WO2019026846A1

WO2019026846A1 - Analysis device, analysis system, method for controlling analysis device, and program for controlling analysis device

Info

Publication number: WO2019026846A1
Application number: PCT/JP2018/028462
Authority: WO
Inventors: 知明橋本; 強長谷川; 亮平勝木
Original assignee: テルモ株式会社
Priority date: 2017-07-31
Filing date: 2018-07-30
Publication date: 2019-02-07
Also published as: JP7186704B2; JPWO2019026846A1

Abstract

[Problem] To provide an analysis device, etc., with which it is possible to easily perform various types of analysis using information obtained by an external circulation device, etc. [Solution] An analysis device 100 having at least: a storage unit 112 that stores various types of information acquired from a medical device 10; and a display unit 104 that displays, from among the plurality of types of information stored in the storage unit, information in a specific time range, the information being displayed at the same time on the same screen, and moreover displays the information in conjunction with a time-of-day specifying unit S indicating a specific time of day on the same screen; the various types of information at the time of day specified by the time-of-day specifying unit being displayed by the display unit in conjunction with the information in the specific time range.

Description

ANALYZER, ANALYZER SYSTEM, ANALYZER CONTROL METHOD, AND ANALYST CONTROL PROGRAM

The present invention relates to an analysis device, an analysis system, a control method of the analysis device, and a control program of the analysis device, which analyze information obtained from an extracorporeal circulation device or the like used by a patient or the like during surgery.

Conventionally, for example, when it is necessary to supply blood to a patient during surgery or the like, an extracorporeal circulation device having a heart-lung machine or the like is used to circulate the blood of the patient outside the body.
Since such an extracorporeal circulatory system has a flow rate sensor, a pressure sensor, a rotational speed detection unit of a drive motor, and the like, by managing these values, etc., the condition of the patient and the condition of the device itself are managed. Can be configured (for example, Patent Document 1).
In addition, values of flow rate sensors and the like of such extracorporeal circulation devices need to be used also by a doctor or the like to study the effects of drugs after surgery.

JP, 2006-122111, A

However, when performing various analyzes using information obtained by an extracorporeal circulation device after surgery, it is necessary to prepare various types of obtained data etc. in advance. The problem is that it takes a lot of effort and in practice it is often difficult.

Therefore, the present invention provides an analysis device, an analysis system, a control method of the analysis device, and a control program of the analysis device capable of easily performing various analyzes using information obtained by the extracorporeal circulation device or the like. To aim.

According to the present invention, in the present invention, at least a storage unit for storing various information acquired from a medical device, and among various information stored in the storage unit, information in a specific time range is simultaneously displayed on the same screen. And a display unit for displaying a time specifying unit indicating a specific time on the same screen, and the display unit includes the various information of the time specified by the time specifying unit. It is achieved by an analyzer characterized in that it is displayed together with the information in said specific time range.

According to the above configuration, the various information from the medical device is stored in the storage unit, and the various information stored in the storage unit is displayed on the same screen in a specific time range (for example, 24 hours). It is a configuration that makes it easy to grasp the transition of various types of information.
In addition, the values of various information at a specific time are displayed together, and the specific time is indicated on the screen, so the values of various information at each time can be grasped on the same screen as a whole. .
Therefore, the configuration is such that doctors and the like can easily conduct research.

Preferably, the time specifying unit is configured to be movable and / or fixed on the screen.

Since the time identification unit can be moved and / or fixed on the screen, the time identification unit can be moved or the like at any time of the patient's various information, and various information such as the movement destination is displayed on the screen It can be done.

Preferably, the time specifying unit is associated with event information generated at a time of the time specifying unit.

According to the above configuration, since the time identification unit is associated with event information (for example, medication time information etc.) that has occurred at the time of the time identification unit, a doctor or the like focuses on the time identification unit on the screen. By observing, it is possible to easily grasp the effects of medication etc.

Preferably, a memo information can be displayed together with the time specifying unit.

According to the above configuration, the memo information is also displayed in association with the time identification unit. Therefore, if a doctor or the like inputs a memo related to the time identification unit, the time identification unit is displayed on the screen. You can associate and leave notes.

Preferably, the various information includes special information to be obtained by special calculation, and includes calculation formula information for generating the special information.

According to the above configuration, the various information includes special information (for example, the oxygen transport amount etc.) to be calculated by a special calculation and is provided with calculation formula information for generating the special information. Can be input so that it can be displayed on the screen, making the device easy to use.

Preferably, the calculation formula information is configured such that various information stored in the storage unit can be included in the calculation formula.

According to the above configuration, since various information stored in the storage unit can be included in the calculation formula, a calculation formula using the information stored in the storage unit can be easily generated, and the calculation formula can be obtained by the calculation formula Special information can also be easily displayed on the screen.

Preferably, a specific time range displayed on the same screen can be changed.

According to the above configuration, since the specific time range (for example, 24 hours to 12 hours etc.) displayed on the same screen can be changed, data of the patient's necessary time range can be appropriately displayed. .

Preferably, the analysis system is characterized by comprising a medical device and having an analysis device capable of communicating with the medical device.

