JP2023174045A - Program, medical image management device, medical image management system, and medical image management method - Google Patents

Abstract

To provide a program, a medical image management apparatus, a medical image management system, and a medical image management method that can more suitably select an image processing parameter at the time of image processing of a medical image for an animal.SOLUTION: A program causes a control unit 31 (computer) of a medical image management apparatus 3 to execute: a reception step (S2) of receiving inputting, by an operator, of information on an affected animal; a specification step (S3) of specifying a type of the animal based on the information on the affected animal; and a display control step (S27) of displaying an image of the animal on an image processing parameter selection screen based on the type of the animal.SELECTED DRAWING: Figure 6

Description

The present invention relates to a program, a medical image management device, a medical image management system, and a medical image management method.

Conventionally, an operator such as a doctor or a technician photographs a patient visiting a medical facility using an image generation device such as a CR (Computed Radiography) imaging device or a DR (Digital Radiography) imaging device, and the resulting images are BACKGROUND ART A medical image management system is known that performs image processing such as gradation processing and outputs a processed image so that it can be provided for diagnosis.

In connection with this, Patent Document 1 includes an image generation device, and a control device that performs all of the following: image processing, input of examination information, linking of images and examination information, and display of images and examination information. A small-scale diagnostic system is described. This small-scale diagnostic system automatically recognizes the body part of the photographed image, determines image processing conditions using image processing parameters corresponding to the body part, performs image processing using the image processing condition, and performs diagnosis. It is possible to generate a final photographed image for Furthermore, it is possible for the operator to adjust the image processing conditions for the final photographed image.

Japanese Patent Application Publication No. 2007-117469

In recent years, digitalization of medical images has become widespread, and in addition to image processing that corresponds to each body part, image adjustment that is more suitable for diagnosis has become required. Therefore, the frequency of image adjustment by the operator is increasing.
Under such circumstances, the small-scale diagnostic system of Patent Document 1 allows an operator such as a doctor to adjust the density, contrast, etc. of the generated final diagnostic image according to the purpose. This was troublesome for the operator because it required input operations.
By the way, the small-scale diagnostic system of Patent Document 1 is intended for human patients, and not for affected animals.
In the case of animals, image processing parameters vary depending on the animal species, making the process even more complex.

An object of the present invention is to provide a program, a medical image management device, a medical image management system, and a medical image management method that can more appropriately select image processing parameters during image processing of medical images of animals.

In order to solve the above problems, the program of the claimed invention is
In the computer of the medical image management device,
a reception step for accepting input of patient information of the animal by the operator;
an identifying step of identifying the type of the animal based on the affected animal information;
a display control step of displaying an image of the animal on an image processing parameter selection screen based on the type of the animal;
Execute.

Furthermore, the medical image management device of the present invention includes:
a reception section that accepts input of animal patient information by an operator;
an identification unit that identifies the type of animal based on the affected animal information;
a display control unit that displays an image of the animal on an image processing parameter selection screen based on the type of the animal;
has.

Furthermore, the medical image management system of the present invention includes:
a reception section that accepts input of animal patient information by an operator;
an identification unit that identifies the type of animal based on the affected animal information;
a display control unit that displays an image of the animal on an image processing parameter selection screen based on the type of the animal;
Equipped with.

Furthermore, the medical image management method of the present invention includes:
a reception step for accepting input of patient information of the animal by the operator;
an identifying step of identifying the type of the animal based on the affected animal information;
a display control step of displaying an image of the animal on an image processing parameter selection screen based on the type of the animal;
including.

According to the present invention, it is possible to provide a program, a medical image management device, a medical image management system, and a medical image management method that can more appropriately select image processing parameters when processing medical images of animals. can.

1 is a block diagram showing the configuration of a medical image management system according to an embodiment of the present invention. FIG. 2 is a block diagram showing the functional configuration of a medical image management device. It is a figure showing an example of a purpose element presetting screen. It is a figure which shows the example of the parameter edit screen classified by objective element. 3 is a flowchart showing photographing processing. 3 is a flowchart showing image capture processing. FIG. 3 is a diagram showing an example of a target element selection screen. FIG. 3 is a diagram showing an example of a target element selection screen. FIG. 3 is a diagram showing an example of a target element selection screen. FIG. 3 is a diagram showing an example of a target element selection screen.

Embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that the present invention is not limited to the illustrated example.

First, with reference to FIG. 1, the device configuration of a medical image management system 1 according to the present embodiment will be described. FIG. 1 is a block diagram showing the system configuration of a medical image management system 1. As shown in FIG.

