KR101694184B1 - Phantom for diagnosing breast disease early - Google Patents

Abstract

The present invention relates to a phantom for early diagnosis of breast disease.
To this end, the phantom is provided with a diagnosis part on one side of a case containing a fluid having a temperature corresponding to a body temperature, and a test part having a temperature corresponding to the temperature of the breast disease tissue is provided in the case.

Description

{PHANTOM FOR DIAGNOSING BREAST DISEASE EARLY}

The present invention relates to a phantom for early diagnosis of breast disease. More specifically, a diagnostic unit is formed on one side of a case containing a fluid having a temperature comparable to body temperature, and a temperature corresponding to the temperature of the breast disease tissue The present invention relates to a phantom for early diagnosis of breast disease, which is capable of measuring electromagnetic energy radiation according to the position of an examined part.

Breast diseases include malignant tumors such as invasive breast cancer, intraepithelial cancer, and malignant follicular tumors, and benign tumors such as cysts, fibroadenoma, ductal papilloma, and aneurysm. In particular, breast cancer is a malignant tumor that occurs in breast cells, mainly in women, but recently it is increasing in males.

When cancer or tumor develops in the human body and its growth or proliferation progresses, the metabolism of malignant tumor cells becomes relatively active compared with normal cells, and the inflow amount of blood around the tumor cells increases, . The heat thus generated increases the thermal activity in the cell molecule and emits a radiation wave with higher electromagnetic energy.

On the other hand, existing diagnostic devices for diagnosing breast diseases including breast cancer include ultrasound, X-ray, magnetic resonance imaging (MRI), and computed tomography (CT). However, these devices judge the difference in the shape of the abnormal tissue between surrounding normal tissues when the cancer or tumor area grows beyond a certain size, and judge the difference in the intensity of the image. Especially, in the case of breast cancer that occurs in women, The early diagnosis of breast cancer can not be performed effectively because it is difficult to distinguish the difference in image intensities due to the small difference in shape between the surrounding normal tissues.

In addition, since such equipment is expensive and is specially managed and used by general hospitals and special inspection agencies, there is a problem that it is difficult for the public to access easily, and since it is harmful to the human body by adopting a diagnosis method using radiation, There is a problem that it is impossible to measure, the diagnosis time is excessive, and the diagnostic procedure is complicated.

Therefore, there is a need for a diagnostic apparatus capable of measuring the abnormality temperature of breast tissue in a noninvasive and convenient manner.

On the other hand, a prior art document related to the phantom for the diagnosis of breast cancer is Registration Practical Utility Model No. 20-0430979.

However, the above prior art documents are merely produced for the purpose of inspecting the mammography apparatus at regular intervals according to rules on safety management using a conventional mammography apparatus.

Korean Utility Model Registration No. 20-0430979 (published on 2006.11.06)

Disclosure of Invention Technical Problem [8] Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a radio meter for early diagnosis of breast disease, which measures an abnormal temperature of a breast disease tissue in a noninvasive and easy manner, And to provide a phantom for early diagnosis of breast disease that can measure the accuracy of a radio meter every predetermined period and database the measurement value of electromagnetic energy radiation measured according to the position and temperature of the breast disease tissue.

The present invention is the result of the research carried out by the support of the international joint technology development project of the Ministry of Commerce, Industry and Energy in 2013.

To this end, the present invention provides a phantom (P) for early diagnosis of breast disease, wherein the phantom (P) is formed with a diagnosis part (20) on one side of a case (10) containing a fluid having a temperature corresponding to the body temperature , And a test portion (30) having a temperature corresponding to the temperature of the breast disease tissue is provided in the case (10).

A guiding means 11 is provided on the upper portion of the case 10 to adjust the height of the tested portion 30 by being coupled to the vertical guide shaft 34. The vertical guide shaft 34 Is fixed to the guide means (11) by a fixing member (11a) formed on the guide means (11).

A horizontal guide shaft 35 protruding from the lower end of the vertical guide shaft 34 in one horizontal direction is provided so that the tested unit 30 is coupled to the end of the horizontal guide shaft 34 .

A horizontal rail 12 and a vertical rail 13 are provided on the upper portion of the case 10 so that the guide means 11 is moved forward, backward, leftward and rightward by the horizontal rail 12 and the vertical rail 13 .

In addition, the diagnosis unit 20 is formed of an elastic member and is inflated hemispherically by the fluid contained in the case 10.

