JPWO2016104288A1 - Image diagnostic apparatus, control method and program for image diagnostic apparatus - Google Patents

Abstract

An imaging apparatus for acquiring reflected light from a tubular tissue while moving a transmitting / receiving unit that continuously transmits and receives light in the axial direction in the tubular tissue, and generates an image based on the reflected light. A line data generation unit that generates line data used for generating a cross-sectional image of the tubular tissue based on the detection unit, a detection unit that detects a branch of the tubular tissue based on the line data, and a detection result by the detection unit A cross section in a direction intersecting the axial direction of the tubular tissue based on the setting unit for setting the construction angle of the longitudinal cross-sectional image in a direction substantially parallel to the axial direction of the tubular tissue, and the line data and the detection result by the detection unit A cross-sectional image generating unit that generates an image, and a vertical cross-sectional image generating unit that generates a vertical cross-sectional image based on the line data and the construction angle.

Description

  The present invention relates to an image diagnostic apparatus, a control method for the image diagnostic apparatus, and a program.

  In recent years, endovascular treatment using highly functional catheters such as balloon catheters and stents has been performed. Image diagnosis devices such as optical coherence tomography (OCT: Optical Coherence Tomography) and intravascular ultrasound (IVUS) are used for pre-operative diagnosis or post-operative confirmation Is common. As an improved version of OCT, an optical coherence tomography (SS-OCT) using wavelength sweep has been developed.

  The diagnostic imaging apparatus is used to determine the necessity of treatment of a blood vessel site from information obtained as a result of diagnosis, such as the stenosis rate or the presence of plaque in a branch, or the stent immediately after treatment is adhered to the blood vessel. It is used for rate evaluation or for checking the procedure.

  Many of the diagnostic imaging apparatuses provide doctors with lesion information of the entire blood vessel by displaying longitudinal cross-sectional images generated by stacking arbitrary angles of the cross-sectional images in time series together with the acquired cut-off screen images ( Patent Document 1).

  In addition, a doctor determines a site to be treated from an X-ray image at the time of treatment. At this time, the cross-sectional image on the blood vessel site displayed in the X-ray image is estimated by comparing the vertical cross-sectional image displayed by the diagnostic imaging apparatus with the X-ray image. In this estimation, a branch on the longitudinal section image is used as a landmark.

  In order to determine the treatment site of the blood vessel, the doctor needs to confirm the cross-sectional image acquired by the image diagnostic apparatus corresponding to the position of the blood vessel displayed on the X-ray image. At present, the confirmation operation is performed by comparing the branch position on the longitudinal cross-sectional image displayed on the diagnostic imaging apparatus with the blood vessel branch position on the X-ray image.

JP 2011-072596 A

  However, in the conventional technology, the longitudinal cross-sectional image displayed on the diagnostic imaging apparatus is generated by stacking images of arbitrary angles of the acquired cross-sectional images in time series, but is divided in the angle direction used at the time of generation. There is no guarantee that the branch exists. Therefore, in order to display the branch position on the longitudinal section image, it is necessary to regenerate the longitudinal section image so that the operator can observe the branch by operating an arbitrary angle.

  Since the time required to regenerate a longitudinal cross-sectional image in which a branch can be observed depends on the operator's proficiency with respect to the image, it may take time to generate a vertical cross-sectional image in which the branch can be observed.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a technique that facilitates the generation of a longitudinal cross-sectional image suitable for observation.

In order to achieve the above object, the diagnostic imaging apparatus according to the present invention has the following configuration. That is,
A diagnostic imaging apparatus that obtains reflected light from the tubular tissue while moving a transmitting / receiving unit that continuously transmits and receives light in the axial direction in the tubular tissue, and generates an image based on the reflected light,
Line data generating means for generating line data used for generating a cross-sectional image of the tubular tissue based on the reflected light;
Detecting means for detecting a branch of the tubular tissue based on the line data;
Setting means for setting a construction angle of a longitudinal section image in a direction substantially parallel to the axial direction of the tubular tissue based on the detection result by the detection means;
A cross-sectional image generating means for generating a cross-sectional image in a direction intersecting the axial direction of the tubular tissue based on the line data and the detection result by the detecting means;
Vertical section image generation means for generating the longitudinal section image based on the line data and the construction angle.

  According to the present invention, it is easy to generate a longitudinal section image suitable for observation.

  Other features and advantages of the present invention will become apparent from the following description with reference to the accompanying drawings. In the accompanying drawings, the same or similar components are denoted by the same reference numerals.

