JP6930638B2 - Dynamic analysis device, dynamic analysis program, dynamic analysis method and control device - Google Patents

Description

The present invention relates to a dynamic analysis device, a dynamic analysis program , a dynamic analysis method, and a control device .

In contrast to conventional still image photography and diagnosis using radiation on a subject using a film / screen or a brilliant phosphor plate, a dynamic image of the subject is taken using a semiconductor image sensor such as an FPD (flat panel detector). A dynamic analysis system that analyzes the obtained dynamic image and provides it for diagnosis is known. The dynamic analysis system includes a photographing device that performs dynamic photography using an FPD, a console for controlling the photographing device and displaying the captured image for confirmation, and a plurality of frame images obtained by the imaging. It is configured to include an analysis device that performs analysis based on the above and a display device for displaying the analysis result (see FIG. 1). In the hospital, from imaging to diagnosis is performed in the flow of (1) dynamic imaging step using an imaging device and console, (2) analysis step using an analysis device, and (3) diagnostic step using a display device. ..

(1) Dynamic imaging step In the dynamic imaging step, the imaging engineer performs positioning so that the part to be inspected is placed at a predetermined position of the imaging device in the imaging room, confirms the body position, and prepares for exposure. Next, the shooting conditions are set, the exposure switch is pressed (dynamic shooting), the image is confirmed, and the like from the console in the operation room.
In the case of dynamic chest radiography, the respiratory condition at the time of radiography differs depending on the type of analysis and the like. For example, when analyzing the ventilation function, take a picture in a resting state, and when analyzing the pulmonary blood flow function and the state of the heart, take a picture in a breath-holding state, and analyze the maximum respiratory volume as one of the ventilation functions. In that case, take a picture in a deep breathing state. Therefore, when performing a plurality of types of analysis, it is necessary to take pictures under a plurality of respiratory conditions. Further, for example, as described in Patent Document 1, depending on the type of analysis, it may be necessary to take images in a plurality of respiratory states even in one analysis. When it is necessary to take a picture of a plurality of respiratory states for one patient, generally, the patient is instructed to take a picture of the respiratory state and the picture is taken for each respiratory state. That is, posture confirmation, exposure preparation, setting of imaging conditions, dynamic imaging (exposure), image confirmation, etc. are repeated for each respiratory state.
The frame image acquired by the dynamic photography is transmitted to the analyzer via the console.

(2) Analysis step In the analysis step, the analysis device first performs analysis processing on the dynamic image transmitted from the console using the default parameter group or the parameter group set by the operator such as a camera operator, and displays the dynamic image. The analysis result is displayed on the display device in response to the request from the device. Operators such as camera operators and doctors wait for the analysis process to finish, check the analysis results, and if the desired analysis results are not obtained, adjust at least a part of the parameter group for analysis. Have the device execute the analysis process again. That is, parameter adjustment, reanalysis instruction, waiting until the reanalysis result is obtained, and confirmation of the analysis result are repeated until the desired analysis result is obtained. When the desired analysis result is obtained, an operator such as a camera operator or a doctor gives an instruction to save the analysis result in the storage unit. As a result, the analysis result is stored in the storage unit of the analysis device or the like.

(3) Diagnosis step In the diagnosis step, the doctor selects the dynamic image and the analysis result of the test to be diagnosed from the captured dynamic image and the analysis result and displays them on the display device to perform the diagnosis.

Japanese Unexamined Patent Publication No. 2012-115581

However, as described in Patent Document 1, when imaging is performed for each respiratory state, as shown in FIG. 8, confirmation of the body position, preparation for exposure, setting of imaging conditions, and the like are repeated for each respiratory state. It takes a long time to complete all the imaging for the patient.

An object of the present invention is to reduce the time required for dynamic imaging of the chest under multiple respiratory conditions.

In order to solve the above problems, the dynamic analysis device of the present invention is used.
An acquisition unit that acquires dynamic image data of the chest including multiple frame image data obtained by radiography, and an acquisition unit.
A feature amount calculation unit that extracts a lung field region from the dynamic image data and calculates a feature amount related to the extracted lung field region,
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. A selection unit that selects two sections, and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. The dynamic analysis department that executes the analysis and
An output unit that outputs the analysis results obtained by the dynamic analysis, and
It is characterized by having.

In addition, the dynamic analysis program of the present invention
A dynamic analysis program that performs dynamic analysis on chest dynamic image data including multiple frame image data obtained by radiography.
On the computer
The process of receiving the dynamic image data and
A process of extracting a lung field region from the dynamic image data and calculating a feature amount related to the extracted lung field region, and
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. Processing to select 2 sections and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. The process of performing the analysis and
Processing to output the analysis result obtained by the dynamic analysis and
Is characterized by executing.

