JP2020170229A - Server and system - Google Patents

Abstract

To provide a sever and a system including the server, which have good convenience for determining whether or not an appointment schedule between a patient and a medical care person is appropriate.SOLUTION: A server 2 is capable of storing biological information of a patient and work schedule information on a medical care worker. The server 2 generates the condition change data of the patient based on the biological information. The server 2 generates display data indicating a change in the condition of the patient and a medical treatment schedule of the patient based on the condition change data and patient-specific schedule data related to work schedule information.SELECTED DRAWING: Figure 2

Description

The present invention relates to servers and systems.

There is known a medical display device that displays both biological information and medication information on a display unit (see Patent Document 1).

Japanese Unexamined Patent Publication No. 2016-086972

According to the medical display device disclosed in Patent Document 1, the medical care worker can collectively confirm the biological information and the medication information of the patient. Therefore, the medical care worker can grasp the change in the patient's condition from the viewpoint of the biological information and the medication information. However, for example, when the patient's condition is deteriorating, the medical care worker can switch the screen to determine whether or not the frequency of visits between the patient and the medical care worker is appropriate. It is necessary to check the schedule and check the work schedule of the medical care worker using another information terminal or information device.

An object of the present invention is to provide a server and a system having good convenience for determining whether or not a medical care worker has an appropriate medical treatment interval for a patient.

The server according to one aspect of the present invention
A server that can store patient biometric information and medical care worker work schedule information.
The server generates the patient's condition change data based on the biological information, and generates the data.
The server generates display data indicating the patient's condition change and the patient's medical treatment schedule based on the condition change data and the patient-specific schedule data related to the work schedule information. To generate.

According to the server related to the above configuration, it is for displaying the patient's condition change and the patient's medical treatment schedule based on the patient's condition change data and the patient-specific schedule data related to the work schedule information of the medical care worker. Data is generated. Therefore, the information on the change in the patient's condition and the patient's medical treatment schedule information are displayed together on the display screen.
As described above, according to the above configuration, it is possible to provide a server having good convenience for determining whether or not the medical care interval of the medical care worker for the patient is appropriate.

The system according to one aspect of the present invention
Information equipment and
A server that can store patient biometric information and work schedule information for medical care workers,
A communication device that can send medical information to the server,
A measuring device that can measure the patient's biological information,
Is a system that includes
The information device has a display unit and has a display unit.
The measuring device can communicate with the server via the communication device, and can communicate with the server.
The information device can communicate with the server via a network.
The server generates the patient's condition change data based on the biological information, and generates the patient's condition change data.
The server generates display data indicating the patient's condition change and the patient's medical treatment schedule based on the condition change data and the patient-specific schedule data related to the work schedule information.
The display data is displayed on the display unit.

According to the system related to the above configuration, display data indicating the patient's condition change and the patient's schedule based on the patient's condition change data and the patient-specific schedule data related to the work schedule information of the medical care worker. Is generated. Then, the display data is displayed on the display unit of the information device. Therefore, the information on the patient's condition change and the patient's schedule information are displayed together on the display screen.
As described above, according to the above configuration, it is possible to provide a highly convenient system for determining whether or not the medical care worker's medical treatment interval for the patient is appropriate.

According to the present invention, it is possible to provide a server and a system having good convenience for determining whether or not a medical care worker has an appropriate medical treatment interval for a patient.

It is a block diagram of the system which concerns on one Embodiment of this invention. It is a functional block diagram of the information device, the server, and the measurement device which concerns on one Embodiment of this invention. It is a figure regarding the work schedule information of a medical care worker. It is a sequence diagram concerning the operation of the system which concerns on one Embodiment of this invention. It is a figure which shows an example of the display screen displayed on the display part of an information device. It is a figure which shows the standard of the appropriate medical treatment interval. It is a figure which shows an example of the display screen displayed on the display part of an information device. It is a figure which shows an example of the display screen displayed on the display part of an information device. It is a figure which shows an example of the display screen displayed on the display part of an information device.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. For convenience of explanation, the description of the element having the same reference number as the element already described in the description of the present embodiment will be omitted.

(First Embodiment)
FIG. 1 is a configuration diagram of a system 100 according to an embodiment of the present invention (hereinafter, simply referred to as “the present embodiment”). As shown in FIG. 1, the system 100 includes an information device 1, a server 2, a measuring device 3, and a gateway device 4 (an example of a communication device). The information device 1 and the server 2 are communicably connected via the network N. The server 2 and the measuring device 3 are communicably connected to each other via the gateway device 4 and the network N. The network N is a general-purpose Internet network.