The accompanying drawings are included in the specification, constitute a part thereof, show an embodiment of the present invention, and are used to explain the principle of the present invention together with the description.
1 is a diagram illustrating an external configuration of an image diagnostic apparatus according to an embodiment of the present invention. It is a figure which shows the function structure of the diagnostic imaging apparatus which concerns on one Embodiment of this invention. It is a figure which shows the function structure of the signal processing part which concerns on one Embodiment of this invention. It is explanatory drawing of the calculation method of the angle which the main pipe and side pipe which concern on one Embodiment of this invention make. It is a flowchart which shows the procedure of the process which the diagnostic imaging apparatus which concerns on one Embodiment of this invention implements. It is explanatory drawing of the production | generation process of the longitudinal cross-section image which concerns on one Embodiment of this invention, and a cross-sectional image. It is explanatory drawing of the production | generation process of the longitudinal cross-section image which concerns on one Embodiment of this invention, and a cross-sectional image. It is a figure which shows an example of the highlight mark which shows the position of the flame | frame containing the branch which concerns on one Embodiment of this invention. It is explanatory drawing of the calculation process of the branch position (angle (theta)) which the branch detection part which concerns on one Embodiment of this invention implements. It is explanatory drawing of the calculation process of the branch position (angle (theta)) which the branch detection part which concerns on one Embodiment of this invention implements. It is explanatory drawing of the calculation process of the branch position (angle (theta)) which the branch detection part which concerns on one Embodiment of this invention implements. It is explanatory drawing of the procedure which calculates the relative magnitude | size of the diameter of the branch which concerns on one Embodiment of this invention. It is explanatory drawing of the procedure which calculates the magnitude | size of the diameter of the branch which concerns on one Embodiment of this invention. It is explanatory drawing of the procedure which calculates the relative magnitude | size of the diameter of the branch which concerns on one Embodiment of this invention. It is a longitudinal cross-sectional schematic diagram (distance of a branch and a constriction part) of the tubular structure | tissue which concerns on one Embodiment of this invention. It is a longitudinal cross-sectional schematic diagram (distance of a branch and a stent) of the tubular structure | tissue which concerns on one Embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiment described below is a preferred specific example of the present invention, and thus various technically preferable limitations are given. However, the scope of the present invention is particularly limited in the following description. Unless otherwise stated, the present invention is not limited to these embodiments. Moreover, the same reference numerals represent the same components throughout the specification.

<1. External configuration of diagnostic imaging apparatus>
FIG. 1 is a diagram showing an external configuration of an image diagnostic apparatus (optical coherence tomographic image diagnostic apparatus (OCT) or wavelength swept optical coherence tomographic image diagnostic apparatus (OFDI)) 100 according to an embodiment of the present invention.

  As illustrated in FIG. 1, the diagnostic imaging apparatus 100 includes an optical probe unit 101, a scanner / pullback unit 102, and an operation control device 103, and the scanner / pullback unit 102 and the operation control device 103 include a signal line 104. Connected by.

  The optical probe 101 is a transmitter / receiver that is inserted directly into a tubular tissue such as a blood vessel and continuously transmits the transmitted measurement light toward the tubular tissue and continuously receives reflected light from the tubular tissue. An imaging core provided at the distal end is inserted, and the state of the tubular tissue is measured by using the imaging core.

  The scanner / pullback unit 102 is configured such that the optical probe unit 101 is detachably attached, and a radial operation (intraluminal) of an imaging core inserted in the optical probe unit 101 by driving a built-in motor. In the axial direction and the rotational direction). In addition, the reflected light received by the transmission / reception unit is acquired, and the acquired reflected light is transmitted to the operation control device 103 via the signal line 104.

  The operation control device 103 has a function for inputting various set values and a function for displaying the measurement result as a cross-sectional image of the tubular tissue when performing the measurement.

  In the operation control device 103, 111 is a main body control unit, which generates interference light data by causing interference between reflected light obtained by measurement and reference light obtained by separating the measurement light, By processing the line data generated based on the interference light data, a plurality of cross-sectional images in the direction orthogonal to the axis of the tubular tissue are generated.

  Reference numeral 111-1 denotes a printer / DVD recorder, which prints a processing result in the main body control unit 111 or stores it as data. Reference numeral 112 denotes an operation panel. The user inputs various setting values and various instructions via the operation panel 112. Reference numeral 113 denotes an LCD monitor as a display device, which displays a plurality of cross-sectional images of the tubular tissue generated by the main body control unit 111.

<2. Functional configuration of diagnostic imaging device>
Next, the functional configuration of the diagnostic imaging apparatus 100 will be described. As described above, the image diagnostic apparatus includes an optical coherence tomographic image diagnostic apparatus (OCT) and an optical coherence tomographic image diagnostic apparatus (OFDI) using a wavelength sweep. The coherent tomographic image diagnosis apparatus (OFDI) will be described.

  FIG. 2 is a diagram illustrating a functional configuration of an optical coherence tomographic image diagnostic apparatus using wavelength sweep, which is the diagnostic imaging apparatus 100.

  Reference numeral 208 denotes a wavelength swept light source, which uses a sweep laser. A wavelength swept light source 208 using a swept laser is a type of extended-cavity laser that includes a coupler 214, an SOA 215 (semiconductor optical amplifier), an optical fiber 216 coupled in a ring shape, and a polygon scanning filter 208a. .

