KR20140001453A - Integrated coherence tomography - Google Patents

Abstract

An integrated coherence tomography system according to an embodiment of the present invention may includes: a housing; an optical coherent tomography unit installed partially in the housing for performing optical coherent tomography of a measurement target using laser beam by a tunable wavelength laser source; an optical acoustic image generation unit partially installed in the housing for generating an optical acoustic image using a pulse laser by a pulsed laser source; and a control unit for implementing an image of the measurement target using information obtained from the optical coherent tomography unit and optical acoustic image generation unit. More high resolution and various image information can be obtained compared to an existing technique while a process of obtaining image information of a measurement target can be simplified by simultaneously implementing optical coherent tomography and optical acoustic image generation with a single system.

Description

{Integrated coherence tomography}

An integrated tomography system is disclosed. More specifically, the optical coherence tomography, the photoacoustic imaging, or the ultrasound imaging can be simultaneously performed in one system, so that the process of acquiring image information of a measurement object can be simplified compared with the conventional method, An integrated tomography system capable of obtaining image information is disclosed.

In recent years, various internal transmissions, such as x-ray imaging, ultrasound imaging, computed tomography, and magnetic resonance imaging (MRI), which can observe the internal structure of living organisms and materials by non-destructive and non- Imaging and tomography acquisition systems have been studied and are being used in various fields.

However, such a conventional biomedical CT using various media has many problems such as harmfulness to living body and difficulty in realizing high resolution. In particular, equipment such as an X-ray machine or MRI has a problem of requiring equipment management personnel due to high price, large volume, and high risk.

Meanwhile, optical coherence tomography (OCT) is a next generation tomographic imaging technique that can obtain an internal image without damaging the inside of living tissue and material in real time using light. In particular, by using an interference light source having a short wavelength, it is possible to obtain a tomographic image of a finer part in a tissue to a sub-micro area with a high resolution, and distinguish a soft tissue difference which is difficult to be analyzed by another tomographic imaging apparatus So that a more accurate image can be obtained.

However, optical coherence tomography has a limitation that the depth of image measurement is only a few millimeters.

In recent years, photoacoustic imaging technology has been increasingly applied because it can detect not only the anatomical structure information in the human body provided by conventional ultrasonic imaging technology but also the difference of lesion tissues such as normal tissue and cancer. Such photoacoustic imaging techniques, for example, show relatively deep imaging depths of 50 millimeters, while achieving a relatively low resolution.

In addition, the optical coherence tomography technique and the photoacoustic imaging technique described above are implemented by a separate device, which is expensive to construct a device. When these devices are integrated, not only cost reduction but also quickness of shooting can be improved Therefore, it is necessary to study this.

It is an object of an embodiment of the present invention to simultaneously implement optical coherence tomography, photoacoustic imaging generation, or ultrasound imaging generation in one system, thereby simplifying the process of acquiring image information of a measurement object, And an integrated tomography system capable of obtaining various image information while having a higher resolution than the conventional one.

Another object of the present invention is to provide an integrated tomography system which can reduce the cost of system construction by integrating a plurality of units in one system.

It is another object of the present invention to provide an integrated tomography system capable of simultaneously implementing different image technologies by a plurality of units and suitably applicable to a medical image field showing more precise and various biometric information .

An integrated tomography system according to an embodiment of the present invention includes: a housing; An optical coherence tomography unit partially mounted in the housing, for performing optical coherence tomography of a measurement object using a laser beam by a tunable laser light source; A photoacoustic imaging generation unit partially mounted in the housing, for generating photoacoustic imaging of the measurement object using a pulsed laser by a pulsed laser light source; And a control unit for implementing an image of the measurement object using the information obtained from the optical coherent tomography unit and the photoacoustic imaging production unit, wherein the optical coherence tomography, the photoacoustic imaging The process of acquiring the image information of the measurement target object can be simplified compared to the conventional method, and a variety of image information can be obtained at a high resolution and at a higher resolution than the conventional method.

According to one aspect, the system may further comprise an ultrasound imaging generation unit, partially mounted in the housing, for generating ultrasound imaging of the measurement object using an electrical signal generated from the electroacoustic transducer, Imaging can be performed.

According to one aspect of the present invention, a rotating mirror for rotating by a rotating motor is mounted on an inner front end region of the housing, and a light transmitting window for transmitting a signal or a beam refracted by the rotating mirror is provided, And a green lens (GRIN lens) connected by the optical fiber to the wavelength tunable laser source to form the laser beam from the wavelength tunable laser source as parallel rays, wherein the parallel light from the green lens is incident on the rotating mirror To the measurement object.

