JP2011062301A - Optical structure image observation device, method for processing the structure information, and endoscope equipped with optical structure image observation device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To generate a tomographic image having a high S/N ratio and appropriate resolution from a shallow position to a deep position. <P>SOLUTION: In the processing part 22 of an OCT (Optical Coherence Tomography) processor 400, a focal position specifying part 230 specifies a plurality of different focal positions of measurement light L1 to an optical structure information detecting part 220. The part 220 detects optical structure information from an interference signal detected by an interference light detecting part at the focal position predetermined by the part 230. A tomographic structure information generating part 225 generates tomographic structure information for each of the plurality of different focal positions of the measurement light L1 based on the optical structure information detected by the part 220. A plurality of focal point images synthesizing part 221 generates synthetic tomographic image based on the tomographic structure information of each of the plurality of different focal positions stored in a memory 231. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an optical structure image observation apparatus, a structure information processing method thereof, and an endoscope apparatus including the optical structure image observation apparatus, and more particularly to an optical structure image observation apparatus characterized by information processing of optical structure information, and the structure information thereof The present invention relates to a processing method and an endoscope apparatus including an optical structure image observation apparatus.

  Conventionally, when acquiring an optical tomographic image of a living tissue, an optical tomographic image acquisition apparatus using OCT (Optical Coherence Tomography) may be used. This optical tomographic image acquisition apparatus divides low-coherent light emitted from a light source into measurement light and reference light, and then reflects or backscatters light from the measurement object when the measurement light is applied to the measurement object. The light and the reference light are combined, and an optical tomographic image is acquired based on the intensity of the interference light between the reflected light and the reference light. Hereinafter, the reflected light and the backscattered light from the measurement object are collectively referred to as reflected light.

  The OCT measurement is roughly divided into two types: TD-OCT (Time domain OCT) measurement and FD-OCT (Fourier Domain OCT) measurement. In the TD-OCT measurement, the reflected light intensity distribution corresponding to the position in the depth direction of the measurement target (hereinafter referred to as the depth position) is acquired by measuring the interference light intensity while changing the optical path length of the reference light. Is the method.

  On the other hand, in the FD-OCT measurement, the interference light intensity is measured for each spectral component of the light without changing the optical path lengths of the reference light and the signal light, and the spectral interference intensity signal obtained here is Fourier transformed by a computer. This is a method of obtaining a reflected light intensity distribution corresponding to a depth position by performing a representative frequency analysis. In recent years, it has attracted attention as a technique that enables high-speed measurement by eliminating the need for mechanical scanning existing in TD-OCT.

  By the way, in the OCT that targets a tissue having high optical scattering characteristics such as the digestive tract and the bronchi, there is a problem that the incident light is rapidly attenuated and the S / N ratio is lowered in a deep portion.

As a solution to this problem, a technique (Non-Patent Document 1) has been proposed in which the focal plane of light is placed at a position deeper than the surface so that attenuation can be compensated for by the light condensing property so that a deep portion can be drawn. Yes.
However, when the focal position is adjusted to a deep part, the lateral resolution is lowered at a position shallower than the focal position due to the influence of the depth of focus and light scattering, and detailed structural information is lost.

  Therefore, a method of optimizing the horizontal resolution in the shallow part by aligning the focal position with the surface (Patent Document 1), a method of obtaining information up to the deep part by overlaying images with different center wavelengths (Patent Document 2), etc. are proposed. Has been.

JP-A-9-133509 JP 2007-151631 A

Biomedical engineering, Vol. 44 (2006), No. 4 pp.606-612, "Tomographic imaging of human arterioles using optical coherence tomography"

  However, in the methods disclosed in Non-Patent Document 1 and Patent Document 1, the visibility of the structure that becomes the observation target can be optimized by adjusting the focus position to the specific position of the target. There is a problem that an image with good visibility cannot be obtained at a portion other than the combined position.

  In the method disclosed in Patent Document 2, it is possible to synthesize and display interference waveforms at a plurality of focal positions by using aberrations of a plurality of types of light sources with a center frequency. Is fixed, the focal position cannot be changed according to the purpose or the state of the target.

  The present invention has been made in view of such circumstances, and an optical structure image observation apparatus capable of generating a tomographic image having a high S / N ratio and an appropriate resolution from a shallow position to a deep position, and structure information thereof. An object is to provide an endoscope apparatus including a processing method and an optical structure image observation apparatus.

  In order to achieve the object, an optical structure image observation apparatus according to claim 1, a light source unit that emits light by sweeping a wavelength, and demultiplexes the light emitted from the light source unit into reference light and measurement light. Orthogonal to the depth direction, and an irradiating / condensing means for irradiating the measurement light in the depth direction of the measurement target and condensing the return light reflected or backscattered by the measurement target. A scanning unit that two-dimensionally scans the irradiation position of the irradiation / condensing unit within a plane at a predetermined scanning interval, and a focal position specification that specifies a plurality of focal positions of the measurement light irradiated by the irradiation / condensing unit Means, focus driving means for positioning and driving the focus of the irradiation / condensing means at the plurality of focal positions, and the return light condensed by the irradiation / condensing means and the reference through a predetermined optical path length path The light is combined for each of the plurality of focal positions and dried. Interfering means for acquiring light, tomographic structure information generating means for generating tomographic structure information of the measurement target for each of the plurality of focal positions based on the interference light, and tomographic structure information for the plurality of focal positions And a tomographic image generating means for generating a tomographic image of the measurement object.

  The optical structure image observation apparatus according to claim 1, wherein irradiation light / condensing means irradiates the measurement light in a depth direction of the measurement object and collects return light reflected or backscattered by the measurement object. Then, the irradiation means of the irradiation / condensing means is two-dimensionally scanned at the predetermined scanning interval in a plane orthogonal to the depth direction by the scanning means, and the irradiation / collection is performed by the focal position specifying means. A plurality of focus positions of the measurement light emitted by the light means are designated, the focus of the irradiation / collection means is positioned and driven to the focus positions by the focus driving means, and the return light is driven by the interference means. And the reference light are combined for each of the plurality of focal positions to acquire the interference light, and the tomographic structure of the measurement target for each of the plurality of focal positions based on the interference light by the tomographic structure information generation unit Information to generate the tomographic image A tomographic image having a high S / N ratio and an appropriate resolution is generated from a shallow position to a deep position by generating a tomographic image of the measurement object based on the tomographic structure information for each of the plurality of focal positions. Make it possible.

  The optical structure image observation device according to claim 1, wherein the scanning unit is scanned at a pre-scan interval coarser than the predetermined scan interval, as in the optical structure image observation device according to claim 2, It is preferable to further include a focal position setting unit that sets the plurality of focal positions designated by the focal position designation unit based on the tomographic structure information obtained by scanning at a pre-scan interval.