  The light output from the SOA 215 travels through the optical fiber 216 and enters the polygon scanning filter 208 a, where the wavelength-selected light is amplified by the SOA 215 and finally output from the coupler 214.

  In the polygon scanning filter 208a, the wavelength is selected by a combination of the diffraction grating 212 that separates light and the polygon mirror 209. Specifically, the light dispersed by the diffraction grating 212 is condensed on the surface of the polygon mirror 209 by two lenses (lens 210 and lens 211). As a result, only light having a wavelength orthogonal to the polygon mirror 209 returns through the same optical path and is output from the polygon scanning filter 208a. Therefore, the time sweep of the wavelength can be performed by rotating the polygon mirror 209.

  For example, a 72-sided mirror is used as the polygon mirror 209, and the rotation speed is about 50000 rpm. A wavelength sweeping method combining the polygon mirror 209 and the diffraction grating 212 enables high-speed and high-output wavelength sweeping.

  The light of the wavelength swept light source 208 output from the coupler 214 is incident on one end of the first single mode fiber 230 and transmitted to the distal end side. The first single mode fiber 230 is optically coupled to the second single mode fiber 237 and the third single mode fiber 231 at an intermediate optical coupler unit 234. Therefore, the light incident on the first single mode fiber 230 is divided by the optical coupler unit 234 into three optical paths at maximum and transmitted.

  On the tip side of the optical coupler portion 234 of the first single mode fiber 230, the non-rotating portion and the rotating portion are coupled to each other, and an optical rotary joint 203 that transmits light and a rotational drive that drives the optical rotary joint 203 are driven. A device 204 is provided.

  Further, the fifth single mode fiber 236 of the optical probe unit 101 is detachably connected to the distal end side of the fourth single mode fiber 235 in the optical rotary joint 203 via the adapter 202. As a result, light from the wavelength swept light source 208 is transmitted to the fifth single mode fiber 236 that is inserted into the imaging core 201 and can be driven to rotate.

  The transmitted light is irradiated from the distal end side of the imaging core 201 to the tubular tissue while performing a radial operation. A part of the reflected light scattered on the surface or inside of the tubular tissue (for example, blood vessel) is taken in by the imaging core 201 and returns to the first single mode fiber 230 side through the reverse optical path. Further, a part of the light is moved to the second single mode fiber 237 side by the optical coupler unit 234 and emitted from one end of the second single mode fiber 237, so that it is received by a photodetector (for example, a photodiode 219). Is done.

  Note that the rotating portion side of the optical rotary joint 203 is rotationally driven by a radial scanning motor 205 of the rotational driving device 204. The rotation angle of the radial scanning motor 205 is detected by the encoder unit 206. Further, the scanner / pullback unit 102 includes a linear drive device 207, and regulates the axial operation of the imaging core 201 based on an instruction from the signal processing unit 223.

  On the other hand, an optical path length variable mechanism 225 for finely adjusting the optical path length of the reference light is provided at the tip of the third single mode fiber 231 opposite to the optical coupler section 234. The optical path length variable mechanism 225 changes the optical path length corresponding to the variation in length so that the variation in length of each optical probe unit 101 when the optical probe unit 101 is replaced and used can be absorbed. It functions as an optical path length changing part.

  Specifically, the third single mode fiber 231 and the collimating lens 226 are provided on a uniaxial stage 232 that is movable as indicated by an arrow 233 in the optical axis direction. When the optical probe unit 101 is replaced, the uniaxial stage 232 functions as an optical path length changing unit by moving a variable range of the optical path length that can absorb variations in the optical path length of the optical probe unit 101. Realize. The single axis stage 232 also functions as an adjustment unit that adjusts the offset. For example, when the tip of the optical probe unit 101 is not in close contact with the surface of the living tissue, the optical path length is minutely changed by the uniaxial stage so as to interfere with the reflected light from the surface position of the living tissue. It becomes possible.

  The light whose optical path length is finely adjusted by the optical path length variable mechanism 225 is combined with the light obtained from the first single mode fiber 230 side by the optical coupler unit 234 provided in the middle of the third single mode fiber 231. The light is received by the photodiode 219 via the second single mode fiber 237.

  The interference light received by the photodiode 219 in this way is photoelectrically converted, amplified by the amplifier 220, and then input to the demodulator 221. The demodulator 221 performs demodulation processing for extracting only the signal portion of the interfered light, and its output is input to the A / D converter 222 as an interference light signal.

  The A / D converter 222 samples the interference light signal for 2048 points at 180 MHz, for example, and generates one line of digital data (interference light data). The sampling frequency of 180 MHz is based on the assumption that about 90% of the wavelength sweep period (12.5 μsec) can be extracted as 2048 digital data when the wavelength sweep repetition frequency is 40 kHz. However, the present invention is not particularly limited to this.

