JP2010146344A - Inspection data fetching device and program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve convenience in the case of fetching inspection data related with a medium to a server. <P>SOLUTION: An inspection data fetching device 70 obtains inspection data from an analyzer 80 through a communication network N2. The inspection data fetching device 70 obtains patient attribute information from a medium M1 in which medical data including patient attribute information are stored. The inspection data fetching device 70 applies the obtained patient attribute information to inspection data as an identifier. The inspection data fetching device 70 transmits (outputs) the inspection data to an inspection data management server 60. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an inspection data fetching apparatus and a program.

  Pathological examinations and clinical examinations are important examinations for grasping a patient's health condition and performing disease name diagnosis. In these examinations, specimens such as blood, cells, urine, and stool collected from patients are examined. In pathological examinations and clinical examinations, specimens are analyzed (inspected) using an analyzer, and examination results are obtained. Test results include the amount of characteristic components in the specimen, the presence or absence of an antibody reaction, the tumor marker value, and the like. This test result is objective data that does not depend on the subjectivity of the patient or medical staff. Therefore, it is not necessary to identify patients in pathological examinations and clinical examinations.

  By the way, small medical facilities often do not have an analyzer. For this reason, in a small medical facility, it is a common practice to request (outsource) specimen testing from an analysis center equipped with an analyzer.

  However, the identifier (patient ID) of the patient managed at the medical facility is not associated with the identifier (sample ID) of the sample managed at the analysis center. Therefore, it has been troublesome to refer to the test result of the desired sample in a medical facility that requests the analysis center to test the sample.

As an apparatus for solving this problem, each specimen ID managed separately in a plurality of analysis centers is associated with a patient ID managed in a medical facility, and a bridge is provided when referring to a test result of the specimen. A specimen test result combining server is disclosed (see Patent Document 1).
JP 2005-267373 A

  By the way, in a medical facility, when capturing test result data (test data) from the analysis center, it is necessary to manually assign an identifier such as a patient attribute (patient ID or patient name) to the test data. It was inconvenient. Furthermore, there was a possibility of causing an input error by manual input.

  Also, until the identifier for the test data is manually entered, the test data is taken into the medical facility and the test data cannot be referred to, resulting in a time loss.

  In the technique of Patent Document 1, since the inspection data is not taken into the medical facility and is managed in the analysis center, the case where the above-described inspection data is taken in is not supported.

  The present invention has been made in view of the above-described problems, and an object of the present invention is to improve convenience at the time of taking test data relating to a sample into a server.

In order to solve the above problems, the invention described in claim 1
A test data capturing device connected to be communicable with a test data management server for storing and managing test data related to a sample collected from a patient,
First acquisition means for acquiring inspection data;
Second acquisition means for acquiring the patient attribute information from a portable storage medium storing medical data including patient attribute information;
Control means for giving the acquired patient attribute information to the acquired examination data as an identifier, and outputting the examination data to the examination data management server;
Is provided.

The invention according to claim 2 is the invention according to claim 1,
The first acquisition unit acquires inspection data from a portable storage medium.

The invention according to claim 3 is the invention according to claim 1,
The first acquisition means acquires inspection data from an external device that is communicably connected.

The invention according to claim 4 is the invention according to any one of claims 1 to 3,
An operation means for instructing output of inspection data to the inspection data management server;
The control unit displays the identifier on a screen, and outputs the inspection data to which the identifier is added to the inspection data management server based on an instruction from the operation unit.

The invention according to claim 5 is the invention according to any one of claims 1 to 4,
The patient attribute information includes a patient ID and / or a patient name.

The program according to claim 6 is:
A computer that is communicably connected to a test data management server that stores and manages test data related to specimens collected from patients.
First acquisition means for acquiring inspection data;
Second acquisition means for acquiring the patient attribute information from a portable storage medium storing medical data including patient attribute information;
Control means for giving the acquired patient attribute information as an identifier to the acquired examination data and outputting the examination data to the examination data management server;
To function as.

The invention according to claim 7 is the invention according to claim 6,
The first acquisition unit acquires inspection data from a portable storage medium.

The invention according to claim 8 is the invention according to claim 6,
The first acquisition means acquires inspection data from an external device that is communicably connected.

