラム |
JP2015084861A (ja) * | 2013-10-29 | 2015-05-07 | パイオニア株式会社 | 信号処理装置及び方法、並びにコンピュータプログラム及び記録媒体 |
JP2019115761A (ja) * | 2019-04-12 | 2019-07-18 | パラマウントベッド株式会社 | 状態判定装置 |
Also Published As
Publication number | Publication date |
---|---|
EP1547518A4 (en) | 2009-04-22 |
JP4376784B2 (ja) | 2009-12-02 |
US7371214B2 (en) | 2008-05-13 |
US20060074321A1 (en) | 2006-04-06 |
CN1678238A (zh) | 2005-10-05 |
AU2003257703A1 (en) | 2004-03-19 |
CN100396235C (zh) | 2008-06-25 |
EP1547518A1 (en) | 2005-06-29 |
JPWO2004019779A1 (ja) | 2005-12-15 |
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