The medical image management system 1 is a system applied to medical facilities such as small-scale animal hospitals that treat patient animals. As shown in FIG. 1, the medical image management system 1 includes an image generation device 2, a medical image management device 3, and a reception device 4. The image generation device 2 includes an ultrasonic diagnostic device (US: UltraSonography) 2a, an endoscope (ES: EndoScope) 2b, an electrocardiogram recording device (ECG: ElectroCardioGram) 2c, a CR reader 2d, and a DR reader 2e.
Here, the term "affected animals" refers to animals that are sick and receiving veterinary treatment, and includes livestock, pets, and the like.

Note that the image generation device 2 is not limited to the configuration shown in FIG. 1, and may be, for example, a CT imaging device (CT: Computed Tomography), a magnetic resonance imaging device (MRI), or a device for imaging the external appearance of the body such as the skin. It may also be configured to include a digital camera or the like. Furthermore, a configuration may be adopted in which a plurality of image generating devices 2 of the same type are provided, for example, two DR reading devices 2e are provided. Further, the combination of image generation devices 2 provided in the medical image management system 1 is not limited to the one illustrated here.

The image generation device 2, the medical image management device 3, and the reception device 4 are connected to a communication network 5 such as a LAN (Local Area Network) via, for example, a switching hub (not shown). The medical image management device 3 is an information processing device such as a workstation provided in an examination room where a veterinarian is permanently stationed. The medical image management device 3 has a function of controlling startup and processing conditions of the image generation device 2, a function of acquiring image data from the image generation device 2 and displaying it in association with patient animal information, and a function of storing image data linked with patient animal information. It has the function of PACS (Picture Archiving and Communication Systems).
The affected animal information includes the type, physique, weight, etc. of the animal. The types of animals include, for example, categories such as dogs, cats, birds, and horses. Furthermore, the physique of an animal is the type of the animal's body, and even animals of the same type have different physiques depending on more detailed classification. For example, if the type of animal is a dog, classification based on body size may include large dogs, medium-sized dogs, small dogs, etc. In addition, the weight of the animal refers to the weight of the affected animal. The patient information is stored in the medical image management device 3 for each patient.

The DICOM (Digital Image and Communications in Medicine) standard is generally used as a communication method within hospitals, and the DICOM MWM (Modality Worklist Management) and D ICOM MPPS ( Modality Performed Procedure Step) is used. Note that the communication method applicable to this embodiment is not limited to this. Furthermore, devices connected to the LAN may include devices that do not comply with the DICOM standard.

A medical facility in which the medical image management system 1 is installed has, for example, a reception desk, a waiting room, a consultation room, a radiography room, an examination room, and the like. The reception device 4 is placed at the reception. The medical image management device 3 and the ultrasound diagnostic device 2a are placed in a consultation room. A CR imaging device (not shown), a CR reading device 2d, a DR imaging device (not shown), and a DR reading device 2e are arranged in the radiography room. A CR imaging device is a device that records radiation images by emitting radiation to a CR cassette through a patient animal as a subject. A DR imaging device is a device that generates and stores radiographic image data by emitting radiation through a patient animal as a subject. Furthermore, it is assumed that the medical image management device 3 also functions as a console of the DR imaging device and is connected to the DR imaging device via the communication network 5. The endoscope 2b and electrocardiogram recording device 2c are placed in the examination room.

A counter staff is assigned at the reception desk of a medical facility, and the counter staff gives each patient animal that comes to the hospital for examination a reception number tag with a reception number printed on it to distinguish each patient animal in the order of reception. . Further, the person in charge at the counter obtains the name of the affected animal from the patient's examination ticket or the information on the medical questionnaire filled out by the owner of the affected animal, and inputs into the reception device 4 the correspondence between the reception number and the affected animal's name.

The owner makes the patient wait in the waiting room after being admitted, and when called by the veterinarian, allows the animal to enter the examination room. A medical image management device 3 is placed above the examination desk in the examination room, and displays image data of the part to be diagnosed (photographed) of the patient animal, test results related to tests performed on the patient animal, etc. . An ultrasonic diagnostic device 2a is also installed in the examination room.

During examination by a veterinarian in the examination room, as necessary, radiographic imaging is performed using a CR imaging device and CR reading device 2d, radiographic imaging is performed using a DR imaging device and DR reading device 2e, and ultrasound imaging is performed using an ultrasound diagnostic device 2a. Photographing, endoscopic image photography with the endoscope 2b, and electrocardiogram recording with the electrocardiogram recording device 2c are performed, and the photographed image data is displayed on the medical image management device 3 and stored in association with patient animal information.

