JP2016197042A - Information integrating method, apparatus, system, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide integrated information by integrating shape (scalar) information and flow (vector) information.SOLUTION: A processor acquires shape (scalar) information and flow (vector) information on the same object from a memory or another device (S101 and 103), extracts from the shape (scalar) information the fastest candidate area or the shape center line (S105), and extracts from the flow (vector) information the fastest area of intra-pipe flow or the flow center line (S107). The processor aligns the extracted fastest candidate area or shape center line with the extracted fastest area or flow center line, thereby figures out the relative positions of the shape (scalar) information and the flow (vector) information (S109), integrates the shape (scalar) information and the flow (vector) information by using their relative positions to generate integrated information, and stores it in the memory and/or displays it on a display (S111).SELECTED DRAWING: Figure 4

Description

  The present invention relates to an information integration method, apparatus, system, and program, and in particular, when shape (scalar) information and flow (vector) information are respectively acquired, an information integration method and apparatus for integrating both pieces of information. The present invention relates to a system and a program.

FIG. 11 is an explanatory diagram of conventional fluid analysis.
Conventional Computational Fluid Dynamics mainly uses a numerical analysis / simulation method for observing a flow by solving an equation relating to fluid motion with a computer. In this case, a flow rate is given in advance to all “inlet” and “outlet” to the computer, and the flow of “between” is calculated by the computer. Such methods are used for most fluid analysis such as medical images such as blood flow, aircraft, automobiles, wind tunnel experiments, and water flow.

  Further, Patent Document 1 discloses that “a first alignment relating to the alignment between the first image data set and the second image data set, the first image data set and the second image data set,” An alignment unit that performs a second alignment for alignment different from the first alignment between the first alignment and the alignment difference between the first alignment and the second alignment; A consistency determination unit for determining the degree of consistency between one image data set and the second image data set ”, and“ the degree of alignment can be determined in the alignment of a plurality of medical images ” A medical image processing apparatus ”is disclosed (see abstract).

JP 2014-185416 A

In the case of conventional fluid analysis, the computer usually has to give the flow velocity to all the “inlet” and “outlet” in advance, and only the flow of “between” is calculated by the computer. Furthermore, it cannot be calculated without "shape". In general, even if the flow is interrupted, the computer cannot calculate.
Conventionally, studies have been made to model and simulate a shape, but integration of shape (scalar) information and flow (vector) information using an actual image has not been performed.

  In view of the above points, the present invention has an object to obtain integrated information by integrating shape (scalar) information and flow (vector) information.

According to the first solution of the present invention,
An information integration method,
The processing unit acquires shape or scalar information and flow or vector information about the same object from the storage unit or another device,
The processing unit extracts the fastest candidate region or shape center line of the flow from the shape or scalar information,
The processing unit extracts the fastest region of the flow in the pipe or the flow center line from the flow or vector information,
The processing unit performs alignment between the extracted fastest candidate region or the shape center line and the extracted fastest region or the flow center line, and between the shape or scalar information and the flow or vector information. Find the relative position,
The processing unit integrates the shape or scalar information and the flow or vector information using the relative position to form integrated information, stores the integrated information in the storage unit and / or displays on the display unit An information integration method is provided.

According to the second solution of the present invention,
An information integration device,
A storage unit for storing shape or scalar information and flow or vector information and integrated information obtained by integrating the two types of information;
A display unit;
A processing unit;
With
The processing unit obtains shape or scalar information and flow or vector information about the same object from a storage unit or another device,
The processing unit extracts the fastest candidate region or shape center line of the flow from the shape or scalar information,
The processing unit extracts the fastest region of the flow in the pipe or the flow center line from the flow or vector information,
The processing unit performs alignment between the extracted fastest candidate region or the shape center line and the extracted fastest region or the flow center line, and between the shape or scalar information and the flow or vector information. Find the relative position,
The processing unit integrates the shape or scalar information and the flow or vector information using the relative position to form integrated information, stores the integrated information in the storage unit, and / or stores in the display unit An information integration device for displaying is provided.