  The optical structure image observation device according to claim 1 or 2, wherein the tomographic structure information generation unit sets the layer to be measured based on the interference light. The tomographic image generation means extracts the tomographic structure information for each layer based on the focal position near the layer among the plurality of focal positions as layer-neighboring structure information, and synthesizes the extracted layer-neighboring structure information It is preferable to generate the tomographic image by doing so.

  The optical structure image observation device according to claim 1 or 2, wherein the tomographic image generation means is configured to obtain the tomographic structure information for each of the plurality of focal positions. Is preferably calculated by a weighting function that changes in the depth direction, and the tomographic image is generated by combining the calculation results for each of the plurality of focal positions.

  The optical structure image observation device according to claim 1, wherein the tomographic image generation unit is configured to provide the tomographic structure information for each of the plurality of focal positions. It is preferable to generate the tomographic image by calculating edge information of horizontal resolution at, and combining the calculation results for each of the plurality of focal positions.

  The optical structure image observation apparatus according to any one of claims 1 to 5, wherein the display control means causes at least the display means to display the tomographic image, as in the optical structure image observation apparatus according to claim 6. And display form designating means for designating a display form of the display means controlled by the display control means, wherein the display control means has the plurality of focus positions on the tomographic image displayed by the display means. Position information and image generation information when the tomographic image generation unit generates a tomographic image are superimposed, and the display form designating unit inputs based on the position information and the image generation information superimposed and displayed on the display unit It is preferable to specify the display form by input information.

  The optical structure image observation apparatus according to any one of claims 1 to 6, as in the optical structure image observation apparatus according to claim 7, wherein the tomographic image generated by the tomographic image generation unit is used. It is preferable to further include a three-dimensional structure image generating unit that generates the optical three-dimensional structure image of the measurement target.

  9. The structure information processing method of the optical structure image observation apparatus according to claim 8, wherein the light source means that emits light by sweeping the wavelength, and the demultiplexing that demultiplexes the light emitted from the light source means into reference light and measurement light. The structure of the optical structure image observation apparatus comprising: means; and irradiation / condensing means for irradiating the measurement light in the depth direction of the measurement target and condensing the return light reflected or backscattered by the measurement target In the information processing method, a scanning step of two-dimensionally scanning an irradiation position of the irradiation / condensing unit at a predetermined scanning interval in a plane orthogonal to the depth direction, and the measurement irradiated by the irradiation / condensing unit A focus position designating step for designating a plurality of focus positions of light, a focus driving step for positioning and driving a focus of the irradiation / condensing means at the plurality of focus positions, and the light collected by the irradiation / condensing means Return light and predetermined path length The reference light that has passed through is combined with each of the plurality of focal positions to obtain interference light, and the tomographic structure information of the measurement target for each of the plurality of focal positions is generated based on the interference light A tomographic structure information generating step; and a tomographic image generating step of generating a tomographic image of the measurement object based on the tomographic structure information for each of the plurality of focal positions.

  The structure information processing method of the optical structure image observation device according to claim 8, as in the structure information processing method of the optical structure image observation device according to claim 9, wherein the pre-scan interval is coarser than the predetermined scan interval. A focal position setting step for setting the plurality of focal positions designated by the focal position designation means based on the tomographic structure information obtained by scanning the scanning means at the pre-scan interval; It is preferable to provide.

  An endoscope apparatus according to a tenth aspect includes the optical structure image observation apparatus according to any one of the first to seventh aspects.

  As described above, according to the present invention, there is an effect that a tomographic image having a high S / N ratio and an appropriate resolution can be generated from a shallow position to a deep position.

The block diagram which shows the internal structure of the OCT processor as an optical structure image observation apparatus concerning 1st Embodiment. The figure which shows the front-end | tip structure of the OCT probe of FIG. The figure which shows the front-end | tip structure of the modification 1 of the OCT probe of FIG. The figure which shows the front-end | tip structure of the modification 2 of the OCT probe of FIG. The figure which shows the front-end | tip structure of the modification 3 of the OCT probe of FIG. The figure which shows the front-end | tip structure of the modification 4 of the OCT probe of FIG. The block diagram which shows the structure of the process part of the OCT processor of FIG. The figure explaining the outline | summary of the process in the process part of the OCT processor of FIG. The flowchart which shows the detail of a process of the process part of the OCT processor of FIG. The figure which shows the acquired image in a different focus position for producing | generating the synthetic | combination tomographic image in the process of FIG. FIG. 9 is a first diagram illustrating weighting for generating a composite tomographic image in the processing of FIG. 2nd figure explaining the weighting for the production | generation of the synthetic | combination tomographic image in the process of FIG. The block diagram which shows the structure of the process part of the OCT processor which concerns on 2nd Embodiment. The figure explaining the prescan interval of the prescan information processing part of FIG. The figure explaining the setting of the focus position by the pre-scan information processing part of FIG. The figure explaining the boundary detection method for the setting of the focus position by the prescan information processing part of FIG. FIG. 13 is a first diagram illustrating a contrast method for setting a focal position by the pre-scan information processing unit in FIG. FIG. 14 is a second diagram illustrating a contrast method for setting a focal position by the prescan information processing unit in FIG. The flowchart which shows the detail of a process of the process part of the OCT processor of FIG. FIG. 19 is a first diagram illustrating a method for determining a combination of focal positions using pre-measurement image information in the pre-scan information processing of FIG. FIG. 19 is a second diagram illustrating a method for determining a combination of focus positions using pre-measurement image information in the pre-scan information processing of FIG. FIG. 19 is a third diagram illustrating a method for determining a combination of focal positions using measurement image information in prescan in the prescan information processing of FIG. FIG. 19 is a fourth diagram illustrating a method for determining a combination of focal positions using measurement image information in prescan in the prescan information processing of FIG. FIG. 19 is a fifth diagram illustrating a method for determining a combination of focal positions using measurement image information in prescan in the prescan information processing of FIG. FIG. 13 is a first diagram for explaining composite tomographic image generation processing of the multifocal image composition unit in FIG. 13. 2nd figure for demonstrating the production | generation process of the synthetic | combination tomographic image of the multifocal image synthetic | combination part of FIG. FIG. 13 is a third diagram for explaining the composite tomographic image generation process of the multifocal image composition unit in FIG. 13. FIG. 14 is a fourth diagram for explaining the composite tomographic image generation processing of the multifocal image composition unit in FIG. 13; The figure which shows the structure of the diagnostic imaging apparatus which consists of an OCT processor in each embodiment, an OCT probe, and an endoscope apparatus. The figure which shows the front-end | tip structure of the OCT probe of FIG. The figure which shows the front-end | tip structure of the modification of the OCT probe of FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, an optical structure image observation apparatus, a structure information processing method thereof, and an endoscope apparatus including an optical structure image observation apparatus according to the present invention will be described in detail with reference to the accompanying drawings.