In this way, the image generation device 2 photographs the photographed region of a patient animal as a subject, digitally converts the photographed image to generate image data of the photographed image, records predetermined test results, and generates image data. It is a modality that generates.

The ultrasonic diagnostic device 2a includes an ultrasonic probe (not shown) that outputs ultrasonic waves, and is connected to the ultrasonic probe and converts the ultrasonic waves (echoes) received by the ultrasonic probe into image data of captured images of internal tissues. It has an ultrasonic diagnostic apparatus main body (not shown) that converts. The ultrasonic diagnostic device 2a sends ultrasonic waves into the body from an ultrasonic probe, receives the sound waves (echo signals) reflected on the tissues of the body again with the ultrasonic probe, and generates digital ultrasonic image data according to the echo signals. is generated by the ultrasound diagnostic equipment itself.

A conversion device 21, which is a conversion means (converter) that converts an analog signal into a digital signal, is connected to the ultrasound diagnostic device 2a, and the ultrasound diagnostic device 2a is connected to a communication network via the conversion device 21. 5. By going through the conversion device 21 in this way, even if data in a format that does not conform to the standards (for example, communication protocol) of other external devices connected to the communication network 5 is output from the ultrasound diagnostic device 2a, it can be outputted as appropriate. After conversion, data can be sent and received with an external device connected to the communication network 5.

The endoscope 2b has a small imaging device (both not shown) provided at the tip of a flexible tube, and the imaging device includes, for example, an objective optical system composed of an optical lens, etc. It includes an imaging section disposed at the imaging position of the objective optical system, and an illumination section configured with LEDs (Light Emitting Diodes) and the like to provide illumination necessary for imaging (none of which are shown). The imaging unit includes a solid-state imaging device such as a CCD (Charge Coupled Device) or a CMOS (Complementary Metal-Oxide Semiconductor), and photoelectrically converts incident light into an electrical signal of an amount corresponding to the amount of incident light. The objective optical system is configured to condense the area illuminated by the illumination unit with an optical lens and form an image on the solid-state image sensor included in the image pickup unit, and the light incident on the solid-state image sensor is photoelectrically converted. As a result, image data of the photographed image is output as an electrical signal.

The electrocardiogram recording device 2c detects an electrocardiogram waveform and acquires and records waveform data, and transmits the generated image data (waveform data) to the medical image management device 3.

The CR reading device 2d reads image data from a CR cassette (not shown), which is a radiation image conversion medium in which radiation image information obtained by photographing a region of a patient animal is recorded. The CR cassette has a built-in radiation image conversion plate that includes, for example, a stimulable phosphor sheet that accumulates radiation energy. placed within. When a CR cassette is exposed to radiation, it accumulates an amount of radiation in the stimulable phosphor layer of the stimulable phosphor sheet in accordance with the radiation transmittance distribution of the imaged area, and the stimulable phosphor layer Record radiographic image information of the imaged area.

When a CR cassette in which radiographic image information of an imaging region is recorded is loaded, the CR reader 2d irradiates excitation light onto a stimulable phosphor sheet in the CR cassette loaded into the CR reader 2d, Thereby, the photostimulated light emitted from the sheet is photoelectrically converted, the obtained image signal is A/D converted, and radiation image data of the photographed image is generated. Note that the CR reading device 2d may be an integrated device integrated with the CR imaging device.

The DR reading device 2e is a device that reads image data of a radiation image from a storage section of a radiation image conversion medium in which radiation image information obtained by photographing a region to be imaged is recorded. The DR reading device 2e generates image data of a radiation image according to the X-rays irradiated through the imaged part of the subject.

FIG. 2 is a block diagram of main parts showing the functional configuration of the medical image management device 3. As shown in FIG.
As shown in FIG. 2, the medical image management device 3 includes a control section 31, a storage section 32, an input section 33, a display section 34, a communication section 35, an image DB (Data Base) management section 36, Equipped with. Each part of the medical image management device 3 is connected via a bus 37.

The control unit 31 is composed of a CPU (central processing unit) and a RAM (Random Access Memory), and expands a specified program from among the system programs and application programs stored in the storage unit 32 into the RAM, and The program and the CPU cooperate to execute various processes (including photographing processing and image capturing processing, which will be described later).