The invention according to claim 9 is the invention according to any one of claims 6 to 8,
The computer,
Operation means for instructing output of inspection data to the inspection data management server;
Further function as
The control unit displays the identifier on a screen, and outputs the inspection data to which the identifier is added to the inspection data management server based on an instruction from the operation unit.

The invention according to claim 10 is the invention according to any one of claims 6 to 9, wherein
The patient attribute information includes a patient ID and / or a patient name.

  According to the first and sixth aspects of the invention, the inspection data capturing device acquires inspection data. Further, the examination data fetching apparatus acquires patient attribute information from a portable storage medium that stores medical data including patient attribute information. Then, the examination data capturing device assigns the acquired patient attribute information as an identifier to the acquired examination data. The inspection data fetching apparatus outputs this inspection data to the inspection data management server.

  This eliminates the need for the user to manually input the identifier, and can improve convenience when taking test data relating to the sample into the server.

  According to the second and seventh aspects of the invention, the inspection data fetching apparatus acquires the inspection data from the portable storage medium. For this reason, it is possible to improve convenience when the inspection data is taken into the server from the portable storage medium.

  According to the third and eighth aspects of the invention, the inspection data capturing device acquires inspection data from an external device that is communicably connected. Therefore, it is possible to improve the convenience when the inspection data is fetched from the external device to the server.

  According to invention of Claim 4, 9, the test | inspection data acquisition apparatus displays an identifier on a screen. Then, the inspection data fetching apparatus outputs the inspection data to which this identifier is assigned to the inspection data management server based on an instruction from the operation means. Therefore, the user can confirm the identifier before giving it to the inspection data.

  According to the fifth and tenth aspects of the present invention, it is possible to identify the examination data captured in the server based on the patient ID and / or the patient name.

[First embodiment]
Hereinafter, a first embodiment of the present invention will be described.

[System configuration of diagnostic system]
FIG. 1 shows a system configuration of the diagnostic system 100.

  The diagnostic system 100 is applied to a relatively small medical facility such as a practitioner or a clinic. The diagnostic system 100 includes a medical accounting system 10, a client PC 20, an electronic medical record server 30, a medical image server 40, a modality 50, an examination data management server 60, and an examination data capturing device 70. Yes. Each of the above-described devices and systems are connected via a communication network N1 such as a LAN (Local Area Network) so that data communication is possible. Further, each of the above devices and systems is connected to an analyzer 80 installed in the analysis center via a communication network N2 such as the Internet so that data communication is possible.

  The modality 50 is an image generation apparatus that performs imaging using a patient's diagnosis target region as a subject and digitally converts the captured image to generate a medical image. A medical image is an image used for interpretation diagnosis in the medical field. The modality 50 adds incidental information to the generated medical image, and generates DICOM-compliant image data in accordance with the DICOM standard. The incidental information includes patient attribute information indicating patient attributes. The modality 50 transmits the generated DICOM-compliant image data to the medical image server 40. As the modality 50, an ultrasonic diagnostic apparatus (US), an FPD (Flat Panel Detector), or the like is applicable.

  The medical image server 40 stores and manages (stores and manages) DICOM-compliant image data generated by the modality 50. A PACS (Picture Archiving and Communication System) or the like is applicable as the medical image server 40.

  When receiving a medical image acquisition request from an external device, the medical image server 40 transmits (provides) DICOM-compliant image data corresponding to the acquisition request to the external device.

  The medium M1 is a portable storage medium (CD-R, floppy (registered trademark) disk, or the like) that stores medical data including patient attribute information. Medical data is information such as medical images, interpretation reports, and letters of introduction. For example, the media M1 has DICOM-compliant image data (patient attribute information) in accordance with the data structure defined by PHE (Portable Data for Imaging) of IHE (Integrating Healthcare Enterprise) and IHE-J (Integrating Healthcare Enterprise-Japan). Including medical data).

  The analyzer 80 analyzes (tests) a sample such as blood or urine collected from a patient, and generates test data as an analysis result. The inspection data includes one or a plurality of inspection items. For example, when the specimen is blood, the test data includes items such as “total protein”, “GOT”, “GPT”, and “LDH”. The analyzer 80 transmits the generated inspection data to the inspection data capturing device 70 via the communication network N2. In the analysis center, in response to a test request from each medical facility, the samples brought from these medical facilities are analyzed by the analyzer 80, and test data as analysis results are provided.