Further, the dynamic analysis method of the present invention is:
It is a dynamic analysis method that performs dynamic analysis on the dynamic image data of the chest including multiple frame image data obtained by radiography.
The process of receiving the dynamic image data and
A step of extracting a lung field region from the dynamic image data and calculating a feature amount related to the extracted lung field region, and
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. The process of selecting 2 sections and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. The process of performing the analysis and
A step of outputting the analysis result obtained by the dynamic analysis and
It is characterized by having.
Further, the control device of the present invention is
It is a control device that controls an imaging device that performs radiography.
An acquisition unit that acquires dynamic image data of the chest including multiple frame image data obtained by radiography, and an acquisition unit.
A feature amount calculation unit that extracts a lung field region from the dynamic image data and calculates a feature amount related to the extracted lung field region,
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. A selection unit that selects two sections, and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. A transmission unit that transmits frame image data corresponding to the first section and frame image data corresponding to the second section to the dynamic analysis device that executes the analysis.
It is characterized by having.

According to the present invention, it is possible to shorten the time required for dynamic imaging of the chest under a plurality of respiratory conditions.

It is a figure which shows the whole configuration example of a dynamics analysis system. It is a block diagram which shows the functional structure of a console. It is a block diagram which shows the functional structure of an analyzer. It is a block diagram which shows the functional structure of a display device. It is a flowchart which shows the process flow of a dynamics analysis system. It is a flowchart of the effective section selection process executed by the analysis apparatus in step S2 of FIG. It is a figure which shows an example of the screen displayed in step S204 of FIG. It is a figure which shows the conventional work flow at the time of performing dynamic photography in a plurality of respiratory states.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the scope of the invention is not limited to the illustrated examples.

[Structure of dynamic analysis system 100]
First, the configuration will be described.
FIG. 1 shows an example of the overall configuration of the dynamic analysis system 100 according to the present embodiment.
As shown in FIG. 1, the dynamic analysis system 100 includes an imaging device 1A provided in the general imaging room R1, a console 2A for controlling the imaging device 1A, an imaging device 1B provided in the emergency room R2, and the imaging device 1B. It is configured to include a console 2B for controlling the photographing device 1B, an analysis device 3, and display devices 4A to 4C. The photographing device 1A and the console 2A, and the photographing device 1B and the console 2B are connected by a communication cable or the like, respectively. Further, the console 2A and the analysis device 3, the console 2B and the analysis device 3, each of the display devices 4A to 4C and the analysis device 3 are connected so as to be able to transmit and receive data via a communication network such as a LAN (Local Area Network). Has been done.

[Structure of imaging devices 1A and 1B]
The imaging device 1A is an imaging means for photographing the dynamics of the chest having a periodicity (cycle), such as morphological changes of lung expansion and contraction due to respiratory movement, and heartbeat, and is a radiation source 11, radiation. It is configured to include an irradiation control device 12 and a radiation detection unit 13. In dynamic photography, radiation such as X-rays is pulsed and repeatedly irradiated at predetermined time intervals (pulse irradiation), or low dose rate is continuously irradiated (continuous irradiation). By doing so, it means to acquire a plurality of images showing the dynamics. A series of images obtained by dynamic photography is called a dynamic image. Further, each of the plurality of images constituting the dynamic image is called a frame image. In the following embodiment, a case where dynamic imaging is performed by pulse irradiation will be described as an example.

The radiation source 11 is arranged at a position facing the radiation detection unit 13 with the subject M interposed therebetween, and irradiates the subject M with radiation (X-rays) under the control of the radiation irradiation control device 12.
The radiation irradiation control device 12 is connected to the console 2A, and controls the radiation source 11 based on the radiation irradiation conditions input from the console 2A to perform radiography. The radiation irradiation conditions input from the console 2A are, for example, pulse rate, pulse width, pulse interval, number of shooting frames per shooting, X-ray tube current value, X-ray tube voltage value, additional filter type, and the like. .. The pulse rate is the number of irradiations per second, which is consistent with the frame rate described later. The pulse width is the irradiation time per irradiation. The pulse interval is the time from the start of one irradiation to the start of the next irradiation, and is consistent with the frame interval described later.