Further, the control unit 31 accepts input of patient information of the animal by the operator.
Further, the control unit 31 identifies the type of animal from the affected animal information stored for each affected animal.
Further, the control unit 31 displays an image of the animal on the display unit 34 (a target element screen 343a to be described later) based on the type of animal.

The storage unit 32 is composed of an HDD (Hard Disk Drive), an SSD (Solid State Drive), a semiconductor non-volatile memory, etc., and stores various programs, as well as patient information for each affected animal and images of photographed images. Various types of data are stored in the data, such as site-specific parameters for performing site-specific image processing and objective element-specific parameters for performing objective-element-specific image processing. The various programs include a photographing program for performing photographing processing and an image capturing program for performing image capturing processing, which will be described later.

The input unit 33 includes a keyboard having character input keys, numeric input keys, various function keys, etc., and a pointing device such as a mouse, and receives key presses operated by an operator such as a veterinarian or technician via the keyboard. The signal and the position operation signal from the mouse are output to the control section 31.

The display unit 34 has a display panel such as an LCD (Liquid Crystal Display) or an EL (Electro Luminescence) display, and displays various screens according to instructions of a display signal input from the control unit 31. Note that a touch panel may be formed on the display panel of the display unit 34 as the input unit 33 to receive touch input from an operator and output a touch operation signal to the control unit 31.

The communication unit 35 is configured with a network interface and the like, and transmits and receives information between each device of the image generation device 2 and the reception device 4 connected to the communication network 5 via a switching hub.

The image DB management unit 36 is constituted by an HDD, SSD, etc., and stores image data of photographed images in association with patient animal information as an image DB.
As shown in FIG. 2, the image DB management unit 36 stores the image data of the confirmed image associated with the affected animal information of the affected animal, and the confirmed image area 36a is not associated with the affected animal information of the affected animal. It also includes an undetermined image area 36b that stores image data of an undetermined image.

The reception device 4 is an information processing device for performing reception registration, accounting calculations, insurance point calculations, etc. for patient animals visiting the hospital, and includes a control section consisting of a CPU and RAM, and an operation section consisting of a keyboard, mouse, etc. A storage unit configured with an HDD or the like, a display unit configured with an LCD or the like, and a communication unit that communicates with each device connected to the communication network 5. When receiving an instruction to display a reception input screen from the operation unit, the reception device 4 displays the reception input screen on the display unit through software processing in cooperation with the CPU and a program stored in the storage unit. When reception information (reception number + patient animal name) is input by the input unit via this reception input screen, a patient information list of the accepted patient animals is created (updated) and stored in the storage unit, and the communication unit sends the information as appropriate. It is transmitted to the medical image management device 3.

Next, the operation of the medical image management system 1 will be explained with reference to FIGS. 3 to 7.
The operator selects a target element in advance on the target element presetting screen 341 shown in FIG. It is possible to do so.
The objective element pre-setting screen 341 can be opened by activating a setting tool installed in the medical image management device 3.

The target element is a location or viewpoint that an operator such as a veterinarian wants to see in the image generated by the image generation device 2 in order to make a diagnosis. For example, the parts of the head you want to see include the tip of the nose and the head, the cervical vertebrae and neck, and the thoracic vertebrae and thoracic region of the thoracic region. In the abdomen, it is the upper abdomen, lower abdomen, etc. In the pelvis, it is the pelvis, hip joint, lumbar vertebrae, etc., and in the upper limbs, it is the shoulders and arms (scapula, humerus, elbow joint), etc. In the lower limbs, these include the femoral system (femur, knee joint, lower leg), in the hands, the carpal bones, phalanges, etc., and in the feet, the tarsal bones, calcaneus, etc. Bones, etc.
In addition, for example, if a disease name is mentioned and a specific disease is suspected, the disease name is set as a target element, and image processing specialized for the set disease name is performed. Furthermore, pregnancy is also included as a point of view.
The above objective elements are just some examples, and the objective elements include the imaging method (imaging direction; abdomen, back, side), the part that the veterinarian or other operator wants to see, and the body size of the affected animal (small, medium, large, (extra large), body weight, sex of the affected animal, and age of the affected animal (second setting step).

When presetting the objective element, the operator starts the setting tool, opens the objective element presetting screen 341 shown in FIG. 3, selects "Specify objective element" in the objective element setting 341a, and selects the Select the desired objective element from the list. In the example shown in Figure 3,
"Chest front" is selected.
Then, the control unit 31 stores the input information of the target element in the storage unit 32.