  The inspection data capturing device 70 is a device for capturing inspection data into an inspection data management server 60 described later. The inspection data capturing device 70 receives inspection data from the analyzer 80 via the communication network N2. The test data capturing device 70 performs various processes on the received test data, and transmits this test data to the test data management server 60 as HL7-compliant sample test result data in accordance with the HL7 standard. As one of these various types of processing, the inspection data capturing device 70 gives an identifier to the inspection data.

  The examination data capturing device 70 reads (acquires) patient attribute information from the medium M1. For example, the examination data capturing device 70 extracts patient attribute information from incidental information included in the DICOM-compliant image data stored in the medium M1, and acquires this patient attribute information. The examination data capturing device 70 gives the acquired patient attribute information to the examination data as an identifier.

  The test data management server 60 stores and manages (stores and manages) the HL7-compliant sample test result data transmitted (output) from the test data capturing device 70. When the test data management server 60 receives a test data acquisition request from an external device, the test data management server 60 transmits (provides) HL7-compliant sample test result data corresponding to the acquisition request to the external device.

  FIG. 2 shows the data flow of inspection data. First, inspection data is generated in the analyzer 80 installed in the analysis center. Next, the inspection data is transmitted to the inspection data capturing device 70 via the communication network N2. Next, in the test data capturing device 70, the test data is provided with the patient attribute information acquired from the medium M1 as an identifier, and is transmitted to the test data management server 60 as HL7-compliant sample test result data. The test data is stored and managed in the test data management server 60 as HL7-compliant sample test result data.

  Returning to FIG. 1, the medical accounting system 10 is a computer device for performing reception registration, accounting calculation, insurance score calculation, and the like of a patient who has visited a hospital. The medical accounting system 10 generates visit information when receiving and registering a patient who has visited by user operation. The medical accounting system 10 stores and manages (stores and manages) the generated visit information. The medical accounting system 10 transmits the generated visit information to the electronic medical record server 30. The visit information is information indicating a patient visit date and time, an insurance card number, and the like. The visit information includes patient attribute information indicating the attributes of the patient who has visited.

  The medical accounting system 10 receives (acquires) prescription data from the electronic medical record server 30. The prescription data is information indicating the treatment contents of diagnosis and the medicine prescribed to the patient. The prescription data includes patient attribute information indicating patient attributes. Based on the received prescription data and the generated visit information, the medical accounting system 10 performs an accounting calculation and an insurance score calculation for the visited patient.

  The electronic medical record server 30 stores and manages (stores and manages) medical record data (information such as a patient's medical condition and diagnosis result) and prescription data created in the client PC 20. The electronic medical record server 30 stores and manages (stores and manages) the visit information received from the medical accounting system 10. The electronic medical record server 30 transmits the prescription data stored and managed to the medical accounting system 10.

  When receiving the visit information acquisition request from the external device, the electronic medical record server 30 transmits (provides) the visit information corresponding to the acquisition request to the external device.

  The client PC 20 is a client terminal such as the electronic medical record server 30, the medical image server 40, and the examination data management server 60. The client PC 20 is installed in a medical room or the like of a medical facility. The doctor diagnoses the patient using the client PC 20.

  The client PC 20 transmits a medical image acquisition request to the medical image server 40 based on an operation signal generated by a user operation, and acquires DICOM-compliant image data corresponding to the acquisition request. The client PC 20 displays a medical image on the screen based on the DICOM-compliant image data.

  The client PC 20 transmits a test data acquisition request to the test data management server 60 based on an operation signal or the like by a user operation, and acquires HL7-compliant sample test result data corresponding to the acquisition request. The client PC 20 displays test data on the screen based on the HL7-compliant sample test result data.

  The client PC 20 transmits a visit information acquisition request to the electronic medical record server 30 based on an operation signal or the like by a user operation, and acquires visit information corresponding to the acquisition request.