According to the above object, in the present invention, at least various information acquired from a medical device is stored in a storage unit, and among various information stored in the storage unit, information in a specific time range is simultaneously displayed on the same screen. While displaying, the time identification unit indicating a specific time is displayed on the same screen together with the display unit, and the display unit displays the various information of the time identified by the time identification unit at the specific time. This is achieved by the control method of the analyzer characterized in that it is displayed together with the information in the range.

According to the above object, according to the present invention, the analysis device includes at least a storage unit for storing various types of information acquired from a medical device, and of various types of information stored in the storage unit, information in a specific time range at the same time The display unit functions as a display unit that displays the same screen and displays a time specifying unit indicating a specific time on the same screen, and the display unit is configured to display the various information of the time specified by the time specifying unit. Is achieved by the control program of the analyzer for functioning to be displayed together with the information in said particular time range.

As described above, according to the present invention, an analysis device, an analysis system, a control method of the analysis device, and control of the analysis device capable of easily performing various analyzes using information obtained by the extracorporeal circulation device etc. There is an advantage that the program can be provided.

FIG. 1 is a schematic view showing a main configuration of an extracorporeal circulation system including an analysis device of the present invention, for example, a data analysis PC, a data storage PC, and a medical device such as an extracorporeal circulation device. FIG. 2 is a schematic block diagram showing the main configuration of “PC for data analysis”, “controller”, “data storage PC” etc. of FIG. It is a schematic block diagram showing the main composition of the 1st various information storage part. It is a schematic block diagram which shows the main structures of a 2nd various information storage part. It is a schematic block diagram which shows the main structures of a 3rd various information storage part. It is a schematic block diagram which shows the main structures of a 4th various information storage part. It is a schematic flowchart which shows the main operation examples of the extracorporeal circulation system concerning this Embodiment. It is a flowchart which shows a basic screen display. It is a schematic flowchart which shows the process of changing a time-axis (time range to display). 17 is a schematic flowchart showing an operation example in the case of moving or fixing the event display axis of FIG. 16 along the flow in time. It is a general | schematic flowchart which shows the operation example which reduces the number of data, such as a flow rate currently displayed on the screen. It is a schematic flowchart which shows the operation example in the case of setting the position of an event display axis | shaft as the time etc. of drug administration. It is a general | schematic flowchart which shows the process of displaying "a memo" in relation to the event display axis | shaft S. FIG. It is a general | schematic flowchart which shows the main process of displaying the data after calculation calculated and calculated | required various data on a screen. It is a schematic flowchart which shows the process of confirming the threshold value etc. of data on a screen. It is a schematic explanatory drawing which shows the state as which various information, such as vital data, were displayed on the display of PC for data analysis of FIG. It is the schematic which shows an example of the screen for event display axis content selection. It is the schematic which shows the "calculation formula" displayed on the screen. It is a schematic diagram showing an example of a screen where threshold information was displayed.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings and the like.
The embodiment described below is a preferable specific example of the present invention, and therefore, various technically preferable limitations are given. However, the scope of the present invention particularly limits the present invention in the following description. As long as there is no statement of purport, it is not limited to these modes.

(About the explanation of the extracorporeal circulation system in FIG. 1)
FIG. 1 is a schematic view showing the main configuration of an extracorporeal circulation system 1 including an analysis apparatus of the present invention, for example, a data analysis PC 100, a data storage PC 2, and a medical instrument, for example, an extracorporeal circulation apparatus IR. .
The extracorporeal circulation system IR etc. shown in FIG. 1 is an apparatus for performing extracorporeal circulation of the blood of the patient P as shown in FIG. 1. For this "extracorporeal circulation", "extracorporeal circulation operation" and "auxiliary circulation operation" Is included.
The “extracorporeal circulation operation” is the extracorporeal circulator IR when the patient P can not exchange gas because blood does not circulate in the heart of the patient (subject) P who is the application target such as the extracorporeal circulator IR. Thus, the blood circulation operation and the gas exchange operation (oxygenation and / or carbon dioxide removal) on the blood are performed.

The “auxiliary circulation operation” is a case where blood circulates in the heart of a patient (subject) P who is an application target such as the extracorporeal circulation device IR and the like, and gas exchange can be performed in the lung of the patient P. IR is also used to assist the blood circulation operation. Some devices have the function of performing a gas exchange operation on blood.

By the way, the extracorporeal circulation system IR etc. shown in FIG. 1 according to the present embodiment is used, for example, in the case of performing cardiac surgery on a patient P or treatment in an ICU (intensive care unit) thereafter.
Specifically, the "centrifugal pump 3" such as the extracorporeal circulation system IR is operated, blood is removed from the vein (Vena cava) of the patient P, and gas exchange in blood is performed by the artificial lung 4 to oxygenate the blood. Perform the “extracorporeal extracorporeal blood circulation” to return this blood to the patient P's artery (aorta) again. In other words, the extracorporeal circulation device IR or the like is a device that performs heart and lung substitution.