The test piece 30 is provided with a spherical centering spherical body 31 and is provided with a cushioning member 32 to surround the centering spherical body 31.

The fluid to be supplied to the case 10 and the test piece 30 is an electrolyte fluid.

The phantom P is provided with a first heater 40 to supply the test piece 30 with a fluid having a temperature corresponding to the temperature of the breast disease tissue.

The phantom P is provided with a supplementary case 50 for exchanging fluids with the first heater 40 and the inspecting part 30 exchanging fluids with the auxiliary case 50 .

An internal supply pipe 33a for injecting the fluid from the auxiliary case 50 into the test piece 30 and an internal discharge pipe 33b through which the fluid is discharged to the auxiliary case 50 through the test piece 30 And an internal circulation pipe (33) is provided.

An external supply pipe 41a for injecting fluid into the auxiliary case 50 from the first heater 40 and an external discharge pipe 41b for discharging fluid from the auxiliary case 50 to the first heater 40 And an external circulation pipe (41) is provided.

The phantom P is provided with a second heater 60 to supply a fluid having a temperature corresponding to a body temperature to the case 10.

And the second heater (60) exchanges fluids with the case (10).

As described above, the phantom for early diagnosis of breast disease according to the present invention uses a radio meter for early diagnosis of breast disease, which measures an abnormal temperature of a breast disease tissue in a non-invasive and simple manner, The case is provided with a diagnosis part on one side of the case and a case having a temperature which is considerably higher than the temperature of the breast disease tissue is provided inside the case and the electromagnetic energy radiation according to the position and temperature of the breast disease tissue is similar to the human body It can radiate.

Accordingly, in order to safely manage the radio meter, it is possible to check the accuracy of the radio meter every predetermined period by contacting the radiometer to the diagnosis unit.

In addition, the measurement value of the electromagnetic energy radiation, which is measured according to the position and temperature of the breast tissue, can be stored in a database, thereby ensuring the accuracy and safety of the diagnosis of breast disease using a radiometer in the future.

1 is a perspective view of a phantom for early diagnosis of breast disease according to a preferred embodiment of the present invention.
2 is a cross-sectional view of a portion to be examined according to a preferred embodiment of the present invention.
3 is a view showing a radio meter product finally manufactured using a radio meter according to a preferred embodiment of the present invention.
4 is a developed view showing the manner and position in which the respective components of the radiometer according to the preferred embodiment of the present invention are combined.
5 is a perspective view of a radio meter according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. Prior to the description, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and should be construed in accordance with the technical concept of the present invention.

First, the principle or method of the radio meter 100 according to the present invention will be briefly described below.

When cancer or tumor progresses in the human body, the metabolism of malignant tumor cells becomes more active than that of normal cells, resulting in an increase of blood flow around the tumor cells, resulting in an increase in caloric value compared to surrounding normal cells. The radiation energy emitted by these tumor cells exceeds the radiant energy emitted by normal cells, based on Flank's blackbody radiation law, in which all objects above absolute temperature radiate energy proportional to absolute temperature. The electromagnetic energy of the microwave band emitted to the outside of the body is received by the radio meter 100, and the abnormal temperature in the body is measured by a method which is harmless to the human body, and is free from the influence of radioactivity.

Specifically, the receiving antenna of the radiometer 100 is brought into contact with the measurement position of the breast to receive and control the microwave energy corresponding to the amount of heat generated, and supplement and amplify the low frequency signal. Thereafter, the signal processing is performed and the state of the lesion is converted into an image by a diagnostic program of the computer. Through the information thus outputted, the examiner can obtain the best diagnostic image utilizing appropriate parameters.

Accordingly, the present invention provides a radio meter (100) for early diagnosis of breast disease, which measures an abnormal temperature of a breast disease tissue in a non-invasive and easy manner. In order to safely manage the radio meter (100) (P) for early diagnosis of breast disease which can check the accuracy of the meter and can database the measurement value of the electromagnetic energy radiation measured according to the position and temperature of the breast tissue.

As shown in FIG. 1, in a preferred embodiment of the present invention, a diagnosis unit 20 is formed on one side of a case 10 containing a fluid having a temperature comparable to a body temperature, A test piece 30 having a temperature that is comparable to the temperature of the breast disease tissue is provided.