  The client PC 20 has a medical record data creation function. The client PC 20 creates medical record data and prescription data based on an operation signal generated by a user operation, visit information acquired from the electronic medical record server 30, and the like. The client PC 20 transmits the created medical record data and prescription data to the electronic medical record server 30. The electronic medical record server 30 stores the transmitted medical record data and prescription data.

[Functional configuration of inspection data management server]
FIG. 3 shows a functional configuration of the inspection data management server 60.

  As shown in FIG. 3, the inspection data management server 60 includes a control unit 61, an operation unit 62, a display unit 63, a communication unit 64, and a storage unit 65, and each unit is connected by a bus 66.

  The control unit 61 includes a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like, and comprehensively controls the processing operation of each unit of the inspection data management server 60. Specifically, the CPU reads various processing programs stored in the storage unit 65 in accordance with an operation signal input from the operation unit 62 or an instruction signal received by the communication unit 64, and is formed in the RAM. The work area is expanded and various processes are performed in cooperation with the program.

  The operation unit 62 includes a keyboard having cursor keys, numeric input keys, various function keys, and the like, and a pointing device such as a mouse. The operation unit 62 controls operation signals input by key operations or mouse operations on the keyboard. To 61.

  The display unit 63 is configured by an LCD (Liquid Crystal Display), and displays various screens based on display data input from the control unit 61.

  The communication unit 64 includes a LAN (Local Area Network) adapter, a router, a TA (Terminal Adapter), and the like, and is connected to external devices such as the inspection data capturing device 70 and the client PC 20 connected via the communication network N1. Send and receive data.

  The storage unit 65 is composed of a hard disk or the like, and stores a control program, parameters and files necessary for executing the program. The storage unit 65 stores one or a plurality of HL7-compliant specimen test result data. The storage unit 65 stores a database program for managing HL7-compliant specimen test result data (not shown).

  The control unit 61 manages the HL7-compliant specimen test result data stored in the storage unit 65 in cooperation with the database program stored in the storage unit 65.

  When the control unit 61 receives HL7-compliant sample test result data from the test data capturing device 70 via the communication unit 64, the control unit 61 stores the HL7-compliant sample test result data in the storage unit 65 and registers it in the database (management). To do).

  When receiving a test data acquisition request from an external device via the communication unit 64, the control unit 61 reads out HL7-compliant sample test result data corresponding to the test data acquisition request from the storage unit 65. Then, the control unit 61 transmits (provides) the read HL7-compliant specimen test result data to the external device via the communication unit 64.

[Functional configuration of inspection data capture device]
FIG. 4 shows a functional configuration of the inspection data capturing device 70.

  As shown in FIG. 4, the test data capturing device 70 includes a control unit 71, an operation unit 72, a display unit 73, a communication unit 74, a storage unit 75, and a media drive 76, and each unit is connected by a bus 77. Has been.

  The control unit 71 includes a CPU, a RAM, and the like, and comprehensively controls the processing operation of each unit of the inspection data capturing device 70. Specifically, the CPU reads various processing programs stored in the storage unit 75 in accordance with an operation signal input from the operation unit 72 or an instruction signal received by the communication unit 74, and is formed in the RAM. The work area is expanded and various processes are performed in cooperation with the program.

  The operation unit 72 includes a keyboard having cursor keys, numeric input keys, various function keys, and the like, and a pointing device such as a mouse. The control unit 72 controls operation signals input by key operations or mouse operations on the keyboard. To 71.

  The display unit 73 is configured by an LCD, and displays various screens based on display data input from the control unit 71.

  The communication unit 74 includes a LAN adapter, a router, a TA, and the like, and an external device such as an inspection data management server 60 connected via the communication network N1, an analyzer 80 connected via the communication network N1, and the communication network N2. Send and receive data to and from.

  The storage unit 75 includes a hard disk or the like, and stores a control program, parameters and files necessary for executing the program, and the like. The storage unit 75 stores an inspection data fetch program 751.

  The media drive 76 reads various data stored in a portable storage medium such as the medium M1 based on a control signal from the control unit 71. Further, the media drive 76 writes various data to the portable storage medium based on the control signal from the control unit 71.