  The line-by-line interference light data generated by the A / D converter 222 is input to the signal processing unit 223. In the signal processing unit 223, the interference light data is frequency-resolved by FFT (Fast Fourier Transform) to generate data in the depth direction (line data), and this is coordinate-converted to obtain the data in the tubular tissue (for example, blood vessel). A cross-sectional image at each position in the axial direction is generated and output to the LCD monitor 113 at a predetermined frame rate under an instruction from the operation panel 112.

  The signal processing unit 223 is further connected to the optical path length adjustment unit control device 218. The signal processing unit 223 controls the position of the uniaxial stage 232 via the optical path length adjustment unit controller 218. The signal processing unit 223 is connected to the motor control circuit 224 and receives a video synchronization signal from the motor control circuit 224. The signal processing unit 223 generates a cross-sectional image in synchronization with the received video synchronization signal.

  The video synchronization signal of the motor control circuit 224 is also sent to the rotation driving device 204, and the rotation driving device 204 outputs a driving signal synchronized with the video synchronization signal.

<3. Functional configuration of signal processing unit>
Next, a functional configuration for realizing various processes in the signal processing unit 223 of the diagnostic imaging apparatus 100 will be described. In the following, among various types of processing realized by the signal processing unit 223, processing for generating a cross-sectional image in the direction orthogonal to the axis, processing for generating a vertical cross-sectional image in the axial direction (generation processing), and line data Will be described focusing on the processing (storage processing) for storing the signal in the signal processing unit 223.

  Further, the generation process and the storage process described below may be realized using dedicated hardware, or the function of each unit may be realized by software (by a computer executing a program).

  FIG. 3A is a diagram illustrating functional blocks for realizing generation processing and storage processing in the signal processing unit 223 of the diagnostic imaging apparatus 100 and functional blocks other than the signal processing unit 223 related to the processing.

  As shown in FIG. 3A, the interference light data generated by the A / D converter 222 is output from the motor control circuit 224 to the encoder unit of the radial scanning motor 205 in the line data generation unit 301 in the signal processing unit 223. Using the signal 206, processing is performed so that the number of lines per rotation of the radial scanning motor is 512. Here, as an example, a cross-sectional image including 512 lines is generated, but the number of lines is not limited to this.

  While the transmitting / receiving unit that continuously transmits and receives light is moved in the axial direction in the tubular tissue, the reflected light from the tubular tissue is acquired, and the line data generation unit 301 is a cross-sectional image of the tubular tissue based on the reflected light. The line data 314 used for generating is generated.

  The line data 314 output from the line data generation unit 301 is stored in the line data memory 302 for each rotation of the radial scanning motor based on an instruction from the control unit 306. At this time, the control unit 306 counts the pulse signal 313 output from the movement amount detector of the linear driving device 207 and generates each line data 314 when the line data 314 is stored in the line data memory 302. And stored in association with the count value counted.

  Here, the case where the line data memory 302 is arranged and the line data 314 and the count value of the pulse signal 313 output from the movement amount detector of the linear drive device 207 are stored in association with each other has been described. The present invention is not limited to this. For example, a cross-sectional image data memory is arranged after the cross-sectional image generation unit 303, and the cross-sectional image 317 and the count value of the pulse signal 313 output from the movement amount detector of the linear drive device 207 are stored in association with each other. You may comprise as follows.

  Returning to the description of FIG. The line data 315 output from the line data memory 302 is input to the branch detection unit 3021 and the cross section image generation unit 303.

  The branch detection unit 3021 uses the line data 315 to detect the branch direction of the tubular tissue as angle information for each frame image. This is to detect in which direction the branch extends in the cross-sectional image as angle information. When generating a longitudinal section image, at least one of the angle information is used as a construction angle of the longitudinal section image. As a result, the presence / absence of a branch for each of the series of frame images and the direction in which the branch extends when the branch is present can be known.

  Further, the line data 315 is read from the branch detection unit 3021 by the longitudinal section image generation unit 304 based on an instruction from the control unit 306. The vertical cross-section image generation unit 304 uses the detection result (branch angle information) by the branch detection unit 3021 and the read line data 315 to use a vertical cross-section in a direction substantially parallel to the axial direction of the tubular tissue. An image 316 is generated.

  More specifically, the branch position setting unit 3022 sets the construction angle of the longitudinal cross-sectional image in a direction substantially parallel to the axial direction of the tubular tissue based on the detection result by the branch detection unit 3021. For example, when branching is detected in a plurality of frames, angle information in a frame at a predetermined position among the angle information of the branching in each frame may be automatically set as the construction angle. The predetermined position is generally set by representing the angle information of the branch of the frame corresponding to the thickest side, for example, since pullback operation is generally performed from the thin side of the tubular tissue to the thick side. This is because the branch from the side of the thick tubular tissue is often a thick branch and is often regarded as a diagnostic object of a doctor.

  However, the setting of the construction angle is not limited to this method. The construction angle may be set based on the diameter of the branch portion of the branch of each frame. For example, the angle information of the frame having the largest diameter may be used as the construction angle. A method of calculating the branch diameter will be described later.