The fluid contained in the case 10 is preferably an electrolyte fluid having a property similar to that of a human tissue such as a breast tissue, and water (a dielectric constant of about 80) may be used as a component that occupies a high percentage in a human tissue structure , And it is more preferable to adopt an electrolyte fluid having a flow rate of a dielectric constant value similar to that of a breast tissue (a dielectric constant of about 10).

On the other hand, the radio meter 100 is brought into contact with the front surface of the diagnosis unit 20 to measure the electromagnetic energy radiation. Therefore, it is preferable that the shape of the diagnosis unit 20 is formed to be similar to the shape of the breast, and the diagnosis unit 20 is formed of an elastic member so as to be hemispherically expanded by the fluid contained in the case 10 Is more preferable.

The test piece 30 should be provided with a temperature corresponding to the temperature of a specific breast disease tissue and the test piece 30 itself may be constituted by a heating element or a fluid having a temperature corresponding to the test piece 30 may be supplied It is possible.

At this time, it is preferable that the fluid supplied to the test portion 30 is an electrolyte fluid for the same reason as the fluid contained in the case 10.

As shown in FIG. 1, the guide unit 11 is provided to be movable on the upper portion of the case 10, and the test piece 30 is coupled to the vertical guide shaft 34 to be adjustable in height The vertical guide shaft 34 may be fixed to the guide means 11 by a fixing member 11a formed on the guide means 11. [

The mammary tissue can be developed at an unspecified site, and the subject 30 should be positioned at an unspecified site of the human body. For this purpose, the test piece 30 should be movable.

The inspection unit 30 can be moved by the fixing member 11a in a variety of ways as long as the inspection unit 30 is provided at the end of the vertical guide shaft 34, And can be moved by the guide means 11 having the fixing member 11a.

Meanwhile, the fixing member 11a may be variously used to fix the vertical guide shaft 34. However, the fixing member 11a may be pressed by elasticity using a rubber material or may be fixed using a fastening mechanism It is.

Therefore, by moving the vertical guide shaft 34 in the vertical direction and fixing it to the guide means 11 using the fixing member 11a at a specific position, it is possible to position the detection unit 30 at an intended height have.

In an embodiment where the guide means 11 is moved, a horizontal rail 12 and a vertical rail 13 are provided on the upper portion of the case 10, And can be moved forward, backward, leftward and rightward by the vertical rail (12) and the vertical rail (13).

1, a pair of the horizontal rail 12 and the vertical rail 13 are provided, but only one or more of the horizontal rail 12 and the vertical rail 13 may be provided.

The test piece 30 may be provided with a spherical body 31 having a spherical shape and a buffer member 32 may be provided to surround the center spherical body 31.

The center sphere 31 may have a structure corresponding to the center of the breast disease tissue and may be constituted by a heating body or a fluid having a temperature corresponding to the disease tissue may be supplied.

At this time, the cushioning member 32 is closed to the center sphere 31 so that the temperature difference between the breast disease tissue and the other breast tissue gradually increases, similar to the tissue of the human body. Therefore, it is preferable that the buffer member 32 is made of a material having a dielectric constant similar to that of human tissue.

When the fluid is supplied to the test piece 30, the phantom P is provided with a first heater 40 and a fluid having a temperature corresponding to the temperature of the breast disease tissue is supplied to the test piece 30 Can supply.

At this time, a horizontal guide shaft 35 projecting in a horizontal direction is provided at the lower end of the vertical guide shaft 34 so that the tested unit 30 can be coupled to the end of the horizontal guide shaft 34.

The fluid supplied along the horizontal guide shaft 34 is present on the same vertical plane as the center sphere 32 of the test piece 30 when the fluid is supplied to the test piece 30, 100) may recognize breast tissue as a single line rather than as a single point, making measurements somewhat inaccurate.

Therefore, the horizontal guide shaft 34 is provided with a horizontal guide shaft 35 protruding in the horizontal direction toward the examination unit 20, so that the fluid to be introduced or discharged and the center ball 32 are arranged on different vertical planes So that the measurement accuracy can be obtained.

The phantom P is provided with an auxiliary case 50 for exchanging fluids with the first heater 40 and the test piece 30 can exchange fluids with the auxiliary case 50 have.

The fluid may be directly supplied to the center spherical body 31 of the test piece 30 by using the first heater 40. In this case, A problem that is different from one temperature occurs.

