阅读说明：本技术 医用信息处理装置以及医用信息处理方法 (Medical information processing apparatus and medical information processing method ) 是由 三森惠太 于 2020-04-02 设计创作，主要内容包括：实施方式的医用信息处理装置具备第一提取部(152)、第二提取部(153)、判断部(154)、以及显示控制部(155)。第一提取部(152)从记载有被检体的诊疗内容的诊疗数据中提取表示所述诊疗内容的第一数据。第二提取部(153)从记载有所述被检体的检查结果的一个或者多个检查数据之中提取包含第二数据的检查数据,该第二数据表示与所述第一数据相关联的所述检查结果。判断部(154)对所述第一数据中包含的项目与所述第二数据中包含的项目进行比较,来判断两项目之间的对应关系。显示控制部(155)使所述诊疗数据与提取出的所述检查数据显示于同一画面,并且使判断为对应关系成立的项目彼此以能够识别的方式加以显示。(A medical information processing device according to an embodiment is provided with a first extraction unit (152), a second extraction unit (153), a determination unit (154), and a display control unit (155). A first extraction unit (152) extracts first data representing medical contents of a subject from medical data in which the medical contents are described. A second extraction unit (153) extracts, from among one or more pieces of examination data in which the examination result of the subject is described, examination data including second data indicating the examination result associated with the first data. A determination unit (154) compares an item contained in the first data with an item contained in the second data, and determines the correspondence between the two items. A display control unit (155) displays the medical data and the extracted examination data on the same screen, and displays items judged that the correspondence relationship is established in a recognizable manner.)

1. A medical information processing device is provided with:

a first extraction unit that extracts first data indicating medical contents of a subject from medical data in which the medical contents are described;

a second extraction unit that extracts, from one or more pieces of examination data on which an examination result of the subject is described, examination data including second data indicating the examination result associated with the first data;

a determination unit that compares an item included in the first data extracted by the first extraction unit with an item included in the second data of the inspection data extracted by the second extraction unit to determine a correspondence relationship between the two items; and

and a display control unit that displays the medical data and the examination data extracted by the second extraction unit on the same screen, and that displays items judged by the judgment unit that the correspondence relationship is established in a manner that the items can be recognized.

2. The medical information processing apparatus according to claim 1,

when the contents of the items included in the first data and the items included in the second data match or are similar to each other, the determination unit determines that the correspondence relationship is established between the items.

3. The medical information processing apparatus according to claim 1,

when there is an independent item whose correspondence relationship is not established between the item included in the first data and the item included in the second data, the determination unit determines that the correspondence relationship of the item is not established,

the display control unit displays the item determined by the determination unit that the correspondence relationship is not established in a recognizable manner.

4. The medical information processing apparatus according to claim 1,

when the content corresponding to the item included in the second data is not included in the first data or when the content corresponding to the item included in the first data is not included in the second data, the determination unit determines that the correspondence relationship between the items is not established,

the display control unit displays the item determined by the determination unit that the correspondence relationship is not established in a recognizable manner.

5. The medical information processing apparatus according to claim 3 or 4,

the display control unit displays a user interface on the screen, the user interface enabling input of a comment regarding an item determined by the determination unit that the correspondence relationship is not established.

6. The medical information processing apparatus according to claim 1,

the display control unit causes an operator for instructing display of the inspection data to be displayed on the screen for each piece of the inspection data extracted by the second extraction unit, and causes the inspection data corresponding to the operator to be displayed on the screen in accordance with an operation performed on the operator.

7. The medical information processing apparatus according to claim 6,

when the inspection data extracted by the second extraction unit includes an item determined by the determination unit that the correspondence relationship is not satisfied, the display control unit adds information indicating that the determined item is not satisfied to the operator corresponding to the inspection data and displays the operator.

8. The medical information processing apparatus according to claim 1,

when the test data is numerical data, the display control unit switches the display mode of the test data according to the patient's condition determined by comparing a measurement value indicated by the test result of the test data with a reference range of the measurement value related to the patient's condition determination of the patient.

9. The medical information processing apparatus according to claim 1,

further comprises a data management unit for executing a process related to the creation of the new medical data,

when the process related to the creation of the medical data is executed by the data management unit, the first extraction unit extracts the first data from the medical data.

10. The medical information processing apparatus according to claim 9,

the data management unit accumulates the number of items determined by the determination unit that the correspondence relationship is not established for each healthcare practitioner who creates the medical data.

11. A medical information processing method comprises the following steps:

extracting first data representing medical contents of a subject from medical data in which the medical contents are recorded;

extracting, from among one or more pieces of examination data on which an examination result of the subject is described, examination data including second data indicating the examination result associated with the first data;

comparing an item included in the first data with an item included in the second data of the extracted inspection data to determine a correspondence between the two items; and

the medical data and the extracted examination data are displayed on the same screen, and items judged to have a correspondence relationship are displayed so as to be recognizable.

Technical Field

Embodiments of the present invention relate to a medical information processing apparatus and a medical information processing method.

Background

Conventionally, medical data used in medical practice includes various types of data such as examination data such as physiological examination data and image data, and medical data such as electronic medical records. A healthcare practitioner such as a doctor comprehensively views the medical data to perform treatment of a subject (for example, a patient). For example, a healthcare practitioner records (records) medical contents performed on a subject in medical data based on the contents of examination data in which examination results are recorded.

Further, the following methods are known: when recording medical contents such as a name of a disease, a healthcare worker can grasp which examination result is based on by registering examination results from which the medical contents are obtained. However, the operation of registering the examination result as a basis is troublesome each time the medical contents are recorded, and convenience is lacking. Further, in the case where the examination result is not registered at the time of recording the medical contents, it is difficult to specify the examination result as the basis.

Prior art documents:

patent documents:

patent document 1: japanese laid-open patent publication No. 2012-155458

Disclosure of Invention

Problems to be solved by the invention

The present invention has been made to solve the problem of being able to easily grasp the correspondence between medical contents described in medical data and examination results based on the medical contents.

Means for solving the problems

A medical information processing device according to an embodiment includes a first extraction unit, a second extraction unit, a determination unit, and a display control unit. A first extraction unit extracts first data indicating medical contents of a subject from medical data in which the medical contents are described. The second extraction unit extracts, from among one or more pieces of inspection data on which an inspection result of the subject is described, inspection data including second data indicating the inspection result associated with the first data. The determination unit compares an item included in the first data extracted by the first extraction unit with an item included in the second data of the inspection data extracted by the second extraction unit, and determines a correspondence relationship between the two items. The display control unit displays the medical data and the examination data extracted by the second extraction unit on the same screen, and displays items judged by the judgment unit that the correspondence relationship is established in a recognizable manner.