Moreover, the setting of the target element may be performed before photographing by the image generation device 2, or may be performed during photographing processing to be described later, or may be performed at any timing. If the objective element is not set in advance, the operator starts the setting tool, opens the objective element pre-setting screen 341 shown in FIG. 3, and selects "Do not specify objective element" in the objective element setting 341a. .

Further, since the control unit 31 stores the objective element corresponding to the objective element-based image processing performed last time in the storage unit 32, it can set in advance that the objective element specified last time will be used. In this case, the operator starts the setting tool, opens the objective element pre-setting screen 341 shown in FIG. 3, and selects "Use the last specified objective element" in the objective element setting 341a.
The target elements specified in the past may be stored for each veterinarian who is the operator of the medical image management device 3, patient animals photographed by the image generation device 2, or each medical image management device 3. In this case, optimal objective elements corresponding to the veterinarian, the patient, and the medical image management device 3 can be set.

Further, by pressing the setting button 341b on the objective element pre-setting screen 341 shown in FIG. 3, it is possible to set a parameter set for each objective element corresponding to each objective element. The objective element-specific parameters are parameters for gradation processing, bone and soft part correction processing, etc., used when performing objective element-specific image processing corresponding to each objective element. In the objective element parameter set setting, there are multiple objective element parameter sets in which objective element parameter values are input in advance, and by selecting one of them, multiple objective element parameter values can be set at once. Can be set to .

Further, by pressing the edit button 341c on the objective element pre-setting screen 341 shown in FIG. 3, the objective element-specific parameter editing screen 342 shown in FIG. 4 is opened, and the objective element-specific parameters corresponding to each objective element can be edited. I can do it. Specifically, the user presses the objective element displayed on the objective element-specific parameter editing screen 342 and inputs each parameter value.

FIG. 5 is a flowchart showing the photographing process, which is the flow from patient reception to image reception.
In this embodiment, a case will be described in which DR imaging is performed in the medical image management system 1.
In the medical image management device 3, for example, when an operator such as a veterinarian or a technician inputs an instruction to execute imaging processing through the input unit 33, the control unit 31 causes the control unit 31 to perform an instruction to perform an imaging process stored in the storage unit 32. Execute the shooting process according to the shooting program.

In advance, a patient animal to be subjected to DR imaging is placed on an imaging table of a DR imaging apparatus in a radiography room of a medical facility. In addition, in the medical image management device 3, all patient animal information such as patient animals subjected to DR imaging is received from the reception device 4 or generated in response to input from the operator via the input section 33, and is stored in the storage section 32. It is assumed that

In the photographing process shown in FIG. 5, first, the control unit 31 receives a click input of the patient reception button from the operator via the input unit 33 (step S1).
Then, the control unit 31 receives, from the operator via the input unit 33, a selective input of the patient animal information of the patient animal to be subjected to DR imaging from among the patient animal information stored in the storage unit 32, and registers it (step S2; reception step). At this time, the control section 31 functions as a reception section.
Then, the control unit 31 identifies the type of affected animal based on the affected animal information (step S3; identification step). At this time, the control section 31 functions as a specifying section. Note that in step S3, the control unit 31 may specify not only the type of the affected animal, but also the physique, weight, etc. of the affected animal.

Then, the control unit 31 receives a click input of the medical examination start button from the operator via the input unit 33 (step S4). Then, the control unit 31 displays on the display unit 34 a patient screen that displays the image data of the radiographic image obtained by DR imaging (step S5). It is assumed that the patient animal screen includes a photography preparation button for transitioning to the image data capture state for DR photography.

Then, the control unit 31 receives a click input of the photographing preparation button from the operator via the input unit 33 (step S6).

Then, the control unit 31 receives a DR imaging operation input from the operator via the input unit 33, transmits the operation information to the DR imaging device via the communication unit 35, and performs DR imaging (step S7). The DR reading device 2e automatically detects the X-rays emitted from the DR imaging device, generates image data of one radiation image, and transmits the image data to the medical image management device 3. Then, the control unit 31 receives the photographed image data from the DR reading device 2e via the communication unit 35, and stores it in the undefined image area 36b of the image DB management unit 36 (step S8).

Then, the control unit 31 executes the image capturing process according to the image capturing program stored in the storage unit 32 (step S9).
FIG. 6 is a flowchart showing image capture processing.