According to one aspect of the present invention, the optical coherent tomography unit further includes an optical signal splitter disposed on the optical fiber connecting the tunable laser light source and the green lens to divide the laser beam, Wherein a part of the laser beam divided through the green lens moves to the measurement object and the other part moves in a direction of a reference mirror disposed in a separate optical fiber path and the laser beam returning from the measurement object and the reference mirror And transmitted to the control unit through a light circulator disposed on the optical fiber.

According to one aspect of the present invention, the photoacoustic imaging production unit further includes a transducer connected to the pulse laser light source through an optical fiber for converting the ultrasound signal generated by the pulse laser into the electrical signal And the electrical signal may be communicated to the control unit.

According to one aspect of the present invention, the ultrasonic imaging generating unit further includes a transducer connected to the electroacoustic transducer and a transducer line for transducing an electric signal from the electroacoustic transducer into an ultrasonic signal, The ultrasound signal transmitted to the measurement object via the transducer and returning after the response to the measurement object may be converted to an electrical signal by the transducer and then transmitted to the control unit.

According to one aspect, the control unit includes: a signal conversion unit for digitizing a signal received from the optical coherent tomography unit, the photoacoustic imaging production unit or the ultrasound imaging generation unit; And a signal processing unit for converting the digital signal into an image by signal processing.

According to one aspect, the signal converting unit is a DAQ board, and the signal processing unit may be a computer device.

Meanwhile, an integrated tomography system according to an embodiment of the present invention includes an optical coherence tomography (OCT) apparatus partially mounted in the housing and performing optical coherence tomography of a measurement object using a laser beam by a wavelength tunable laser light source unit; An ultrasound imaging generating unit, partially mounted in the housing, for generating ultrasound imaging of the measurement object using an electrical signal generated from the electroacoustic transducer; And a control unit for implementing an image of the measurement object using information obtained from the optical coherent tomography unit and the ultrasound imaging generation unit.

According to another aspect of the present invention, there is provided an integrated tomography system including: a housing; A photoacoustic imaging generation unit partially mounted in the housing, for generating photoacoustic imaging of the measurement object using a pulsed laser by a pulsed laser light source; And an ultrasound imaging generating unit, partially mounted in the housing, for generating ultrasound imaging of the measurement object using an electrical signal generated from the electroacoustic transducer; And a control unit for implementing an image of the measurement object using information obtained from the photoacoustic imaging production unit and the ultrasound imaging production unit.

According to the embodiment of the present invention, optical coherence tomography, photoacoustic imaging generation, or ultrasound imaging generation can be simultaneously performed in one system, so that the process of acquiring image information of a measurement object can be simplified compared to the conventional method, Various image information can be obtained with high resolution.

In addition, according to the embodiment of the present invention, since a plurality of units are integrated in one system, the cost for system construction can be reduced.

In addition, according to the embodiment of the present invention, each different image technique can be simultaneously implemented by a plurality of units, so that it can be suitably applied to a medical image field showing more precise and various biometric information.

1 is a view schematically showing the configuration of an integrated tomography system according to an embodiment of the present invention.
2 is a view illustrating the configuration of the integrated tomography system shown in FIG.
FIG. 3 is a top view of the internal structure of the housing of the integrated tomography system shown in FIG. 1. FIG.
FIG. 4 is a side view of the inner structure of the housing of the integrated tomography system shown in FIG. 3. FIG.
FIG. 5 is a view showing the internal structure of the housing of the integrated tomography system shown in FIG. 3 from the other side.
FIG. 6 is a view schematically showing a measurement process of a measurement object by the optical coherence tomography unit shown in FIG. 3. FIG.
7 is a view schematically showing a process of measuring a measurement object by the photoacoustic imaging production unit shown in FIG.
FIG. 8 is a view schematically showing a process of measuring a measurement object by the ultrasound imaging generating unit shown in FIG. 3. FIG.

Hereinafter, configurations and applications according to embodiments of the present invention will be described in detail with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE INVENTION The following description is one of many aspects of the claimed invention and the following description forms part of a detailed description of the present invention.

In the following description, well-known functions or constructions are not described in detail for the sake of clarity and conciseness.

FIG. 1 is a view schematically showing a configuration of an integrated tomography system according to an embodiment of the present invention, FIG. 2 is a diagram illustrating the configuration of the integrated tomography system shown in FIG. 1, FIG. 4 is a side view of the internal structure of the housing of the integrated tomography system shown in FIG. 3, and FIG. 5 is a view illustrating an internal structure of the housing of the integrated tomography system shown in FIG. 1 is a view showing the internal structure of the housing of the tomographic system from the other side.