  Alternatively, the angle formed between the main tube and the side tube (branch) of the tubular tissue may be calculated, and the construction angle may be set based on the angle formed. For example, from an X-ray fluoroscopic image taken together with a cross-sectional image of a tubular tissue, an approximate value of an angle formed between a main tube and a side tube in a branch portion to be targeted is input in advance via the operation panel 112, and the approximate value It is good also considering the angle information of the frame which has an angle close to as the construction angle. Further, the angle information of the frame that maximizes the angle formed between the main tube and the side tube (branch) of the tissue may be used as the construction angle.

Here, with reference to FIG. 3B, an example of a method for calculating an angle formed by the main tube and the side tube (branch) of the tubular tissue will be described. As shown in FIG. 3B, an angle between a straight line connecting points A and B and the main tube of the tubular tissue is defined as θ _AB . M and n in FIG. 3B are obtained using the line data of the frames F ₁ and F ₂ . Further, p is obtained from the interval between the frames F ₁ and F ₂ . From this information, tan θ _AB = (mn) / p, and therefore, it can be calculated as θ _AB = tan ⁻¹ {(mn) / p}.

  The angle information that maximizes the number of branches displayed when the longitudinal section image is generated may be used as the construction angle. Furthermore, when a guide wire exists in the branch, the angle information of the frame in which the guide wire passing through the branch can be visually recognized may be used as the construction angle.

  The generated longitudinal cross-sectional image 316 is read by the image processing unit 305 based on an instruction from the control unit 306, subjected to image processing for display on the LCD monitor 113, and then as a longitudinal cross-sectional image 316 ′. It is output to the LCD monitor 113.

  Further, the cross-sectional image generation unit 303 determines a frame for generating a cross-sectional image in a direction intersecting the axial direction of the tubular tissue based on the detection result by the branch detection unit 3021, and performs various kinds of processing on the line data 315. After performing processing (line addition averaging processing, filter processing, etc.), Rθ conversion is performed and a cross-sectional image 317 is output. The generated cross-sectional image 317 is read out by the image processing unit 305 based on an instruction from the control unit 306 and subjected to image processing for display on the LCD monitor 113, and then as a cross-sectional image 317 ′. It is output to the LCD monitor 113.

  The LCD monitor 113 displays the cross-sectional image 317 ′ and the vertical cross-sectional image 316 ′ that have been subjected to image processing in the image processing unit 305 in parallel.

<4. Generation processing of longitudinal section image and transverse section image>
Next, details of the vertical cross-sectional image and cross-sectional image generation processing performed by the diagnostic imaging apparatus 100 according to the present embodiment will be described.

  FIG. 3C is a flowchart illustrating a procedure of processes performed by the diagnostic imaging apparatus 100 according to the present embodiment. 4A to 4C are explanatory diagrams of the generation processing of the longitudinal section image and the transverse section image. The diagnostic imaging apparatus 100 acquires reflected light from the tubular tissue while moving a transmitting / receiving unit that continuously transmits and receives light in the axial direction of the tubular tissue.

  In S3001, the line data generation unit 301 generates line data used for generating a cross-sectional image of the tubular tissue based on the reflected light from the tubular tissue. Reference numeral 401 in FIG. 4A denotes line data in each frame generated by the line data generation unit 301 and stored in the line data memory 302.

  In S3002, the branch detection unit 3021 detects a branch of the tubular tissue from each frame based on the line data generated by the line data generation unit 301. Reference numeral 402 in FIG. 4A denotes line data of one frame among the plurality of line data 401. Reference numeral 4021 denotes a branch position (angle θ).

Reference numeral 403 denotes a frame in which branch detection is performed by the branch detection unit 3021 in the line data 401 in each frame, and a branch position (angle θ) calculated for each frame. In the line data 401, branches are detected in some frames, and the branch positions (angles θ) of the frames where the branches are detected are θ ₁ , θ ₂ ,..., Θ _n , respectively. It is represented. The branch position (angle θ) calculation process will be described later with reference to FIGS.

  In S3003, the branch position setting unit 3022 sets the construction angle of the longitudinal cross-sectional image in a direction substantially parallel to the axial direction of the tubular tissue, based on the detection result by the branch detection unit 3021. For example, as described with reference to FIG. 3A, when branching is detected in a plurality of frames, the branching angle information in each frame is on the thickest side (pullback direction side) of the tubular tissue. The angle information of the branch in the corresponding frame is set as the construction angle.

Reference numeral 404 in FIG. 4B denotes line data, and shows an example in which the construction angle of the longitudinal section image is set by the branch position setting unit 3022. In the example of the line data 404, it is assumed that θ _x that is the angle information of the branch of the Xth frame is set as the construction angle of the longitudinal section image.