Further, the extracorporeal circulation device IR and the like have the following configuration.
That is, as shown in FIG. 1, the extracorporeal circulation system IR etc. has a "circulation circuit 1R" for circulating blood, and the circulation circuit 1R is "artificial lung 4", "centrifugal pump 3", "motor 5" For example, the controller 3 which manages the “vein cannula (blood removal cannula) 6”, the “arterial cannula (blood delivery cannula) 7”, and the extracorporeal circulation system IR and the like.
The centrifugal pump 3 is also referred to as a blood pump, and pumps other than centrifugal type can also be used.

And the vein side cannula (blood removal side cannula) 6 of FIG. 1 is inserted from the femoral vein, and the tip of the vein side cannula 6 is indwelled in the right atrium.
The arterial cannula (blood feeding cannula) 7 is inserted from the femoral artery. The venous cannula 6 is connected to the centrifugal pump 3 using a blood removal tube 8.
Further, a pressure sensor 9 for measuring the pressure of the blood in the blood removal tube 8 is disposed in the blood removal tube 8.
The pressure sensor 9 is communicably connected to the controller 16, and the value of the pressure sensor 9 is transmitted to the controller 16.

The motor 5 is communicably connected to the controller 16. When the centrifugal pump 3 is operated according to a command from the controller 16, the centrifugal pump 3 removes blood from the blood removal tube 8 and passes the blood to the artificial lung 4. Are returned to the patient P via the blood feeding tube 10.

The artificial lung 4 is disposed between the centrifugal pump 3 and the blood feeding tube 10.
The oxygenator 4 performs a gas exchange operation (oxygenation and / or carbon dioxide removal) on the blood. The artificial lung 4 is, for example, a membrane-type artificial lung, and particularly preferably a hollow fiber membrane-type artificial lung. The blood feeding tube 10 is a conduit connecting the artificial lung 4 and the arterial catheter 7.

In addition, a flow rate sensor 11 is disposed in the blood feeding tube 10, and the flow rate sensor 11 is communicably connected to the controller 16.
Therefore, the flow rate sensor 11 is configured to detect the value of the flow rate of blood flowing from the patient P through the blood removal tube 8 and to transmit the value to the controller 16.
Further, a temperature sensor 15 for measuring the temperature of the blood in the blood feeding tube 10 is disposed in the blood feeding tube 10.
The temperature sensor 15 is communicably connected to the controller 16, and the value of the temperature sensor 15 is transmitted to the controller 16.

As the blood removal tube 8 and the blood delivery tube 10, for example, a flexible plastic tube such as a vinyl chloride resin or silicone rubber having high transparency and flexibility can be used.
In the blood removal tube 8, the blood flows in the V direction of FIG. 1, and in the blood feeding tube 10, the blood flows in the W direction of FIG.

Further, in the extracorporeal circulation system 1 of the present embodiment, as shown in FIG. 1, a blood gas monitor sensor 12a is disposed in the blood feeding tube 10, and the blood gas monitor sensor 12a is shown in FIG. , Is connected to the blood gas monitor 12.
Thus, data of blood gas in the blood feeding tube 10 is configured to be displayed on the blood gas monitor 12.

On the other hand, as shown in FIG. 1, the saturated oxygen measurement sensor 13a is attached to the patient P, and data of the saturated oxygen is displayed on the oxygen saturation monitor 13 of FIG.
In addition, the extracorporeal circulation system 1 according to the present embodiment has a data storage PC 2, which is communicably connected to the controller 16, the blood gas monitor 12, the oxygen saturation monitor 13, and the like.

Further, as shown in FIG. 1, an infusion pump 14 for administering a drug solution or the like is disposed to the patient P via an indwelling needle or the like, and a drug solution bag 14 a is connected to the infusion pump 14.
The infusion pump 14 is connected to the data storage PC 2 as shown in FIG.

Therefore, the data storage PC 2 is configured to acquire not only data of oxygen saturation and blood gas but also data such as flow rate and pressure acquired by the controller 16 and accumulate.
Further, the data accumulation PC 2 is configured to acquire data of the liquid medicine administration of the infusion pump 14 of FIG.

By the way, in the extracorporeal circulation system 1, a “data analysis PC 100” that analyzes data accumulated by the data accumulation PC 2 is connected to the data accumulation PC 2.

In the present embodiment, although the data analysis PC 100 is described below as an example of an analyzer, the present invention is not limited to this, and the data analysis PC 100 may be configured to double as the data storage PC 2. .

Further, in the present embodiment, not only when the data stored in the data storage PC 2 is transmitted to the data analysis PC 100 via a wired or wireless LAN, etc., the data is used for data analysis via a medium such as USB. It may be migrated to the PC 100.

The data analysis PC 100, the data storage PC 2, the controller 16 and the like of the extracorporeal circulation system 1 shown in FIG. 1 have a computer, and the computer is a CPU (Central Processing Unit), RAM (Random Access Memory), ROM (not shown). Read Only Memory) and the like are connected via a bus.

(About the block diagram of Fig. 2 etc.)
FIG. 2 is a schematic block diagram showing the main configuration of “data analysis PC 100”, “controller 16”, “data storage PC 2” etc. of FIG.
As shown in FIG. 2, the data analysis PC 100 has an "analysis PC control unit 101", and the analysis PC control unit 101 has a "communication for the data analysis PC 100 to communicate with the data storage PC 2 etc. Device 102 ”,“ timekeeping device 103 ”for generating time information,“ display unit ”for displaying various information such as“ display 104 ”,“ various information input device (keyboard etc.) 105 ”and the like are controlled.