According to the third solution of the present invention,
An information integration system,
A first measuring device for measuring the shape or scalar information;
Information as described above, wherein the shape or scalar information and the flow or vector information are input from the second measuring device that measures the flow or vector information, the first measuring device, and the second measuring device, respectively. An integrated device;
An information integration system is provided.

According to the fourth solution of the present invention,
An information integration program,
A processing unit obtaining shape or scalar information and flow or vector information about the same object from a storage unit or another device; and
The processing unit extracting the fastest candidate region or shape center line of the flow from the shape or scalar information;
The processing unit extracting the fastest region of the flow in the pipe or the flow center line from the flow or vector information;
The processing unit performs alignment between the extracted fastest candidate region or the shape center line and the extracted fastest region or the flow center line, and between the shape or scalar information and the flow or vector information. Determining a relative position;
The processing unit integrates the shape or scalar information and the flow or vector information using the relative position to form integrated information, stores the integrated information in the storage unit and / or displays on the display unit An information integration program for causing a computer to execute the step of performing is provided.

  According to the present invention, integrated information can be obtained by integrating shape (scalar) information and flow (vector) information.

The block diagram of an information integration system. The block diagram of an information integration device. Explanatory drawing of the data format of an integrated information file. The flowchart of an information integration process. Explanatory drawing of shape (scalar) information. Explanatory drawing of flow (vector) information. Explanatory drawing of the fastest candidate area | region or shape centerline of shape (scalar) information. Explanatory drawing of the fastest area | region or flow centerline of flow (vector) information. Explanatory drawing of a positioning process and integrated information. (A) Explanatory drawing of the fastest candidate area or shape center line of blood vessel shape (scalar) information, (B) Explanatory drawing of the fastest area or flow center line of blood flow (vector) information. Explanatory drawing of the conventional fluid analysis.

1. Information integration processing

FIG. 1 shows a configuration diagram of an information integration system.
The system includes an information integration device 10, a shape (scalar) information measurement device 20, and a flow (vector) information measurement device 30. The information integration device 10 and the shape (scalar) information measurement device 20 and the flow (vector) information measurement device 30 may be connected via a wired or wireless appropriate network as shown in the figure. Alternatively, the connection may be made without going through a network. Further, the information integration device 10 is not connected to the shape (scalar) information measurement device 20 and the flow (vector) information measurement device 30, and is measured by the shape (scalar) information measurement device 20 and the flow (vector) information measurement device 30. The information may be input in advance and stored inside.

FIG. 2 shows a configuration diagram of the information integration apparatus.
The information integration device 10 includes a processing unit 1, an input unit 2, a display unit 3, an interface unit (I / F) 4, and a storage unit 5. The I / F 4 is an interface for connecting the shape (scalar) information measuring device 20 and the flow (vector) information measuring device 30 and inputting a shape (scalar) information image and a flow (vector) information image, respectively. The storage unit 5 includes an integrated information file 50.

FIG. 3 is an explanatory diagram of the data format of the integrated information file.
FIG. 3A shows a first example of the integrated information file 50.
Here, the integrated information file 50 stores, for each identification information (ID) 51, shape (scalar) information 52, flow (vector) information 53, and integrated information 54 obtained by integrating both pieces of information.
FIG. 3B shows a second example of the integrated information file 50. The integrated information file 50 stores a shape (scalar) information image, a flow (vector) information image, and integrated information for each ID in separate files 55 to 57.

FIG. 4 shows a flowchart of the information integration process.
The information integration process when shape (scalar) information and flow (vector) information are acquired will be described below. Specifically, the information integration process can target, for example, the shape of a tube or the like and the flow thereof, and can be integrated by utilizing the laminar flow flowing inside.
As an example, the processing unit 1 inputs shape (scalar) information measured by the shape (scalar) information measuring device 20 via the I / F 4 and stores it in advance in the integrated information file 50 of the storage unit 5 for each ID. Can be. Alternatively, the processing unit 1 inputs the shape information image measured by the shape (scalar) information measuring device 20 via the I / F 4, obtains shape (scalar) information from the shape information image, and the like. 5 integrated information files 50 may be stored in advance for each ID.
Further, the processing unit 1 inputs the flow (vector) information measured by the flow (vector) information measuring device 30 through the I / F 4 and stores it in advance in the integrated information file 50 of the storage unit 5 for each ID. Can be. Alternatively, the processing unit 1 inputs the flow information image measured by the flow (vector) information measuring device 30 via the I / F 4 and obtains the flow (vector) information from the flow information image by extraction or the like, and the storage unit 5 integrated information files 50 may be stored in advance for each ID.
Note that the processing unit 1 may omit the ID and do not perform the processing for each ID when the number of objects is one, or is designated in advance (the same applies to the following processing).