The radiation detection unit 13 is composed of a semiconductor image sensor such as an FPD, and is provided so as to face the radiation source 11 with the subject M interposed therebetween. The radiation detection unit 13 has, for example, a glass substrate or the like, and detects and detects radiation emitted from the radiation source 11 at a predetermined position on the substrate and transmitted at least through the subject M according to the intensity thereof. A plurality of detection elements (pixels) that convert and store an electric signal are arranged in a matrix. Each pixel is configured to include a switching unit such as a TFT (Thin Film Transistor). The radiation detection unit 13 controls the switching unit of each pixel based on the image reading condition input from the console 2A to switch the reading of the electric signal stored in each pixel, and is stored in each pixel. Image data is acquired by reading the electric signal. This image data is a frame image. Then, the radiation detection unit 13 outputs the acquired frame image to the console 2A. The image reading conditions are, for example, a frame rate, a frame interval, a pixel size, an image size (matrix size), and the like. The frame rate is the number of frame images acquired per second, which is consistent with the pulse rate. The frame interval is the time from the start of one frame image acquisition operation to the start of the next frame image acquisition operation, and is consistent with the pulse interval.

Here, the radiation irradiation control device 12 and the radiation detection unit 13 are connected to each other and exchange synchronization signals with each other to synchronize the radiation irradiation operation and the image reading operation.

The imaging device 1B is configured to include a radiation source 11, a radiation irradiation control device 12, and a radiation detection unit 13 in the same manner as the imaging device 1A described above. However, the radiation irradiation control device 12 and the radiation detection unit 13 of the imaging device 1B are connected to the console 2B, and the radiation irradiation control device 12 controls the radiation source 11 based on the radiation irradiation conditions input from the console 2B. Perform radiography. Further, the radiation detection unit 13 controls the switching unit of each pixel based on the image reading condition input from the console 2B, and acquires and acquires the image data by reading the electric signal accumulated in each pixel. The image data of the frame image is output to the console 2B.

[Console 2A and 2B configuration]
The console 2A is provided in an operation room near the general imaging room R1 and outputs radiation irradiation conditions and image reading conditions to the imaging device 1A to control radiation imaging and radiation image reading operations by the imaging device 1A, as well as the imaging device. The dynamic image acquired by 1A is displayed for confirmation by the photographing engineer.
As shown in FIG. 2, the console 2A includes a control unit 21, a storage unit 22, an operation unit 23, a display unit 24, and a communication unit 25, and each unit is connected by a bus 26.

The control unit 21 is composed of a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like. The CPU of the control unit 21 reads out the system program and various processing programs stored in the storage unit 22 in response to the operation of the operation unit 23, expands them in the RAM, and operates each unit of the console 2A according to the expanded programs. In addition, the irradiation operation and the reading operation of the photographing apparatus 1A are centrally controlled.

The storage unit 22 is composed of a non-volatile semiconductor memory, a hard disk, or the like. The storage unit 22 stores data such as parameters or processing results necessary for executing processing by various programs and programs executed by the control unit 21. Various programs are stored in the form of a readable program code, and the control unit 21 sequentially executes operations according to the program code.
In addition, the storage unit 22 stores the irradiation conditions and the image reading conditions corresponding to the imaging site (here, the chest). Further, the storage unit 22 stores shooting order information transmitted from a RIS (Radiology Information System) or the like (not shown). The imaging order information includes patient information, examination information (examination ID, examination target site (here, chest)), analysis type (for example, ventilation analysis, pulmonary blood flow analysis, measurement of maximum ventilation volume, etc.), and data attributes ( Emergency, general outpatient, ward follow-up), etc.) are included.

The operation unit 23 is configured to include a keyboard equipped with cursor keys, number input keys, various function keys, and a pointing device such as a mouse, and controls instruction signals input by key operations on the keyboard or mouse operations. Output to 21. Further, the operation unit 23 may include a touch panel on the display screen of the display unit 24, and in this case, the operation unit 23 outputs an instruction signal input via the touch panel to the control unit 21. Further, the operation unit 23 is provided with an exposure switch for instructing the radiation irradiation control device 12 to perform dynamic imaging.

The display unit 24 is composed of a monitor such as an LCD (Liquid Crystal Display) or a CRT (Cathode Ray Tube), and displays input instructions, data, and the like from the operation unit 23 according to instructions of display signals input from the control unit 21. do.

The communication unit 25 includes a LAN adapter, a modem, a TA (Terminal Adapter), and the like, and controls data transmission / reception with the analysis device 3 and the like connected to the communication network.

The console 2B is provided in the operation room near the emergency room R2. Similar to the console 2A, the console 2B includes a control unit 21, a storage unit 22, an operation unit 23, a display unit 24, and a communication unit 25, and each unit is connected by a bus 26. The console 2B centrally controls the operation of each part of the console 2B, the irradiation operation of the photographing apparatus 1B, and the reading operation.