FIG. 2 is a functional block diagram of the information device 1, the server 2, and the measuring device 3. As shown in FIG. 2, the information device 1 includes a display unit 11, an operation unit 12, a control unit 13, and a communication interface (communication IF) 14. These are communicably connected to each other via the bus 15. As the information device 1, for example, an electronic device such as a desktop type PC, a notebook PC, a tablet terminal, or a smartphone can be used.

The display unit 11 is a touch screen type display such as a liquid crystal display or an organic EL display, and is configured to display an image (an operation image, an image related to medical information, or the like).

The operation unit 12 is configured to accept an input operation of an operator who operates the information device 1 and generate an instruction signal corresponding to the input operation. The operation unit 12 is, for example, a touch panel arranged on the display unit 11, an operation button attached to the housing of the information device 1, and the like. The operation unit 12 receives an input operation for displaying the patient information screen on the display unit 11, an input operation for switching the display screen, an input operation for giving a predetermined instruction to the server 2, and the like. Generates an instruction signal corresponding to the input operation. The generated instruction signal is transmitted to the control unit 13 via the bus 15. The control unit 13 is configured to control the operation of the information device 1 based on the instruction signal. Further, when the input operation received by the operation unit 12 is an input operation for giving a predetermined instruction to the server 2, the control unit 13 is configured to transmit an instruction signal based on the input operation to the server 2. There is.

The control unit 13 includes a memory and a processor. The memory is composed of, for example, a ROM (Read Only Memory) in which various programs and the like are stored, a RAM (Random Access Memory) having a plurality of work areas in which various programs and the like executed by the processor are stored, and the like. The processor is, for example, a CPU (Central Processing Unit), which is configured to expand a program specified from various programs embedded in the ROM on the RAM and execute various processes in cooperation with the RAM. ..

The communication interface 14 is an interface that enables connection to the network N. The information device 1 can appropriately communicate with the server 2 connected to the network N via the communication interface 14.

As shown in FIG. 2, the server 2 includes a control unit 21 and a communication interface (communication IF) 22. These are communicably connected to each other via the bus 23.

The control unit 21 includes a memory and a processor. The memory is composed of, for example, a ROM (Read Only Memory) in which various programs and the like are stored, a RAM (Random Access Memory) having a plurality of work areas in which various programs and the like executed by the processor are stored, and the like. The processor is, for example, a CPU (Central Processing Unit), which expands a program specified from various programs incorporated in the ROM on the RAM, and in cooperation with the RAM, a storage unit 211, a generation unit 212, etc. It is configured to perform various processes.

The control unit 21 includes a storage unit 211 and a generation unit 212. The storage unit 211 includes patient information, patient biometric information, information about the person who measures the biometric information (measurer information), information about the medical care service that the patient plans to receive (patient's medical care schedule information), and medical care worker's information. It is possible to store work schedule information, information on criteria for appropriate medical treatment intervals, and so on. The patient information includes, for example, information on the age, sex, blood type, chronic disease, pre-existing disease, etc. of the patient. Medical care workers are those who are involved in the medical and long-term care fields such as doctors, nurses, pharmacists, and long-term care workers. The work schedule information of the medical care worker is information on the work date and time and vacation of the medical care worker. The information regarding the criteria for the appropriate medical care interval is information regarding the type of medical care worker and the appropriate medical care interval that match the patient's condition. The medical treatment interval can be set arbitrarily. In addition, the term "patient" in the present specification includes a person who receives medical services or long-term care services. The generation unit 212 generates the condition change data of the patient from the biological information of the patient stored in the storage unit 211. The condition change data includes raw biological information such as changes in blood pressure, body temperature, SpO ₂ (percutaneous arterial oxygen saturation), body weight, and blood glucose level of the patient. Data that are continuously arranged in chronological order, analysis data based on these raw biometric information, and the like.

The generation unit 212 generates patient-specific schedule data of the medical care worker based on the work schedule information of the medical care worker stored in the storage unit 211. The patient-specific schedule data of the medical care worker is data related to the work date and time of the medical care worker, which is generated for each patient. That is, the patient-specific schedule data is data relating to the date and time when the medical care worker conducts an interview or visit to the patient. The patient-specific schedule data may include patient-specific schedule data of a plurality of medical care workers (for example, doctors, nurses, care workers, etc.).

Here, the process in which the generation unit 212 generates the patient-specific schedule data will be described with reference to FIG. FIG. 3 is a diagram relating to work schedule information of medical care workers. In this embodiment, Kotaro is described as a doctor, Ayako Koden is a nurse, and Kumiko Koden is a care worker. Others (Hanako Koden, Jiro Koujiro, Saburo Kotobuki, Shiro Kotobuki, Akiko Koden) will be described as patients.