Further, the controller 16 in FIG. 2 is connected to the motor 5, the flow rate sensor 11, the pressure sensor 9 and the temperature sensor 15 shown in FIG. 1.
On the other hand, the oxygen saturation monitor 13, the blood gas monitor 12 and the infusion pump 14 are directly connected to the data storage PC 2 without the intervention of the controller 3.

Then, the analysis PC control unit 101 is configured as the "first various information storage unit 110", the "second various information storage unit 120", the "third various information storage unit 130", and the "fourth various information storage unit 130" shown in FIG. The various information storage unit 140 "is also controlled.

3 to 6 show “first various information storage unit 110”, “second various information storage unit 120”, “third various information storage unit 130” and “fourth various information storage unit 140”. Is a schematic block diagram showing the main configuration of “. The specific contents of these will be described later.

(About operation example of extracorporeal circulation system 1)
7 to 15 are schematic flowcharts showing main operation examples of the extracorporeal circulation system 1 according to the present embodiment.
That is, in the present embodiment, various information obtained in the operation of patient P or the like is stored in "data analysis PC 100" through "data storage PC 2" by extracorporeal circulation system 1 shown in FIG. .
Then, based on the various information accumulated in this manner, various information and the like are displayed on the display 104 of the data analysis PC 100 so that a doctor or the like can easily conduct research after the operation. There is.

Then, although the example of a display of the main various information displayed on the display 104 of PC100 for data analysis is demonstrated hereafter, the acquisition process of the various information memorize | stored in PC100 for data analysis using FIG. explain.

(About acquisition process of various information to memorize during the operation such as patient P)
As shown in step 1 (hereinafter referred to as “ST”) in FIG. 7, in the extracorporeal circulation system 1 in FIG. 1, for example, “motor 5” “flow sensor 11” “pressure sensor 9” during surgery of patient P. "Various information such as vital data such as" rotational speed "," flow rate "," temperature "and" pressure "are acquired from" temperature sensor 15 "," oxygen saturation monitor 13 "," blood gas monitor 12 "and the like.
Then, each information is associated with the corresponding “time information”, and the “rotational speed information storage unit 111”, “flow rate information storage unit 112”, “temperature information storage unit 113”, “pressure information storage unit 114”, etc. Remember.

Specifically, for example, the following various types of information are stored.
● Acquire "rotational speed (Arterial) information" from "motor 5", acquire corresponding time information from "timekeeping device 103", associate them, and store them in "rotational speed information storage unit 111" in FIG.
● Acquire "flow information (Flow) information" from "flow sensor 11", acquire corresponding time information from "time measurement device 103", associate them, and store them in "flow information storage unit 112" in FIG.
● Acquire "Temperature (Temp) Information" from "Temperature Sensor 15", acquire corresponding time information from "Timekeeping device 103", associate them, and store them in "Temperature information storage unit 113" in FIG.
● Acquire "Pressure (Press) Information" from "Pressure Sensor 9", acquire corresponding time information from "Timekeeping device 103", associate them, and store them in "Pressure information storage unit 114" in FIG.
● "Local tissue oxygen saturation (rSO2) information" is acquired from "Oxygen saturation monitor 13", the corresponding time is acquired from "time counting device 103", and "local tissue oxygen saturation information storage" in FIG. Stored in section 115 ".

● “Percutaneous arterial blood oxygen saturation (SpO2) information” is acquired from “Ox saturation monitor 13”, corresponding time information is acquired from “timekeeping device 103”, and the “percutaneous” in FIG. Stored in the arterial blood oxygen saturation information storage unit 116 ".
● “Pulse rate information” is acquired from “oxygen saturation monitor 13”, corresponding time information is acquired from “timekeeping device 103”, and is associated and stored in “pulse rate information storage unit 117” in FIG.
● The “pH information” is stored from the “blood gas monitor 12”, the corresponding time information is acquired from the “time measurement device 103”, and stored in the “pH information storage unit 118” in FIG.
● Obtain "CO2 partial pressure (PCO2) information" from "blood gas monitor 12", acquire corresponding time information from "time measurement device 103", associate them, and "CO2 partial pressure information storage unit 119" in FIG. Remember to ".
● "Oxygen partial pressure (PO2) information" is acquired from "blood gas monitor 12", the corresponding time information is acquired from "timekeeping device 103", and it is related to "oxygen partial pressure information storage unit 225" in FIG. Memory.
● "Oxygen saturation (SO2) information" is acquired from "blood gas monitor 12", the corresponding time information is acquired from "time counting device 103", and "oxygen saturation information information 100 billion part 221" of FIG. Remember.