1 and 2, an integrated tomography system 100 according to an embodiment of the present invention includes a housing 110, an optical coherence tomography unit 130, a photoacoustic imaging generation unit 130, An ultrasound imaging generating unit 170, and a control unit 180 for controlling the ultrasound imaging generating unit 170 and the ultrasound imaging generating unit 170. The ultrasound imaging generating unit 170 and the control unit 180 control the ultrasound imaging generating unit 170 and the ultrasound imaging generating unit 170, respectively.

In other words, the optical coherence tomography unit 130 can perform the optical coherence tomography of the measurement target object 101 and the photoacoustic imaging generation unit 150 can perform the optical coherence tomography of the measurement target body 101, And the ultrasonic imaging of the measurement object 101 can be generated by the ultrasonic imaging generating unit 170. [ However, since the image information acquisition process is implemented as one system, the process for image information can be simplified compared to the conventional method, and the cost for system construction can also be reduced.

The structure of the housing 110 in which the sensing is performed through the present system will be described before describing the respective constitutions. The housing 110 includes at least a part of the above-described units 130, 150 and 170, And a sensor probe 111 for sensing.

3 to 5, a light transmitting window 112 for transmitting light is provided at a front end of the housing 110 and a light transmitting window 112 is provided at the front end of the housing 110 from each unit 130, 150, A rotating mirror 113 for refracting a signal to be transmitted to the light-transmitting window 112 is rotatably disposed. The rotary motor 115 is connected to the control unit 180 by a control line 116 on which a rotary motor driver 117 is mounted to drive the rotary mirror 113, The degree of rotation of the rotating mirror 113 can be controlled according to an instruction from the control unit 180. [

4 and 5, the rotating mirror 113 has a shape inclined to one side so that a beam, which is diverted from each unit 130, 150, and 170 in the direction of the rotating mirror 113, So that not only the corresponding signal can be transmitted to the measurement object 101 but also the reflected signals can be returned to the respective units 130, 150 and 170 through the rotating mirror 113 have.

The optical coherent tomography unit 130 of the present embodiment is an optical coherent tomography apparatus that partially mounts the optical coherence tomography unit 130 in the housing 110 and uses the laser beam from the wavelength laser source 131 to perform optical coherence tomography Can be executed.

2 to 5, the optical coherence tomography unit 130 receives the laser beam generated from the tunable laser light source 131 and the wavelength tunable laser light source 131 and converts it into a parallel light beam And a green lens 132 (GRIN lens). Here, the tunable laser light source 131 and the green lens 132 are connected to an optical fiber, and a plurality of configurations are mounted in the optical fiber.

The optical fiber 133 connecting the tunable laser light source 131 and the green lens 132 is divided in the middle and the optical signal distributor 134 is mounted in the divided portion. Therefore, a part of the laser beam from the wavelength tunable laser light source 131 is moved to the green lens 132 described above, and the other part is moved in the direction of the reference mirror 135 disposed on the other divided optical fiber 133a . Here, the polarization controller 136 and the objective lens 137 may be disposed on the other optical fiber 133a.

The optical circulator 138 is mounted on the optical fiber 13 and the optical fiber 133a divided therefrom to react with the measurement target 101 via the laser beam and the green lens 132 coming from the reference mirror 135 And can transmit the returning laser beam to the control unit 180.

An optical signal splitter 134 and a parallel optical detector 139 are mounted on the optical fiber 133b connecting the control unit 180 and each optical circulator 138 to form a laser beam that is mounted and returns from the reference mirror 135 and It is possible to detect a laser beam which reacts with the measurement object 101 through the green lens 132 and return to the measurement object 101, thereby performing the optical coherence tomography of the measurement target object 101. [

Here, the control unit 180 has a configuration in which the returned laser beam, that is, a signal is converted into a digital signal and then implemented as an image, which will be described later.

2, 3 and 5, the photoacoustic imaging generation unit 150 of the present embodiment includes a pulse laser light source 151 for providing a pulsed laser for photoacoustic imaging generation, And the pulse laser light source 151 and the transducer 152 may be connected by an optical fiber 153. [

With this configuration, the pulse laser generated from the pulse laser light source 151 is transmitted to the measurement target object 101 through the transducer 152, and the pulse laser reflected and returned after reacting with the measurement target object 101, It may be converted into an electric signal in the ducer 152 and then transmitted to the control unit 180 through the transducer line 173.