FIG. 3A is a diagram relating to Kotaro's work schedule information. As shown in FIG. 3A, for example, Kotaro is scheduled to deal with outpatients on July 7, 2018. In addition, Kotaro is scheduled to visit Koujiro from 15:00 to 16:00 on July 8, 2018. In addition, Kotaro will take a vacation on July 11, 2018.

FIG. 3B is a diagram relating to work schedule information of Ayako Photoelectric. As shown in FIG. 3B, Photoelectric Ayako plans to provide home nursing care for Photoelectric Akiko, for example, from 13:00 to 15:00 on July 8, 2018. In addition, Ayako Photoelectric is scheduled to take a vacation on July 12, 2018.

FIG. 3C is a diagram relating to work schedule information of Kumiko Photoelectric. As shown in FIG. 3C, Kumiko Photoelectric is scheduled to provide home care for Hanako Photoelectric, for example, on July 7, 2018. In addition, Kumiko Koden is scheduled to take a vacation on July 10, 2018.

The generation unit 212 combines the work schedule information of each medical care worker (photoelectric Taro, photoelectric Ayako, and photoelectric Kumiko), and then divides the combined work schedule information for each patient. In this way, the generation unit 212 generates patient-specific schedule data based on the work schedule information of each medical care worker.
The generation unit 212 may edit the patient-specific schedule data and reflect the edited result of the patient-specific schedule data in the work schedule information of each medical care worker based on the edited patient-specific schedule data. .. In this case, for example, the medical care worker performs an input operation for causing the operation unit 12 of the information device 1 to have the generation unit 212 of the server 2 edit the schedule data for each patient. The operation unit 12 generates an instruction signal corresponding to the input operation. The instruction signal is transmitted to the server 2 via the control unit 13. When the server 2 receives the instruction signal, the generation unit 212 of the server 2 edits the patient-specific schedule data based on the instruction signal. Then, the generation unit 212 reflects the edited result of the patient-specific schedule data in the work schedule information of the medical care worker based on the edited patient-specific schedule data.

In this way, the work schedule information of the medical care worker and the schedule data for each patient are linked. In this sense, the work schedule information of medical care workers and the schedule data for each patient are related.

Returning to FIG. 2, the generation unit 212 will be described. The generation unit 212 is for displaying the patient condition change and the patient's medical treatment schedule based on the patient condition change data stored in the storage unit 211 and the patient-specific schedule data of each medical care worker. Generate data. At this time, display data is generated for each patient. Therefore, the display data may include a plurality of display data.

In addition, the generation unit 212 determines whether or not the medical treatment interval for the patient is appropriate based on the patient-specific schedule data of the medical care worker stored in the storage unit 211 and the information regarding the standard of the appropriate medical treatment interval. Can be done. When the generation unit 212 determines that the medical treatment interval for the patient is inappropriate, the generation unit 212 generates display data including information indicating that the medical treatment interval for the patient is not appropriate. In addition, the information indicating that the medical treatment interval for the patient is not appropriate includes change candidate data regarding the schedule data for each patient. Further, the display data includes patient-specific schedule data at least after the time when the generation unit 212 generates the display data, and condition change data before the time when the generation unit 212 generates the display data.

The communication interface 22 is an interface that enables connection to the network N. The server 2 can appropriately communicate with the information device 1 connected to the network N and the measuring device 3 connected to the network N via the gateway device 4 via the communication interface 22.

As shown in FIG. 2, the measuring device 3 includes a measuring unit 31, an input operation unit 32, a control unit 33, and a communication interface (communication IF) 34. These are communicably connected to each other via the bus 35. Examples of the measuring device 3 include a sphygmomanometer, a thermometer, a pulse oximeter, a weight scale, a blood glucose meter, and the like.

The measuring unit 31 can measure the biological information of the patient. The patient's biological information includes blood pressure, body temperature, SpO ₂ , body weight, blood glucose level, and the like.

The input operation unit 32 is configured to receive an input operation of an operator who operates the measuring device 3 and to generate an instruction signal corresponding to the input operation. The input operation unit 32 is, for example, a touch panel arranged so as to be superimposed on the display screen of the measurement device 3, an operation button attached to the housing of the measurement device 3, an event switch, or the like. The input operation unit 32 receives, for example, an input operation for starting the acquisition of biometric information, and generates an instruction signal corresponding to the input operation. The generated instruction signal is transmitted to the control unit 33 via the bus 35. The control unit 33 is configured to control the operation of the measuring device 3 based on the instruction signal.