First embodiment:
FIG. 1 is a block diagram showing an internal configuration of an OCT processor as an optical structure image observation apparatus according to the first embodiment of the present invention.

  An OCT processor 400 shown in FIG. 1 is for acquiring an optical tomographic image of a measurement object by an optical coherence tomography (OCT) measurement method, and is a first light source unit that emits light La for measurement. One light source (first light source unit) 12 and light La emitted from the first light source 12 are branched into measurement light (first light flux) L1 and reference light L2, and a measurement target S that is a subject. An optical fiber coupler (branching / combining unit) 14 as a demultiplexing unit that multiplexes the return light L3 from the laser beam and a reference light L2 that has passed through an optical path length adjusting unit 26, which will be described later, to generate interference light L4 and L5; An OCT probe 600 as an optical probe including a probe-side optical fiber FB1 that guides the measurement light L1 branched by the coupler 14 to the measurement target and guides the return light L3 from the measurement target; An optical fiber FB2 that guides the constant light L1 to the probe-side optical fiber FB1, and guides the return light L3 guided by the probe-side optical fiber FB1, and the probe-side optical fiber FB1 are connected to the optical fiber FB2, and the measurement light The optical connector 18 for transmitting L1 and the return light L3, the interference light detection unit 20 as interference means for detecting the interference light L4 and L5 generated by the optical fiber coupler 14 as interference signals, and the interference light detection unit 20 And a processing unit 22 that processes the detected interference signal to acquire optical information and processes the information. An image is displayed on the monitor device 500 based on the optical structure information acquired by the processing unit 22.

  The OCT processor 400 also includes a second light source (second light source unit) 13 that emits aiming light (second light flux) Le for indicating a mark of measurement, and an optical path that adjusts the optical path length of the reference light L2. A length adjusting unit 26, an optical fiber coupler 28 that splits the light La emitted from the first light source 12, and detection units 30a and 30b that detect the interference lights L4 and L5 combined by the optical fiber coupler 14, And an operation control unit 32 for inputting various conditions to the processing unit 22 and changing settings.

  In the OCT processor 400 shown in FIG. 1, various lights including the above-described emission light La, aiming light Le, measurement light L1, reference light L2, return light L3, and the like are guided between components such as optical devices. Various optical fibers FB (FB3, FB4, FB5, FB6, FB7, FB8, etc.) including the probe-side optical fiber FB1 and the optical fiber FB2 are used as light paths for wave transmission.

  The first light source 12 emits light for OCT measurement (for example, laser light having a wavelength of 1.3 μm or low coherence light), and the first light source 12 sweeps the frequency at a constant period. It is a light source that emits a laser beam La centered at a wavelength of 1.3 μm, for example, in the infrared region. The first light source 12 includes a light source 12a that emits laser light or low-coherence light La, and a lens 12b that condenses the light La emitted from the light source 12a. The light La emitted from the first light source 12 is branched into the measurement light L1 and the reference light L2 by the optical fiber coupler 14 through the optical fibers FB4 and FB3, and the measurement light L1 is input to the optical connector 18. .

  Further, the second light source 13 emits visible light so as to make it easy to confirm the measurement site as the aiming light Le. For example, red semiconductor laser light with a wavelength of 0.66 μm, He—Ne laser light with a wavelength of 0.63 μm, blue semiconductor laser light with a wavelength of 0.405 μm, or the like can be used. Therefore, the second light source 13 includes, for example, a semiconductor laser 13a that emits red, blue, or green laser light and a lens 13b that collects the aiming light Le emitted from the semiconductor laser 13a. The aiming light Le emitted from the second light source 13 is input to the optical connector 18 through the optical fiber FB8.

  In the optical connector 18, the measurement light L <b> 1 and the aiming light Le are combined and guided to the probe-side optical fiber FB <b> 1 in the OCT probe 600.

  The optical fiber coupler 14 is composed of, for example, a 2 × 2 optical fiber coupler, and is optically connected to the optical fiber FB2, the optical fiber FB3, the optical fiber FB5, and the optical fiber FB7, respectively.

  The optical fiber coupler 14 branches the light La incident from the first light source 12 via the optical fibers FB4 and FB3 into the measurement light (first light beam) L1 and the reference light L2, and the measurement light L1 is split into the optical fiber FB2. The reference light L2 is incident on the optical fiber FB5.

  Furthermore, the optical fiber coupler 14 is incident on the optical fiber FB5, is subjected to frequency shift and optical path length change by the optical path length adjusting unit 26 described later, and is returned by the optical fiber FB5 and acquired by the OCT probe 600 described later. Then, the light L3 guided from the optical fiber FB2 is multiplexed and emitted to the optical fiber FB3 (FB6) and the optical fiber FB7.

  The OCT probe 600 is connected to the optical fiber FB2 through the optical connector 18, and the measurement light L1 combined with the aiming light Le from the optical fiber FB2 through the optical connector 18 is probe-side optical fiber FB1. Is incident on. The measurement light L1 combined with the incident aiming light Le is transmitted by the probe side optical fiber FB1, and is irradiated to the measurement object S. Then, the return light L3 from the measuring object S is acquired, and the acquired return light L3 is transmitted by the probe-side optical fiber FB1 and emitted to the optical fiber FB2 through the optical connector 18.

  In addition, the OCT probe 600 is combined with the aiming light Le, and the measurement optical L1 is a scanning unit that irradiates the measurement target S with the measurement light L1 emitted from the probe-side optical fiber FB1 and irradiates the measurement target S. A system 601 and an optical system driving mechanism 602 as a focus driving means for two-dimensionally scanning the measuring light L1 in the measuring optical system 601 and for changing the focal position of the measuring light L1 are provided.

  The optical connector 18 combines the measurement light (first light beam) L1 and the aiming light (second light beam) Le.

  The interference light detection unit 20 is connected to the optical fibers FB6 and FB7, and uses the interference lights L4 and L5 generated by combining the reference light L2 and the return light L3 by the optical fiber coupler 14 as interference signals. The interference means to detect is comprised.

  Here, the OCT processor 400 is provided on the optical fiber FB6 branched from the optical fiber coupler 28. The detector 30a detects the light intensity of the interference light L4, and the light of the interference light L5 on the optical path of the optical fiber FB7. And a detector 30b for detecting the intensity.

  The interference light detection unit 20 performs Fourier transform on the interference light L4 detected from the optical fiber FB6 and the interference light L5 detected from the optical fiber FB7 based on the detection results of the detectors 30a and 30b, thereby measuring the measurement target S. The intensity of the reflected light (or backscattered light) at each depth position is detected.