[Structure of analysis device 3]
The analysis device 3 receives the dynamic image transmitted from the console 2A and the console 2B, analyzes the received dynamic image, displays the analysis result according to the request of the display devices 4A to 4C, and performs re-analysis. do. In the present embodiment, the analysis device 3 analyzes the ventilation function, the pulmonary blood flow function, and the like based on the dynamic image of the chest.
As shown in FIG. 3, the analysis device 3 includes a control unit 31, a storage unit 32, an operation unit 33, a display unit 34, and a communication unit 35, and each unit is connected by a bus 36.

The control unit 31 is composed of a CPU, RAM, and the like. The CPU of the control unit 31 reads out the system program and various processing programs stored in the storage unit 32 and expands them in the RAM in response to the operation of the operation unit 33, and according to the expanded program, each unit of the analysis device 3 Centrally control the operation of. In addition, the control unit 31 executes a dynamic image reception process, an effective section selection process, and an analysis process, which will be described later, in cooperation with the program. Further, the control unit 31 causes the display unit 34 or the display devices 4A to 4C to display the analysis result in response to the request of the operation unit 33 or the display devices 4A to 4C. The control unit 31 functions as a feature amount calculation unit, a section selection unit, a setting unit, and a deletion unit.

The storage unit 32 is composed of a non-volatile semiconductor memory, a hard disk, or the like. The storage unit 32 stores data such as parameters or processing results required for executing processing by various programs or programs. These various programs are stored in the form of a readable program code, and the control unit 31 sequentially executes an operation according to the program code.
In addition, the storage unit 32 contains a list showing patient information, examination information, and status (for example, progress status such as reception, analysis processing, and analysis completion) related to each dynamic image that has started reception from the console 2A or 2B. Information is stored. Further, the storage unit 32 stores the analysis result in association with the dynamic image.

The operation unit 33 is configured to include a keyboard equipped with cursor keys, number input keys, various function keys, and a pointing device such as a mouse, and controls an instruction signal input by key operation on the keyboard or mouse operation. Output to 31. Further, the operation unit 33 may include a touch panel on the display screen of the display unit 34, and in this case, the operation unit 33 outputs an instruction signal input via the touch panel to the control unit 31.

The display unit 34 is composed of a monitor such as an LCD or a CRT, and performs various displays according to an instruction of a display signal input from the control unit 31.

The communication unit 35 includes a LAN adapter, a modem, a TA, and the like, and controls data transmission / reception with each device connected to the communication network. The communication unit 35 functions as a transmission unit.

[Configuration of display devices 4A to 4C]
As shown in FIG. 4, the display devices 4A to 4C are configured to include a control unit 41, a storage unit 42, an operation unit 43, a display unit 44, a communication unit 45, and the like, and each unit is connected by a bus 46. The display devices 4A to 4C are provided in a medical examination room or the like, and acquire a dynamic image and its analysis result from the analysis device 3 according to an operation of a camera operator, a doctor, or the like and display them on a viewer screen. Further, the display devices 4A to 4C display the process designation screen described later in response to the instruction from the operation unit 43, accept the parameter adjustment in response to the input from the operation unit 43, and perform reanalysis with the adjusted parameter. Instruct the analyzer 3.

[Processing flow of dynamic analysis system 100]
Next, the processing flow in the dynamic analysis system 100 will be described. FIG. 5 is a flowchart showing a processing flow of the dynamic analysis system 100.

First, dynamic imaging is performed by the imaging device 1A and the console 2A of the general imaging room R1 or the imaging device 1B and the console 2B of the emergency room R2 (step S1).
For example, when the subject M is an emergency patient, dynamic imaging is performed by the imaging device 1B and the console 2B in the emergency room R2. When the subject M is not an emergency patient, dynamic imaging is performed by the imaging device 1A and the console 2A in the general imaging room R1.
Specifically, the camera operator selects the shooting order information related to the next inspection from the shooting order information list screen displayed on the display unit 24 of the console 2A or 2B by the operation unit 23, and the inspection target part (here, here). , Chest) and type of analysis (eg, ventilation analysis, pulmonary blood flow analysis, measurement of maximum ventilation, etc.). Next, the camera operator positions the patient (subject M) so that the examination target site is arranged at a predetermined position on the imaging device 1A or 1B, confirms the patient's position, and prepares for exposure. Next, the camera operator sets the shooting conditions and presses the exposure switch (dynamic shooting) from the operation unit 23 of the console 2A or 2B, and is acquired by the shooting device 1A or 1B by the dynamic shooting and displayed on the display unit 24. Check the image, etc.