The control unit 33 includes a memory and a processor. The memory is composed of, for example, a ROM (Read Only Memory) in which various programs and the like are stored, a RAM (Random Access Memory) having a plurality of work areas in which various programs and the like executed by the processor are stored, and the like. The processor is, for example, a CPU (Central Processing Unit), which is configured to expand a program specified from various programs embedded in the ROM on the RAM and execute various processes in cooperation with the RAM. ..

The communication interface 34 is an interface that enables connection to the gateway device 4. The measuring device 3 and the gateway device 4 are connected by, for example, communication using Wi-Fi or short-range wireless communication. The measuring device 3 can appropriately communicate with the server 2 connected to the network N via the communication interface 34 and the gateway device 4.

The gateway device 4 is, for example, a router. The gateway device 4 is a communication device that relays biometric information measured by the measuring device 3 between two or more different networks. The measuring device 3 is connected to the network N via the gateway device 4. As a result, the measuring device 3 can communicate with the server 2. The measuring device 3 and the server 2 may directly transmit and receive data without going through the gateway device 4.

The gateway device 4 has a substantially rectangular parallelepiped housing. The width and depth of the gateway device 4 is about 10 cm, and the height is about 4 cm. The gateway device 4 weighs about 120 grams. As described above, the gateway device 4 is small and lightweight.

FIG. 4 is a sequence diagram relating to the operation of the system 100 according to the embodiment of the present invention. The patient's biological information is measured by the measuring device 3 (step S1). For example, the measurement of patient biometric information is performed by a healthcare professional. The patient may measure the patient's biological information by himself / herself. The measured biological information of the patient and the measurer information are transmitted to the gateway device 4 by the control unit 33 of the measuring device 3 (step S2). The gateway device 4 transmits the received biometric information and the measurer information to the server 2 via the network N (step S3). The server 2 stores the received biometric information and the measurer information in the storage unit 211 (step S4).

The generation unit 212 of the server 2 generates condition change data indicating the condition change of the patient based on the biometric information of the patient stored in the storage unit 211 (step S5). The generation unit 212 generates, for example, data in which data relating to the body temperature of the patient are continuously arranged in chronological order. In addition, the generation unit 212 generates, for example, analytical data regarding changes in the patient's condition based on a plurality of biological information of the patient. The condition change data is stored in the storage unit 211 (step S6).

On the other hand, the medical care worker inputs his / her work schedule information via the operation unit 12 of the information device 1 (step S7). When the operation is performed, an instruction signal for transmitting the work schedule information to the server 2 is generated. The generated instruction signal is transmitted to the control unit 13 via the bus 15. The control unit 13 controls the information device 1 so as to transmit the work schedule information to the server 2 based on the instruction signal (step S8). The server 2 saves the received work schedule information in the storage unit 211 (step S9).

The generation unit 212 of the server 2 generates patient-specific schedule data of the medical care worker for each patient based on the work schedule information of the medical care worker stored in the storage unit 211 (step S10). The patient-specific schedule data may include patient-specific schedule data of a plurality of medical care workers. The patient-specific schedule data generated by the generation unit 212 is stored in the storage unit 211.

The generation unit 212 of the server 2 determines the patient's condition change and the patient's medical treatment based on the patient's condition change data stored in the storage unit 211 and the patient-specific schedule data of the medical care worker regarding the patient. Display data indicating the schedule is generated (step S11). The generation unit 212 may generate display data based not only on the patient's condition change and the patient's medical treatment schedule but also on the measurer information. The display data is transmitted from the server 2 to the information device 1 via the network N (step S12).

The control unit 13 of the information device 1 controls the display unit 11 so as to display the display screen based on the received display data (step S13).

Which of steps S1 to S6 and steps S7 to S9 may be executed first.
Further, steps S11 to S13 may be executed based on a display request operation on the information device 1 by the medical care worker.

FIG. 5 is a diagram showing an example of a display screen displayed on the display unit 11 of the information device 1. The image displayed on the display unit 11 includes a first display area 11A and a second display area 11B. The first display area 11A is arranged above the display unit 11. The second display area 11B is arranged below the display unit 11. The patient name is displayed on the upper left side of the first display area 11A and the upper left side of the second display area 11B. In the display screen shown in FIG. 5, the patient's biological information and information on the condition change are displayed in the first display area 11A. The patient's medical treatment schedule is displayed in the second display area 11B. Further, in the present embodiment, July 6, 2018 is set as the present time. The display screen shown in FIG. 5 is based on the display data generated by the generation unit 212 of the server 2 on July 6, 2018.