  In S3004, the cross-sectional image generation unit 303 generates a cross-sectional image in a direction intersecting the axial direction of the tubular tissue based on the line data generated by the line data generation unit 301 and the detection result by the branch detection unit 3021. Generate. 406 in FIG. 4B is a cross-sectional image generated by the cross-sectional image generation unit 303 for the Xth frame. A white line segment 406 corresponds to a cut surface of the longitudinal cross-sectional image, and a white ellipse portion is a branch portion of the Xth frame.

In step S3005, the longitudinal section image generation unit 304 generates a longitudinal section image based on the line data generated by the line data generation unit 301 and the construction angle set by the branch position setting unit 3022. 405 in FIG. 4B is an example of a longitudinal section images vertical sectional image generating unit 304 has generated in the construction angle theta _x. A white line segment 405 corresponds to the Xth frame, and a white ellipse portion is a branch portion of the Xth frame.

  In step S <b> 3006, the image processing unit 305 performs image processing on the vertical cross-sectional image 405 and the horizontal cross-sectional image 406 and displays them on the LCD monitor 113. As shown in FIG. 4C, a cross-sectional image 411 generated for the M-th frame and a vertical cross-sectional image 412 generated using the branch angle information (construction angle) of the M-th frame are displayed. Furthermore, highlight marks 421 to 426 indicating the positions of the frames including the branches may be displayed together. Then, in response to the user selecting any one of the highlight marks 422 to 426, the cross-sectional image of the frame at the selected position is regenerated, and the vertical cross section at the construction angle related to the frame at the selected position. The image may be regenerated and displayed on the LCD monitor 113 again.

  Furthermore, when branches are detected in a plurality of frames, a plurality of longitudinal cross-sectional images are generated and displayed on the LCD monitor 113 using the construction angle information about each frame so that each branch can be observed. It may be a configuration.

  According to the series of processes described above, it is easy to generate a longitudinal section image suitable for observation.

<5. Branch detection method>
Next, a branch position (angle θ) calculation process performed by the branch detection unit 3021 will be described with reference to FIGS. As shown in FIG. 5, for each frame, each line is scanned and a line having a peak luminance value equal to or less than a threshold is determined as a branch. The angle of the line corresponding to the center of the plurality of lines determined to be a branch is detected as the branch position (angle θ). In the figure, the line range of θ _{a to} θ _b has a peak luminance value equal to or less than a threshold value, indicating a branch. Here is the center angle θ _a ~θ _b θ _c is detected as a branching position.

Alternatively, as shown in FIG. 6, the degree of eccentricity is defined as the shortest diameter / maximum diameter (L _max / L _min ), and for a plurality of frames, the eccentricity degree of the frame of interest is the eccentricity degree of adjacent frames before and after In the case where there is a large change in comparison (the eccentricity of the frame of interest is large), it may be determined that there is a branch in the frame of interest. Then, the angle formed by the straight line connecting the intersection of the maximum diameter line segment and the lumen and the image center with the reference line 60 is detected as a branch position (angle θ). Among the cross-sectional images 601 to 605, branches are detected in the frames of the cross-sectional images 602, 604, and 605.

  More specifically, as shown in FIG. 7, when the eccentricity is calculated and plotted for each frame, the eccentricity greatly changes between the frame of interest with branches and the frames before and after it. ing. For example, when the difference D between the eccentricity of the frame of interest and the eccentricity of the frames before and after it is greater than or equal to a threshold value, it can be determined that there is a branch in the frame of interest.

  Alternatively, in consideration of the eccentricity of a plurality of frames before and after, the difference D between the eccentricity of the frame of interest and all of the eccentricities of the plurality of frames before and after that is equal to or more than a threshold value. It may be determined that there is a branch. Thereby, the branch can be detected with higher accuracy.

[5-1. Calculation method of relative size of branch diameter]
Next, with reference to FIG. 8A, an example in which the relative magnitude relationship between the branch diameters in each frame is obtained will be described. In FIG. 8A, 801 is an example of line data, and 802 is an example of a cross-sectional image of the xth frame. In the line data 801, the number of lines included in the width dθ _x is counted in order to evaluate the width dθ _x corresponding to the diameter of the branch. Reference numeral 803 denotes an example of a longitudinal cross-sectional image in each frame. The x-th frame width dθ _x (number of lines), the x + 1-th width dθ _{x + 1} (number of lines),..., The n-th frame width dθ _n ( The number of lines) is calculated from each frame.

804 is a diagram in which the relationship between the frame number and the width dθ _n is plotted. In this example, the width dθ _y at the frame number _y is the largest value (number of lines). That is, the frame corresponding to the number y may be the frame with the largest diameter, and the angle information of the frame with the largest diameter may be determined as the construction angle. This method does not directly calculate the diameter, but relatively compares the number of lines corresponding to branches.