  The control unit 71 functions as follows in cooperation with the inspection data fetch program 751. That is, the control unit 71 receives (acquires) examination data from the analyzer 80 via the communication unit 74. In addition, the control unit 71 acquires patient attribute information from the medium M1 via the media drive 76. The control unit 71 assigns the acquired patient attribute information to the examination data as an identifier. Then, the control unit 71 transmits (outputs) the test data to the test data management server 60 via the communication unit 74 as HL7-compliant sample test result data.

  FIG. 5 shows the data structure of test data and the data structure of HL7-compliant sample test result data.

  As shown in FIG. 5, the test data includes specimen identification information, container identification information, and result identification information. The sample identification information is information related to the sample such as the sample ID, the collection method, the collection amount, the collection date / time, and the reception date / time. The container identification information is information about the container such as the container ID, the container volume, the additive, the dilution rate, and the temperature. The result identification information is information relating to the inspection result such as the inspection item, inspection value, unit, reference value, practitioner, analysis date and time, and device ID.

  The HL7-compliant specimen test result data includes header information, patient identification information (patient attribute information), visit identification information (visit information), specimen identification information, container identification information, result identification information, and examination identification information. The patient identification information is information about the patient (patient attribute information) such as patient ID, patient name, date of birth, and sex. The visit identification information is information (visit information) related to a patient visit such as a visit number, a visit date and time, a patient ID, and an insurance card number. The inspection identification information is information relating to the inspection such as the inspection purpose, the inspection content, and the acquisition date and time.

  Returning to FIG. 4, when receiving the test data (sample identification information, container identification information, and result identification information) from the analyzer 80, the control unit 71 adds header information, patient identification information, visit identification information, and examination identification to the examination data. HL7-compliant specimen test result data is generated by adding information and the like. Here, patient identification information, visit identification information, and examination identification information are empty data (invalid values).

  When the medium M1 is set in the media drive 76, the control unit 71 acquires patient attribute information from the medium M1 via the media drive 76. The control unit 71 reflects the values of “patient ID” and “patient name” included in the acquired patient attribute information in the values of “patient ID” and “patient name” included in the patient identification information added to the examination data. (Give). Here, it is assumed that the value of “patient ID” included in the acquired patient attribute information is “0000000001” and the value of “patient name” is “Yukawa ^ Manabu”. In addition, the control unit 71 sets values such as “birth date” and “sex” included in the patient identification information added to the examination data to values such as “birth date” and “sex” included in the acquired patient attribute information. To reflect (give). Patient attribute information such as “patient ID”, “patient name”, etc. is an identifier of examination data.

  Next, the control unit 71 transmits HL7-compliant sample test result data to the test data management server 60 via the communication unit 74.

[Specific operation of each device in the diagnostic system]
Next, specific operations of each device executed in the diagnostic system 100 will be described with reference to FIG.

  Assume that a patient visits a medical facility A equipped with a diagnostic system 100 by introduction from an external medical facility B. And this patient brings the media M1 which memorize | stored the DICOM conformity image data image | photographed and produced | generated in the medical facility B. FIG.

  When the doctor of the medical facility A determines that a sample test is necessary for this patient, a sample is collected from the patient. The sample is stored in a container and sent to the analysis center.

  The analyzer 80 installed in the analysis center analyzes this sample, acquires a result for each test item, and generates test data (step S1). For example, when the specimen is blood, the test data result identification information includes a plurality of test items “total protein”, “GOT”, “GPT”, and “LDH”. The result identification information includes “inspection value”, “unit”, “reference value”, “performer”, “analysis date”, and “apparatus ID” corresponding to these inspection items.

  Next, the analyzer 80 transmits the generated inspection data to the inspection data capturing device 70 via the communication network N2 (step S2).

  The control unit 71 of the test data fetching apparatus 70 adds patient identification information, which is empty data, to the received test data, and generates HL7-compliant sample test result data. The control unit 71 displays a test result display screen 731 (see FIG. 7A) on the display unit 73 based on the HL7-compliant sample test result data (step S3). The inspection result display screen 731 is a screen for displaying inspection data (inspection result).