The first display region 11A, in the July 12, 2018 July 2, 2018, the graph G1 and graph G2 showing a change in the body temperature and SpO ₂ photoelectric Hanako is displayed. In this embodiment, the display screen at the present time (July 6, 2018) is shown. Therefore, the graphs G1 and G2 are graphs generated based on the biological information measured by July 6, 2018.

In the first display area 11A, an item of biometric information of the patient is displayed below the patient name. In this embodiment, body temperature and SpO ₂ are displayed.

Below each item, the scale of each item is displayed. In this embodiment, the body temperature and SpO ₂ scale are displayed. In this embodiment, the body temperature of photoelectric Hanako as of July 2, 2018 is 36.0 ° C. The body temperature of photoelectric Hanako on July 3 and July 4 of the same year was 37.5 ° C. The body temperature of photoelectric Hanako as of July 5, 2018 is 38.5 ° C. The body temperature of photoelectric Hanako as of July 6, 2018 is 39.2 ° C. Similarly, the SpO ₂ of photoelectric Hanako as of July 2, 2018 is 98%. The SpO ₂ of photoelectric Hanako as of July 3, 2018 is 93%. The SpO ₂ of photoelectric Hanako as of July 4, 2018 is 95%. The SpO ₂ of photoelectric Hanako as of July 5, 2018 is 90%. The SpO ₂ of photoelectric Hanako as of July 6, 2018 is 85%.

Graph G1 and graph G2 are displayed on the right side of the portion where the scale of SpO ₂ of photoelectric Hanako is displayed. The points plotted on the graph G1 indicate the body temperature of the photoelectric Hanako on the corresponding day. The points plotted on the graph G1 are circular. The points plotted on the graph G2 indicate SpO ₂ of photoelectric Hanako on the corresponding day. The points plotted on the graph G2 are triangles. Needless to say, the shapes of the points plotted on the graphs G1 and G2 are not limited to circles and triangles. Graphs G1 and G2 are line graphs. Therefore, the medical care worker can know the change in the patient's condition only by looking at the display unit 11 of the information device 1. The graphs G1 and G2 shown in FIG. 5 are line graphs, but are not limited to this example. The graph may be any graph that allows the medical care worker to grasp the change in the patient's condition, and the graphs G1 and G2 may be, for example, a bar graph.

When the patient's biometric information is measured by a healthcare professional, the points on graph G1 and the points on graph G2 are, for example, colored. For example, if the patient's biometric information is measured by a doctor, these points are marked in green. If the patient's biometric information is measured by a nurse, these points are marked in yellow. If the patient's biometric information is measured by a caregiver, these points are marked in blue. In the embodiment shown in FIG. 5, hatching is added instead of the color. The hatch corresponding to green is a diagonal line that slopes from the upper left to the lower right. The hatches corresponding to yellow are horizontal lines. The hatches corresponding to blue are vertical lines. On the other hand, for example, when the patient's biological information is measured by the patient himself, the points on the graph G1 and the points on the graph G1 are not colored.

In the embodiment shown in FIG. 5, the body temperature and SpO ₂ of photoelectric Hanako on July 2, 2018 and July 3, 2018 are measured by Kumiko photoelectric. Therefore, the points on the corresponding graphs G1 and G2 are colored blue. The body temperature and SpO ₂ of photoelectric Hanako on July 4, 2018 and July 5, 2018 are measured by photoelectric Ayako. Therefore, the points on the corresponding graphs G1 and G2 are marked with yellow. Photoelectric Hanako's body temperature and SpO _{2 as} of July 6, 2018 have been measured by Photoelectric Taro. Therefore, the points on the corresponding graphs G1 and G2 are colored in green.