[5-2. Calculation method of branch diameter]
Next, a method of calculating the branch diameter in each frame will be described. 811 to 813 in FIG. 8B are examples of cross-sectional images. An intersection point P between the line of the branch position (angle θ) and the lumen in the cross-sectional image 811 is obtained. Next, points are plotted at predetermined intervals of 90 degrees clockwise and counterclockwise from the intersection point P, and the curvature of the lumen is obtained for each point. A method for calculating the curvature will be described later. Then, the largest curvature is determined among the curvatures of the lumens of the points obtained in both directions, and the maximum curvature is compared with a threshold value. If the curvature is greater than or equal to the threshold, the branch diameter is calculated according to any of the following procedures.

  When a point having a curvature equal to or greater than the threshold value is detected in both directions, a line segment 8123 connecting the point 8121 detected in the clockwise direction and the point 8122 detected in the counterclockwise direction as shown in the cross-sectional image 812. Is calculated as the diameter of the branch.

  When a point having a curvature greater than or equal to the threshold value is detected only in one direction, a perpendicular is drawn from the detected point 8131 to the long axis 8132 of the lumen and the perpendicular is extended as shown in the cross-sectional image 813. The intersection point 8134 between the straight line 8133 and the opposite lumen is obtained, and the distance between the detection point 8131 and the intersection point 8134 is calculated as the branch diameter.

  On the other hand, if a point having a curvature equal to or greater than the threshold value is not detected in both directions, the frame is excluded from the branch detection target.

  Next, with reference to FIG. 8C, a method for calculating the curvature of the lumen for each point will be described. First, the approximate curve A is calculated by using the attention point 831 and a total of four lumen positions including the previous point 832, the point 833, and the point 834 with respect to the rotation direction. Next, similarly, the approximate curve B is calculated using the attention point 831 and the total four lumen positions of the point 835, the point 836, and the point 837 after the rotation direction.

Then, a unit vector a having the inclination of the straight line A and passing through the attention point 831 is obtained, and similarly, a unit vector b having the inclination of the straight line B and passing through the attention point 831 is obtained. Unit vector a, the unit vector b is the angle theta _ab and curvature determined by Equation (1).

  As described above, in “5-1. Calculation Method of Relative Size of Branch Diameter”, the number of lines having a correlation with the branch diameter is obtained as the relative size of the branch diameter. On the other hand, in “5-2. Calculation method of branch diameter”, the value of the branch diameter itself is obtained. Therefore, it should be noted that the values obtained by the respective methods cannot be directly compared.

  In general, a branch whose relative diameter is determined by “5-1. Calculation Method of Relative Diameter of Branch” is a side tube (a certain blood vessel) with respect to the main tube (blood vessel). There are two possible cases in which another blood vessel that branches off from the tube exists in the vertical direction, or the size of the branch is large and the near infrared light does not reach the blood vessel wall of the branch. It should be noted that since it is highly likely that this is a case where the branch size is large and near-infrared light does not reach the branch vessel wall, “5-1”, “5-2” When the diameter is obtained by each of the methods “”, priority is given to the size of the branch obtained by the method “5-1”.

  The construction angle of the longitudinal section image may be set based on the branch diameter (or the relative size) obtained here. For example, the angle information of the frame having the largest diameter (or the relative size of the diameter) may be used as the construction angle.

<6. Display of distance information between branch and frame having minimum lumen diameter>
The LCD monitor 113 displays a cross-sectional image of the target frame to be displayed and a vertical cross-sectional image generated at a construction angle with respect to the target frame, and further calculates a distance between the branch and the frame having the minimum lumen diameter. Then, the distance information may be displayed. The frame having the minimum lumen diameter indicates a stenosis part to be diagnosed, and information on how far away from the branch position is important. As shown in the schematic longitudinal sectional view of the tubular tissue in FIG. 9, the distance between the branch and the frame having the smallest lumen diameter can be calculated by any one of the methods L ₁ , L ₂ , and L _3. .

Where L ₁ is the distance between the branch boundary position (Distal edge) and stenosis position (frame with the smallest lumen diameter). L ₂ is the distance between the branch center and constriction position (frame with the smallest lumen diameter). L ₃ is the distance between the branch boundary position (Proximal edge) and stenosis position (frame with the smallest lumen diameter).

  In addition, the structure which calculates and displays the distance from the branch position of all the frames detected by the branch detection part 3021 to the stenosis part position may be sufficient. In addition, when generating and displaying a longitudinal section image for all frames in which branches are detected, calculate the distance from the branch position that is the display target of each longitudinal section image to the stenosis position. The structure to display may be sufficient.

<7. Display of distance information between branch and stent>
The LCD monitor 113 displays the cross-sectional image of the target frame that is the display target and the vertical cross-sectional image generated at the construction angle related to the target frame, and further displays the distance information by calculating the distance between the branch and the stent. May be. A stent is a medical device that expands a tubular tissue (blood vessel, trachea, esophagus, duodenum, large intestine, biliary tract, etc.) from the inside of a lumen. For a doctor, grasping the stent position is very important.