  FIG. 7A shows a screen example of the inspection result display screen 731. As shown in FIG. 7A, the test result display screen 731 displays a sample management number (corresponding to “sample ID”), a sample collection date and time (“collection date and time”) based on the sample identification information included in the test data. Is displayed. The test result display screen 731 displays “test values” corresponding to the test items “total protein”, “GOT”, “GPT”, and “LDH” based on the result identification information included in the test data. . The examination result display screen 731 displays a patient ID display area e1 and a patient name display area e2 for displaying values of “patient ID” and “patient name” of the patient identification information. Here, the patient identification information is empty data. Therefore, the patient ID display area e1 and the patient name display area e2 are blank.

  The inspection result display screen 731 displays a read button b1. The read button b1 is a button for acquiring patient attribute information from the medium M1 set in the media drive 76.

  Returning to FIG. 6, a user such as a doctor sets the media M <b> 1 brought by the patient in the media drive 76. Then, the user presses the read button b1.

  Based on the operation signal from the operation unit 72 by the user operation, the control unit 71 extracts patient attribute information from the incidental information included in the DICOM-compliant image data stored in the medium M1, and acquires the patient attribute information. (Step S4). When DICOM-compliant image data corresponding to a plurality of patients is stored in the medium M1, the control unit 71 causes the display unit 73 to display a list of patient attribute information corresponding to each of these patients, and the user operation is performed. Based on the operation signal from the operation unit 72, the patient attribute information to be acquired may be selected.

  Then, the control unit 71 displays the value “0000000001” of “patient ID” and the value “Yukawa ^ Manabu” of “patient name” included in the patient attribute information acquired in step S <b> 4 on the display unit 73. Specifically, these values are displayed in the patient ID display area e1 and the patient name display area e2 of the examination result display screen 731, respectively.

  FIG. 7B shows a screen example of the examination result display screen 731 on which the values of “patient ID” and “patient name” included in the patient attribute information acquired in step S4 are displayed. As shown in FIG. 7B, the value “0000000001” of “patient ID” included in the acquired patient attribute information is displayed in the patient ID display area e1. In the patient name display area e2, the value “Yukawa ^ Manabu” of “patient name” included in the acquired patient attribute information is displayed.

  In addition, a transmission button b2 is newly displayed on the inspection result display screen 731. The send button b2 is a button for reflecting the patient attribute information acquired in step S4 to the patient identification information included in the HL7-compliant sample test result data, and sending this HL7-compliant sample test result data to the test data management server 60. It is. By providing this transmission button b2, the user can confirm the identifier to be given before giving the identifier to the inspection data.

  Returning to FIG. 6, a user such as a doctor confirms “patient ID” and “patient name” displayed in the patient ID display area e1 and patient name display area e2 of the examination result display screen 731 and presses the send button b2. To do. Based on the operation signal from the operation unit 72 by this user operation, the control unit 71 reflects the patient attribute information acquired in step S4 in the patient identification information included in the HL7-compliant specimen test result data. That is, the control unit 71 assigns the acquired patient attribute information to the examination data as an identifier (step S5). Then, the control unit 71 transmits the HL7-compliant sample test result data to the test data management server 60 (step S6).

  When the control unit 61 of the test data management server 60 receives the HL7-compliant sample test result data from the test data capturing device 70 via the communication unit 64, the control unit 61 stores the HL7-compliant sample test result data in the storage unit 65 ( Save) and register in the database (step S7).

  The doctor performs a user operation on the client PC 20 to search for HL7-compliant specimen test result data based on the patient ID and patient name given in step S5. The client PC 20 generates an examination data acquisition request including the patient ID and patient name given in step S5 and transmits the examination data acquisition request to the examination data management server 60. The control unit 61 of the test data management server 60 reads out HL7-compliant sample test result data corresponding to the acquisition request from the storage unit 65 based on the patient ID and the patient name included in the received test data acquisition request. Then, the control unit 61 transmits the read HL7 compliant specimen test result data to the client PC 20. The client PC 20 receives (acquires) this HL7-compliant specimen test result data.

  The client PC 20 displays test data based on the HL7-compliant sample test result data on the screen based on an operation signal generated by a user operation.

  As described above, according to the first embodiment, the control unit 71 of the test data capturing device 70 acquires test data from the analyzer 80 via the communication unit 74. The control unit 71 acquires patient attribute information from the medium M1 via the media drive 76. The control unit 71 assigns the acquired patient attribute information to the examination data as an identifier. The control unit 71 transmits (outputs) the inspection data to the inspection data management server 60 via the communication unit 74.