First, the control unit 31 identifies a region from the outline, shape, etc. of the imaging target in the image data of the captured image generated by the DR reading device 2e (step S21).
Then, the control unit 31 reads out the site-specific parameters corresponding to the site identified in step S21 from the storage unit 32 (step S22).
Then, the control unit 31 determines region-specific image processing conditions based on the region-specific parameters read in step S22 (step S23).
Then, the control unit 31 performs region-specific image processing such as gradation processing to adjust image contrast, density adjustment processing, frequency processing to adjust sharpness, etc. to the image data under the region-specific image processing conditions determined in step S23. is applied to generate a first image (step S24).
Then, the control unit 31 displays the first image generated in step S24 on the display unit 34 (step S25).

Then, the control unit 31 determines whether the target element has been set in advance (step S26).
If the target element has not been set in advance (step S26; NO), the control unit 31 receives input of the target element from the operator via the input unit 33, and determines whether the target element has been specified ( Step S27).

When setting the target element, the control unit 31 displays the target element selection screen 343 shown in FIG. 7 on the display unit 34 (display control step). At this time, the control section 31 functions as a display control section. Then, the control unit 31 receives input from the operator via the input unit 33 (selection step).
The control unit 31 selects the type (physique, weight, etc.) of the affected animal (animal) specified in step S3 (identifying step) on the objective element screen 343a (image processing parameter selection screen) in the objective element selection screen 343. Based on this, an image of the animal and a target element name corresponding to each target element are displayed (display control step). An image of an animal is a schematic diagram of an animal or the like. In the example shown in FIG. 7, the type of animal is a dog, and the animal image is a schematic diagram of a dog.
Note that the objective element screen 343a is displayed when the type of animal identified in step S3 (identifying step) is "cat", FIG. 8 when it is "bird", FIG. 9 when it is "other", and FIG. 10. be done. The animal image displayed on the target element screen 343a is switched depending on the type of animal.
Furthermore, although not shown, by displaying an image of the animal based on the animal's physique, it is possible to switch between "large dog,""mediumdog," and "small dog," even for dogs of the same type, for example.
Further, by pressing the target element in the target element screen 343a, the target element can be selected. In the example shown in FIG. 7 ("dog"), "head", which is part information in the animal image, is selected. In the example shown in FIG. 10 ("Others"), the imaging method and physique can be selected.
Further, by pressing the selection clear button 343b, the selection of the target element can be cleared.
Furthermore, by pressing the cancel button 343c, the setting of the target element can be canceled and the target element selection screen 343 can be closed.
Further, by pressing the OK button 343d, the setting of the target element is confirmed, the information on the target element is stored in the storage unit 32, and the target element selection screen 343 can be closed.
Further, in the examples of FIGS. 7 to 9, the images of animals are schematic diagrams, but they may also be photographs, icons, or the like. The image is not limited to the above example as long as it is an image that allows the type of animal to be confirmed by looking at the image of the animal.
Furthermore, by switching the tabs (“dog,” “cat,” “bird,” and “other”) on the objective element screen 343a, the animal image can be switched.

If the target element is not specified (step S27; NO), the control unit 31 displays the image on the patient screen of the display unit 34 (step S28). The image in this case is the first image.

Further, if the target element is set in advance (step S26; YES) or if the target element is specified (step S27; YES), the control unit 31 controls the target element to correspond to the set or designated target element. Parameters for each objective element (image processing parameters) are read from the storage unit 32 (step S29; read step). In other words, the objective element-specific parameters correspond to the type (physic, weight, etc.) of the affected animal identified in step S3.
Then, the control unit 31 determines image processing conditions for each objective element (image processing conditions) based on the parameters for each objective element read in step S29 (step S30; determination step).
Then, the control unit 31 performs objective element-specific image processing on the image data of the first image under the objective element-specific image processing conditions determined in step S30, and generates a second image (processed medical image) (step S31; generation step), the process moves to step S28. In this case, the image displayed on the patient screen of the display unit 34 is the second image.

Then, the control unit 31 receives a change in the objective element from the operator via the input unit 33, and determines whether the objective element has been changed (step S32).
If the objective element is not changed (step S32; NO), the control unit 31 displays the image on the patient screen (step S33), ends the image capturing process, and returns to the photographing process shown in FIG. 5. The image displayed in this case is the image displayed in step S28.

If the target element has been changed (step S32; YES), the control unit 31 executes steps S34 to S36 similar to steps S29 to S31 (change step), and proceeds to step S33. The image displayed in this case is the image generated by subjecting the target element-based image processing to step S36.