The procedure is described below.
In step S101, the processing unit 1 acquires shape (scalar) information stored in the integrated information file 50 of the storage unit 5 in accordance with the ID specified by the input unit 2 or the like.
FIG. 5 is an explanatory diagram of shape (scalar) information.
In step S103, the processing unit 1 acquires the flow (vector) information stored in the integrated information file 50 of the storage unit 5 according to the ID specified by the input unit 2 or the like.
FIG. 6 is an explanatory diagram of flow (vector) information.
In step S101 and / or S103, the shape (scalar) information and / or the flow (vector) information is not stored in the integrated information file 50 of the storage unit 5 in advance. A measurement image is input at an appropriate timing from the (scalar) information measuring device 20 and / or the flow (vector) information measuring device 30 and the shape (scalar) information and / or flow (vector) information is extracted from the input data. Or you may acquire. The processing unit 1 may extract or acquire shape (scalar) information and flow (vector) information from each input image, and store these information in the integrated information file 50 of the storage unit 5 for each ID.

In step S105, the processing unit 1 extracts the fastest candidate region or shape center line of the flow from the shape (scalar) information. For example, the processing unit 1 can set the position of the center of gravity and the vicinity thereof in the cross section perpendicular or substantially perpendicular to the direction of the pipe or the like as the fastest candidate region as a region having a high flow velocity. Alternatively, the processing unit 1, for example, in shape information (scalar) such as luminance representing the shape of a tube or the like, the maximum luminance or the center of gravity or the like in a cross section perpendicular to or substantially perpendicular to the direction of the tube or the like May be acquired as the shape center line. Further, the processing unit 1 may thin the shape (scalar) information and extract the center axis of the shape. Note that the processing unit 1 may acquire the peripheral region with respect to the center of gravity position using various image processing methods such as a Gaussian filter. In addition, the processing unit 1 restricts the shape (scalar) information to a region near the center using data that is greater than or equal to a predetermined threshold value, data in a predetermined direction, and the like, and then flows from the shape (scalar) information. The fastest candidate region or shape center line may be extracted.
Note that the reason why the fastest candidate area is used here is only that the fastest candidate area is assumed, and is not necessarily the fastest. The fastest candidate region or the shape center line can be appropriately represented by, for example, a line along the flow of the tube or the like, or a line-shaped region having a constant or non-constant width along the flow of the tube or the like.

  In step S107, the processing unit 1 extracts the fastest region or the flow center line of the flow in the pipe from the flow (vector) information. For example, the processing unit 1 can extract the fastest region as a set of regions in which the speed (vector norm value / size) change is small and the speed is locally maximum in a direction perpendicular to the flow direction. . Alternatively, the processing unit 1 causes the magnitude (vector norm value) of the flow (vector) information at each position to flow at a position such as the maximum or the center of gravity in a cross section perpendicular to or substantially perpendicular to the direction of the tube or the like. You may acquire as a centerline. In addition, the processing unit 1 extracts the position where the velocity is maximum in the cross-sectional direction of the pipe or the like from the obtained flow (vector) information, and acquires the center line of the flow by connecting it to the flow direction. You may make it do. At this time, the processing unit 1 performs noise removal and information enhancement using various image processing methods such as smoothness constraint (the region obtained in the flow direction is continuous) and a Gaussian filter. Also good. In addition, the processing unit 1 limits the flow (vector) information to a region near the center by using data that is greater than or equal to a predetermined threshold, data in a predetermined direction, and the like, and then the flow from the flow (vector) information The fastest region or the flow center line may be extracted. The fastest region or the flow center line can be appropriately represented by, for example, a line along the flow of the tube or the like, or a line-shaped region having a constant or non-constant width along the flow of the tube or the like.