  The processing unit 22 acquires optical structure information from the interference signals extracted by the interference light detection unit 20 at a plurality of different focal positions, and generates an optical tomographic structure image and an optical three-dimensional structure image based on the acquired optical structure information. Then, an image obtained by performing various kinds of processing on the optical three-dimensional structure image is output to the monitor device 500. The detailed configuration of the processing unit 22 will be described later.

  The optical path length adjustment unit 26 is disposed on the emission side of the reference light L2 of the optical fiber FB5 (that is, the end of the optical fiber FB5 opposite to the optical fiber coupler 14).

  The optical path length adjustment unit 26 includes a first optical lens 80 that converts the light emitted from the optical fiber FB5 into parallel light, a second optical lens 82 that condenses the light converted into parallel light by the first optical lens 80, and The reflection mirror 84 that reflects the light collected by the second optical lens 82, the base 86 that supports the second optical lens 82 and the reflection mirror 84, and the base 86 are moved in a direction parallel to the optical axis direction. The optical path length of the reference light L2 is adjusted by changing the distance between the first optical lens 80 and the second optical lens 82.

  The first optical lens 80 converts the reference light L2 emitted from the core of the optical fiber FB5 into parallel light, and condenses the reference light L2 reflected by the reflection mirror 84 on the core of the optical fiber FB5.

  The second optical lens 82 condenses the reference light L2 converted into parallel light by the first optical lens 80 on the reflection mirror 84 and makes the reference light L2 reflected by the reflection mirror 84 parallel light. Thus, the first optical lens 80 and the second optical lens 82 form a confocal optical system.

  Further, the reflection mirror 84 is disposed at the focal point of the light collected by the second optical lens 82 and reflects the reference light L2 collected by the second optical lens 82.

  As a result, the reference light L2 emitted from the optical fiber FB5 becomes parallel light by the first optical lens 80 and is condensed on the reflection mirror 84 by the second optical lens 82. Thereafter, the reference light L2 reflected by the reflection mirror 84 becomes parallel light by the second optical lens 82 and is condensed by the first optical lens 80 on the core of the optical fiber FB5.

  The base 86 fixes the second optical lens 82 and the reflection mirror 84, and the mirror moving mechanism 88 moves the base 86 in the optical axis direction of the first optical lens 80 (direction of arrow A in FIG. 1). .

  By moving the base 86 in the direction of arrow A with the mirror moving mechanism 88, the distance between the first optical lens 80 and the second optical lens 82 can be changed, and the optical path length of the reference light L2 can be adjusted. Can do.

  Although not shown, the operation control unit 32 includes input means such as a keyboard and a mouse, and control means for managing various conditions based on the input information, and is connected to the processing unit 22. The operation control unit 32 inputs, sets, and changes various processing conditions and the like (including focus position designation information described later) in the processing unit 22 based on an operator instruction input from the input unit.

  Note that the operation control unit 32 may display the operation screen on the monitor device 500, or may provide a separate display unit to display the operation screen. In addition, the operation control unit 32 controls the operation of the first light source 12, the second light source 13, the optical connector 18, the interference light detection unit 20, the optical path length, the detection units 30a and 30b, and sets various conditions. May be.

  FIG. 2 is a diagram showing the configuration of the OCT probe of FIG. The measurement optical system 601 of the OCT probe 600 according to the present embodiment uses the measurement light L1 combined with the aiming light Le emitted from the probe-side optical fiber FB1 (hereinafter simply referred to as measurement light L1) on the measurement target S. A galvanometer mirror 604 for scanning and a lens unit 606 for converting the measurement light L1 into parallel light and condensing the galvanometer mirror 604 are configured.

  In the OCT probe 600, the measurement target S is arranged on the table 612 of the movable stage 611 that can be provided on the base 610. For example, as shown in FIG. 2, the movable stage 611 moves the table 612 to the X axis, which is an axis on a horizontal plane substantially orthogonal to the Y axis, when the scanning axis scanned by the galvano mirror 604 is the Y axis. An X-axis movable unit 613 for scanning along the Z-axis, and a Z-axis movable unit 614 that drives in the depth direction of the measuring object S that is the Z-axis direction orthogonal to the XY plane.

  The optical system drive mechanism 602 (see FIG. 1) of the OCT probe 600 drives the galvanometer mirror 604, the X-axis movable unit 613, and the Z-axis movable unit 614.

  The OCT processor 400 and the OCT probe 600 according to the present embodiment can perform desired operations at a plurality of focal positions with respect to the measurement target S by moving the Z-axis movable unit 614 in the Z-axis direction by the optical system driving mechanism 602. A plurality of optical structure information in a range can be obtained, and a tomographic image and an optical three-dimensional structure image can be obtained based on the acquired plurality of optical structure information.

The configuration of the OCT probe is not limited to the configuration in FIG. 2 in which the stage on which the measurement target is placed moves in the depth direction, and can be configured as in the following modifications 1 to 4 of the OCT probe.
(1) OCT probe modification 1: Configuration in which the measurement optical system 601 moves in the Y-axis direction and the Z-axis direction (depth direction) (see FIG. 3)
(2) Modification 2 of OCT probe: Configuration for changing the lens interval of the lens unit 606 (see FIG. 4)
(3) Modification 3 of the OCT probe: a configuration in which the probe-side optical fiber FB1 and the lens unit 606 (inside the two-dot broken line in FIG. 5) move as a whole and change the optical path length with respect to the measurement target S (see FIG. 5).
(4) Modification 4 of the OCT probe: a configuration in which the optical path length is changed by horizontal movement of the galvanometer mirror 604 and the table 612 (within the two-dot broken line in FIG. 6) (see FIG. 6).

  FIG. 7 is a block diagram showing the configuration of the processing unit of the OCT processor. As shown in FIG. 7, the processing unit 22 of the OCT processor 400 includes a focal position designation unit 230, an optical structure information detection unit 220, a tomographic structure information generation unit 225, a memory 231, a multifocal image synthesis unit 221, and an optical stereoscopic structure image. A construction unit 222, a display control unit 224, and an I / F unit 228 are provided.

  The focal position designation unit 230 designates a plurality of different focal positions of the measurement light L1 with respect to the optical structure information detection unit 220, and constitutes a focal position designation unit.

  The optical structure information detection unit 220 detects optical structure information from the interference signal detected by the interference light detection unit 20 at the focal position designated by the focal position designation unit 230. The optical structure information detection unit 220 controls the optical system driving mechanism 602 of the OCT probe 600 based on the focal position designated by the focal position designation unit 230.

  The tomographic structure information generation unit 225 generates tomographic structure information (tomographic image data) for each of a plurality of different focal positions of the measurement light L1 based on the optical structure information detected by the optical structure information detection unit 220. Structure information generating means is configured.