  Therefore, when the user takes the examination data transmitted from the analyzer 80 into the examination data management server 60, the user only allows the examination data fetching apparatus 70 to read the patient attribute information stored in the medium M1 brought by the patient. Thus, patient attribute information such as “patient ID”, “patient name”, “age”, and “sex” can be given to the examination data as an identifier. That is, the user does not need to manually input values such as “patient ID”, “patient name”, “age”, and “sex”. Therefore, the convenience at the time of taking test | inspection data into the test | inspection data management server 60 can be improved.

  Further, the inspection data is taken into the diagnostic system 100. Therefore, the user can refer to the desired inspection data based on the identifier given by the inspection data capturing device 70 in the own system (diagnostic system 100).

[Second Embodiment]
Next, a second embodiment of the present invention will be described. In the second embodiment, instead of the inspection data capturing device 70 receiving the inspection data from the analyzer 80 via the communication network N2, the inspection data capturing device 70 receives the inspection data from the portable storage medium. It is configured to read. Here, the configuration different from the first embodiment will be mainly described.

[System configuration of diagnostic system]
FIG. 8 shows a system configuration of the diagnostic system 100.

  The diagnostic system 100 includes a medical accounting system 10, a client PC 20, an electronic medical record server 30, a medical image server 40, a modality 50, an examination data management server 60, and an examination data capturing device 70. Yes. Each of the above-described devices and systems are connected via a communication network N1 such as a LAN (Local Area Network) so that data communication is possible. An analyzer 80 is installed in the analysis center.

  The analyzer 80 analyzes (tests) a sample such as blood or urine collected from a patient, and generates test data as an analysis result. The analyzer 80 writes the generated inspection data in the medium M2, which is a portable storage medium. In the analysis center, in response to a test request from each medical facility, the samples brought from these medical facilities are analyzed by the analyzer 80, and the media M2 on which the test data is written is provided to each medical facility.

  The inspection data capturing device 70 reads inspection data from the medium M2. The test data capturing device 70 performs various processes on the read test data, and transmits this test data to the test data management server 60 as HL7-compliant sample test result data. As one of these various types of processing, the inspection data capturing device 70 gives an identifier to the inspection data.

  FIG. 9 shows the data flow of inspection data. First, inspection data is generated in the analyzer 80 installed in the analysis center. Next, in the analyzer 80, the inspection data is written to the medium M2. This medium M2 is transferred to the diagnostic system 100 of the medical facility A. Then, in the inspection data capturing device 70, the inspection data is read from the medium M2. The test data is given to the test data capturing device 70 using the patient attribute information acquired from the medium M1 as an identifier, and is transmitted to the test data management server 60 as HL7-compliant sample test result data. The test data is stored and managed in the test data management server 60 as HL7-compliant sample test result data.

[Functional configuration of inspection data capture device]
The control unit 71 of the inspection data capturing device 70 functions as follows in cooperation with the inspection data capturing program 751. That is, the control unit 71 reads (acquires) the inspection data from the medium M2 via the media drive 76. In addition, the control unit 71 acquires patient attribute information from the media M1 via the media drive 76. The control unit 71 assigns the acquired patient attribute information to the examination data as an identifier. Then, the control unit 71 transmits (outputs) the test data to the test data management server 60 via the communication unit 74 as HL7-compliant sample test result data. Note that the process in which the control unit 71 assigns the identifier to the inspection data is the same as the process described in the first embodiment.

  As described above, according to the second embodiment, the control unit 71 of the inspection data capturing device 70 acquires the inspection data from the medium M <b> 2 via the media drive 76. In addition, the control unit 71 acquires patient attribute information from the medium M1 via the media drive 76. The control unit 71 assigns the acquired patient attribute information to the examination data as an identifier. The control unit 71 transmits (outputs) the inspection data to the inspection data management server 60 via the communication unit 74.