In the second display area 11B, the medical treatment schedule of Photoelectric Hanako from July 2, 2018 to July 12, 2018 is displayed. The name of the same patient as the patient displayed in the first display area 11A is displayed on the upper part of the second display area 11B. In this embodiment, the name of the photoelectric Hanako is displayed. Below the display portion of the patient name, dates of the same period as the period displayed in the first display area 11A are arranged in the left-right direction. In the present embodiment, the dates from July 2, 2018 to July 12, 2018 are displayed in the second display area 11B. The period can be set arbitrarily. Below each date, the patient's medical treatment schedule is displayed so as to extend vertically for each time zone. From July 2, 2018 to July 3, 2018, Koden Hanako is receiving home care service by Koden Kumiko. During the time zone from 13:00 to 15:00 on July 4, 2018 and the time zone from 13:00 to 15:00 on July 5, 2018, Photoelectric Hanako received home nursing service by Photoelectric Ayako. There is. From 10:00 to 11:00 on July 6, 2018, Koden Hanako is receiving a home-visit medical service by Kotaro. In addition, on July 7, 2018, Koden Hanako is scheduled to receive home care service by Koden Kumiko. During the time zone from 10:00 to 12:00 on July 8, 2018 and the time zone from 10:00 to 12:00 on July 9, 2018, Photoelectric Hanako will receive home nursing service by Photoelectric Ayako. Is. From 13:00 to 14:00 on July 10, 2018, Koden Hanako will receive a home-visit medical service by Kotaro. From July 11, 2018 to July 12, 2018, Koden Hanako will receive home care services by Koden Kumiko. In the second display area 11B, the color of the display characters, the background color, and the like may be changed as appropriate so that the type of the medical care worker can be recognized. As described above, the medical treatment schedule of Hanako Koden includes schedules for a plurality of medical care workers (Kumiko Koden, Ayako Koden, Taro Koto). In addition, the screen shown in FIG. 5 shows the medical treatment schedule of photoelectric Hanako before and after the present time (July 6, 2018) and the condition change of photoelectric Hanako before the present time (July 6, 2018). Information indicating that, and is displayed.

FIG. 6 is a diagram showing a standard of an appropriate medical treatment interval. As shown in FIG. 6, when a patient has a slight fever, the person who should deal with the patient is a care worker. In this case, the interval until the next medical examination day is within five days. If the patient has a high fever, the person who should deal with the patient is the nurse. In this case, the interval until the next medical examination day is within three days. If the patient has a high fever for several hours, the person who should deal with the patient is the doctor. In this case, the interval until the next medical examination day is within two days. In general, if a high fever of 38.0 ° C. or higher continues, there is a possibility of suffering from pneumonia.

The process after the step S13 of FIG. 4 has been performed will be described back to FIG. The body temperature of photoelectric Hanako on July 5, 2018 and July 6, 2018 is 38.0 ° C. or higher. Therefore, Photohanako may be suffering from pneumonia. Therefore, within two days (within July 8, 2018) from the present time (July 6, 2018), a doctor (photoelectric Taro in this embodiment) needs to perform medical treatment for photoelectric Hanako. However, the next day for Kotaro to treat Koden Hanako is July 10, 2018. The medical treatment interval from the present time until the day when Kotaro treats Koden Hanako next time is four days. Since the medical treatment interval exceeds the permissible interval shown in FIG. 6, the generation unit 212 determines that the medical treatment interval is inappropriate. In this case, the generation unit 212 attaches red color to the part from 13:00 to 14:00 on July 10, 2018, which is the next scheduled medical treatment date and time of Kotaro, as information indicating that the medical treatment interval for the patient is not appropriate. Generate display data including. Therefore, when the display data is transmitted from the server 2 to the information device 1, as shown in FIG. 7, the display unit 11 of the information device 1 shows information (indicating that the medical treatment interval for the patient is not appropriate). A screen including the red color attached to the portion from 13:00 to 14:00 on July 10, 2018 is displayed. In the embodiment shown in FIG. 7, hatching is added instead of the color. The hatch corresponding to red is a diagonal line that slopes from the upper right to the lower left. As a result, the medical care worker can easily recognize the part where the medical treatment interval is set, which is inappropriate in view of the patient's condition. Needless to say, the method of displaying the part where the medical treatment interval is inappropriate is not limited to coloring. For example, a message indicating that the medical treatment interval is inappropriate in view of the patient's condition or a symbol such as a question mark may be displayed. The medical care worker recognizes that there is a place where the medical treatment interval is inappropriate, and changes the schedule related to the place.

In this way, the medical care worker can quickly respond to changes in the condition of the photoelectric Hanako. In addition, the medical care worker can quickly and easily determine whether or not the frequency of home visits is appropriate. When changing the scheduled date and time of Kotaro's next medical treatment from 13:00 to 14:00 on July 10, 2018 to 13:00 to 14:00 on July 8, 2018 in the medical treatment schedule of Hanako Koden , The medical care worker performs an input operation on the operation unit 12 for changing the patient-specific schedule of the medical care worker. When the input operation is performed, the display screen is changed to that shown in FIG. The changed portion is, for example, light blue. The hatch corresponding to light blue is a grid-like line formed by intersecting vertical lines and horizontal lines.

Further, on the display screen shown in the present embodiment, a patient-specific schedule of a plurality of medical care workers (doctor Kotaro, nurse Koden Ayako, care welfare worker Koden Kumiko) for a certain patient (photohanako) Since it is displayed, it is possible to cooperate between each occupation.