Drawings

Fig. 1 is a diagram showing an example of the configuration of a medical information system according to an embodiment.

Fig. 2 is a diagram showing an example of the configuration of the medical information processing apparatus according to the embodiment.

Fig. 3 is a diagram for explaining a method of generating a model according to the first extraction function and the second extraction function in the embodiment.

Fig. 4 is a diagram showing an example of the data configuration of the inspection result DB according to the embodiment.

Fig. 5 is a diagram for explaining an example of the operation of the first extraction function and the second extraction function in the embodiment.

Fig. 6 is a diagram showing an example of a screen displayed by the display control function of the embodiment.

Fig. 7 is a diagram showing an example of a screen displayed by the display control function of the embodiment.

Fig. 8 is a diagram showing an example of a screen displayed by the display control function of the embodiment.

Fig. 9 is a diagram showing an example of a screen displayed by the display control function of the embodiment.

Fig. 10 is a diagram showing an example of a screen displayed by the display control function of the embodiment.

Fig. 11 is a diagram showing an example of a screen displayed by the display control function of the embodiment.

Fig. 12 is a flowchart showing an example of processing executed by the medical information processing apparatus according to the embodiment.

Fig. 13 is a diagram showing an example of a screen displayed by the display control function according to modification 3 of the embodiment.

Fig. 14 is a diagram showing an example of a screen displayed by the display control function according to modification 3 of the embodiment.

Fig. 15 is a diagram showing an example of a screen displayed by the display control function according to modification 3 of the embodiment.

Detailed Description

Hereinafter, embodiments of a medical information processing apparatus and a medical information processing method will be described with reference to the drawings.

Fig. 1 is a diagram showing an example of the configuration of the medical information system according to the present embodiment. As shown in fig. 1, the medical information system 1 includes a medical information processing apparatus 100, a specimen examination system 200, a radiation department system 300, an integrated data server 400, and the like. The medical information processing apparatus 100, the specimen examination system 200, the radiation department system 300, and the integrated data server 400 are communicably connected via a Network N1 such as a LAN (Local Area Network). The number of medical information processing apparatuses 100 connected to the network N1 is not particularly limited.

The medical information processing apparatus 100 is prepared for each medical practitioner such as a doctor or a department, for example, and is used for various purposes. For example, the medical information processing apparatus 100 is used for displaying various kinds of medical data of a subject such as a patient. The medical information processing apparatus 100 is used for creating medical data relating to medical contents performed on a subject such as a patient. The medical data created (generated) in the medical information processing apparatus 100 is transmitted to the integrated data server 400. For example, the medical information processing apparatus 100 is implemented by a computer device such as a workstation, a personal computer, or a tablet terminal.

The sample testing system 200 generates sample test data relating to a sample test performed on a subject, and stores the sample test data in a storage circuit in the sample testing system 200. Also, the sample inspection system 200 transmits the sample inspection data stored in the storage circuit to the integrated data server 400.

The radiation department system 300 stores image data obtained by imaging a subject in a storage circuit in the radiation department system 300. The radiation department system 300 generates report data and conference data relating to a physiological examination or an image examination performed on a subject, and stores the report data and the conference data in a storage circuit in the system. For example, the radiation department system 300 includes a PACS (Picture Archiving and Communication Systems) and the like. The image examination includes an examination using a CT image captured by an X-ray CT (Computed Tomography) apparatus, an examination using an MR image captured by an MRI (Magnetic Resonance Imaging) apparatus, an examination using an ultrasonic image captured by an ultrasonic diagnostic apparatus, an examination using an X-ray image captured by an X-ray diagnostic apparatus, and the like. The radiation department system 300 then transmits the image data, report data, and conference data stored in the storage circuit to the integrated data server 400.

The integrated data server 400 is realized by a computer device such as a workstation or a server device, which includes a processing circuit such as a processor; semiconductor Memory devices such as RAM (Random Access Memory) and flash Memory; and a storage circuit implemented by a hard disk, an optical disk, or the like.

The integrated data server 400 collects various data from the medical information processing device 100, the specimen inspection system 200, the radiation department system 300, and the like, and stores the data in a storage circuit in the server. Specifically, the storage circuit of the integrated Data server 400 holds an integrated DB (Data Base: database) 410 for storing and managing various Data acquired from the medical information processing apparatus 100, the specimen examination system 200, the radiation department system 300, and the like.

For example, the integrated DB410 includes clinical data, sample examination data, physiological examination data, image data, report data, conference data, and the like. The medical data is medical data such as an electronic medical record related to medical contents of the subject acquired from the medical information processing apparatus 100. The specimen inspection data is inspection data relating to a specimen inspection acquired from the specimen inspection system 200. The physiological examination data is examination data related to a vital sign acquired from the radiation department system 300. The image data, the report data, and the conference data are examination data related to an image examination acquired from the radiation department system 300. Hereinafter, the clinical data, the specimen examination data, the physiological examination data, the image data, the report data, and the clinical data are also collectively referred to as "medical data".

The medical data stored in the integrated DB410 includes information such as medical contents, information indicating date and time of preparation, information (patient ID) identifying a subject, information (healthcare provider ID) identifying a preparation provider (healthcare provider), and the like. The examination data includes information indicating the date and time of creation and the patient ID, information such as a numerical value (measurement value) obtained by the examination, an image, and an interpretation report, information indicating the date and time of examination, a healthcare practitioner ID of a healthcare practitioner who is responsible for the examination, and the like.

The integrated data server 400 may be configured to collect not only medical data stored in each system such as the medical information processing apparatus 100, the specimen testing system 200, and the radiation department system 300, but also medical data obtained from each system directly. The integrated data server 400 may be configured to collect medical data distributed in the medical information processing apparatus 100, the specimen inspection system 200, and the radiation department system 300 or outside these systems.

In the configuration of the medical information system 1 described above, the medical information processing apparatus 100 can display medical data managed by the integrated data server 400. For example, a medical practitioner (hereinafter, also referred to as a user) who operates the medical information processing apparatus 100 can acquire and display examination data of a subject or previously-generated clinical data from the integrated data server 400 for the purpose of clinical data generation, diagnosis of the subject, or the like. The following describes the structure of the medical information processing apparatus 100.

Fig. 2 is a diagram showing an example of the configuration of the medical information processing apparatus 100. As shown in fig. 2. The medical information processing apparatus 100 includes a communication interface 110, a storage circuit 120, an input interface 130, a display 140, and a processing circuit 150.

The communication interface 110 is connected to the processing circuit 150, and controls transmission and communication of various data between the medical information processing apparatus 100 and each system. Specifically, the communication interface 110 receives medical data from each system and outputs the received medical data to the processing circuit 150. For example, the communication Interface 110 is implemented by a Network card, a Network adapter, an NIC (Network Interface Controller), or the like.