In other words, when the pulsed laser is reflected on the rotating mirror 113 in the housing 110 and arrives at the measuring object 101, the measuring object 101 absorbing the pulsed laser thermally expands, and the resulting ultrasonic signal The measurement can be performed using the rotating mirror 113 and the transducer 152. The measured ultrasound signal may be converted into an electrical signal by the transducer 152 and then supplied to the control unit 180 through the transducer line 173.

Then, the control unit 180 can generate photoacoustic imaging for the measurement object 101 by digitizing the electrical signal and implementing it as an imaging.

2, 3 and 5, the ultrasonic imaging generating unit 170 of the present embodiment includes an electroacoustic transducer 171 for generating an electric signal for generating ultrasonic imaging, a transducer (for example, 152, where the electroacoustic transducer 171 and the transducer 152 can be connected by a transducer line 173.

The transducer 152 is the same transducer as the transducer 152 applied to the photoacoustic imaging production unit 150 described above. Therefore, it is not necessary to provide a separate transducer for each of the units 150 and 170, thereby realizing cost reduction and slimming down the apparatus.

The transducer 152 converts the electric signal generated from the electroacoustic transducer 171 into an ultrasonic signal when the ultrasonic imaging unit 170 is applied to the ultrasonic imaging generation unit 170. The converted ultrasonic signal is transmitted through the rotary mirror 113 So that it can be transmitted to the measurement target body 101. The transducer 152 converts the ultrasonic signal returned through the rotating mirror 113 into an electric signal after reacting with the measurement object 101, and then transmits the converted electric signal to the control unit 180.

Then, the control unit 180 can generate the ultrasonic imaging for the measurement target object 101 by digitizing the electrical signal and implementing it as an imaging.

On the other hand, the control unit 180 of the present embodiment receives each acquisition information from the above-described optical coherent tomography unit 130, photoacoustic imaging generation unit 150 and ultrasonic imaging generation unit 170, Signal and then implement it by imaging. By the way, in the case of this embodiment, because the image information of the optical coherent tomography unit 130, the photoacoustic imaging generation unit 150, and the ultrasonic imaging generation unit 170 can be integrally implemented by this control unit 180 , A high-resolution image can be obtained and a variety of image information can be obtained.

2, the control unit 180 includes a signal conversion unit 181 for converting the signal received from each of the units 130, 150, and 170 into a digital signal, The signal converting unit 181 may be provided as a DAQ board and the signal processing unit 185 may be provided as a computer device.

The signal converter 181, that is, the DAQ board of the present embodiment sequentially emits a trigger signal to integrate three different units 130, 150, and 170 into one image, and each unit 130, 150, 170 The signal processing unit 185 processes the image information obtained by the image processing unit 185 to provide one piece of image information or image information for each of the units 130,

Hereinafter, a measurement process of a measurement object by each unit will be schematically described with reference to the drawings.

FIG. 6 is a view schematically showing a process of measuring a measurement object by the optical coherence tomography unit shown in FIG. 3, and FIG. 7 is a flowchart illustrating a process of measuring a measurement object by the photoacoustic imaging production unit shown in FIG. FIG. 8 is a view schematically showing a process of measuring a measurement object by the ultrasound imaging generating unit shown in FIG. 3; FIG.

6, the laser beam L1 generated from the wavelength tunable laser light source 131 is refracted by the rotating mirror 113 through the green lens 132, and is transmitted to the measurement target body 101. FIG. The laser beam generated in response to the measurement object 101 is reflected in the direction of the rotating mirror 113 and the laser beam L2 refracted by the rotating mirror 113 passes through the green lens 132 again, (Not shown). By this process, information acquisition by the optical coherence tomography unit 130 can be performed.

7, the pulse laser P1 generated from the pulse laser light source 151 is moved to the transducer 152 through the optical fiber 153, refracted by the rotating mirror 113, 101). The ultrasonic wave signal P2 generated as a result of thermal expansion of the measurement target body 101 absorbing the pulse laser P1 is reflected in the direction of the rotating mirror 113 and is reflected by the rotating mirror 113, (P2) may be converted into an electrical signal at the transducer 152 and then transmitted to the control unit 180. [ Acquisition of information by the photoacoustic imaging generation unit 150 can be performed by this process.

8, the electric signal generated from the electroacoustic transducer 171 is transferred to the transducer 152 through the transducer line 173 and then converted into the ultrasonic signal U1 by the transducer 152 And the converted ultrasound signal U1 is then refracted by the rotating mirror 113 and transmitted to the measurement object 101. [ The ultrasonic signal U2 generated in response to the measurement object 101 is then returned to the transducer 152 through the rotary mirror 113 and converted into an electric signal by the transducer 152. [ The converted electric signal is transmitted to the control unit 180. By this process, information acquisition by the ultrasonic imaging generating unit 170 can be performed.

