KR100780402B1 - Apparatus of detecting cancer - Google Patents

Abstract

According to an aspect of the present invention, a cancer detection device includes a first electronic device, a second electronic device connected to the first electronic device, and a probe connected to the first electronic device and in contact with human tissue. The first electronic device transmits an ultra-high frequency signal to the human tissue and sends data received from the human tissue to the second electronic device, wherein the second electronic device transmits the electromagnetic data of the human tissue through the received data. Extract the property.

As such, it is possible to quickly screen malignancy of various tumors including breast tumors using ultra-high frequency signals, thereby providing a more efficient and economical cancer diagnosis method than the conventional methods in the medical diagnostic field, and thus economical and comfortable. Accurate early diagnosis of cancer can be made.

Microwave, Cancer Diagnosis, Permittivity, Microwave, Millimeter Wave, Wideband

Description

Cancer Detection Device {APPARATUS OF DETECTING CANCER}

1 is a schematic diagram of an apparatus for detecting cancer according to an embodiment of the present invention.

2A is a schematic diagram of a portable cancer detection device according to another embodiment of the present invention.

FIG. 2B is an exploded view of the portable cancer detection device shown in FIG. 2A.

Figure 3 is a graph measuring the dielectric constant of breast cancer tissue and adipose tissue around it in accordance with an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for detecting cancer, and more particularly, to an apparatus for detecting cancer using broadband ultrahigh frequency.

For example, in the case of breast cancer, the early diagnosis of cancer mainly uses X-rays called mammography. However, this accuracy is quite flexible depending on the age of the patient and the composition of the breast tissue. In addition, it is easy to determine whether there is an abnormality in the breast tissue, but in many cases the site of the lesion is not necessarily a malignant tumor (cancer). Therefore, the same test is often re-executed or other test methods are used, which causes inconvenience and economic burden to both patients and hospital personnel.

Specifically, in the case of mammography, which is used for the early diagnosis of breast cancer and various cancers, the purpose is not to detect cancer, but rather to detect abnormal tissues. In addition, another imaging method, for example, ultrasound, is performed again. In addition, since the biopsy is performed for accurate diagnosis thereafter, it takes a lot of time and money due to duplication of tests. In other words, X-rays such as mammography, which are widely used for early diagnosis of cancer, are very low in efficiency and therefore not suitable for early diagnosis of cancer. In addition, ultrasound diagnostic imaging method must be accompanied by a certain morphological change over a certain size to determine whether the cancer.

In addition, in the conventional imaging methods, the reading of test results is thoroughly determined by the experience of a doctor or a reading expert, and the accuracy is flexible according to the experience of the reader.

The technical problem to be achieved by the present invention is to provide a cancer detection device that can solve such a conventional problem.

According to an aspect of the present invention, a cancer detection device includes a first electronic device, a second electronic device connected to the first electronic device, and a probe connected to the first electronic device and in contact with human tissue. The first electronic device transmits an ultra-high frequency signal to the human tissue and sends data received from the human tissue to the second electronic device, wherein the second electronic device transmits the electromagnetic data of the human tissue through the received data. Extract the property.

The electromagnetic characteristics may include dielectric constant, conductivity, and impedance.

In this case, the first electronic device may be a network analyzer, or the second electronic device may be a computer.

Alternatively, the first electronic device may be a monolithic microwave integrated chip or the second electronic device may be a digital signal processor.

Meanwhile, the human tissue may include normal tissue and infected tissue, and the normal tissue and the infected tissue may have different electromagnetic characteristics.

In addition, the ultra-high frequency signal may be microwave or millimeter wave.

The ultra-high frequency signal may have a frequency band in the range of 300 MHz to 50 GHz, and the ultra-high frequency signal used in the present invention may have a specific frequency in a frequency band in the range of 300 MHz to 50 GHz.

In addition, the first electronic device is a single high frequency integrated circuit, the second electronic device is a digital signal processor, a display unit connected to the digital signal processor, a probe connected to the single high frequency integrated circuit, and the single high frequency It may include a cover for covering the integrated circuit and the digital signal processor, and may further include a guide for guiding the probe.

The cover may include a display unit window in which the display unit is located, and a connection unit for connecting to an external device.

The probe may be any one of an open-ended coaxial probe, a waveguide probe, and a planar type probe.

DETAILED DESCRIPTION Embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

Then, a cancer detection apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a schematic diagram of a cancer detection apparatus according to an embodiment of the present invention, Figure 2 is a schematic diagram of a cancer detection apparatus according to another embodiment of the present invention, Figure 3 is a breast cancer tissue and according to an embodiment of the present invention It is a graph measuring the dielectric constant of the surrounding adipose tissue.

Referring to FIG. 1, an arm detecting apparatus according to an embodiment of the present invention includes a computer 200, a network analyzer 100 connected thereto, a cable 110 connected thereto, a connection unit 120, and a probe connected thereto. 130).

The network analyzer 100 transmits and receives the microwave signal and outputs the result to the computer 200. That is, the magnitude and phase of the reflection and transmission rate of the microwave signal is measured, and the measured data is sent to the computer 200.

The computer 200 is connected to the network analyzer 100 to receive measurement data from the network analyzer 100 to extract characteristic parameters such as, for example, dielectric constant through the measured data and display them on the screen through a monitor.

The probe 130 is connected to the cable 110 through the connection 120, the probe 130 is an open-ended coaxial probe, waveguide probe, planar type probe ) May be included.