● “Hematocrit (HCT) information” is acquired from “blood gas monitor 12”, corresponding time information is acquired from “timekeeping device 103”, and is correlated and stored in “hematocrit information storage unit 222” in FIG.
● Acquire “hemoglobin (Hgb) information” from “blood gas monitor 12”, acquire corresponding time information from “timekeeping device 103”, associate it, and store it in “hemoglobin information storage unit 223” in FIG.
● Obtain “bicarbonate ion (HCO3) information” from “blood gas monitor 12”, obtain corresponding time information from “timekeeping device 103”, associate it with “bicarbonate ion information information 100 billion unit 121” in FIG. Remember.
● “Oxygen consumption information” is acquired from “blood gas monitor 12”, corresponding time information is acquired from “timekeeping device 103”, and it is stored in “oxygen consumption information storage unit 122” of FIG.
● Obtain "potassium value (K +) information" from "blood gas monitor 12", acquire corresponding time information from "time measurement device 103", associate it, and store it in "potassium value information storage unit 123" in FIG.

● Acquire "Base excess value (BE) information" from "Blood gas monitor 12", acquire corresponding time information from "Timekeeping device 103", associate it with "Base excess value information storage unit 124" in FIG. Memory.
● Acquire “dosing injection information” from “infusion pump 14”, obtain corresponding time information from “timekeeping device 103”, associate it, and store it in “dosing injection information storage unit 125” in FIG.
● Obtain “artificial lung replacement information” from “artificial lung 4”, obtain corresponding time information from “timekeeping device 103”, associate it, and store it in “artificial lung replacement information storage unit 126” in FIG.

In addition, when storing the above-mentioned various information, event information (for example, dosing time information etc.) can be associated and stored.

In addition, the data analysis PC 100 acquires body surface area information of the patient P in advance, and stores the acquired information in the “body surface area information storage unit 127” of FIG. 4.

Next, the process proceeds to ST2 in FIG. 7, and information to be obtained by calculation is acquired based on the above acquired information.
Specifically, “index information generation processing unit (program) 128” in FIG. 4 operates, “flow rate information” in “flow rate information storage unit 112” in FIG. 3, and “body surface area information storage unit 127 in FIG. The "cardian index information" is generated based on the body surface area information of "," and stored in the "cardian index information storage unit 129" of FIG. 4 together with the related time information.

This is the end of the preparation stage of acquisition and generation of necessary information.
Then, researchers such as doctors display such information on the “data analysis PC 100” in FIG. 1 to conduct various researches.
In the present embodiment, the display of information suitable for research can be performed by the operation of an operator who is a researcher or the like.
The details will be described below.

(Display various information in the same time zone)
FIG. 8 is a flowchart showing basic screen display.
As shown in the flowchart, the following information is displayed on the display 104 of the data analysis PC 100 of FIG.
Specifically, as shown in the flowchart of ST11 of FIG. 8, the “basic screen display processing unit (program) 131” of FIG. 5 operates, and various information such as vital data stored in each storage unit described above. Based on the above, vital data etc. of 24 hours (24 hours from 8:00 on May 31, 2017 to 8:00 on June 1) which is a previously set time axis are displayed.
This 24 hours is one example of a predetermined time range.

At the same time, the event display axis S, which is a time specifying unit, is displayed on the screen at an arbitrary time (for example, an intermediate time).
Furthermore, each data of various storage units at the time of the event display axis S is also displayed on the screen.

FIG. 16 is a schematic explanatory view showing a state where various information such as vital data are displayed on the display 104 of the data analysis PC 100 of FIG.
As shown in FIG. 16, since 24 hours is designated as the time axis at the lower right of the screen, the information acquired by the data analysis PC 100 according to the flow of time from left to right at the center of the screen, In the case, temperature information (Temp), rotational speed (Arterial) information of the motor 5, information of pressure (Press), and the like are displayed.
And, a vertically elongated axis shaped event display axis S is displayed at the center. Then, information corresponding to the time when the event display axis S is arranged is displayed in the upper frame and the lower frame of the screen. For example, the time in the case of FIG. 16 is “5/31 20:33:04”.

For example, the frame at the left end of the upper part of the screen of FIG. 16 is “Flow”, and the numerical value at the time “5/31 20:33:04” of the event display axis S is displayed.
Similarly, a numerical value of "motor rotational speed (Arterial)" is displayed on the right of "flow rate".

Further, the value of “pH” is displayed in the lower left frame, and this value is a numerical value at the time “5/31 20:33:04” of the event display axis S.

Therefore, since researchers can visually recognize not only the change in each information, for example, in 24 hours, but also each information of the time indicated by the event display axis S at the same time by visually recognizing the display 104, as a research tool , Very easy to use.

(When changing the time axis (for example, 24 hours))
Here, since the amount of data is too large on the time axis (for example, 24 hours) of the screen in FIG. 16, a case in which the researchers etc. change the time to 12 hours, 1 hour, or 20 minutes will be described below.
FIG. 9 is a schematic flowchart showing the process of changing the time axis (time range to be displayed).

When the researcher inputs a time axis (time range to be displayed) change signal in ST21 of FIG. 9, the “time axis change input processing unit (program) 132” in FIG. 5 operates in ST22, and the time axis is displayed on the screen. Display “Change input screen”.
Next, at ST23, it is determined whether "time axis change information" has been input.
Here, for example, when the researcher inputs “12 hours” from “8 o'clock to 20 o'clock on May 31, 2017”, the process goes to ST24.