The memory circuit 120 is connected to the processing circuit 150, and stores various data. Specifically, the storage circuit 120 stores medical data received from each system. Further, the storage circuit 120 stores a condition setting table and the like. For example, the Memory circuit 120 is implemented by a semiconductor Memory device such as a RAM (Random Access Memory), a flash Memory, a hard disk, an optical disk, or the like. The memory circuit 120 is an example of an implementation of the memory unit.

The input interface 130 is connected to the processing circuit 150, and receives various instructions and input operations of various information from an operator. Specifically, the input interface 130 converts an input operation received from an operator into an electric signal and outputs the electric signal to the processing circuit 150. For example, the input interface 130 is implemented by a trackball, a switch button, a mouse, a keyboard, a touch panel that performs an input operation by touching an operation surface, a touch panel in which a display screen and the touch panel are integrated, a non-contact input circuit using an optical sensor, a voice input circuit, and the like. The input interface 130 is not limited to physical operation members such as a mouse and a keyboard. For example, a processing circuit that receives an electric signal corresponding to an input operation from an external input device provided independently of the apparatus and outputs the electric signal to the control circuit is also included in the input interface 130.

The display 140 is connected to the processing circuit 150, and displays various information and various images. Specifically, the display 140 converts various information and various image data sent from the processing circuit 150 into electric signals for display and outputs the electric signals. For example, the display 140 is implemented by a liquid crystal monitor, a CRT (Cathode Ray Tube) monitor, a touch panel, or the like.

The processing circuit 150 controls the components of the medical information processing apparatus 100 in accordance with an input operation received from the operator via the input interface 130. Specifically, the processing circuit 150 stores the medical data output from the communication interface 110 in the storage circuit 120. The processing circuit 150 reads the medical data from the memory circuit 120 and displays the medical data on the display 140. For example, the processing circuit 150 is implemented by a processor.

The medical information processing apparatus 100 also has a function of assisting medical practitioners in association with a procedure of creating medical data, a procedure of confirming medical contents described in the medical data, and the like. Specifically, the medical information processing apparatus 100 has a data management function 151, a first extraction function 152, a second extraction function 153, a determination function 154, and a display control function 155. The data management function 151 is an example of a data generation unit. The data management function 151 is an example of a data management unit. The first extraction function 152 is an example of the first extraction unit. The second extraction function 153 is an example of the second extraction unit. The determination function 154 is an example of the determination section. The display control function 155 is an example of a display control unit.

The data management function 151 executes various processes related to management of medical data. For example, the data management function 151 cooperates with the display control function 155 to execute a process related to creation of new medical data. Specifically, when medical contents are input (described) via the input interface 130 or the like, the data management function 151 generates medical data in which the input medical contents are recorded, and stores the medical data in the storage circuit 120. When the data management function 151 is instructed to complete the medical data, the medical data stored in the storage circuit 120 is transmitted to the integrated data server 400.

Here, the method of inputting medical contents is not particularly limited. For example, the medical contents may be inputted by using a description method such as SOAP format. In this SOAP format, medical contents are input for each symptom of a Subject in a manner of S (Subject: subjective information), O (objective information), a (Assessment), and P (Plan).

When medical data or a specific item included in the medical data is input, such as a comment, the data management function 151 executes processing for storing the input content. Specifically, the data management function 151 stores comment data in which input content is recorded in association with medical data and items to be input.

The first extraction function 152 extracts first data indicating medical contents from medical data in which medical contents of a subject are described. Further, the second extraction function 153 extracts, from among examination data (sample examination data, physiological examination data, image data, report data, conference data) in which an examination result of the subject is recorded, examination data including second data indicating the examination result associated with the first data.

Here, the method of implementing the first extraction function 152 and the second extraction function 153 is not particularly limited, and various methods can be employed. In the present embodiment, a method of using a model such as a machine learning model will be described as a method of implementing the first extraction function 152 and the second extraction function 153.

First, a method of generating models by the first extraction function 152 and the second extraction function 153 will be described with reference to fig. 3. Fig. 3 is a diagram for explaining a method of generating a model by the first extraction function 152 and the second extraction function 153.

First, a model (hereinafter, referred to as a first model) M1 of the first extraction function 152 is generated from past clinical data of a plurality of subjects stored in the integrated DB410 of the integrated data server 400. Specifically, the first model M1 capable of outputting first data representing medical treatment content is generated by analyzing (machine learning) the relationship of character strings representing the medical treatment content represented by the medical treatment data on a lexical level and a contextual level, with each of the medical treatment data stored in the integration DB410 being input. Here, the first data output from the first model M1 is generated in a form that can be compared with the inspection result (second data described later) of the inspection data. For example, the first data is composed of items such as a vocabulary group, a character string, and the like, which can be compared with the second data.

For example, a technique such as Word2Vec or Doc2Vec can be used to analyze the medical contents. When this technique is used, the first data is output as vector data obtained by vectorizing a character string representing the medical contents on a vocabulary level or a context level. Further, by using a rule engine or the like that recognizes the SOAP format, the first model M1 may be generated for each item, with any one of the four SOAP categories being an analysis target. Fig. 3 shows an example in which the first model M1 (first model M1a, first model M1b) is generated for each category, with the categories O and a as analysis targets.

Further, a model (hereinafter, referred to as a second model) M2 of the second extraction function 153 is generated from past examination data of a plurality of subjects stored in the integration DB 410. Specifically, the second model M2 capable of outputting the second data representing the inspection result is generated by analyzing (machine learning) the relationship of character strings representing the inspection result expressed by the inspection data at the vocabulary level and the context level, using the respective inspection data as input. Here, the second data output from the second model M2 is generated in a form that can be compared with the clinical result (first data) of the clinical data. For example, the second data is constituted by items such as vocabulary groups, character strings, and the like, which can be compared with the first data.

For example, similar to the analysis of medical contents, the analysis of the examination result can use a technique such as Word2Vec or Doc2 Vec. When this technique is used, the second data is output as vector data obtained by vectorizing a character string indicating the inspection result in a vocabulary level and a context level. Further, a specific inspection result or the like may be set as an analysis target by using a rule engine or the like that recognizes the format of the inspection data.

In addition, as for the second model M2, one second model M2 may be generated from different types of inspection data, or the second model M2 may be generated for each type of inspection data. An example of generating the second model M2a from physiological examination data and the second model M2b from report data and meeting data is shown in fig. 3.

In addition, when the inspection data is image data, the second model M2 that outputs the feature as second data may be generated by analyzing (machine learning) the feature expressed by the image. When the examination result is expressed by a measurement value such as a vital sign, it is preferable to generate the second model M2 that can be output in a form that also takes into account the time-series rate of change of the value.