Returning to the photographing process shown in FIG. 5, the control unit 31 links the image data of the image displayed in step S43 of the image capture process shown in FIG. 6 with the affected animal information selected in step S2 (step S10). ), the associated image data and patient animal information are stored in the confirmed image area 36a of the image DB management unit 36. Then, the control unit 31 displays the image data and patient animal information linked in step S10 on the patient animal screen (step S11), and ends the photographing process. The processing of steps S7 to S11 is repeated for the number of images to be photographed.

(effect)
As described above, according to the present embodiment, the program of the medical image management system 1 includes the reception step (S2 ), a specifying step (S3) for specifying the type of animal based on the patient information, and a display control step (S27) for displaying an image of the animal on the image processing parameter selection screen based on the type of animal.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals. Specifically, the image of the animal makes it easier to visually recognize the target animal on the target element screen 343a (image processing parameter selection screen) in the target element selection screen 343, thereby making it easier to select image processing parameters. becomes easier.

Further, the specifying step (S3) further specifies the physique of the animal based on the patient animal information, and the display control step (S27) displays an image of the animal on the image processing parameter selection screen based on the physique of the animal.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals. Specifically, the image of the animal makes it easier to visually recognize the target animal on the target element screen 343a (image processing parameter selection screen) in the target element selection screen 343, thereby making it easier to select image processing parameters. becomes easier.

The program of the medical image management system 1 also includes a reading step (S29) of reading out image processing parameters corresponding to the type of animal from the storage section, a determining step (S30) of determining image processing conditions based on the image processing parameters, and a step (S30) of determining image processing conditions based on the image processing parameters. The control unit 31 is caused to execute a generation step (S31) of performing image processing on the image data of the medical image under the processing conditions to generate a processed medical image.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals.

Further, the identification step (S3) further specifies the physique of the animal based on the patient animal information, and the program of the medical image management system 1 reads out the image processing parameters corresponding to the physique of the animal from the storage unit (S29); The control unit 31 performs a determination step (S30) of determining image processing conditions based on image processing parameters, and a generation step (S31) of performing image processing on image data of a medical image under the image processing conditions to generate a processed medical image. have it executed.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals.

Further, in the identification step (S3), the weight of the animal is identified based on the patient animal information, and the program of the medical image management system 1 includes a readout step (S29) in which image processing parameters corresponding to the weight of the animal are read out from the storage unit, and the weight of the animal is A determining step (S30) for determining image processing conditions based on the processing parameters, and a generating step (S31) for performing image processing on image data of a medical image using the image processing conditions to generate a processed medical image, are performed in the control unit 31. Let it run.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals. Specifically, the image of the animal makes it easier to visually recognize the target animal on the target element screen 343a (image processing parameter selection screen) in the target element selection screen 343, thereby making it easier to select image processing parameters. becomes easier.

The program of the medical image management system 1 also includes a selection step (S27) for selecting animal part information from an animal image, a reading step (S29) for reading image processing parameters corresponding to the part information from the storage unit, and an image processing parameter The control unit 31 causes the control unit 31 to execute a determining step (S30) of determining image processing conditions based on the image processing conditions, and a generating step (S31) of generating a processed medical image by performing image processing on the image data of the medical image under the image processing conditions. .
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals.

The medical image management device 3 also includes a reception unit (control unit 31) that accepts input of animal patient information by an operator, and an identification unit (control unit 31) that identifies the type of animal based on the patient animal information. The apparatus includes a display control section (control section 31) that displays an image of the animal on an image processing parameter selection screen based on the type of animal.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals. Specifically, the image of the animal makes it easier to visually recognize the target animal on the target element screen 343a (image processing parameter selection screen) in the target element selection screen 343, thereby making it easier to select image processing parameters. becomes easier.

The medical image management system 1 also includes a reception unit (control unit 31) that accepts input of animal patient information by an operator, and an identification unit (control unit 31) that identifies the type of animal based on the patient animal information. The apparatus includes a display control section (control section 31) that displays an image of the animal on an image processing parameter selection screen based on the type of animal.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals. Specifically, the image of the animal makes it easier to visually recognize the target animal on the target element screen 343a (image processing parameter selection screen) in the target element selection screen 343, thereby making it easier to select image processing parameters. becomes easier.

In addition, the medical image management method includes a reception step in which an operator receives input of animal patient information, a identification step for identifying the type of animal based on the patient information, and an image of the animal based on the type of animal. A display control step of displaying on an image processing parameter selection screen is included.
Therefore, it is possible to more appropriately select image processing parameters when processing medical images for animals. Specifically, the image of the animal makes it easier to visually recognize the target animal on the target element screen 343a (image processing parameter selection screen) in the target element selection screen 343, thereby making it easier to select image processing parameters. becomes easier.