According to the server 2 and the system 100 according to the above configuration, display data indicating the patient's condition change and the patient's medical treatment schedule is generated based on the patient's condition change data and the patient-specific schedule data of the medical care worker. To. Then, the patient's condition change is displayed in the first display area 11A, and the patient's medical treatment schedule is displayed in the second display area 11B at the same time. Therefore, the patient or the medical care worker can view the information on the change in the patient's condition and the patient's medical treatment schedule information together on one display screen. As a result, the medical care worker can provide home-visit medical care to the patient at an appropriate frequency in response to the change in the condition of each patient.

According to the server 2 and the system 100 according to the above configuration, the generation unit 212 of the server 2 can also generate patient-specific schedule data of the medical care worker based on the work schedule information of the medical care worker. Therefore, for example, the medical care worker simply inputs the work schedule information into the information device 1, and the patient-specific schedule data is generated by the generation unit 212.

According to the server 2 and the system 100 according to the above configuration, when the generation unit 212 of the server 2 determines that the medical treatment interval for the patient is not appropriate, the generation unit 212 determines that the medical treatment interval for the patient is not appropriate. Generate display data that includes the information shown. Then, a screen based on the display data is displayed on the display unit 11 of the information device 1. Therefore, the medical care worker can easily visually recognize that there is a place where the medical treatment interval for the patient is not appropriate.

According to the server 2 and the system 100 according to the above configuration, the patient-specific schedules related to a plurality of medical care workers are displayed on the screen displayed on the display unit 11 of the information device 1, so that cooperation between occupations is performed. Can also be planned.

According to the server 2 and the system 100 according to the above configuration, the server 2 is for display including at least the patient-specific schedule data after the time when the display data is generated and the patient's condition change data before the time. Data is generated and transmitted to the information device 1. The display unit 11 of the information device 1 displays the biometric information measured so far of the patient and the future medical examination schedule for the patient. Therefore, the medical care worker can easily grasp the change in the patient's condition and confirm the future medical examination schedule for the patient.

According to the server 2 and the system 100 according to the above configuration, the information indicating the change in the patient's condition is arranged in chronological order on the screen displayed on the display unit 11 of the information device 1. In addition, information indicating changes in the patient's condition is graphed. Therefore, the medical care worker can visually and quickly recognize the change in the patient's condition.

According to the server 2 and the system 100 according to the above configuration, the generation unit 212 of the server 2 generates display data based on the patient condition change data, the patient-specific schedule data, and the measurer information. That is, on the screen displayed on the display unit 11 of the information device 1, information indicating a person who has measured the biological information of the patient is displayed. Therefore, the medical care worker can quickly recognize the person who measured the biological information of the patient.

In the present embodiment, as a medical care method for a patient of a medical care worker, home-visit medical care has been described as an example, but the present invention is not limited to this example. For example, it may be telemedicine using communication technology such as the Internet, or visiting medical care in which a patient goes to a medical care worker.

In addition, the number of days to be displayed may be appropriately changed, or may be displayed on a monthly basis or the like, on the graph relating to the patient's biological information and the change in condition, and the display screen displaying the patient's medical treatment schedule.

(Second Embodiment)
Next, the second embodiment will be described with reference to FIG. The second embodiment is different from the first embodiment in the display data generated by the generation unit 212 of the server 2. More specifically, when the server 2 according to the second embodiment determines that the medical care interval for the medical care worker is inappropriate, the generation unit 212 determines that the patient-specific schedule data of the medical care worker and the patient-specific schedule data. Change candidate data is generated based on the patient's condition change data and information on an appropriate medical treatment interval. The change candidate data is data related to a change proposal (change candidate schedule) of the patient-specific schedule of the medical care worker when the medical treatment interval for the patient is not appropriate. Further, in the second embodiment, the patient-specific schedule change proposal (change candidate schedule) is displayed on the display unit 11 of the information device 1.

When the change candidate data is generated, the change candidate data is stored in the storage unit 211 and transmitted to the information device 1. Then, on the display unit 11 of the information device 1, a change proposal (change candidate schedule) of the patient-specific schedule based on the change candidate data is displayed. In the present embodiment, the part where the inappropriate medical treatment interval is set (the part from 13:00 to 14:00 on July 10, 2018) is colored in red, and as a change candidate schedule, 2018 7 The part from 13:00 to 14:00 on the 8th of the month is colored orange. The hatch corresponding to red is a diagonal line that slopes from the upper right to the lower left. The hatch corresponding to orange is a grid-like line formed by intersecting two diagonal lines. Therefore, the medical care worker can easily recognize that the part marked in red is inappropriate and that the part marked in orange is the change candidate schedule. The number of change candidate schedules displayed on the display unit 11 is not one, but may be multiple.