  The memory 231 stores the tomographic structure information (tomographic image data) generated by the tomographic structure information generation unit 225 for each of a plurality of different focal positions.

  The multi-focus image composition unit 221 is a tomographic image generation unit that generates a composite tomographic image based on tomographic structure information (tomographic image data) for each of a plurality of different focal positions stored in the memory 231. The composite tomographic image generated by the image 221 will be described later.

  The optical three-dimensional structure image constructing unit 222 generates an optical three-dimensional structure image based on the combined tomographic image generated by the multi-focus image combining unit 221 and constitutes a three-dimensional structure image generating unit.

  The display control unit 227 displays the combined tomographic image generated by the multi-focus image combining unit 221 or the optical three-dimensional structure image from the optical three-dimensional structure image constructing unit 222 according to a control signal from the operation control unit 32 via the I / F unit 228. This is output to the monitor device 500 and constitutes a display control means.

  The I / F unit 228 is a communication interface unit that transmits a setting signal and a designation signal from the operation control unit 32 to each unit, and constitutes a display form designation unit.

  First, an outline of processing in the processing unit 22 of the OCT processor 400 of the present embodiment configured as described above will be described with reference to FIG.

  As illustrated in FIG. 8, the processing unit 22 of the present embodiment acquires tomographic structure information (tomographic image data of the image A having a shallow focal position and the image B having a deep focal position in FIG. 8) that are images having different focal positions. Then, by generating a combined tomographic image that is a combined image obtained by combining these tomographic structure information (tomographic image data of the image A and the image B) by image combining processing such as addition processing, from a shallow position to a deep position A composite tomographic image having a high S / N ratio and appropriate resolution is displayed and presented on the monitor device 500.

  Details of the operation of the processing unit 22 of the OCT processor 400 according to the present embodiment will be described with reference to FIGS.

  As shown in FIG. 9, the processing unit 22 of the OCT processor 400 sets the parameter k to 1 (step S1).

  Next, the processing unit 22 acquires the kth focus position Fd (k) from the focus position specifying unit 230, and the optical structure information detection unit 220 scans the measurement light L1 at the focus position Fd (k) ( Scan) (step S2), and the tomographic structure information generation unit 225 generates tomographic structure information (tomographic image data) at the focal position Fd (k) (step S3).

  In the processing in step S3, the optical structure information detection unit 220 converts the scan data into tomographic structure information (tomographic image data) at the focal position Fd (k) through A / D conversion and signal processing, and generates the generated focus. The tomographic structure information (tomographic image data) at the position Fd (k) is stored in the memory 231.

  Then, the processing unit 22 determines whether or not the parameter k exceeds a predetermined number (the number of focal positions to be scanned) N in step S4. If the parameter k does not exceed N (k ≦ N), the process proceeds to step S5. The parameter k is incremented and the process returns to step S2. If the parameter k exceeds N (k> N), the process proceeds to step S6.

  Subsequently, the processing unit 22 generates composite tomographic images at a plurality of focal positions using the N pieces of tomographic structure information (tomographic image data) stored in the memory 231 by the multifocal image synthesis unit 221 ( Step S6). The generation of the composite tomographic image will be described later.

  Then, the processing unit 22 generates a light stereoscopic structure image based on the combined tomographic image generated by the multi-focus image combining unit 221 in the light stereoscopic structure image constructing unit 222, and the display control unit 227 generates a multi-focus image combining unit. An image display process is performed to display the composite tomographic image generated by 221 or the optical three-dimensional structure image from the optical three-dimensional structure image constructing unit 222 on the monitor device 500 by a control signal of the operation control unit 32 via the I / F unit 228. (Step S7), the process ends.

  Note that in the image display processing in step S7, the combination of the applicable image synthesis method, the synthesis parameter, and the measured depth of focus are displayed together so that the user can specify and change them. It is possible to generate and display an image suitable for the purpose of use of the user.

  The generation of a composite tomographic image in the processing of FIG. 9 will be described. 9, the memory 231 stores the tomographic structure information (tomographic image data) of the acquired image at the focal position Fd (1), the focal position Fd (2), and the focal position Fd (3) as shown in FIG. ) Is stored.

  Therefore, in the process of step S6, a plurality of tomographic structure information (tomographic image data) at the focal position Fd (1), the focal position Fd (2), and the focal position Fd (3) is averaged and synthesized to obtain a synthetic tomography. Generate an image.

  Since simple averaging integrates even depth information beyond the focal depth, in this embodiment, weighting is performed around the focal position using a weighting function as shown in FIGS. The converted tomographic structure information (tomographic image data) is averaged.

  Note that the weighting function used for weighting may be a rectangular function in which the focal depth region is 1 and the non-focal depth region is 0, or a function that changes gently around the focal position.

  As described above, in this embodiment, a plurality of different focal positions are designated, tomographic structure information (tomographic image data) for each designated different focal position is acquired, and these tomographic structure information (tomographic image data) is synthesized. Thus, a tomographic image having a high S / N ratio and an appropriate resolution can be generated from a shallow position to a deep position.

Second embodiment:
Since the second embodiment is almost the same as the first embodiment, only different points will be described, and the same components will be denoted by the same reference numerals and description thereof will be omitted.

  As illustrated in FIG. 13, the processing unit 22 of the second embodiment includes a focal position designation unit 230, an optical structure information detection unit 220, a tomographic structure information generation unit 225, a memory 231 and a plurality of focal points that are the configurations of the first embodiment. In addition to the image composition unit 221, the optical three-dimensional structure image construction unit 222, the display control unit 224, and the I / F unit 228, a prescan information processing unit 240 is provided.

  The pre-scan information processing unit 240 causes the optical structure information detection unit 220 to scan the measurement light L1 at a pre-scan interval that is coarser than a normal scan interval, and the tomography obtained by scanning at the pre-scan interval. A focal position setting unit that sets a plurality of focal positions Fd (k) designated by the focal position designation unit 230 based on the structure information.

  Note that the prescan information processing unit 240 controls the optical structure information detection unit 220 so that the optical system driving mechanism 602 (see FIG. 1) causes the measurement light L1 to be at a predetermined focal position and a prescan interval at the time of prescan. The measuring object S is two-dimensionally scanned.

  Other configurations are the same as those of the first embodiment.

  Here, an outline of pre-scanning by the pre-scan information processing unit 240 in the present embodiment will be described.

(A) Horizontal resolution: Δx
The horizontal resolution Δx of the OCT is determined by the center wavelength λ of the light source, the focal length f, and the beam diameter d hitting the sample, as shown in Equation (1). In order to obtain a high horizontal resolution Δx, it is necessary to narrow the beam with a lens having a high numerical aperture NA.