In ST24, the processing unit (program) 132 operates, and the corresponding data is extracted from each storage unit described above, with the time axis of display data as 12 hours from "8 o'clock to 20 o'clock on May 31, 2017". To display.
In addition, this time can be freely selected, and can be 10 minutes or the like.

(When moving or fixing the event display axis S)
FIG. 10 is a schematic flow chart showing an operation example when the event display axis S of FIG. 16 is moved or fixed along the flow in time.
Hereinafter, the operation when the researcher desires to move the event display axis will be described using FIG.

First, at ST31 in FIG. 10, it is determined whether “event display axis operation processing unit (program) 133” in FIG. 5 operates and movement instruction or fixing instruction of the event display axis S is input.
Specifically, it is determined whether or not there is an input of “one click” for moving the event display axis S on the screen of FIG.
When the "one click" is made, the event display axis S is set to the movable "moving mode" state.

Next, when there is an input of a movement instruction in ST32, the process proceeds to ST33. Specifically, in ST33, it is determined whether the event display axis S in FIG. 16 has been moved by a point operation on the screen.
If it is determined at ST34 that the event display axis S has moved, the process proceeds to ST35.
At ST35, the value of the information corresponding to the time of the movement destination, for example, the numerical value of the flow rate etc. is displayed.

On the other hand, when it is determined in ST32 that the movement instruction is not input, the process proceeds to ST36.
At ST36, it is determined whether or not a fixed input instruction has been given to the event display axis S.
Specifically, it is determined whether or not there is a "one click" input on the event display axis S.
Next, in ST37, when the fixing instruction is input, the movement of the event display axis S is made impossible in ST38.

As described above, in the present embodiment, the researcher moves the event display axis S to an arbitrary position along the flow of time on the screen by inputting the movement instruction or the like to the event display axis S on the screen. It can be done. Then, values of various information at the time of the movement destination can be changed and displayed in the upper and lower frames in FIG.

Therefore, the researcher can quickly display the value of various information (flow rate etc.) of the time he / she wants to check on the screen simply by operating the event display axis S.

(When decreasing the number of data displayed on the screen)
FIG. 11 is a schematic flowchart showing an operation example for reducing the number of data such as the flow rate displayed on the screen.
For example, when the researcher wants to decrease the number of data (flow rate etc.) displayed on the screen, for example, when the researcher inputs a signal on the data selection screen as shown in ST41 of FIG. The “display information selection processing unit (program) 134” in FIG. 5 operates to determine whether “display data selection” is completed.

Here, the researcher performs selection of necessary data.
Next, in ST42, when it is determined that the selection is finished, the process proceeds to ST43, and only selected data (flow rate etc.) can be displayed on the screen.
Thus, in the present embodiment, the researcher can display only the required type of data (flow rate etc.).

(When changing the display content of the event display axis S)
When a researcher (operator) wants to study changes in data (such as flow rate) before and after administration of a certain drug, which is event information, for example, in addition to using event information that has already been stored, It is also possible to perform an operation to associate the position of the event display axis S with the time of drug administration.

FIG. 12 is a schematic flow chart showing an operation example in the case where the position of the event display axis S is the time of drug administration or the like.
First, as shown at ST51 in FIG. 12, when the researcher inputs a display for selecting the content of the event display axis S, the “event display axis content selection processing unit (program) 135” in FIG. 5 operates. , The event display axis content selection screen is displayed on the screen as another window.

FIG. 17 is a schematic view showing an example of an event display axis content selection screen.
The event display axis content selection screen displays data such as an event during surgery, for example, a dosing time, an artificial lung replacement time, and the like.
In addition, as for this data, data corresponding to the range of the time axis of the current display screen is extracted from the “dosage injection information storage unit 125” and the “artificial lung replacement information storage unit 126” in FIG. It is.

Then, for example, the researcher selects a medication (drug AAA) on May 31, 2017 at 20:42:30 in FIG.
In this example, a researcher chooses to study changes in data (such as flow rate) before and after dosing of the drug AAA.

Then, in ST32 of FIG. 12, it is determined that the content data of the event display axis S has been selected, and in ST53, the processing unit (program) 135 operates, and the event display axis S is 20:00 May 31, 2017. It is displayed on the screen according to 42 minutes and 30 seconds.

The event display axis S in FIG. 16 is displayed on the screen in accordance with May 31, 2017 at 20:42:30.
Therefore, the researcher can easily grasp changes in data (flow rate etc.) before and after administration of the medicine AAA, that is, effects such as administration etc., by observing before and after the event display axis S in FIG. .

In the present embodiment, the “drug administration time” is selected as the event display axis S. However, the present invention is not limited to this, and other events such as artificial lung replacement may be selected.

(When displaying a "memo" in relation to the event display axis S)
FIG. 13 is a schematic flowchart showing the process of displaying a “memo” in relation to the event display axis S.
First, if the researcher wants to display a "memo" on the screen in relation to the event display axis S, for example, if the researcher wants to display a memo about changes in data before and after the medication AAA, At ST61 in FIG. 13, the "memo input screen" is displayed.