Here, for example, when performing multiple types of analysis (for example, ventilation analysis, pulmonary blood flow analysis, measurement of maximum ventilation volume, etc.), when it is necessary to photograph a plurality of respiratory states for one patient, conventionally. Was photographed for each respiratory condition (see FIG. 8). That is, for each respiratory state, confirmation of the patient's position, preparation for exposure, setting of imaging conditions, dynamic imaging (exposure), image confirmation, and the like were repeated. Therefore, it took a long time to complete all the imaging for one patient.

In the present embodiment, when it is necessary to take a picture of a plurality of respiratory states, a single dynamic picture is taken including a plurality of different respiratory states. That is, after confirming the patient's position, preparing for exposure, and setting the imaging conditions, the camera operator instructs the patient on the initial respiratory state and presses the exposure switch on the console 2A or 2B. The control unit 21 controls the imaging device 1A or 1B in response to the pressing of the exposure switch to start imaging. After a predetermined time has passed from the start of imaging, the imaging engineer instructs the patient to have different respiratory conditions. When the shooting under all necessary breathing conditions is completed, the camera operator releases the exposure switch to stop the shooting and check the image. When the operation unit 23 inputs an instruction to take a picture, the control unit 21 gives each of the acquired frame images an identification ID for identifying a dynamic image, patient information, examination information, irradiation conditions, and an image. Information such as reading conditions, a number indicating the shooting order (frame number), and console identification information is attached and transmitted from the communication unit 25 of the console 2A or 2B to the analysis device 3. As described above, in the present embodiment, even when taking pictures in a plurality of different breathing states, it is sufficient to check the body position, prepare for exposure, set the shooting conditions, press the exposure switch, and check the image once. The time required for dynamic photography can be significantly reduced.

When the communication unit 35 receives the transmission request of the dynamic image from the console 2A or 2B in the analysis device 3, the control unit 31 starts receiving the dynamic image and starts receiving the list information stored in the storage unit 32. The patient information, examination information, etc. of the dynamic image are added, and the status of the dynamic image is set to "Receiving". When the reception of the series of frame images is completed, the control unit 31 changes the status to "analysis processing", analyzes the dynamic image, and selects an effective section of the series of frame images that is effective for analysis ( Step S2).
For example, when performing ventilation analysis, the section where the respiratory state is resting breathing, when performing pulmonary blood flow analysis, the section where the respiratory state is breath-holding, and when analyzing the maximum respiratory volume, the respiratory state. Select the section where is deep breathing as a valid section for analysis.

When the selection of the effective section is completed, the control unit 31 of the analysis device 3 executes the analysis process for the dynamic image (step S3).
In step S3, the control unit 31 executes an analysis process according to the type of analysis attached to the dynamic image. At that time, the control unit 31 performs analysis processing automatically using a predetermined parameter group or using a parameter group set by the operation of the operation unit 33 by the operator. As the analysis process, for example, known analysis processes such as ventilation analysis and pulmonary blood flow analysis described in JP2012-110451A can be applied.
When the analysis process is completed, the control unit 31 changes the status of the list information stored in the storage unit 32 for the dynamic image to "analysis completed", and analyzes the analysis result with the identification ID, frame number, and analysis of the dynamic image. It is stored in the storage unit 32 in association with the parameter group and the like used in. In addition, the control unit 31 automatically sets a parameter group of the same type but different value as the parameter group used when the analysis process was first performed, executes the analysis process, and identifies the analysis result as a dynamic image. It is stored in the storage unit 32 in association with the ID, the frame number, the parameter group used for the analysis, and the like.

Here, when an operator such as a camera operator or a doctor logs in to any of the display devices 4A to 4C and accesses the analysis device 3, in the logged-in display devices 4A to 4C, the control unit 41 is moved by the communication unit 45. The list information is acquired from the analysis device 3, and the list screen is displayed on the display unit 44. When the operator selects an inspection from the list information displayed on the display unit 44 by the operation unit 43, the control unit 41 displays the viewer screen for the selected inspection on the display unit 44 and selects the analysis device 3. Request the display of the analysis result of the dynamic image of the inspection performed. The viewer screen is a screen that displays a dynamic image and the analysis result of the dynamic image. When the inspection whose status is "Analysis completed" is selected, the analysis result transmitted from the analysis device 3 is displayed on the viewer screen. Further, from the viewer screen, a process specification screen for setting (adjusting) the parameter group of the analysis process can be opened. When the operator does not obtain the desired analysis result by looking at the analysis result, the operator opens the process designation screen from the viewer screen by the operation of the operation unit 43 and adjusts the parameter group. The control unit 41 requests the analysis device 3 to perform reanalysis processing on the adjusted parameter group and display the analysis result. Here, since the analysis result analyzed by a plurality of different parameter groups is stored in the storage unit 32 of the analysis device 3, when the operator adjusts the parameter group from the process specification screen, the adjusted parameter group is stored. When the analysis process in is completed, the analysis result using the adjusted parameter group can be displayed immediately.