In the medical information system 1, the examination result DB420 generated using the second model M2 is prepared as a data set relating to the operation of the second extraction function 153. The inspection result DB420 correspondingly holds the second data obtained by inputting the inspection data to the second model M2, for each inspection data stored in the unified DB 410.

Fig. 4 is a diagram showing an example of the data structure of the inspection result DB 420. As shown in fig. 4, the examination result DB420 stores the patient ID of the subject of the examination data D2, the second data obtained by inputting the examination data D2 into the second model M2, and the examination result ID identifying the examination data D2 in correspondence.

The first model M1 and the second model M2 are models generated in advance, but the device for generating the models is not particularly limited. For example, the first model M1 and the second model M2 may be generated by the integrated data server 400 or may be generated by a dedicated device for model generation. The first model M1, the second model M2, and the examination result DB420 may be held by the storage circuit 120 or the like of each medical information processing apparatus 100, or may be held by another apparatus such as the integrated data server 400. In the latter case, the first extraction function 152 and the second extraction function 153 execute extraction processing using the first model M1 and the inspection result DB420 held by other devices such as the integrated data server 400.

Next, the operation of the first extraction function 152 and the second extraction function 153 using the first model M1 and the inspection result DB420 will be described with reference to fig. 5. Here, fig. 5 is a diagram for explaining an example of the operation of the first extraction function 152 and the second extraction function 153.

For example, when confirmation (Check) of the description contents or the like is instructed by the user with respect to the clinical data D1 of the newly created subject, the first extraction function 152 inputs the clinical data D1 into the first model M1. The first extraction function 152 extracts (acquires) the output result of the first model M1 as first data D1a indicating the medical contents described in the medical data D1. Fig. 5 shows an example of extracting the first data D1a and D1b by using the first models M1a and M1b, which are generated by using O and a classes among SOAP classes constituting the clinical data D1 as the first models M1a and M1 b.

On the other hand, the second extraction function 153 refers to the examination result DB420 and specifies examination data (examination result ID) of the subject, which includes second data associated with the first data D1a and D1b extracted by the first extraction function 152. Specifically, the second extraction function 153 refers to the examination result DB420 and screens data items including the patient ID of the subject of the clinical data D1. Next, the second extraction function 153 compares the first data D1a and D1b extracted by the first extraction function 152 with the second data included in the screened data entries, and determines the inspection result ID of the data entries including the second data associated with the first data D1a and D1b, respectively. Further, the second extraction function 153 extracts the inspection data corresponding to the determined inspection result ID from the integrated DB 410.

In addition, the correlation degree between the first data D1a, D1b and the second data can be calculated using a well-known technique. For example, when the first data D1a, D1b and the second data are both represented by vector data, the degree of correlation between the two data can be determined based on the angle formed by the two vectors. Here, the degree of correlation is an index indicating the correspondence relationship between the first data and the second data or the strength of the correlation relationship, and means that the higher the degree of correlation is, the more common description contents or similar description contents are included. That is, the second extraction function 153 specifies the second data having a higher correlation by using a threshold or the like, thereby specifying the examination data in which the examination result based on the medical contents described in the medical data D1 is described. The second extraction function 153 associates and holds the identified examination result ID with a case ID for identifying the medical data D1 to be processed. In addition, when there are a plurality of second data having the correlation degree exceeding the threshold value, the second extraction function 153 may determine one second data having the maximum correlation degree, or may determine all the second data.

In this way, the first extraction function 152 extracts first data indicating clinical contents from clinical data of a subject to be processed by using the first model M1. The second extraction function 153 extracts examination data including second data indicating an examination result associated with the first data extracted by the first extraction function 152, that is, examination data including an examination result that is a basis of medical contents.

Returning to fig. 2, the determination function 154 compares the items included in the first data extracted by the first extraction function 152 with the items included in the second data of the inspection data specified by the second extraction function 153 to determine the correspondence between the two items. Here, the term included in the first data and the second data means, for example, a character string (including a numeric value) indicating the diagnosis and treatment contents and the examination result, which are distinguished in a lexical level or a contextual level.

Specifically, when there is an item having a string match or an item having similar contents to which a string means between an item included in the first data and an item included in the second data, determination function 154 determines that a correspondence relationship is established between the two items. When there is an independent item whose correspondence relationship is not established between the item included in the first data and the item included in the second data, determination function 154 determines that the correspondence relationship of the item is not established.

For example, when the content corresponding to the item included in the second data is not included in the first data, the determination function 154 determines that the correspondence relationship of the item is not established. In this case, the term means that the examination result of the item determined that the correspondence relationship is not satisfied is not reflected in the medical contents of the medical data. For example, when the content corresponding to the item included in the first data is not included in the second data, the determination function 154 determines that the correspondence relationship between the items is not established. In this case, the term means that the medical contents of the items determined that the correspondence relationship is not established are not based on the examination result of the examination data. The determination function 154 may be configured to determine the correspondence relationship for all items included in the first data and the second data, or may be configured to determine the correspondence relationship for items such as character strings and words in a predetermined format.

The display control function 155 displays various screens for assisting the healthcare practitioner on the display 140 in cooperation with the data management function 151, the first extraction function 152, the second extraction function 153, and the determination function 154 described above.

Fig. 6 is a diagram showing an example of a screen displayed by display control function 155. As shown in fig. 6, the screen G1 has a timeline display area G11, a data display area G12.

In the timeline display area G11, the medical actions performed on the subject are displayed in chronological order as events. The event means an acquisition event (sample test) of a sample test performed by the sample test system 200, an acquisition event (physiological test) of physiological test data performed by the radiation department system 300, an acquisition event (image test, report, meeting) based on image data, report data, and meeting data of the radiation department system 300, an acquisition event (case) based on clinical data of the medical information processing apparatus 100, and the like. For example, the display control function 155 arranges and displays a graph representing the content of an event representing a clinical action performed on a patient in chronological order.

When an operation for specifying an event displayed in the timeline display area G11 is received via the input interface 130 or the like, the display control function 155 refers to the integrated data server 400 and acquires medical data corresponding to the specified event. When an operation for specifying a certain time or period of the display periods displayed in the time line display area G11 is received, the display control function 155 refers to the integrated data server 400 and acquires medical data corresponding to an event performed at the specified time or period. Then, the display control function 155 causes the acquired medical data to be displayed in the data display area G12.

For example, when the medical data is image data, the display control function 155 causes the content of the image data to be displayed in the data display area G12. For example, when the medical data is sample examination data, physiological examination data, or the like, the display control function 155 causes the data display area G12 to display a measurement value at a specified time, each measurement value obtained during a specified period, a graph indicating a time-series change of the measurement values, or the like.