As shown in the schematic longitudinal sectional view of the tubular tissue in FIG. 10, the distance between the branch and the end of the stent 1001 can be calculated as L ₄ . L ₄ represents a distance between the branch center position and the stent end portion. As described with reference to FIG. 9, the distance between the branch boundary position (Distal edge) and the end of the stent or the distance between the branch boundary position (Proximal edge) and the stent 1001 may be calculated. .

  Note that the processing in each embodiment described above is performed by the signal processing unit 223 configured by a microprocessor. Since the microprocessor realizes its function by executing a program, the program naturally falls within the scope of the present invention. Further, the program is usually stored in a computer-readable storage medium such as a CD-ROM or DVD-ROM, and is set in a reading device (CD-ROM drive or the like) included in the computer and copied or installed in the system. It is obvious that such a computer-readable storage medium is also within the scope of the present invention.

  The present invention is not limited to the above-described embodiment, and various changes and modifications can be made without departing from the spirit and scope of the present invention. Therefore, in order to make the scope of the present invention public, the following claims are attached.

  This application claims priority based on Japanese Patent Application No. 2014-265204 filed on Dec. 26, 2014, the entire contents of which are incorporated herein by reference.

Claims (13)

A diagnostic imaging apparatus that obtains reflected light from the tubular tissue while moving a transmitting / receiving unit that continuously transmits and receives light in the axial direction in the tubular tissue, and generates an image based on the reflected light,
Line data generating means for generating line data used for generating a cross-sectional image of the tubular tissue based on the reflected light;
Detecting means for detecting a branch of the tubular tissue based on the line data;
Setting means for setting a construction angle of a longitudinal section image in a direction substantially parallel to the axial direction of the tubular tissue based on the detection result by the detection means;
A cross-sectional image generating means for generating a cross-sectional image in a direction intersecting the axial direction of the tubular tissue based on the line data and the detection result by the detecting means;
An image diagnostic apparatus comprising: a longitudinal section image generating unit configured to generate the longitudinal section image based on the line data and the construction angle.   The setting means, when a branch is detected in a plurality of frames by the detection means, calculates a diameter of the branch portion of the branch for each frame, and sets the construction angle based on the diameter The diagnostic imaging apparatus according to claim 1.   When the detection unit detects a branch in a plurality of frames, the setting unit calculates an angle formed by the main tube of the tubular tissue and the branch for each frame, and the construction angle is based on the formed angle. The diagnostic imaging apparatus according to claim 1, wherein:   The image diagnosis according to claim 1, wherein the setting unit sets the construction angle based on the number of branches that can be displayed when branches are detected in a plurality of frames by the detection unit. apparatus.   When the detection unit detects a branch in a plurality of frames, the setting unit determines whether a guide wire passes through the branch for each frame, and sets the construction angle based on the determination result. The diagnostic imaging apparatus according to claim 1.   The diagnostic imaging apparatus according to any one of claims 1 to 5, further comprising display means for displaying the cross-sectional image and the vertical cross-sectional image.   The display means further displays a plurality of highlight marks indicating branch positions on the longitudinal section image when branches are detected in a plurality of frames by the detection means. The diagnostic imaging apparatus described. It further comprises an operation means for accepting user input,
The setting means, when one of the plurality of highlight marks is selected by the user input, updates the construction angle based on the selection,
The image diagnosis apparatus according to claim 7, wherein the longitudinal section image generation unit regenerates the longitudinal section image based on the line data and the updated construction angle. When a branch is detected in one or more frames by the detection means, a calculation means for calculating a distance between a frame position where the branch is detected and a frame position having a minimum lumen diameter of the tubular tissue is further provided. ,
The image diagnostic apparatus according to claim 6, wherein the display unit further displays the distance calculated by the calculation unit. A calculation means for calculating a distance between the frame position of the cross-sectional image to be displayed including the branch and the frame position including the stent;
The image diagnostic apparatus according to claim 6, wherein the display unit further displays the distance calculated by the calculation unit. The angle information indicating the position of the branch detected in each frame is angle information corresponding to the center of the branch,
The diagnostic imaging apparatus according to claim 1, wherein the setting unit sets angle information corresponding to a center of the branch as the construction angle. A method of controlling an image diagnostic apparatus that acquires reflected light from a tubular tissue while moving a transmitting / receiving unit that continuously transmits and receives light in the axial direction of the tubular tissue and generates an image based on the reflected light. And
A line data generation step for generating line data used for generating a cross-sectional image of the tubular tissue based on the reflected light;
Detecting a branch of the tubular tissue based on the line data;
A setting step for setting a construction angle of a longitudinal section image in a direction substantially parallel to the axial direction of the tubular tissue based on the detection result by the detection step;
Based on the line data and the detection result of the detection step, a cross-sectional image generation step of generating a cross-sectional image in a direction intersecting the axial direction of the tubular tissue,
A method for controlling an image diagnostic apparatus, comprising: a longitudinal section image generating step for generating the longitudinal section image based on the line data and the construction angle.   The program for making a computer perform each process of the control method of the diagnostic imaging apparatus of Claim 12.