(Other embodiments)
Note that the description in the above embodiment is an example of a suitable medical image management device, medical image management method, and program according to the present invention, and the present invention is not limited thereto.

For example, in the embodiment described above, the setting of the objective element is performed by input from the operator via the input unit 33, or the objective element corresponding to the previously performed image processing by objective element is set. It is not limited to this.
The control unit 31 may determine the selection of the target element using artificial intelligence. The control unit 31 accumulates data by associating the imaged region identified in the medical image with the objective element input by the operator and storing it in the storage unit 32 or an external storage device. Then, the accumulated data is learned to construct a learning model regarding the relationship between the imaged body part and the target element. The control unit 31 uses the constructed learning model to determine the optimal target element based on the imaging site identified in the medical image.
Therefore, the optimum objective element can be automatically set without the operator having to input the objective element.

Further, in step S25 of the image capture process in the above embodiment, the control unit 31 displays the first image generated in step S24 on the display unit 34, but the present invention is not limited to this. The control unit 31 does not need to display the first image on the patient screen.

Further, in the above embodiment, when presetting a target element, the operator opens the target element presetting screen 341 shown in FIG. 3, selects "specify target element" in the target element setting 341a, Although the desired objective element is selected from the drop-down list, the present invention is not limited to this. When selecting a target element, the target element selection screen 343 shown in FIG. 7 may be opened and input may be made.

Further, the detailed configuration and detailed operation of each part constituting the medical image management system 1 in the above embodiment can be changed as appropriate without departing from the spirit of the present invention.

1 Medical image management system 2 Image generation device 2a Ultrasound diagnostic device 2b Endoscope 2c Electrocardiogram recording device 2d CR reading device 2e DR reading device 3 Medical image management device 31 Control unit (reception unit, identification unit, display control unit)
32 Storage section 33 Input section 34 Display section 35 Communication section 36 Image DB management section 4 Reception device

Claims (9)

In the computer of the medical image management device,
a reception step for accepting input of patient information of the animal by the operator;
an identifying step of identifying the type of the animal based on the affected animal information;
a display control step of displaying an image of the animal on an image processing parameter selection screen based on the type of the animal;
A program to run. The identifying step further identifies the physique of the animal based on the affected animal information;
The program according to claim 1, wherein the display control step displays the image of the animal on an image processing parameter selection screen based on the physique of the animal. a reading step of reading image processing parameters corresponding to the type of animal from the storage unit;
a determining step of determining image processing conditions based on the image processing parameters;
a generation step of performing image processing on the image data of the medical image under the image processing conditions to generate a processed medical image;
The program according to claim 1, which causes the computer to execute. The identifying step further identifies the physique of the animal based on the affected animal information;
a reading step of reading image processing parameters corresponding to the physique of the animal from the storage unit;
a determining step of determining image processing conditions based on the image processing parameters;
a generation step of performing image processing on the image data of the medical image under the image processing conditions to generate a processed medical image;
The program according to claim 1, which causes the computer to execute. The identifying step identifies the weight of the animal based on the patient information;
a reading step of reading image processing parameters corresponding to the body weight of the animal from the storage unit;
a determining step of determining image processing conditions based on the image processing parameters;
a generation step of performing image processing on the image data of the medical image under the image processing conditions to generate a processed medical image;
The program according to claim 1, which causes the computer to execute. a selection step of selecting animal part information from the animal image;
a reading step of reading image processing parameters corresponding to the region information from a storage unit;
a determining step of determining image processing conditions based on the image processing parameters;
a generation step of performing image processing on the image data of the medical image under the image processing conditions to generate a processed medical image;
The program according to claim 1, which causes the computer to execute. a reception section that accepts input of animal patient information by an operator;
an identification unit that identifies the type of animal based on the affected animal information;
a display control unit that displays an image of the animal on an image processing parameter selection screen based on the type of the animal;
A medical image management device having: a reception section that accepts input of animal patient information by an operator;
an identification unit that identifies the type of animal based on the affected animal information;
a display control unit that displays an image of the animal on an image processing parameter selection screen based on the type of the animal;
A medical image management system equipped with a reception step for accepting input of patient information of the animal by the operator;
an identifying step of identifying the type of the animal based on the affected animal information;
a display control step of displaying an image of the animal on an image processing parameter selection screen based on the type of the animal;
A medical image management method including.

Images