Here, each piece of medical data is displayed in a small area (hereinafter referred to as a panel) smaller than the data display area G12 in the data display area G12. As a result, in the data display area G12, a plurality of pieces of medical data can be displayed on the same screen.

The size of the panel is not particularly limited. For example, the size of the panel may be a fixed value determined for each data type of medical data, or may dynamically change depending on the number of medical data to be displayed. The number of panels that can be displayed in the data display area G12 is not particularly limited, and may be a fixed value or may be dynamically increased or decreased according to the number of medical data displayed, for example. The layout of the panel is not particularly limited, and may be a fixed layout or may dynamically change depending on the number of medical data to be displayed.

In addition, the display control function 155 causes the data display area G12 to display a panel for creating new medical data in cooperation with the data management function 151. Specifically, when generation of new medical treatment data is instructed via the input interface 130 or the like, the display control function 155 causes a panel, into which medical treatment contents can be input, to be displayed in the data display area G12.

Fig. 7 is a diagram showing an example of a screen displayed by the display control function 155, and shows an example in which a panel P11 of newly created clinical data is displayed in the data display area G12. Here, characters can be input to the panel P11 via the input interface 130 or the like. The user of the medical information processing apparatus 100 operates the input interface 130 and the like to input the medical contents to be performed on the subject to the panel P11. Fig. 6 shows an example in which medical contents of a subject are inputted in the form of SOAP.

After the medical contents are input to the panel P11, when an instruction such as confirmation of the description contents or completion of creation is received via the input interface 130 or the like, the data management function 151 stores the contents input to the panel P11 in the storage circuit 120 as new medical data. For example, when new medical data is stored in the storage circuit 120, the first extraction function 152 extracts first data from the medical data. In addition, the second extraction function 153 and the determination function 154 operate in association with the extraction of the first data.

The display control function 155 displays the medical data extracted by the first extraction function 152 as the first data and the examination data extracted by the second extraction function 153 on the same screen. Specifically, the display control function 155 displays the examination data extracted by the second extraction function 153 in the data display region G12 in which the new medical data (panel P11) is displayed. The display control function 155 causes the items determined by the determination function 154 to be in correspondence relationship to be displayed in a recognizable manner. Then, the display control function 155 displays the item determined by the determination function 154 that the correspondence relationship is not established so as to be recognizable.

Fig. 8 is a diagram showing an example of a screen displayed by the display control function 155, and shows a state in which the inspection data extracted by the second extraction function 153 is displayed in the data display area G12 of fig. 7. In fig. 8, the display control function 155 displays the inspection data extracted by the second extraction function 153 as a panel P2 in the data display area G12 together with the panel P11. In other words, the display control function 155 displays the clinical data and the examination data representing the examination result based on the clinical data on the same screen.

The display control function 155 causes the item a1 in the panel P11 and the item a 1' in the panel P2 determined by the determination function 154 that the correspondence relationship is established to be displayed in a recognizable state. For example, the display control function 155 displays the items having the correspondence relationship so as to be recognizable by surrounding them with a frame line of the same color or line type. Thus, the user of the medical information processing apparatus 100 can easily grasp where the examination result, which is the basis of the medical content, exists in the examination data by checking the medical data and the examination data displayed so as to be recognizable.

Note that the item a2 in the panel P2 is an item that is present in the second data but not present in the first data and is determined that the correspondence relationship is not established. Therefore, the display control function 155 causes the corresponding item a2 to be displayed in a recognizable manner. Specifically, the display control function 155 highlights the item a2 in a recognizable manner by adding a mark MK1 to the item a2 and displaying the item a. The item a2 is highlighted by attaching a marker MK1 to the item a 2. This allows the user of the medical information processing apparatus 100 to easily grasp items that are not reflected in the clinical data, among the items described in the examination data.

In fig. 8, display control function 155 displays, in the event displayed in timeline display area G11, an event corresponding to inspection data including an item determined that the correspondence relationship is not established, so as to be recognizable. Specifically, the display control function 155 displays the event corresponding to the inspection data displayed on the panel P2 with the mark MK2 added thereto, thereby highlighting the event in a recognizable manner. Thus, the user of the medical information processing apparatus 100 can easily grasp to which event the examination data determined that the correspondence relationship is not established relates, among the events displayed in the timeline display area G11.

Note that, although the display example in the case where the content corresponding to the item included in the second data is not included in the first data is described in fig. 8, the display is similarly controlled even in the case where the content corresponding to the item included in the first data is not included in the second data. Specifically, when the content corresponding to the item included in the first data is not included in the second data, the display control function 155 displays the corresponding item included in the first data so as to be recognizable by highlighting the item or the like.

Further, the display control function 155 causes a user interface, which enables input of a comment regarding the item or medical data determined to have no correspondence relationship, to be displayed in the data display area G12 in accordance with an operation or the like performed via the input interface 130. The operation method for instructing the comment input is not particularly limited, but for example, the marker MK1 may be made to function as an operator for inputting a comment related to the item a 2. In this case, when an operation for the marker MK1 is received, the display control function 155 causes the data display region G12 to display an input region W1 in which a comment related to the item a2 can be input, as shown in fig. 9.

Fig. 9 is a diagram showing an example of a screen displayed by display control function 155, and shows an example of a screen in a case where mark MK1 in fig. 8 is operated. In fig. 9, characters can be input to the input area W1 via the input interface 130 or the like. The user of the medical information processing apparatus 100 can input a comment related to the item a2 or the like into the input area W1 by operating the input interface 130 or the like.

The content input to the input area W1 is not particularly limited, and any content can be input. For example, a content (hereinafter, referred to as a reason for not adopting) describing that the examination result related to the item a2 is not described in the medical content may be input as the comment related to the item a 2. For example, a content requesting execution of an inspection corresponding to the inspection result of the item a2 (hereinafter referred to as an inspection request) may be input as a comment on the item a 2. The comment inputted into the input area W1 is stored as comment data in association with the item a2 and the medical data including the item a2 by the data management function 151, for example. For example, the content of the comment data requested for the examination is confirmed by a person in charge of the system that is the source of the examination data, and the examination of the subject is performed.

Further, the display control function 155 may display the dedicated input area W1 for each purpose of the comment. For example, when an operation is accepted for marker MK1, display control function 155 displays a selection means that can select a purpose that does not cause adoption or request for examination, and displays an input region corresponding to the selected purpose. In this case, the data management function 151 may switch the method of managing the comment data according to the selected purpose. For example, when comment information of an examination request is input, comment data may be transmitted to a system that performs examination data to which the marker MK1 is added or an examination related to a project.