  Therefore, when the user takes the examination data stored in the medium M2 into the examination data management server 60, the user only allows the examination data fetching apparatus 70 to read the patient attribute information stored in the medium M1 brought by the patient. Thus, patient attribute information such as “patient ID”, “patient name”, “age”, and “sex” can be given to the examination data as an identifier. That is, the user does not need to manually input values such as “patient ID”, “patient name”, “age”, and “sex”. Therefore, the convenience at the time of taking test | inspection data into the test | inspection data management server 60 can be improved.

  The descriptions in the first and second embodiments are examples of the inspection data fetching apparatus according to the present invention, and the present invention is not limited to this. The detailed configuration and detailed operation of the system and each device can be changed as appropriate.

  For example, although the examination data capturing device 70 acquires patient attribute information from the medium M1, it may have the following configuration. That is, the inspection data capturing device 70 has an infrared communication function. The examination data capturing device 70 acquires this patient attribute information from a mobile phone terminal or the like storing the patient attribute information by using an infrared communication function.

  In this embodiment, an example in which a portable storage medium or a hard disk is used as a computer-readable medium storing a program is disclosed, but the present invention is not limited to this example. As another computer-readable medium, a non-volatile memory such as a flash memory can be applied. Also, a carrier wave can be applied as a medium for providing program data via a communication line.

It is a system configuration figure of a diagnostic system in a 1st embodiment of the present invention. It is a figure which shows the data flow of the test | inspection data in the 1st Embodiment of this invention. It is a block diagram of an inspection data management server. It is a block diagram of a test | inspection data taking-in apparatus. It is a data block diagram of test | inspection data and HL7 reference | standard test result data. It is a ladder chart which shows the process performed in a diagnostic system. It is an example of a test result display screen. It is a system configuration figure of a diagnostic system in a 2nd embodiment of the present invention. It is a figure which shows the data flow of the test | inspection data in the 2nd Embodiment of this invention.

Explanation of symbols

10 Medical Accounting System 20 Client PC
30 electronic medical record server 40 medical image server 50 modality 60 inspection data management server 61 control unit 62 operation unit 63 display unit 64 communication unit 65 storage unit 66 bus 70 test data capturing device 71 control unit 72 operation unit 73 display unit 74 communication unit 75 Storage unit 76 Media drive 77 Bus 80 Analyzer 100 Diagnostic system 731 Inspection result display screen 751 Inspection data capture program M1 Media M2 Media N1 Communication network N2 Communication network

Claims (10)

A test data capturing device connected to be communicable with a test data management server for storing and managing test data related to a sample collected from a patient,
First acquisition means for acquiring inspection data;
Second acquisition means for acquiring the patient attribute information from a portable storage medium storing medical data including patient attribute information;
Control means for giving the acquired patient attribute information to the acquired examination data as an identifier, and outputting the examination data to the examination data management server;
An inspection data capturing device comprising: The first acquisition means acquires inspection data from a portable storage medium.
The inspection data capturing device according to claim 1. The first acquisition means acquires inspection data from an external device that is communicably connected.
The inspection data capturing device according to claim 1. An operation means for instructing output of inspection data to the inspection data management server;
The control means causes the identifier to be displayed on a screen, and outputs inspection data to which the identifier is assigned to the inspection data management server based on an instruction from the operation means.
The inspection data capturing device according to any one of claims 1 to 3. The patient attribute information includes a patient ID and / or a patient name.
The inspection data capturing device according to any one of claims 1 to 4. A computer that is communicably connected to a test data management server that stores and manages test data related to specimens collected from patients.
First acquisition means for acquiring inspection data;
Second acquisition means for acquiring the patient attribute information from a portable storage medium storing medical data including patient attribute information;
Control means for giving the acquired patient attribute information as an identifier to the acquired examination data and outputting the examination data to the examination data management server;
Program to function as. The first acquisition means acquires inspection data from a portable storage medium.
The program according to claim 6. The first acquisition means acquires inspection data from an external device that is communicably connected.
The program according to claim 6. The computer,
Operation means for instructing output of inspection data to the inspection data management server;
Further function as
The control means causes the identifier to be displayed on a screen, and outputs inspection data to which the identifier is assigned to the inspection data management server based on an instruction from the operation means.
The program as described in any one of Claims 6-8. The patient attribute information includes a patient ID and / or a patient name.
The program as described in any one of Claims 6-9.

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