Therefore, the auxiliary case 50, in which the fluid having a predetermined temperature is stored, exchanges the fluid with the first heater 40 and simultaneously exchanges the fluid with the tested part 30 Whereby the fluid having a constant temperature can be supplied to the test portion 30. [

Specifically, in order to achieve the above-mentioned object, an internal supply pipe 33a for injecting fluid from the auxiliary case 50 to the inspected part 30, and a discharge port for discharging fluid to the auxiliary case 50 through the inspected part 30 An internal circulation pipe 33 including an internal discharge pipe 33b may be provided.

An external supply pipe 41a for injecting fluid into the auxiliary case 50 from the first heater 40 and an external discharge pipe 41b for discharging fluid from the auxiliary case 50 to the first heater 40 An external circulation pipe 41 may be provided.

The phantom P is preferably provided with a second heater 60 to supply the case 10 with a fluid having a temperature corresponding to the body temperature.

It is further preferable that the second heater 60 interchanges the fluid with the case 10 in order to supply a fluid having a constant temperature to the case 10.

A radiometer 100 for early diagnosis of breast disease according to the present invention includes a body 110, a ceramic antenna unit 120, an infrared sensor unit 130, and a printed circuit board 150.

4, a printed circuit board 150 is mounted on one side of a cylindrical body 110 having an information transmitting unit 111 protruded to the outside and a ceramic antenna unit (not shown) is mounted on the other side of the body 110 120 are inserted into the body 110 and the infrared sensor unit 130 is inserted on one side of the ceramic antenna unit 120 which is exposed to the outside in order to directly contact the breast of the pierced terminal.

Preferably, the body 110 is made of a metal material. In order to prevent performance deterioration, the body 110 is preferably sealed to prevent external air or moisture from entering the body. The information transmitting unit 110 is provided on one side of the body 110 on which the printed circuit board 150 is mounted. And finally transmits the collected information to the central information processing apparatus A. [

The ceramic antenna unit 120 preferably has a cylindrical shape corresponding to the body 110. One side of the ceramic antenna unit 120 is exposed to the outside for direct contact with the breast of the pierced terminal and the other side is exposed to the outside of the breast tissue And an antenna 121 for receiving a radiation wave emitted from the antenna 121.

At this time, it is preferable that the one side face is directed to the outside, and the other side face is mounted inside the body 110. In another embodiment, the ceramic antenna unit 120 may be a disc- 1 ceramics 120a and a second ceramic 120b may be stacked and formed. The first ceramic 120a and the second ceramic 120b are laminated so that the first ceramic 120a is located inside and the second ceramic 120b is located at the outside. The antenna 121 is provided on one side of the first ceramic 120a, It is more preferable that one side of the pivot terminal is exposed to the outside so as to directly contact the breast of the pivot terminal. In addition, a center portion of the second ceramic 120b is formed to penetrate in a donut shape so that an infrared sensor unit 130 to be described later can be inserted. In the central portion of the first ceramic 120a, It is preferable that a wire guide is provided so that the wire connected to the infrared sensor unit 130 can pass through the left and right outer sides.

The relative dielectric constant of a human breast is generally known to have a value of about 10 or more. The relative permittivity is a value representing the relative permittivity of a substance to the permittivity of vacuum. The material of the ceramic antenna unit 120 is preferably a ceramic having a relative dielectric constant in the range of 8 to 10. The dielectric constant of the ceramic antenna unit 120 is similar to that of the breast so that generation of the opposite wave is suppressed, ) Without loss of electromagnetic energy.

The ceramic antenna unit 120 serves as a radiometer for receiving a microwave emitted from the mammary tissue of the pit terminal, that is, microwave radiation. GHz range of microwaves. If the received radiation wave band is less than 3.4 GHz, there is a noise problem due to a long wavelength, and there is a problem that it is not suitable for a proper depth measurement of 3 to 5 cm in the body. If the received radiation wave band exceeds 4,2 GHz, There is a problem that it is uneconomical to accept radiation waves.

The infrared sensor unit 130 is an apparatus for measuring a breast skin temperature by detecting infrared rays emitted from a breast skin, and is a device for measuring a reference for comparing and analyzing skin temperature and internal tissue temperature. In one preferred embodiment, the infrared sensor unit 130 may be provided at a central portion of one side of the ceramic antenna unit 120 exposed to the outside in order to directly contact the breast of the pierced terminal, And further, does not affect the absorption of the radiation wave in the ceramic antenna unit 120.