Note that, although the configuration in which a comment can be input to the examination data is described in fig. 9, the present invention is not limited to this, and a configuration in which a comment can also be input to the medical data is also possible. For example, when a predetermined operation is performed on the medical data displayed in the data display area G12, the display control function 155 displays the input area W2 in association with the medical data, as shown in fig. 10.

Fig. 10 is a diagram showing an example of a screen displayed by display control function 155, and shows an example of a screen in a case where comment input is instructed to panel P11 of fig. 8. When a predetermined operation is received for panel P11, display control function 155 causes input region W2 to be displayed in association with panel P11. The input area W2 can input characters via the input interface 130 and the like, as in the input area W1. The user of the medical information processing apparatus 100 can input comments related to the item a2, the medical data, and the like to the input area W1 by operating the input interface 130 and the like.

For example, a content (reason not adopted) explaining that the clinical content related to the item a2 is not reflected in the clinical data may be input as a comment related to the item a2 and the clinical data. The comment inputted to the input area W2 is stored as comment data in association with, for example, clinical data by the data management function 151. In addition, the medical contents of the medical data can be edited before the completion of the preparation of the medical data is instructed.

The number of pieces of medical data displayed in the data display area G12 is not limited to one, and may be plural. For example, when there are a plurality of medical data during the production, the display control function 155 may display the plurality of medical data in the data display area G12. For example, the display control function 155 may display the past medical data specified from the timeline display area G11 in the data display area G12 together with the medical data being created. The past medical data may be excluded from the processing targets of the first extraction function 152, the second extraction function 153, and the determination function 154, or may be processed in the same manner as newly created medical data.

Fig. 11 is a diagram showing an example of a screen displayed by the display control function 155, and shows an example of a screen in a case where a plurality of medical data are displayed. Here, the medical data at different times are displayed on the panels P11, P12, P13, and P14 on the left side of the data display area G12. Further, the examination data extracted by the second extraction function 153 based on the clinical data of the panels P11, P12, P13, and P14 is displayed on the panels P2 and P3 on the right side of the data display area G12. The contents of the panel P11 and the panel P2 are the same as those of fig. 8.

In fig. 11, the contents of three examination data (sample examinations) associated with the clinical contents of the clinical data of panels P12 to P14 are displayed on panel P3. Specifically, the item A3' displayed on the panel P3 corresponds to the item A3 included in the clinical data of the panel P12. The item a 4' shown in the panel P3 corresponds to the item a4 included in the medical data of the panel P13. The item a 5' shown in the panel P3 corresponds to the item a5 included in the medical data of the panel P14. Here, the display control function 155 displays two items for which the correspondence relationship is established, in a manner that can be recognized, as in fig. 7.

In fig. 10, the examination data associated with the clinical data of panels P12 to P14 indicates the same kind of examination result (sample examination, blood examination), and therefore, the examination data is displayed on the same panel, but the display method is not limited to this. For example, the inspection data may be displayed on the same panel in a display form such as a graph form. In addition, for example, panel display may be performed individually for each inspection data.

For example, when the inspection data is numerical data such as a measurement value, the display control function 155 may switch the display mode of the inspection data depending on where the measurement value indicated by the inspection result of the inspection data belongs to the reference range of the measurement value. Here, the reference range is an index for determining the state of a disease (or state) of the subject, such as the determination of normality or abnormality, the determination of severity, or the like, and is set in advance for each test type or measurement value.

For example, the display control function 155 determines the severity, which is an example of the disease state of the subject, by comparing the reference range of the measurement values with the measurement values indicated by the examination result of the examination data, and changes the display mode of the examination data according to the determined severity. Here, the method of changing the display mode is not particularly limited, and various methods can be employed. For example, the display control function 155 may switch the display color of the test data or the panel color according to the state of the subject such as the severity. For example, the display control function 155 may display an icon or a message indicating the state of the subject in association with the examination data. Thus, the user of the medical information processing apparatus 100 can easily grasp what state the subject is in by looking at the examination data displayed in the data display area G12.

Next, an operation example of the medical information processing apparatus 100 will be described with reference to fig. 12. Fig. 12 is a flowchart showing an example of processing executed by the medical information processing apparatus 100. As a premise of the present processing, after the patient ID of the subject is input, the screen shown in fig. 6 is displayed on the display 140 (step S11). In this process, an operation example in the case of newly creating clinical data will be described.

The display control function 155 waits until generation of new medical data is instructed (step S12; no). Upon receiving an instruction to create new medical data (step S12; yes), the display control function 155 cooperates with the data management function 151 to cause an area (panel) in which medical contents can be input to be displayed in the data display area G12 (step S13). Further, the user of the medical information processing apparatus 100 can display desired medical data in the data display area G12 via the timeline display area G11 even before the user instructs creation of medical data.

Next, when a Check (Check) instruction of the newly input medical contents is received via the input interface 130 or the like (step S14; yes), the data management function 151 stores the input medical contents as new medical data in the storage circuit 120. In addition, in the case where confirmation is not instructed (step S14; NO), the process proceeds to step S25.

When new medical data is stored in the storage circuit 120, the first extraction function 152 extracts first data indicating medical contents from the medical data (step S15). Further, the second extraction function 153 extracts clinical data including second data indicating examination contents associated with the first data extracted in step S15, from among the clinical data of the subject managed by the integrated data server 400 (step S16). Next, the judgment function 154 judges the correspondence between the items by comparing the items included in the first data with the items included in the second data (step S17).

The display control function 155 causes the inspection data to be displayed in the data display region G12 based on the processing results of steps S15 to S17. Specifically, the display control function 155 causes the data display area G12 to display the newly created clinical data and the examination data extracted by the second extraction function 153 (step S18). Further, the display control function 155 causes the items determined in step S17 that the correspondence relationship is established to be displayed so as to be recognizable (step S19).

Next, the display control function 155 determines whether or not there is an item whose correspondence relationship is determined to be not satisfied in the determination processing in step S17 (step S20). If there is an item determined that the correspondence relationship is not established (step S20; yes), the display control function 155 emphatically displays the item determined to be not established (step S21), and the process proceeds to step S22. If there is no item for which the correspondence relationship is determined not to be established (step S20; no), the process proceeds to step S25.

Next, the display control function 155 determines whether or not a comment input is instructed via the input interface 130 or the like (step S22). When an instruction for comment input is received (step S22; yes), display control function 155 causes the area for comment input to be displayed in data display area G12 (step S23). When the instruction to complete the comment input is received, the data management function 151 stores the content input to the input area as comment data (step S24), and the process proceeds to step S25. If no comment input instruction is given (step S22; no), the process immediately proceeds to step S25.

Next, the data management function 151 determines whether the user has instructed completion of medical data creation (step S25). If the completion of the production is not instructed (step S25; no), the data management function 151 returns the process to step S15 to continue the production of the medical data. In this case, since the medical data is being created, the user of the medical information processing apparatus 100 can directly edit the record or the like relating to the item determined that the correspondence relationship is not established with respect to the medical data being created.