When the analysis process is completed, the display devices 4A to 4C perform a diagnosis by a doctor (step S4).
As described above, the doctor selects an examination from the list screens of the display devices 4A to 4C, displays a dynamic image and an analysis result, and makes an observation. For example, the emergency doctor observes the dynamic image taken by the imaging device 1B of the emergency room R2 and its analysis result prior to the dynamic image captured by the imaging device 1A of the general imaging room R1 and its analysis result. Then, a diagnosis is made based on the observed result.

Hereinafter, the effective section selection executed by the analysis device 3 in step S2 will be described in detail.
FIG. 6 shows a flowchart of the effective section selection process executed by the analysis device 3 in step S2. The effective section selection process is executed in collaboration with the control unit 31 of the analysis device 3 and the program stored in the storage unit 32.

First, the control unit 31 calculates the feature amount in the lung field region of the dynamic image (step S201).
Here, the respiratory cycle is composed of an expiratory phase and an inspiratory phase. In the expiratory phase, air is expelled from the lungs and the area of the lung field becomes smaller. As a result, the density of the lung field becomes high, and the lung field is drawn with a low density value (pixel signal value) in the dynamic image. In the inspiratory phase, air is taken into the lungs and the area of the lung field becomes larger. As a result, the density of the lung field becomes low, and the lung field is drawn with a high density value in the dynamic image. In deep breathing, changes in lung field size and density are slow, and in resting breathing, changes in lung field size and density are faster than in deep breathing. In addition, with breath holding, there is almost no change in the size or density of the lung field. That is, the change in the pixel signal value or the area of the lung field region of the dynamic image is a feature amount indicating the respiratory state of the lung field region.
Therefore, in step S201, the control unit 31 extracts, for example, the lung field region from each frame image, calculates a representative value (for example, an average value or a median value) of the pixel signal values in the extracted lung field region, and then calculates the representative value (for example, the average value or the median value). The difference value (inter-frame difference value) of the representative value of the pixel signal value is calculated between the frame images adjacent in time. Then, the calculated difference value between frames is plotted in time series to generate a differential waveform of the pixel signal value in the lung field region. Further, for example, the lung field region is extracted from each frame image, the area of the extracted lung field region is calculated, and the difference value (interframe difference value) of the lung field region area between the frame images adjacent in time is obtained. A differential waveform of the area of the lung field region may be generated by calculating and plotting the calculated difference value between frames in a time series.

Any known method may be used for extracting the lung field region from each frame image. For example, a threshold value is obtained by discriminant analysis from a histogram of the pixel values of each pixel of the frame image, and a region having a signal higher than this threshold value is primarily extracted as a lung field region candidate. Next, edge detection is performed near the boundary of the primary extracted lung field region candidate, and the boundary of the lung field region can be extracted by extracting the point where the edge is maximum in the small region near the boundary along the boundary. can.
Further, the area of the lung field region can be calculated by, for example, the number of pixels in the extracted lung field region × the pixel size.

Next, the control unit 31 determines the respiratory state of the lung field at the time of taking each frame image of the dynamic image based on the extracted feature amount (step S202).
Here, when the respiratory state is resting breathing, the waveform period of the inter-frame difference value generated in step S201 is constant and shorter than a predetermined threshold value. When the respiratory state is deep breathing, the period of the waveform generated in step S201 is constant and longer than a predetermined threshold. When the breathing state is breath-holding, the waveform generated in step S201 is approximately 0 (the absolute value of the inter-frame difference value is less than a predetermined threshold).
Therefore, in step S202, for example, the control unit 31 first extracts a section having periodicity from the differential waveform generated in step S201, and the similarity of the waveforms of the adjacent periods of the extracted section, for example, the mutual phase. Calculate the number of relationships. Next, the control unit 31 extracts a section in which the similarity of the waveforms of adjacent cycles is equal to or higher than a predetermined threshold value, and among the extracted sections, a section having a period shorter than the predetermined threshold value is a resting breathing section. , A section having a cycle equal to or greater than a predetermined threshold value is determined as a deep breathing section. In addition, a section in which the difference value between frames is smaller than a predetermined threshold value is determined as a breath-holding section.

Next, the control unit 31 selects an effective section and an invalid section based on the respiratory state (step S203). For example, the section of the respiratory state according to the type of analysis executed in step S3 of FIG. 5 is selected as the valid section, and the other sections are selected as the invalid section. For example, if the type of analysis specified by the imaging order information includes ventilation analysis, the respiratory status is resting breathing, and if pulmonary blood flow analysis is included, respiratory status is respiratory arrest. If the section includes an analysis of maximum respiration, select the section where the respiratory state is deep breathing as a valid section for the analysis.