FIG. 7 shows the fastest repair region or shape center line of shape (scalar) information.
FIG. 8 shows the fastest region or flow center line of flow (vector) information.
Here, the fastest repair region or the shape center line, the fastest region or the flow center line is represented by a line as an example, but may be represented by a mesh or other color or pattern in addition to the line. The processing unit 1 may or may not display these fastest repair region or shape center line, fastest region or flow center line on the display unit 5. Moreover, the process part 1 may memorize | store these information in the memory | storage part 5, and does not need to memorize | store it.

In step S109, the processing unit 1 performs registration (registration) on the assumption that either the fastest candidate region or the shape center line obtained in step S105 matches the fastest region or the flow center line obtained in step S107. Do. For example, when obtaining the fastest candidate area in step S105 and obtaining the fastest area in step S107, the processing unit 1 performs registration (registration) assuming that the fastest candidate area matches the fastest area. Alternatively, when the processing unit 1 obtains the shape center line in step S105 and obtains the flow center line in step 107, the processing unit 1 performs registration (registration) on the assumption that the shape center line matches the flow center line. Alternatively, alignment by the fastest candidate region and the flow center line, or alignment (registration) by the shape center line and the fastest region may be performed. The registration method may be, for example, an inter-shape registration method performed after shaping region information, an inter-image registration method performed using pixel information, or a combination thereof, or various registration processing methods / alignment processing methods. Can be used. In addition, the processing unit 1 may align the shape center line of the pipe or the like obtained in step S105 and the flow center line obtained in step S107 by an alignment process such as an iterative closest point method.
In step S109, the processing unit 1 further obtains the obtained relative position (relative position and orientation) as a relative position (relative position and orientation) between the shape (scalar) information and the flow (vector) information.

In step S111, the processing unit 1 performs registration (registration) using the relative position (relative position and orientation) obtained in step S109 by using visualization software or the like, thereby obtaining shape (scalar) information and flow (vector) information. Are integrated to form integrated information, integrated information is stored in the integrated information file 50 of the storage unit 5 for each ID, the integrated information file 50 of the storage unit 5 is referenced, and the integrated information is displayed on the display unit 3 To do. The processing unit 1 may display the shape (scalar) information and / or the flow (vector) information on the display unit 3 together with the integrated information.
FIG. 9 is an explanatory diagram of the alignment process and the integrated information.
FIG. 9A shows an example of a display image before alignment (an image obtained by superimposing shape (scalar) information and flow (vector) information), and FIG. 9B shows a display image after alignment ( An example of an image of integrated information) is shown.

(Application to time change)
The processing unit 1 can further acquire and form the shape (scalar) information, the flow (vector) information, and the integrated information of the above-described embodiment at predetermined time intervals. And the process part 1 memorize | stores these information in the integrated information file 50 of the memory | storage part 5 for every ID, and displays a time change with a moving image on the display part 3, or displays with a several continuous still image. be able to.

(Application example)
In the present invention and / or the present embodiment, for example, each information can be used in correspondence as follows.
-Shape (scalar) information: Various TOF-MRA (time-of-flight MR angiography), information acquired by 3D angiography, CT angiography, etc.-Information based on images, etc.-Flow (vector) information: PC-MRA ( phase-contrast MR angiography), cerebral angiography, fluorescence angiography using indocyanine green, information based on acquired information and images, etc. by ultrasound

In addition, medical imaging such as blood vessels, blood flow, and lymph, aircraft, rockets, automobiles, ships, etc., wind tunnels, water currents, tidal currents, physics such as the earth, space, time machines (space-time transfer devices, etc.) ) The present invention and / or this embodiment can be applied to various fluid analyzes that can acquire both shape (scalar) information and flow (vector) information from an object (the same (measurement) object). it can.

2. Application to blood vessel shape information and blood flow information

Hereinafter, as an example, a case where multidimensional diagnosis is performed by integrally displaying a blood vessel shape (scalar) and blood flow information (vector) will be described.