On the other hand, when the user has instructed completion of the preparation (step S25; yes), the data management function 151 stores the prepared medical data in the storage circuit 120, and transmits the medical data to the integrated data server 400 to store the medical data in the integrated DB410 (step S26).

As described above, in the present embodiment, examination data in which examination results related to medical contents described in medical data of a subject are described is extracted, and the medical data and the extracted examination data are displayed on the same screen. In the present embodiment, the correspondence between items included in the medical data and the examination data is determined, and the items having the correspondence between the two data are displayed so as to be recognizable. Thus, the user of the medical information processing apparatus 100 can easily grasp examination data including examination results based on medical contents described as medical data, and can easily grasp where the examination results based on medical contents exist in the examination data. Therefore, in the present embodiment, convenience in creating and interpreting medical data can be improved.

In the present embodiment, when there is an independent item whose correspondence relationship is not established among the items included in the medical data and the examination data, the item is displayed so as to be recognizable. Thus, in the present embodiment, when the description of the examination result is omitted from the medical data or when insufficient medical contents are described in the medical data, the user can grasp the corresponding item, and thus defective medical data can be prevented from being generated.

In the present embodiment, when there is an item for which it is determined that the correspondence relationship between the clinical data and the examination data is not satisfied, a user interface is provided that enables input of a comment related to the item, and the input comment content is stored in association with each other. Thus, the user of the medical information processing apparatus 100 can keep the comment on the reason why the examination result is not reflected in the medical data or the reason why insufficient medical contents are described in the medical data. Further, for example, when the accuracy of the examination result described in the examination data is questioned and is not reflected in the medical details, the user of the medical information processing apparatus 100 can request the reexamination via the interface provided by the medical information processing apparatus 100. Therefore, in the present embodiment, convenience in creating and interpreting medical data can be improved.

The above-described embodiment can also be implemented by modifying a part of the configuration or functions of the medical information processing apparatus 100 as appropriate. Therefore, several modifications of the above embodiment will be described below. In the following description, points different from the above-described embodiments will be mainly described, and points common to those already described will not be described in detail. The modifications described below may be implemented individually or in appropriate combinations.

(modification 1)

In the above-described embodiment, the mode of reporting a defect (omission of description or insufficient basis) of the medical contents described in the medical data based on the determination result of the determining function 154 has been described, but the determination result of the determining function 154 may be used for other purposes. For example, in order to determine the proficiency and reliability of medical data creation, the number of items determined by the determination function 154 that the correspondence relationship is not established may be recorded.

Specifically, each time new medical data is created, the data management function 151 accumulates the number of items determined to be not in correspondence with the medical data for each creator (healthcare practitioner) of the medical data. The accumulated value is associated with, for example, the healthcare worker ID of the creator, and is stored in the storage circuit or the like of the integrated data server 400.

Thus, in the present modification, the degree of skill and reliability of each healthcare practitioner who creates clinical data can be determined by referring to the integrated values. The data management function 151 may record the accumulated value together with the total number of medical data created, the number of times a comment is input, and the like.

(modification 2)

In the above-described embodiment, the mode in which the examination data extracted by the second extraction function 153 is displayed on the screen displaying the medical data obtained by extracting the first data by the first extraction function 152 has been described. However, depending on the number of pieces of inspection data or the amount of information extracted by the second extraction function 153, all pieces of inspection data may not be displayed on the screen.

Therefore, the display control function 155 may display, for example, the screens shown in fig. 13 and 14, instead of the screen example described in the above embodiment. Here, fig. 13 and 14 are diagrams showing an example of a screen displayed by the display control function 155 of the present modification.

As shown in fig. 13, the screen G2 has a timeline display area G11 and a data display area G12, as with the screen G1 described in the first embodiment. Note that, as in the first embodiment, medical data is displayed in the data display area G12. In addition, although fig. 13 shows an example in which one medical data is displayed on the panel P11, a plurality of medical data may be displayed as described with reference to fig. 11.

Further, a check data display area G21 for displaying the check data extracted by the second extraction function 153 is provided in the data display area G12. Specifically, in the inspection data display area G21, each piece of inspection data extracted by the second extraction function 153 is displayed as a panel. Fig. 13 shows an example in which six inspection data are extracted, and the inspection data are displayed in parallel as panels P41 to P46. Fig. 13 shows a state where the panels P41 to P44 are displayed on the panels P41 to P46, and the remaining panels P45 and P46 are not displayed. Hereinafter, the panels P41 to P46 are also collectively referred to as panels P4.

Here, a scroll bar G21a is provided in the inspection data display area G21. The scroll bar G21a can perform a scroll operation in the arrangement direction of the panel P4, and moves the panel P4 in the inspection data display region G21 in accordance with a user operation (scroll operation). For example, in the inspection data display area G21 of fig. 13, when the scroll bar G21a is scrolled downward on the screen, the panels P41 to P46 arranged in the inspection data display area G21 move upward on the screen. As a result, as shown in fig. 14, the user of the medical information processing apparatus 100 can cause the panels P45 and P46, which are not displayed in fig. 13, to be displayed in the examination data display area G21.

The display control function 155 displays the items in the medical data and the examination data determined by the determination function 154 that the correspondence relationship is established, in a manner that can be recognized, as in the above-described embodiment. For example, in fig. 13 and 14, the display control function 155 displays the item a11 in the panel P11 and the item a 11' in the panels P41 to P46, which are determined by the determination function 154 that the correspondence relationship is established, in a recognizable manner. Thus, the medical information processing apparatus 100 according to the present modification can provide the same effects as those of the above-described embodiment. Thus, the user of the medical information processing apparatus 100 can easily grasp where the examination result, which is the basis of the medical content, exists in the examination data by checking the medical data and the examination data displayed so as to be recognizable.

In addition, the display control function 155 displays the items determined by the determination function 154 that the correspondence relationship is not established, in a recognizable manner, as in the above-described embodiment. For example, in fig. 13 and 14, the display control function 155 displays the items a12 and a13 in the panels P22 and P24 determined by the determination function 154 that the correspondence relationship is not established, with a mark MK1 added thereto. Thus, the medical information processing apparatus 100 according to the present modification can achieve the same effects as those of the above-described embodiment. This allows the user of the medical information processing apparatus 100 to easily grasp items that are not reflected in the clinical data, among the items described in the examination data.

Further, an operator for instructing display of the inspection data extracted by the second extraction function 153 is displayed in the data display area G12. Fig. 13 and 14 show examples in which operation panels P51 to P56, which are examples of operators, are displayed on the right side of the inspection data display area G21. Hereinafter, the operation panels P51 to P56 are also collectively referred to as operation panels P5.