(B) Depth of focus: Z
On the other hand, the focal depth Z decreases as the horizontal resolution Δx decreases. That is, the focal depth Z calculated by the equation (2) becomes shorter as the beam is narrowed down to obtain a higher horizontal resolution Δx. Since the depth of focus is proportional to the square of the horizontal resolution, the depth of focus Z decreases rapidly as the horizontal resolution Δx increases.

  In the case of OCT targeting the fundus and blood vessels, the measurement of the layer structure is emphasized and it is required to be able to measure to a deep part. For this reason, horizontal resolution is often sacrificed in order to obtain a high depth of focus.

  However, in the case of OCT for the digestive tract and bronchi, since the travel of the gland duct and blood vessels is important information for diagnosis, it is necessary to have a high horizontal resolution. On the other hand, it is necessary to be able to measure changes in the layer structure, such as discontinuity of the mucosal muscularis located about several hundred um deep from the surface of the mucosa.

  In the second embodiment, the problem of achieving both horizontal resolution and measurable depth is solved by performing pre-scan processing and changing the focal position of the measurement light L1.

The living tissue to be measured S is
(1) The depth at which the structure of interest is located from the surface is unknown (2) The distance to the measuring device is not constant due to the rise or depression of the surface, etc. Multiple focal positions determined for the above two reasons When OCT measurement is performed in this way, measurement is performed while changing the focal position even at a deep position that is not the background or measurement target, which is not efficient. This problem is particularly serious when acquiring 3D data.

  If the position of the surface of the measuring object S and the depth of the observation target structure can be roughly grasped, the focal positions necessary for the OCT measurement can be limited to several points, and the efficiency can be improved.

  Usually, OCT scanning is performed at sampling intervals equal to or smaller than the horizontal / vertical resolution determined by the characteristics of the light source to obtain detailed internal information. However, in order to roughly grasp the position of the surface and the internal structure and calculate the focal position used in the main (normal) scan, it is not necessary to measure at fine intervals.

  In the three-dimensional Fourier domain OCT, the sampling interval in the vertical direction is determined by data processing by Fourier transform, and does not significantly affect the scan speed. The concept of pre-scanning in this embodiment is to limit the range of horizontal scanning (x and y directions in FIG. 14) or to widen the sampling interval (pre-scanning interval).

During pre-scanning, the internal structure and surface irregularities are unknown, so it is necessary to acquire images at as many focal positions as possible. Therefore, in this embodiment, setting is made so that “focus position z _n = z _n−1 + focus depth” as shown in FIG.

  For example, the following boundary detection method or contrast method is used as a method for setting the combination of focus depths using the prescan result.

Boundary detection method:
(A) When the layer to be measured is determined As shown in FIG. 16, the boundary between the target surface and the layer is extracted from the image obtained by the pre-scan. If the layer to be measured is between the surface and the boundary 1, the focal position may be selected between the shallowest point on the surface and the deepest point on the boundary 1. In the case of FIG. 16, z1 ′, z2 ′, and z3 ′ are the focal positions used in the main scan.
(B) When the depth range to be measured is determined Extract the surface of the object from the image obtained by pre-scanning. The shallowest point of the surface is set as the reference point z1 ′, and the focal position zn ′ is determined at the focal depth interval so as to cover the measurement depth range.

Contrast method:
The standard deviation of the signal intensity is calculated in the region of the focal depth range centered on the focal position zn as shown in FIGS. 17 and 18 in the image acquired by the pre-scan. The standard deviation is small in a region where there is no structural change as shown in FIG. 17, and the standard deviation is large in a region where there is a structural change as shown in FIG. A focus position with a standard deviation equal to or greater than a certain value is determined as a focus position used in the main scan.

  Next, details of the operation of the processing unit 22 of the OCT processor 400 of this embodiment will be described with reference to FIGS. 20 to 24 using the flowchart of FIG.

  In the processing unit 22 of the present embodiment, as shown in FIG. 19, prior to the processing of steps S1 to S7 (see FIG. 9) of the first embodiment, the prescan information processing unit 240 performs the processing of steps S11 to S13. I do. Therefore, in the present embodiment, only steps S11 to S13 will be described, and the processes in steps S1 to S7 are the same as those in the first embodiment, and thus description thereof will be omitted.

  As shown in FIG. 19, first, the processing unit 22 of the present embodiment controls the optical structure information detection unit 220 by the prescan information processing unit 240 to prescan the measurement target S at an interval coarser than the normal scan interval ( Step S11).

  Next, the processing unit 22 performs pre-scan information processing for determining an appropriate combination of focus positions Fd (k) at the time of the main scan in the pre-scan information processing unit 24 (step S12).

  Then, the processing unit 22 sets the focal position Fd (k) at the time of the main scan determined in step S12 to the focal position designation unit 230 (step S13), and proceeds to the processing of step S1.

  By the pre-scan information processing in step S12, it is possible to reduce the number of times the focal position is changed during the main scan and shorten the measurement time.

In the prescan information processing, the following examples are conceivable as a method for determining a combination of focus positions using measurement image information in prescan.
(1) As shown in FIGS. 20 to 22, the surface of the object (boundary A: FIG. 20) and the boundary position of the layer (boundary B: FIG. 21, boundary C: FIG. 22) are detected, and the focal position Fd ( k). In addition, since a signal stronger than the periphery is detected at the boundary surface between layers as the OCT signal, a technique such as using a differential value of the depth direction signal is effective.
(2) The OCT tomographic image has a high contrast in the in-focus histogram portion as shown in FIGS. A contrast within a certain range is calculated from the acquired image, and a focal position at which the highest contrast is obtained in the target structure is selected.

  In this embodiment, in step S6, the multi-focus image composition unit 221 prescans N pieces of tomographic structure information (tomographic image data) stored in the memory 231 as shown in FIGS. It is possible to generate a composite tomographic image at a plurality of focal positions by dividing each layer obtained by information processing and adding only the tomographic structure information (tomographic image data) at the focal position closest to each layer.

  In this embodiment, in step S6, the multi-focus image composition unit 221 extracts an edge having a high resolution in the horizontal direction from an image with a shallow focus position (for example, the focus position is Fd (1)), as shown in FIG. Then, it is possible to generate an overlay image at a plurality of focal positions by overlaying on an image having a deep focal position (for example, the focal position is Fd (2)).

  As described above, in this embodiment, in addition to the effects of the first embodiment, the focal position Fd (k) can be dynamically changed according to the purpose and the state of the object by pre-scan information processing, from a shallow position to a deep position. It is possible to efficiently acquire tomographic structure information (tomographic image data) necessary for generating a tomographic image having a high S / N ratio and an appropriate resolution by using the minimum different focal position Fd (k).