In the field of neurosurgery, the determination of surgical indications for intracranial vascular lesions based on the evaluation of medical images and the formulation of treatment plans are important processes and have also been used for vascular lesion diagnosis. Blood vessel shape information and blood flow information are required for evaluation of vascular lesions, but there has been no technology that integrates a blood vessel information with a three-dimensional image of a blood vessel shape.
In addition, blood vessels can obtain information from various medical image examinations. For example, time-of-flight magnetic resonance angiography (TOF-MRA) is used for blood vessel shape information, and phase-contrast magnetic resonance angiography (PC-MRA) is used for blood flow information. The former is scalar information and the latter is a vector image with different dimensions. Therefore, in order to perform diagnosis by integrating shape information and blood flow information, it is necessary to propose an alignment method between different dimensions. Conventionally, for example, a blood flow simulation may be performed by modeling a blood vessel shape, but the shape and blood flow information using an actual medical image have not been integrated.

Therefore, in the present embodiment, the blood vessel shape information obtained by extracting the shape of the blood vessel from the measurement image obtained by the shape (scalar) information measurement device 20 such as TOF-MRI, CT, and blood vessel imaging is used as shape (scalar) information. Use. Further, blood flow information acquired from the flow (vector) information measuring device 30 such as PC-MRA is used as the flow (vector information). These shape (scalar) information and flow (vector) information are both images of the same (same target) blood vessel.
According to the present embodiment, it is possible to provide a method for integrating blood vessel shape information (scalar information) and blood flow information (vector information), which has been impossible in the past.
Here, as an example, on the assumption that the fastest candidate region or shape center line of blood vessel shape information and the fastest region or flow center line of blood flow information are common by the processing unit 1, information on these fastest regions or center lines is obtained. Performs alignment between images under constraint conditions.

In this case, for example, the following processes 1) to 3) can be added and executed before the flowchart of FIG.
1) First, the shape (scalar) information measurement device 20 and the flow (vector) information measurement device 30 measure the patient's TOF-MRA, etc., PC-MRA, etc. as an example, and the processing unit 1 acquires these images. To do.
2) The processing unit 1 extracts blood vessel shape information from TOF-MRA or the like as shape (scalar) information, and stores it in the integrated information file 50 of the storage unit 5 for each patient ID.
3) The processing unit 1 extracts blood flow information from PC-MRA or the like as flow (vector) information, and stores it for each patient ID in the integrated information file 50 of the storage unit 5.
4) The processing unit 1 can form, display, and / or store integrated information by executing each step using the acquired information according to the flowchart of FIG. 5 described above.

FIG. 10A shows the fastest candidate region or shape center line of blood vessel shape (scalar) information, and FIG. 10B shows the fastest region or flow center line of blood flow (vector) information.
Here, the fastest candidate area or shape center line and the fastest area or flow center line are represented by lines as an example. The processing unit 1 may display these on the display unit 5 or may not display them. Moreover, the process part 1 may memorize | store these information in the memory | storage part 5, and does not need to memorize | store it.
The processing unit 1 performs alignment between the fastest candidate region or shape center line and the fastest region or flow center line.

  As described above, according to the present embodiment, the TOF-MRA and the PC-MRA are integrated and displayed, so that the blood vessel shape (scalar) information and the blood flow (vector) information can be presented in an integrated manner. It is expected that diagnosis of this will be possible more easily. In addition, this embodiment is used to evaluate the prognosis (bleeding risk during follow-up) in intracranial vascular lesions (unruptured cerebral aneurysms, cerebral arteriovenous malformations, etc.) It is expected to be applied to preoperative planning (determining the priority order for processing a large number of diseased blood vessels) such as cranioangioblastoma extraction and cranioclipping.

  An information integration method or an information integration apparatus / system of the present invention includes an information integration program for causing a computer to execute each procedure, a computer-readable recording medium recording the information integration program, and an internal memory of the computer including the information integration program Can be provided by a program product that can be loaded on the computer, a computer such as a server including the program, and the like.