The operation panel P5 is provided for each piece of inspection data extracted by the second extraction function 153. Information that can identify the corresponding examination data is displayed on the operation panel P5. For example, information such as the date of creation of the inspection data, the type of the inspection data, and the data name is displayed on the operation panel P5. Here, the operation panels P51 to P56 correspond to the respective inspection data shown in the panels P41 to P46. For example, the operation panel P51 displays the data name "inspection X1" of the inspection data in addition to the date of creation of the corresponding inspection data (inspection data of the panel P41). Thus, the user of the medical information processing apparatus 100 can easily grasp which of the panels P5 is a panel for instructing display of which examination data is displayed.

When items judged that the correspondence relationship is not satisfied are included in the inspection data extracted by the second extraction function 153, the display control function 155 adds and displays information indicating that there is an item judged that the correspondence relationship is not satisfied to the operation panel P5 corresponding to the inspection data. As described above, in the examples of fig. 13 and 14, the items a12 and a13 determined that the correspondence relationship is not established are included in the check data of the panels P43 and P45. Therefore, the display control function 155 displays the operation panels P53 and P55 corresponding to the inspection data of the panels P43 and P45 with a mark MK3 indicating the presence of an item determined to be not standing added. Thus, the user of the medical information processing apparatus 100 can easily grasp the operation panel P5 having the examination data not reflected in the items of the medical data.

Upon receiving the selection operation on the operation panel P5, the display control function 155 causes the inspection data corresponding to the selected operation panel P5 to be displayed in the inspection data display area G21. Here, the display method of the inspection data via the operation panel P5 is not particularly limited, and various display methods can be used.

For example, as shown in fig. 13, when the inspection data extracted by the second extraction function 153 is displayed in advance in the inspection data display area G21 so as to be scrollable, any one or all of the following display methods may be used. For example, the display control function 155 may automatically scroll so that the panel P4 of the inspection data corresponding to the selected operation panel P5 is displayed in the inspection data display area G21. In this case, the display control function 155 may automatically scroll so that the panel P4 of the inspection data corresponding to the selected operation panel P5 is positioned at the center of the inspection data display area G21. The display control function 155 may also be configured to display a panel P4 of the inspection data corresponding to the selected operation panel P5 in a recognizable manner.

As another display method, as shown in fig. 15, the display control function 155 may display only the panel P4 of the inspection data corresponding to the selected operation panel P5 in the inspection data display area G21. Here, fig. 15 is a diagram showing an example of a screen displayed by the display control function 155 of the present modification, and shows a display example in a case where the operation panel P53 is selected.

As shown in fig. 15, upon receiving selection of operation panel P53, display control function 155 causes panel P43, which represents inspection data corresponding to operation panel P53, to be displayed in inspection data display area G21. In this case, for example, the selection and release may be alternately switched by using the operation panel P5 as a switch button (toggle button) or the like.

In the case of the display method of fig. 15, the number of pieces of inspection data that can be selected via the operation panel P5 is not limited to one, and may be plural. For example, when the operation panels P53 and P55 are selected, the display control function 155 causes panels P43 and P45 of the inspection data corresponding to the operation panels P53 and P55 to be displayed in parallel in the inspection data display area G21. Here, the order of arrangement of the panels P4 may be the order of the production day, or the order of the inspection data selected by the operation panel P5.

As described above, according to the present modification, even when all the inspection data extracted by the second extraction function 153 cannot be displayed at once on the same screen, the inspection data not displayed can be displayed by a simple operation. Therefore, in the present modification, convenience in creating and reading medical data can be improved.

(modification 3)

In the above-described embodiment, the medical information processing apparatus 100 is provided with the data management function 151, the first extraction function 152, the second extraction function 153, the determination function 154, and the display control function 155, but some or all of these functions may be provided by an apparatus other than the medical information processing apparatus 100.

For example, the data server 400 may be integrated to have a part or all of the above functions. In this case, the integrated data server 400 functions as a medical information processing apparatus, and displays the various screens on the display 140 of the medical information processing apparatus 100 by means of, for example, a Web service or the like. The medical information processing apparatus is not limited to one computer apparatus, and may be realized by a plurality of computer apparatuses connected via a network.

In the above embodiments, the data management unit, the first extraction unit, the second extraction unit, the determination unit, and the display control unit in the present specification are realized by the data management function 151, the first extraction function 152, the second extraction function 153, the determination function 154, and the display control function 155 of the processing circuit 150, respectively, but the embodiments are not limited thereto. For example, the data management unit, the first extraction unit, the second extraction unit, the determination unit, and the display control unit in this specification may be realized by only hardware or may be realized by a mixture of hardware and software, in addition to the data management function 151, the first extraction function 152, the second extraction function 153, the determination function 154, and the display control function 155 described in the embodiments.

In addition, the expression "processor" used in the above description means, for example, a CPU (Central Processing Unit), a GPU (Graphics Processing Unit), an Application Specific Integrated Circuit (ASIC), a Programmable Logic Device (e.g., a Simple Programmable Logic Device (SPLD), a Complex Programmable Logic Device (CPLD), a Field Programmable Gate Array (FPGA)), and the like. The processor realizes the functions by reading out and executing the program held in the storage circuit 120. Instead of holding the program in the memory circuit 120, the program may be directly incorporated into the circuit of the processor. In this case, the processor realizes the functions by reading out and executing a program incorporated in the circuit. The processor according to the present embodiment is not limited to the case of being configured as a single circuit, and may be configured as a single processor by combining a plurality of independent circuits to realize the functions thereof.

Here, a program executed by the processor is incorporated in advance into a ROM (Read Only Memory), a Memory circuit, or the like. The program may be provided as a file in a form that can be installed in or executed by these apparatuses, and recorded on a computer-readable storage medium such as CD (compact Disk) -ROM, FD (Flexible Disk), CD-r (recordable), dvd (digital Versatile Disk), or the like. The program may be stored in a computer connected to a network such as the internet, downloaded via the network, and provided or distributed. For example, the program is constituted by modules including the above-described functional units. As actual hardware, the CPU reads and executes a program from a storage medium such as a ROM, and loads each module on the main storage device to generate the module on the main storage device.

According to at least one of the embodiments and the modifications described above, it is possible to easily grasp the correspondence between the medical contents described in the medical data and the examination results based on the medical contents.

While several embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These embodiments can be implemented in other various manners, and various omissions, substitutions, and changes can be made without departing from the spirit of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalent scope thereof.

Description of reference numerals:

1 medical information processing system

100 medical information processing device

151 data management function

152 first extraction function

153 second extraction function

154 judging function

155 display control function