Specifically, the “memo input processing unit (program) 141” in FIG. 6 operates, and the “memo input screen” is displayed.
Here, the researcher inputs, for example, a memo such as “Medication, medicine AAA” on the “memo input screen”.
Next, the process proceeds to ST62, and it is determined whether the memo input is completed.

When the memo input is completed in ST62, the process proceeds to ST63. At ST63, the "memo information" is stored in the "memo information storage unit 142" of FIG. 6 in association with the event display axis S at the relevant time, and displayed in association with the event display axis S on the screen.
The balloon indicated by M in FIG. 16 is the displayed “memo information”.
in this way. By displaying “memo information” in association with the event display axis S on the screen, it becomes an easy-to-use tool for researchers.

(When you want to display on the screen the data after calculation which is calculated and calculated various data)
FIG. 14 is a schematic flowchart showing main steps for displaying on the screen the after-calculation data obtained by calculating various data.
First, if the researcher wants to display special data, such as calculated data, for example, oxygen transport amount, as data, which is special information obtained by calculating various data such as flow rate, the process proceeds to ST71 of FIG. .
In ST71, when the researcher obtains a display of the calculation formula, the “calculation formula input calculation processing unit (program) 143” of FIG. 6 operates and the calculation formula input screen is displayed.

FIG. 18 is a schematic view showing “calculation formula” displayed on the screen.
As shown in FIG. 18, on the calculation formula input screen, each data name (item name such as flow) can be used as a part of the formula, and a numerical keypad for calculation and the like are displayed.
Then, a calculation formula can be created using these data names and the ten keys.

When the items of each data name (flow rate etc.) are taken into a formula, necessary data is extracted from the corresponding storage unit, for example, flow rate information storage unit 112 etc., in the part of the data name, and calculation is performed It has become.

In the present embodiment, for example, since the researcher desires to display the oxygen delivery amount on the screen, the following equation is input to the equation of FIG.
_{"((1.36 × SO 2 × Hgb} ) + (0.0031 × PO 2)) × Flow "
Among them, “SO ₂ ”, “Hgb”, “PO ₂ ” and “Flow” are selected by selecting the key of the same name prepared in advance in FIG. The numbers are input using the ten keys of FIG.

By inputting in this manner, “SO ₂ ” extracts data from the “oxygen saturation information storage unit 221” in FIG. 3 and performs calculation.
Similarly, “Hgb” is “hemoglobin information storage unit 223” in FIG. 3, “PO ₂ ” is “oxygen partial pressure information storage unit 225” in FIG. 3, and “Flow” is flow rate information in FIG. Calculation is performed by extracting data from the storage unit 112 ".

Therefore, in the present embodiment, by inputting the calculation formula on a special screen, it is possible to obtain the value of the oxygen transport amount etc. using the value of the data such as the flow rate actually acquired from the extracorporeal circulation device 10 Therefore, it is an extremely easy-to-use device for researchers.

Further, in the present embodiment, the calculation formula has been described taking oxygen transport amount as an example, but in the case of “differential pressure”, it can be obtained by inputting “Press2-Press1”.

Next, in ST72, it is determined whether or not there is an input of a formula, and when there is an input of the formula, the process goes to ST73.
In ST73, the input calculation formula, in the case of the present embodiment, the oxygen transfer amount formula “((1.36 × SO ₂ × Hgb) + (0.0031 × PO ₂ )) × Flow” is shown in FIG. Are stored in the “calculation formula data storage unit 144”.

Next, the process proceeds to ST74. In ST74, the same calculation processing unit (program) 143 operates, and the data name of the calculation formula of “calculation formula data storage unit 144” corresponds to the data of each storage unit, and in the present embodiment, “oxygen saturation in FIG. Data of information storage unit 221 "," hemoglobin information storage unit 223 "," oxygen partial pressure information storage unit 225 ", and" flow rate information storage unit 112 "are substituted and calculated, and the result is calculated after" calculation "in FIG. It is stored in the data storage unit 145 ".

Next, the process proceeds to ST75. In ST75, the post-calculation data of the "post-calculation data storage unit 145" of FIG.
For example, as shown in the right end frame of the upper frame of FIG. 16, the numerical value of “DO2” (oxygen transport amount) is displayed.

As described above, in the present embodiment, the researcher can display the data necessary for the research on the screen without calculating the data himself and can quickly compare this with other data.
Therefore, the researcher can generate data necessary for the research by a calculation formula and display the data on the screen, which makes the apparatus extremely easy to use.

(When confirming the threshold etc. of data on the screen)
FIG. 15 is a schematic flow chart showing the process of confirming the threshold value of data and the like on the screen.
When a researcher observes the transition of certain data, it may be desirable to confirm the data, for example, a threshold such as the flow rate.
In that case, first, in ST 81 of FIG. 15, when there is an input of threshold display request from the researcher, “Threshold display request display processing unit (program) 146” of FIG. 6 operates to display the threshold display desired data input screen. Do.

Here, in the present embodiment, the trainee inputs, for example, “Flow”.
Then, the processing proceeds to ST82, and the processing unit (program) 146 determines that "the threshold display request data" is input, and stores the input data name in the "threshold display request information storage unit 147" in ST83. .