Then, the control unit 31 sets the division position between the effective section and the invalid section, or between a plurality of different effective sections, and among the differential waveform generated in step S201, the division position of the section, and the respiratory state. At least one is displayed on the display unit 34 (step S204).

FIG. 7 shows an example of the screen displayed on the display unit 34 in step S204. As shown in FIG. 7, in step S204, for example, the differential waveform generated in step S201, the selected valid section, the invalid section, the division position of each section, and the respiratory state are displayed. NS. The operator confirms that there are no errors in the selected valid section and invalid section, and if there is an error, the operator can correct the section to the correct section by sliding the division position by the operation unit 33.

Then, the control unit 31 deletes the frame image of the invalid section from the series of frame images (step S205), and ends the valid section selection process.
When the analysis device 3 is connected to a billing information management device that charges according to the number of shots via a communication network, the control unit 31 is connected to the billing information management device by the communication unit 35 from a series of frame images. It is preferable to transmit information on the number of effective sections selected. This makes it possible to charge according to the number of respiratory states taken.

As described above, according to the analysis device 3 of the dynamic analysis system 100, the control unit 31 extracts the lung field region from the dynamic image of the chest transmitted from the console 2A or 2B, and relates to the extracted lung field region. The feature amount is calculated, and based on the calculated feature amount, an effective section effective for dynamic analysis is selected from a series of frame images of the dynamic image.
Therefore, when dynamic images of a plurality of respiratory states are required for dynamic analysis, it is possible to include a plurality of different respiratory states in one dynamic image without taking a picture for each respiratory state, and under a plurality of respiratory states. It is possible to shorten the time required for dynamic imaging of the chest. Further, even when the dynamic imaging is performed in one respiratory state, the analysis can be performed using only the effective section effective for the dynamic analysis, so that the analysis accuracy can be improved.

For example, the control unit 31 calculates the difference value of the pixel signal value of the lung field region or the difference value of the area between the frame images that are temporally adjacent to each other in the series of frame images of the dynamic image, and calculates the pixel signal of the lung field region. Generate a differential waveform of value or area. Next, the control unit 31 determines the respiratory state at the time of taking each frame image based on the generated waveform, and based on the determined respiratory state, performs dynamic analysis of the chest in a series of frame images of the dynamic image. Select a valid valid interval. For example, in the generated waveform, a section having a constant cycle and shorter than a predetermined threshold value is determined as a resting breathing section, and a section having a constant cycle and a predetermined threshold value or more is defined as a deep breathing section. A section in which the calculated difference value is smaller than a predetermined threshold value is determined as a breath-holding section, and is determined to be resting breathing, deep breathing, and / or breath-holding depending on the type of dynamic analysis to be performed. Select the section as a valid section. Therefore, it is possible to shorten the time required for photographing when a plurality of dynamic images of respiratory states are required for dynamic analysis.

Further, the control unit 31 sets a division position between the selected effective section and the invalid section not selected as the effective section, or between a plurality of different effective sections, and generates the waveform, the division position, and the respiration. At least one of the states is displayed on the display unit 34.
Therefore, the operator can confirm the effective section determined to be the effective section and the respiratory state thereof.

Further, since the control unit 31 deletes the frame image of the invalid section that is not selected as the valid section, the analysis can be performed using only the section that is valid for the analysis.

Further, when a plurality of effective sections are selected from a series of frame images of the dynamic image, the control unit 31 transmits information on the number of selected effective sections to the charge information management device by the communication unit 35, so that the charge is charged. In the information management device, it is possible to charge according to the number of respiratory states taken.

The description in the above embodiment is a preferable example of the present invention, and is not limited thereto.
For example, in the above embodiment, the respiratory state of the lung field is determined based on the pixel signal value or the waveform of the area of the lung field region of the dynamic image, and the valid section and the invalid section of the series of frame images are determined based on the respiratory state. Although the case of selecting is described as an example, the selection method of the valid section and the invalid section is not limited to this. For example, a waveform of the pixel signal value or area of the lung field region of the dynamic image different from the dynamic image to be analyzed, such as the past dynamic image of the same patient as the dynamic image, is generated, and the similarity with the waveform is predetermined. A section equal to or larger than the threshold value may be selected as an effective section. In this way, it is possible to select a section of the respiratory state similar to the past test as an effective section effective for analysis.