For example, if a probe 130 is placed on a site where a tumor is expected to be present in the human body 300, that is, an area suspected of being infected 310, and the ultra-high frequency is emitted, the infected area 310 and a normal site Reference numeral 320 shows different electromagnetic characteristics for the microwave. Such electromagnetic characteristics include dielectric constant, conductivity, and impedance derived from a reflection coefficient that reflects microwaves at the infected part 310 and the normal part 320. In FIG. 3, the infected part 310 is measured by measuring the dielectric constant. ) And a graph distinguishing the normal region 320 is shown.

Here, the horizontal axis represents frequency and the unit is GHz, and the vertical axis represents relative permittivity.

At this time, the dielectric constant was measured while varying the ultra-high frequency signal to 30 GHz in the breast cancer tissue corresponding to the infected region 310 extracted from the actual patient and the adipose tissue corresponding to the normal region 320 around the infected region 310. As curve 31, the normal region 320 is shown as curve 32. Three samples were used for the material under test. In each sample, the infection site 310 exhibited a higher dielectric constant than the normal site 320, so that it was easy to determine whether the infection was normal and the same. It can be seen that.

At this point, the signal can be microwave or millimeter piled, and the bandwidth can be in the 50 GHz range above 30 GHz, for example. In addition to such a wide bandwidth, the diagnosis can be performed at a specific frequency.

On the other hand, such a detection device can be implemented as a portable as shown in Figures 2a and 2b.

2A and 2B, the portable arm detecting apparatus 40 according to another embodiment of the present invention includes a cover 42, a display window 44 provided on one side thereof, and a display unit located on the display window 44. (46), the control button 43 located under the display window 44, the connecting portion 41 located at one end of the cover 42 and the digital signal processor located inside the cover 42, DSP 45, a high frequency monolithic integrated circuit (MMIC) 47 connected thereto, and a probe 48 and a probe guide 49 connected thereto.

The connection part 41 is used to connect to the display device in addition to the display part 46. The digital signal processor 45 and the high frequency single integrated circuit 47 serve as the computer 200 and the network analyzer 100 in FIG. 1, respectively. The probe guide 49 serves to guide the probe 48 when measuring the infection site 310 in living tissue.

On the other hand, for such a portable miniaturization it may be to use the microelectromechanical system (MEMS) technology including the MMIC described above.

Next, a cancer detection method according to an embodiment of the present invention will be described.

First, a microwave signal is transmitted to a site suspected of being affected. Subsequently, an ultra-high frequency signal reflected from the affected part is received. Next, by analyzing the microwave signal reflected from the affected part, to determine the electromagnetic characteristics of the affected part.

Finally, the presence or absence of cancer cells is determined based on the electromagnetic characteristics.

In this case, the above-described electromagnetic properties such as permittivity, conductivity, and impedance, as well as various electromagnetic properties or parameters that can be obtained through other analysis are applicable thereto. In cancer tissues and the surrounding normal tissues, various electromagnetic characteristics, including permittivity, are different, and broadband is more pronounced in a particular frequency band depending on the type of tissue. Based on this analysis, cancer tissue can be stably detected from the surrounding normal tissue. In addition, this method uses cancer cell-specific characteristics, so it can successfully distinguish benign tumors, which were the most difficult to distinguish in the conventional cancer diagnosis.

According to the present invention, it is possible to quickly screen malignancy of various tumors including breast tumors using ultra-high frequency, thereby providing a more efficient and economical cancer diagnosis method than the conventional methods in the field of medical diagnosis, and thus economical and comfortable Accurate early diagnosis of cancer can be made.

Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (14)

Probes for transmitting ultra-high frequency signals on the surface of the living tissue or inside the living tissue; A first electronic device for measuring a response from the living tissue to the stimulus of the microwave signal; And And a second electronic device for receiving the response data measured from the first electronic device and extracting electromagnetic characteristics of the biological tissue using the reaction data. And the probe is one of an open-ended coaxial probe, a waveguide probe, and a planar type brobe. The method of claim 1, The measured response data includes at least one of reflectance and transmission rate of an ultrahigh frequency signal, The electromagnetic characteristic of the biological tissue comprises at least one of dielectric constant, conductivity, impedance. In claim 1, And the first electronic device is a network analyzer. In claim 1, And the second electronic device is a computer. In claim 1, And the first electronic device is a monolithic microwave integrated chip. In claim 1, And the second electronic device is a digital signal processor. In any one of claims 2 to 6, The living tissue includes normal tissue and infected tissue, The normal tissue and the infected tissue have different electromagnetic characteristics. Cancer detection device. In claim 7, The ultra-high frequency signal is a microwave (microwave) or millimeter wave (milimeterwave) cancer detection device. In claim 7, The ultra-high frequency signal is a cancer detection device having a frequency range of 300MHz to 50GHz range. In claim 7, The ultra-high frequency signal is a cancer detection device having a specific one of the frequency bands in the range of 300MHz to 50GHz. In claim 1, The first electronic device is a single high frequency integrated circuit, the second electronic device is a digital signal processor, A display unit connected to the digital signal processor; And And a cover covering the single high frequency integrated circuit and the digital signal processor. In claim 11, Cancer detection device further comprising a guide for guiding the probe. In claim 12, The cover is A display unit window in which the display unit is located, and Connection for connecting to external device Containing Cancer detection device. delete

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