According to the server 2 and the system 100 according to the above configuration, when the medical care worker's medical treatment interval for the patient is inappropriate, the data is related to the change plan (change candidate schedule) of the medical care worker's schedule for each patient. Candidate data is generated by server 2. Therefore, the medical care worker does not need to manually change his / her work schedule information, and can reduce the occurrence of inappropriate medical treatment intervals.

In the present embodiment, the description has been made using an example of coloring the points plotted on the graph G1 and the graph G2 based on the measurer information, but the present embodiment is not limited to this example. For example, a symbol or icon indicating the person who measured the biological information may be displayed above the plotted points.

In the present embodiment, the first display area 11A and the second display area 11B are arranged side by side in the vertical direction, but the present invention is not limited to this example. The first display area 11A and the second display area 11B may be arranged side by side in the left-right direction, for example. Further, in addition to the measurement information and the work schedule information, information such as medication timing may be displayed as appropriate. Further, only the first display area 11A may be displayed, and the items displayed in the second display area 11B may be displayed in a format (so-called tooltip) that is displayed only when the mouse cursor is placed on the date. It may be displayed in other display formats.

In the present embodiment, the display unit 11 displayed on the information device 1 shows the medical treatment schedule of the patient (photoelectric Hanako) before and after the present time (July 6, 2018) and the condition of the patient before the present time. Information indicating the change and information indicating the change are displayed, but the present invention is not limited to this. For example, only the information indicating the medical treatment schedule of the patient after the present time and the change in the patient's condition before the present time may be displayed on the display unit 11. That is, the medical treatment schedule of the patient before the present time does not have to be displayed on the display unit 11.

The present invention is not limited to the above-described embodiment, and can be freely modified, improved, and the like as appropriate. In addition, the material, shape, size, numerical value, form, number, arrangement location, etc. of each component in the above-described embodiment are arbitrary and are not limited as long as the present invention can be achieved.

1: Information equipment, 2: Server, 3: Measurement equipment, 4: Gateway equipment, N: Network, 100: System

Claims (10)

A server that can store patient biometric information and medical care worker work schedule information.
The server generates the patient's condition change data based on the biological information, and generates the patient's condition change data.
The server is a server that generates display data indicating the patient's condition change and the patient's medical treatment schedule based on the condition change data and patient-specific schedule data related to the work schedule information. The server according to claim 1, wherein the server generates patient-specific schedule data of the medical care worker based on the work schedule information. The server can further store information regarding a medical treatment interval preset for each condition of the patient.
The server determines whether or not the medical treatment interval for the patient is appropriate based on the information regarding the medical treatment interval and the schedule data for each patient.
The server according to claim 1 or 2, wherein when the server determines that the medical treatment interval for the patient is not appropriate, the server generates the display data including information indicating that the medical treatment interval for the patient is not appropriate. The server according to claim 3, wherein the information indicating that the medical treatment interval for the patient is not appropriate includes change candidate data for the patient-specific schedule data. The server according to any one of claims 1 to 4, wherein the patient-specific schedule data includes the patient-specific schedule data for a plurality of the medical care workers. The display data is any one of claims 1 to 5, which includes the patient-specific schedule data at least after the time when the server generates the display data, and the condition change data before the time. The server described in paragraph 1. The server according to any one of claims 1 to 6, wherein the condition change data includes data in which the biometric information is continuously arranged in a time series and analysis data based on the biometric information. The server can further store information about the person measuring the biometric information.
According to any one of claims 1 to 7, the server generates the display data based on the condition change data, the patient-specific schedule data, and the information about the person who measures the biological information. The listed server. Information equipment and
A server that can store patient biometric information and work schedule information for medical care workers,
A communication device that can send medical information to the server,
A measuring device that can measure the patient's biological information,
Is a system that includes
The information device has a display unit and has a display unit.
The measuring device can communicate with the server via the communication device, and can communicate with the server.
The information device can communicate with the server via a network.
The server generates the patient's condition change data based on the biological information, and generates the patient's condition change data.
The server generates display data indicating the patient's condition change and the patient's medical treatment schedule based on the condition change data and the patient-specific schedule data related to the work schedule information.
A system for displaying the display data on the display unit. The server can further store information on a medical treatment interval preset for each patient's condition.
The server determines whether or not the medical treatment interval for the patient is appropriate based on the information regarding the medical treatment interval and the schedule data for each patient.
The system according to claim 9, wherein when the server determines that the medical treatment interval for the patient is not appropriate, information indicating that the medical treatment interval for the patient is not appropriate is displayed on the display unit.

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