  In addition, as shown in FIG. 29, the OCT processor 400 and the OCT probe 600 in each of the above embodiments can constitute the diagnostic imaging apparatus 10 together with the endoscope apparatus.

  That is, as shown in FIG. 29, the diagnostic imaging apparatus 10 mainly includes an endoscope 100, an endoscope processor 200, a light source device 300, the above-described OCT processor 400 of the first embodiment, and the monitor device 500, for example. Composed. The endoscope processor 200 may be configured to incorporate the light source device 300.

  The endoscope 100 includes a hand operation unit 112 and an insertion unit 114 that is connected to the hand operation unit 112. The surgeon grasps and operates the hand operation unit 112 and performs observation by inserting the insertion unit 114 into the body of the subject.

  The hand operation part 112 is provided with a forceps insertion part 138, and the forceps insertion part 138 communicates with the forceps port 156 of the distal end part 144. In the diagnostic imaging apparatus 10 according to the present invention, the OCT probe 600 is led out from the forceps port 156 by inserting the OCT probe 600 from the forceps insertion portion 138. The OCT probe 600 is inserted from the forceps insertion part 138 and inserted from the forceps port 156, an operation part 604 for the operator to operate the OCT probe 600, and the OCT processor 400 via the connector 410. It consists of a cable 606 to be connected.

  At the distal end portion 144 of the endoscope 100, an observation optical system 150, an illumination optical system 152, and a CCD (not shown) are disposed.

  The observation optical system 150 forms an image of a subject on a light receiving surface (not shown) of the CCD, and the CCD converts the subject image formed on the light receiving surface into an electric signal by each light receiving element. The CCD of this embodiment is a color CCD in which three primary color red (R), green (G), and blue (B) color filters are arranged for each pixel in a predetermined arrangement (Bayer arrangement, honeycomb arrangement). is there.

  The light source device 300 causes visible light to enter a light guide (not shown). One end of the light guide is connected to the light source device 300 via the LG connector 120, and the other end of the light guide faces the illumination optical system 152. The light emitted from the light source device 300 is emitted from the illumination optical system 152 via the light guide, and illuminates the visual field range of the observation optical system 150.

  An image signal output from the CCD is input to the endoscope processor 200 via the electrical connector 110. The analog image signal is converted into a digital image signal in the endoscope processor 200, and necessary processing for displaying on the screen of the monitor device 500 is performed.

  In this manner, observation image data obtained by the endoscope 100 is output to the endoscope processor 200, and an image is displayed on the monitor device 500 connected to the endoscope processor 200.

  For example, as shown in FIG. 30, the distal end of the OCT probe 600 inserted from the forceps insertion portion 138 includes a probe sheath 620 that is a sheath, a cap 622, a probe-side optical fiber FB1, a spring 624, a fixing member 626, An irradiating unit, a first scanning unit, and an optical lens 628 as a condensing unit are included.

  The probe sheath (sheath) 620 is a flexible cylindrical member and is made of a material that allows the measurement light L1 combined with the aiming light Le and the return light L3 to pass through the optical connector 18. The probe sheath 620 is on the tip (the tip of the probe side optical fiber FB1 opposite to the optical connector 18; hereinafter referred to as the tip of the probe sheath 620) through which the measurement light L1 (aiming light Le) and the return light L3 pass. It suffices that a part is formed of a material that transmits light over the entire circumference (transparent material), and a part other than the tip may be formed of a material that does not transmit light.

  The cap 622 is provided at the distal end of the probe sheath 620 and closes the distal end of the probe sheath 620.

  The probe-side optical fiber FB1 is a linear member and is accommodated in the probe sheath 620 along the probe sheath 620. The probe-side optical fiber FB1 is emitted from the optical fiber FB2 and emitted from the optical fiber FB8 by the optical connector 18. Is guided to the optical lens 628 and irradiated with the measurement light L1 (aiming light Le) to the measurement object S, and the return light L3 from the measurement object S acquired by the optical lens 628 is emitted as light. It guides to the connector 18 and enters the optical fiber FB2 (see FIG. 1).

  Here, the probe side optical fiber FB1 and the optical fiber FB2 are connected by the optical connector 18, and are optically connected in a state where the rotation of the probe side optical fiber FB1 is not transmitted to the optical fiber FB2. The probe-side optical fiber FB1 is disposed so as to be rotatable with respect to the probe sheath 620 and movable in the axial direction of the probe sheath 620.

  The spring 624 is fixed to the outer periphery of the probe side optical fiber FB1. The probe-side optical fiber FB1 and the spring 624 are connected to the optical connector 18.

  The optical lens 628 is disposed at the measurement-side tip of the probe-side optical fiber FB1 (tip of the probe-side optical fiber FB1 opposite to the optical connector 18), and the tip is measured from the probe-side optical fiber FB1. In order to collect the light L1 (aiming light Le) with respect to the measuring object S, it is formed in a substantially spherical shape.

  The optical lens 628 irradiates the measuring object S with the measuring light L1 (aiming light Le) emitted from the probe-side optical fiber FB1, collects the return light L3 from the measuring object S, and enters the probe-side optical fiber FB1. .

  The fixing member 626 is disposed on the outer periphery of the connection portion between the probe-side optical fiber FB1 and the optical lens 628, and fixes the optical lens 628 to the end portion of the probe-side optical fiber FB1. Here, the method of fixing the probe-side optical fiber FB1 and the optical lens 628 by the fixing member 626 is not particularly limited, and the fixing member 626, the probe-side optical fiber FB1, and the optical lens 628 are bonded and fixed by an adhesive. Alternatively, it may be fixed with a mechanical structure using a bolt or the like. The fixing member 626 may be any member as long as it is used for fixing, holding or protecting the optical fiber such as a zirconia ferrule or a metal ferrule.

  The probe-side optical fiber FB1 and the spring 624 are connected to a rotating cylinder (not shown), and the probe-side optical fiber FB1 and the spring 624 are rotated by the rotating cylinder, whereby the optical lens 628 is moved with respect to the probe sheath 620. , Rotate in the direction of arrow R2. The optical connector 18 includes a rotary encoder (not shown), and detects the irradiation position of the measurement light L1 from the position information (angle information) of the optical lens 628 based on a signal from the rotary encoder. That is, the measurement position is detected by detecting the angle of the rotating optical lens 628 with respect to the reference position in the rotation direction.

  Further, the probe-side optical fiber FB1, the spring 624, the fixing member 626, and the optical lens 628 are moved inside the probe sheath 620 in the arrow S1 direction (forceps opening direction) and S2 direction (probe sheath 620) by a drive unit (not shown). It is configured to be movable in the direction of the tip.