Next, in ST84, the processing unit (program) 146 operates to set the threshold range of the corresponding data based on the threshold display request information of the “threshold display request information storage unit 147” of FIG. 6, for example, “Flow”. On the screen.

FIG. 19 is a schematic view showing an example of a screen on which threshold information is displayed. In FIG. 19, the numerical range of the flow rate (Flow) threshold is indicated by diagonal lines.
As described above, in the present embodiment, the trainee can easily understand the correlation between the flow rate and the allowable range, for example, because the threshold range which is the allowable range of the specific flow rate data and the like is displayed on the screen. be able to.

As described above, by using the extracorporeal circulation system 1 according to the present embodiment, the researcher can smoothly acquire various types of information from the extracorporeal circulation system IR etc. and other devices etc., and efficiently acquired information Can be displayed on the display to conduct research and the like.

The present invention is not limited to the above embodiment.

1 · · · extracorporeal circulation system, 2 · · · data storage PC, 3 · · · centrifugal pump, 4 · · · · · · · · · · · · · · · · · · · · · · · · · · · · vein side cannula, 7 · · · artery side Cannula, 8: blood removal tube, 9: pressure sensor, 10: blood feeding tube, 11: flow sensor, 12: blood gas monitor, 12a: blood gas monitor sensor, 13. ···· Oxygen saturation monitor, 13a · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · medical solution bag, 15 · · · temperature sensor, 16 · · · · · · · · · · 100 for data analysis PC 101: analysis PC control unit 102: communication device 103: clock device 104: display 105: various information input device (keyboard etc.) 110: 110 1 Various information storage unit 111 ... rotation speed information storage unit, 112 ... flow rate information storage unit, 113 ... temperature information storage unit, 114 ... pressure information storage unit, 115 ... local tissue oxygen saturation information storage unit, 116: Percutaneous arterial blood oxygen saturation information storage unit 117: pulse rate information storage unit 118: pH information storage unit 119: carbon dioxide partial pressure information storage unit 120: 120 Second various information storage unit, 121 · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · · oxygen consumption information storage unit, 123 · · · potassium value information storage unit, 124 · · · base excess value information storage unit 125: Medication injection information storage unit 126: Artificial lung replacement information storage unit 127: Body surface area information storage unit 128: Index information generation processing unit (program) 129: Car Dian index information Storage unit 130: Third various information storage unit 131: Basic screen display processing unit (program) 132: Time axis change input processing unit (program) 133: Event display axis operation Processing unit (program), 134 ... display information selection processing unit (program), 135 ... event display axis content selection processing unit (program), 140 ... fourth various information storage unit, 141 ... Memo input processing unit (program) 142 Memo information storage unit 143 Calculation formula input calculation processing unit (program) 144 Calculation data storage unit 145 Post-calculation data storage unit · · · · · · · · · · · · · · · · · · · · · · · · · · · · Threshold display request display processing unit (program), 147 · · · threshold display request information storage unit, M · · · memo information, 221 · · · · · · oxygen saturation information storage portion, 222 · · · hematocry Information storage unit, 223 ... hemoglobin information storage unit, 225 ... oxygen partial pressure information storage unit, P ... patient, S ... event display axis

Claims

A storage unit for storing at least various information acquired from the medical device;
A display unit for simultaneously displaying information in a specific time range among various information stored in the storage unit on the same screen, and displaying a time specifying unit indicating a specific time on the same screen at the same time; Have
The analyzer displays the various information of the time specified by the time specifying unit together with the information in the specific time range on the display unit.
The analyzer according to claim 1, characterized in that the time identification unit can be moved and / or fixed on the screen.
The analyzer according to claim 1, wherein the time specifying unit is associated with event information generated at a time of the time specifying unit.
The analyzer according to any one of claims 1 to 3, wherein the analyzer is configured to be able to display memo information together with the time specifying unit.
The analyzer according to any one of claims 1 to 4, wherein the various information includes special information to be obtained by special calculation, and includes calculation formula information for generating the special information. .
The analyzer according to claim 5, wherein the calculation formula information is configured to be able to include various information stored in the storage unit in the calculation formula.
The analyzer according to any one of claims 1 to 5, wherein the specific time range displayed on the same screen can be changed.
Equipped with medical equipment,
An analysis system comprising the analyzer according to any one of claims 1 to 7, which can communicate with the medical device.
Storing at least various information acquired from the medical device in the storage unit;
Among various information stored in the storage unit, information in a specific time range is simultaneously displayed on the same screen, and a time specifying unit indicating a specific time is displayed on the same screen on the display unit.
The control method of an analyzer according to claim 1, wherein the various information of the time specified by the time specifying unit is displayed on the display unit together with information in the specific time range.
A storage unit that stores various information acquired from at least a medical device, and an analyzer;
Among various information stored in the storage unit, it functions as a display unit that simultaneously displays information in a specific time range on the same screen, and simultaneously displays a time specifying unit indicating a specific time on the same screen And a control program of an analysis device for causing the display unit to display the various information of the time specified by the time specifying unit together with the information in the specific time range.