Further, in the above embodiment, the case where the effective section and the invalid section are selected after obtaining the respiratory state based on the waveform of the feature amount generated in step S201 of FIG. 6 has been described as an example, but the feature amount (waveform) You may directly select the valid section and the invalid section from. For example, in the case of a ventilation analysis in which the type of analysis includes the measurement of the maximum ventilation volume, a section having periodicity is extracted from the waveform generated in step S201, and the similarity of the waveforms of adjacent cycles of the extracted section is predetermined. A section that is equal to or greater than the specified threshold value may be selected as a valid section, and a section other than the specified threshold value may be selected as an invalid section. Further, for example, when the type of analysis is pulmonary blood flow analysis, a section in which the inter-frame difference value calculated in step S201 is smaller than a predetermined threshold value is selected as a valid section, and other sections are selected as invalid sections. May be good.

Further, in the above embodiment, the effective section selection process is performed by the analysis device 3 of the dynamic analysis system 100, but the effective section selection process is performed by the consoles 2A and 2B, and only the frame image of the effective section is analyzed by the analysis device. It may be configured to transmit to 3. As a result, the amount of data transferred to the analysis device 3 can be suppressed to the minimum necessary, and the time required for data transfer and the load on the communication network can be reduced.

In addition, the detailed configuration and detailed operation of each device constituting the dynamic analysis system can be appropriately changed without departing from the spirit of the present invention.

100 Dynamic analysis system 1A, 1B Imaging device 2A, 2B Console 21 Control unit 22 Storage unit 23 Operation unit 24 Display unit 25 Communication unit 26 Bus 3 Analysis device 31 Control unit 32 Storage unit 33 Operation unit 34 Display unit 35 Communication unit 36 Bus 4A, 4B, 4C Display device 41 Control unit 42 Storage unit 43 Operation unit 44 Display unit 45 Communication unit 46 Bus

Claims (10)

An acquisition unit that acquires dynamic image data of the chest including multiple frame image data obtained by radiography, and an acquisition unit.
A feature amount calculation unit that extracts a lung field region from the dynamic image data and calculates a feature amount related to the extracted lung field region,
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. A selection unit that selects two sections, and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. The dynamic analysis department that executes the analysis and
An output unit that outputs the analysis results obtained by the dynamic analysis, and
A dynamic analysis device characterized by being equipped with. The dynamic analysis apparatus according to claim 1, wherein the photographing order information includes a type of analysis. The dynamic analysis apparatus according to claim 2, wherein the type of analysis includes at least two of ventilation analysis, pulmonary blood flow analysis, and measurement of maximum ventilation volume. The dynamic analysis apparatus according to any one of claims 1 to 3, further comprising an adjusting unit capable of manually adjusting the first section and the second section. It has a storage unit for storing the analysis result, and has a storage unit.
The output unit outputs the analysis result to the storage unit.
The dynamic analysis apparatus according to any one of claims 1 to 4. It has a display unit that displays the analysis result.
The output unit outputs the analysis result to the display unit.
The dynamic analysis apparatus according to any one of claims 1 to 5. The output unit outputs the analysis result to an external display device.
The dynamic analysis apparatus according to any one of claims 1 to 6. A dynamic analysis program that performs dynamic analysis on chest dynamic image data including multiple frame image data obtained by radiography.
On the computer
The process of receiving the dynamic image data and
A process of extracting a lung field region from the dynamic image data and calculating a feature amount related to the extracted lung field region, and
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. Processing to select 2 sections and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. The process of performing the analysis and
Processing to output the analysis result obtained by the dynamic analysis and
A dynamic analysis program characterized by executing. It is a dynamic analysis method that performs dynamic analysis on the dynamic image data of the chest including multiple frame image data obtained by radiography.
The process of receiving the dynamic image data and
A step of extracting a lung field region from the dynamic image data and calculating a feature amount related to the extracted lung field region, and
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. The process of selecting 2 sections and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. The process of performing the analysis and
A step of outputting the analysis result obtained by the dynamic analysis and
A dynamic analysis method characterized by being provided with. It is a control device that controls an imaging device that performs radiography.
An acquisition unit that acquires dynamic image data of the chest including multiple frame image data obtained by radiography, and an acquisition unit.
A feature amount calculation unit that extracts a lung field region from the dynamic image data and calculates a feature amount related to the extracted lung field region,
A first section for performing dynamic analysis on the dynamic image data based on the feature amount and shooting order information, and a section different from the first section and not continuous with the first section. A selection unit that selects two sections, and
The first dynamic analysis is performed using the frame image data corresponding to the first section, and the second dynamic is different from the first dynamic analysis using the frame image data corresponding to the second section. A transmission unit that transmits frame image data corresponding to the first section and frame image data corresponding to the second section to the dynamic analysis device that executes the analysis.
A control device characterized by being provided with.

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