  In the case of the diagnostic imaging apparatus 10, as shown in FIG. 30, the probe sheath (sheath) 620 of the OCT probe 600 has a liquid filling portion 620 a that can inject a liquid for changing the refractive index over the entire inner circumference of the sheath. Is provided along the longitudinal axis, and by appropriately injecting a plurality of types of liquids into the liquid filling portion 620a, the refractive index can be changed, and the focal position of the measurement light L1 can be varied. As in the first and second embodiments, the tomographic structure information (tomographic image data) necessary for generating a tomographic image having a high S / N ratio and an appropriate resolution from a shallow position to a deep position is minimized. The focal position Fd (k) can be acquired efficiently.

  Further, in the case of the diagnostic imaging apparatus 10 described above, the measurement light L1 (aiming light Le) emitted from the probe-side optical fiber FB1 is applied to the measurement target S by the optical lens 628 whose tip is formed in a substantially spherical shape. While condensing and injecting liquid into the liquid filling unit 620a, the refractive index is changed to change the focal position of the measurement light L1 (see FIG. 30). Further, the measuring light L1 (aiming light Le) from the probe-side optical fiber FB1 is condensed on the measuring object S by the galvanometer mirror 631 driven by the motor 63, and the exit end of the probe-side optical fiber FB1 is set in the direction of arrow S1. As a configuration in which the focal position of the measurement light L1 is varied by moving in the (forceps opening direction) and S2 direction (the distal direction of the probe sheath 620). As in the first and second embodiments, the tomographic structure information (tomographic image data) necessary for generating a tomographic image having a high S / N ratio and an appropriate resolution from a shallow position to a deep position is minimized. The focal position Fd (k) can be acquired efficiently.

  The optical structure image observation apparatus, the structure information processing method, and the optical structure image observation apparatus of the present invention have been described in detail above. However, the present invention is not limited to the above examples and does not depart from the gist of the present invention. Of course, various improvements and modifications may be made.

  DESCRIPTION OF SYMBOLS 22 ... Processing part, 220 ... Light structure information detection part, 221 ... Multifocal image composition part, 222 ... Optical three-dimensional structure image construction part, 223 ... Display control part, 224 ... I / F part, 225 ... Tomographic structure information generation part , 230: Focus position designation unit, 231 ... Memory, 400 ... OCT processor, 500 ... Monitor device, 600 ... OCT probe, 601 ... Measurement optical system, 602 ... Optical system drive mechanism

Claims (10)

Light source means for emitting light by sweeping wavelengths;
Demultiplexing means for demultiplexing the light emitted from the light source means into reference light and measurement light;
An irradiation / condensing unit that irradiates the measurement light in the depth direction of the measurement target and collects the return light reflected or backscattered by the measurement target;
Scanning means for two-dimensionally scanning the irradiation position of the irradiation / condensing means within a plane perpendicular to the depth direction at a predetermined scanning interval;
A focus position specifying means for specifying a plurality of focus positions of the measurement light emitted by the irradiation / condensing means;
Focus driving means for positioning and driving the focus of the irradiation / condensing means at the plurality of focus positions;
Interference means for obtaining interference light by combining the return light collected by the irradiation / condensing means and the reference light having passed through a predetermined optical path length path for each of the plurality of focal positions;
Based on the interference light, tomographic structure information generating means for generating tomographic structure information of the measurement object for each of the plurality of focal positions;
Based on the tomographic structure information for each of the plurality of focal positions, a tomographic image generating means for generating the tomographic image of the measurement object;
An optical structure image observation device comprising:   The plurality of focal positions designated by the focal position designation means based on the tomographic structure information obtained by scanning the scanning means at a pre-scanning interval coarser than the predetermined scanning interval and obtained by scanning at the pre-scanning interval. The optical structure image observation apparatus according to claim 1, further comprising a focal position setting unit that sets   The tomographic structure information generating unit extracts the measurement target layer based on the interference light, and the tomographic image generating unit is configured to extract the tomographic structure information for each layer based on a focal position close to the layer among the plurality of focal positions. The optical tomographic image observation apparatus according to claim 1, wherein the tomographic image is generated by extracting the layer vicinity structure information and combining the extracted layer vicinity structure information.   The tomographic image generation means calculates the tomographic structure information for each of the plurality of focal positions by a weighting function that changes in the depth direction, and synthesizes the calculation results for the plurality of focal positions. The optical structure image observation apparatus according to claim 1, wherein an image is generated.   The tomographic image generation means calculates horizontal resolution edge information in the tomographic structure information for each of the plurality of focal positions, and generates the tomographic image by combining the calculation results for the plurality of focal positions. The optical structure image observation apparatus according to claim 1 or 2, characterized in that   A display control unit that displays at least the tomographic image on a display unit; and a display mode specification unit that specifies a display mode of the display unit that is controlled by the display control unit. The display control unit includes: Position information of the plurality of focal positions and image generation information when the tomographic image generating unit generates a tomographic image are superimposed on the tomographic image to be displayed, and the display form designating unit is superimposed and displayed on the display unit. The optical structure image observation apparatus according to claim 1, wherein the display form is specified by input information input based on the position information and the image generation information.   The three-dimensional structure image generation means for generating the optical three-dimensional structure image of the measurement object based on the tomographic image generated by the tomographic image generation means is further provided. Optical structure image observation device. Light source means for emitting light by sweeping wavelengths;
Demultiplexing means for demultiplexing the light emitted from the light source means into reference light and measurement light;
A structure information processing method for an optical structure image observation apparatus comprising: irradiation / condensing means for irradiating the measurement light in the depth direction of the measurement object and condensing the return light reflected or backscattered by the measurement object In
A scanning step for two-dimensionally scanning the irradiation position of the irradiation / condensing means at a predetermined scanning interval in a plane orthogonal to the depth direction;
A focus position designation step for designating a plurality of focus positions of the measurement light emitted by the irradiation / condensing means;
A focus driving step for positioning and driving the focus of the irradiation / condensing means at the plurality of focus positions;
An interference step of combining the return light collected by the irradiation / condensing means and the reference light that has passed through a predetermined optical path length path for each of the plurality of focal positions to obtain interference light;
A tomographic structure information generating step for generating tomographic structure information of the measurement object for each of the plurality of focal positions based on the interference light;
A tomographic image generation step for generating a tomographic image of the measurement object based on the tomographic structure information for each of the plurality of focal positions;
A structure information processing method for an optical structure image observation apparatus.   The plurality of focal positions designated by the focal position designation means based on the tomographic structure information obtained by scanning the scanning means at a pre-scanning interval coarser than the predetermined scanning interval and obtained by scanning at the pre-scanning interval. The structure information processing method for an optical structure image observation apparatus according to claim 8, further comprising a focal position setting step for setting the position.   An endoscope apparatus comprising the optical structure image observation apparatus according to any one of claims 1 to 7.