As described above, according to an embodiment of the present invention, optical coherence tomography, photoacoustic imaging generation, and ultrasound imaging generation can be simultaneously performed in one system 100, thereby obtaining image information of the measurement object 101 Can be simplified as compared with the related art, and it is possible to obtain a variety of image information while having a higher resolution than the conventional one.

In addition, since the plurality of units 130, 150, and 170 are integrated in one system 100, it is possible to reduce the cost of system construction, 170), and thus can be suitably applied to a medical image field showing more accurate and various biometric information.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

100: Integrated tomography system
110: Housing
130: Photosynthesis tomography unit
150: photoacoustic imaging generating unit
170: Ultrasound imaging generating unit

Claims (10)

housing;
An optical coherence tomography unit partially mounted in the housing, for performing optical coherence tomography of a measurement object using a laser beam by a tunable laser light source;
A photoacoustic imaging generation unit partially mounted in the housing, for generating photoacoustic imaging of the measurement object using a pulsed laser by a pulsed laser light source; And
A control unit for implementing an image of the measurement object using information obtained from the optical coherence tomography unit and the photoacoustic imaging generation unit;
Integrated tomography system comprising a.
The method of claim 1,
And an ultrasonic imaging generating unit, partially mounted in the housing, for generating an ultrasonic imaging of the measurement object using an electrical signal generated from an electroacoustic transducer.
3. The method of claim 2,
In the inner leading region of the housing, a rotating mirror rotating by a rotating motor is mounted, and a light transmitting window for transmitting a signal or a beam refracted by the rotating mirror is provided.
The optical coherent tomography unit comprises:
And a green lens (GRIN lens) connected to the tunable laser light source by an optical fiber to form the laser beam from the wavelength tunable laser light source into a parallel light beam,
Wherein the parallel rays from the green lens are transmitted to the measurement object through the rotating mirror.
3. The method of claim 2,
The optical coherent tomography unit comprises:
An optical signal splitter disposed on the optical fiber connecting the tunable laser light source and the green lens to split the laser beam;
Wherein a portion of the laser beam split through the optical signal splitter moves through the green lens to the measurement object and the other portion travels in a direction of a reference mirror disposed in a separate fiber optic path and from the measurement object and the reference mirror Wherein the returning laser beam is transmitted to the control unit through a light circulator disposed on the optical fiber.
3. The method of claim 2,
Wherein the photoacoustic imaging production unit comprises:
Further comprising a transducer connected to the pulse laser light source by an optical fiber and converting the ultrasound signal generated by the pulse laser into the electrical signal,
Wherein the electrical signal is delivered to the control unit.
3. The method of claim 2,
Wherein the ultrasonic imaging generating unit comprises:
Further comprising a transducer connected to the electroacoustic transducer and a transducer line for transducing an electrical signal from the electroacoustic transducer into an ultrasonic signal,
Wherein the ultrasonic signal is transmitted to the measurement object through the transducer, and the ultrasonic signal, which is returned after the measurement object is reacted, is converted into an electrical signal by the transducer and then transmitted to the control unit.
3. The method of claim 2,
Wherein the control unit comprises:
A signal converting unit for digitizing a signal received from the optical coherent tomography unit, the photoacoustic imaging production unit or the ultrasound imaging generation unit; And
And a signal processing unit for converting the digital signal into an image by signal processing.
The method of claim 7, wherein
Wherein the signal converter is a DAQ board, and the signal processor is a computer device.
housing;
An optical coherence tomography unit partially mounted in the housing, for performing optical coherence tomography of a measurement object using a laser beam by a tunable laser light source;
An ultrasound imaging generating unit, partially mounted in the housing, for generating ultrasound imaging of the measurement object using an electrical signal generated from the electroacoustic transducer; And
A control unit configured to implement an image of the measurement object by using information obtained from the optical coherence tomography unit and the ultrasonic imaging generating unit;
Integrated tomography system comprising a.
housing;
A photoacoustic imaging generation unit partially mounted in the housing, for generating photoacoustic imaging of the measurement object using a pulsed laser by a pulsed laser light source; And
An ultrasound imaging generating unit, partially mounted in the housing, for generating ultrasound imaging of the measurement object using an electrical signal generated from the electroacoustic transducer; And
A control unit for implementing an image of the measurement object using the photoacoustic imaging generating unit and the information obtained from the ultrasonic imaging generating unit;
Integrated tomography system comprising a.

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