DESCRIPTION OF SYMBOLS 10 Information integration apparatus 20 Shape (scalar) information measurement apparatus 30 Flow (vector) information measurement apparatus

JP 2014-171867 A

Claims (11)

An information integration method,
The processing unit acquires shape or scalar information and flow or vector information about the same object from the storage unit or another device,
The processing unit extracts the fastest candidate region or shape center line of the flow from the shape or scalar information,
The processing unit extracts the fastest region of the flow in the pipe or the flow center line from the flow or vector information,
The processing unit performs alignment between the extracted fastest candidate region or the shape center line and the extracted fastest region or the flow center line, and between the shape or scalar information and the flow or vector information. Find the relative position,
The processing unit integrates the shape or scalar information and the flow or vector information using the relative position to form integrated information, stores the integrated information in the storage unit and / or displays on the display unit Information integration method.
The information integration method according to claim 1,
The processing unit measures the shape or scalar information measured by the first measuring device or the shape or scalar information obtained from the shape or scalar image measured by the first measuring device, and measured by the second measuring device. An information integration method, wherein the flow or vector information or the flow or vector information obtained from the flow or vector image measured by the second measuring device is stored in the storage unit.
In the information integration method according to claim 1 or 2,
After the processing unit limits the shape or scalar information and / or the flow or vector information based on a predetermined threshold or direction, the fastest candidate region or shape center line of the flow is extracted from the shape or scalar information. And / or extracting the fastest region or flow center line of the flow in the pipe from the flow or vector information.
In the information integration method according to any one of claims 1 to 3,
The information integration method, wherein the processing unit further displays the shape or scalar information and / or the flow or vector information together with the integration information on the display unit.
The information integration method according to any one of claims 1 to 4,
The processing unit further acquires and forms the shape or scalar information, the flow or vector information, and the integrated information at predetermined time intervals, and stores the information in the storage unit. And / or the information integration method characterized by displaying the time change on the display unit as a moving image or a plurality of continuous still images.
The information integration method according to any one of claims 1 to 5,
The shape or scalar information and the flow or vector information include medical images such as blood vessels, blood flows, and lymph, aircraft, rockets, automobiles, ships, wind tunnels, water currents, tidal currents, the earth, space, time machines, and other physics. An information integration method characterized in that the information is acquired from the same object in any one of the technical fields.
The information integration method according to any one of claims 1 to 6,
The shape or scalar information is information acquired based on any of TOF-MRA (time-of-flight MR angiography), three-dimensional angiography, CT angiography, or information based on an image,
The flow or vector information is PC-MRA (phase-contrast MR angiography), cerebral angiography, fluorescence angiography using indocyanine green, acquired information by ultrasound, or information based on an image. Information integration method.
The information integration method according to any one of claims 1 to 7,
The information integration method, wherein the shape or scalar information and the flow or vector information are blood vessel shape information and blood flow information or lymph vessel shape and lymph flow information, respectively.
An information integration device,
A storage unit for storing shape or scalar information and flow or vector information and integrated information obtained by integrating the two types of information;
A display unit;
A processing unit;
With
The processing unit obtains shape or scalar information and flow or vector information about the same object from a storage unit or another device,
The processing unit extracts the fastest candidate region or shape center line of the flow from the shape or scalar information,
The processing unit extracts the fastest region of the flow in the pipe or the flow center line from the flow or vector information,
The processing unit performs alignment between the extracted fastest candidate region or the shape center line and the extracted fastest region or the flow center line, and between the shape or scalar information and the flow or vector information. Find the relative position,
The processing unit integrates the shape or scalar information and the flow or vector information using the relative position to form integrated information, stores the integrated information in the storage unit, and / or stores in the display unit Information integration device to display.
An information integration system,
A first measuring device for measuring the shape or scalar information;
The shape or scalar information and the flow or vector information are input from the second measurement device that measures the flow or vector information, the first measurement device, and the second measurement device, respectively. Information integration device,
An information integration system with
An information integration program,
A processing unit obtaining shape or scalar information and flow or vector information about the same object from a storage unit or another device; and
The processing unit extracting the fastest candidate region or shape center line of the flow from the shape or scalar information;
The processing unit extracting the fastest region of the flow in the pipe or the flow center line from the flow or vector information;
The processing unit performs alignment between the extracted fastest candidate region or the shape center line and the extracted fastest region or the flow center line, and between the shape or scalar information and the flow or vector information. Determining a relative position;
The processing unit integrates the shape or scalar information and the flow or vector information using the relative position to form integrated information, stores the integrated information in the storage unit and / or displays on the display unit Information integration program for causing a computer to execute the step of performing.

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