On the other hand, the configuration of the apparatus including the infrared sensor unit 130 is heated to a predetermined temperature by a temperature control sensor or the like which will be described later. In order to correct the temperature noise from the outside and improve the accuracy of the measured value, filtering circuitry to perform the operation.

Various circuits for driving the device are printed on the printed circuit board 150 and mounted on the opposite side of the surface of the body 110 which contacts the body of the pivot terminal. 4 and 5, the printed circuit board 150 includes at least one wing board 152 (not shown) around a circular substrate 151 corresponding to one side of the printed circuit board 150 mounted on the body 110 The circular substrate 151 is mounted on one side of the body 110 and the wing board 152 is mounted on the side surface of the body 110 by a mounting groove 112, As shown in FIG. This makes it possible to integrate the size of the printed circuit board by efficiently utilizing the external space of the device.

On the other hand, various circuits can be printed on the printed circuit board 150 irrespective of position. According to a preferred embodiment, the circuits such as the temperature control circuit 153, the power supply circuit 154 and the control circuit 155 Can be printed.

The temperature regulating circuit 153 is a circuit for keeping the temperature of the device constants constant. Preferably, the temperature regulating circuit 153 is equipped with two 2 kΩ resistors and a voltage of 12 V is applied thereto to constitute a heating circuit. By keeping the temperature of the device configurations constant at about 32 ° C, it is possible to improve the accuracy of the information collected and alleviate heterogeneity in direct contact with the body.

Further, when the operation of the temperature control circuit 153 is abnormal, the apparatus temperature continuously rises, causing problems such as the failure of the apparatus or the burning of the user's body. Therefore, A secondary circuit for preventing the secondary battery can be additionally provided.

The power supply circuit 154 is a circuit that supplies power supplied from the outside or internally supplied to the necessary parts of the device configuration.

The control circuit 155 collects various pieces of information received from the ceramic antenna unit 120 and the infrared sensor unit 130 and transmits the collected information to the outside through the information transmitting unit 111 provided in the body 110. [ To the processing unit (A), and controls the operation of the respective circuits. It also controls the operation of the optical sensor unit 140, which will be described later.

Meanwhile, the radiometer 100 according to another embodiment of the present invention may be provided on the other side of the body 110 to be in direct contact with the body of the pierced terminal, 110 may be further provided with a light sensor part 140 for identifying whether or not the other side of the pivot terminal is in contact with the breast of the pivot terminal.

When the radiometer 100 according to the present invention is used for diagnosis, when one side of the device is completely brought into contact with the breast of the pivot terminal, the external light flowing into the optical sensor unit 140 is blocked, A circuit that controls the operation of the configuration is driven. On the other hand, when the device is detached from the breast of the pivot terminal, external light is introduced into the optical sensor unit 140, and the circuit for controlling the operation of each device configuration is intercepted. However, in the case of the temperature control circuit 153 for maintaining a constant temperature of each configuration of the apparatus, continuous operation is required irrespective of the optical signal sensed by the optical sensor unit 140. Therefore, It should be additionally provided.

The present invention is not limited to the above-described specific embodiment and description, and various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention as claimed in the claims. And such modifications are within the scope of protection of the present invention.

P: Phantom 10: Case
11: guide means 11a: fixing member
12: Horizontal rail 13: Vertical rail
20: diagnosis part 30:
31: center core 32: buffer member
33: internal circulation pipe 33a: internal supply pipe
33b: inner discharge pipe 34: vertical guide shaft
40: first heater 41: outer circulation tube
41a: external supply pipe 41b: external discharge pipe
50: auxiliary case 60: second heater
100: Radio meter 110: Body
111: Information transmission unit 120: Ceramic antenna unit
120a: first ceramic 120b: second ceramic
121: antenna 130: infrared sensor part
140: optical sensor unit 150: printed circuit board
151: circular substrate 152: wing substrate
153: Temperature control circuit 154: Power supply circuit
155: Control circuit

Claims (13)

In the phantom (P) for early diagnosis of breast disease,
The phantom P has a diagnostic unit 20 formed on one side of a case 10 containing a fluid having a temperature comparable to a body temperature and is provided inside the case 10 with a temperature A detection unit 30 is provided,
A radiometer (100) for receiving electromagnetic energy of a microwave band emitted from a breast tissue,
The radio meter (100)
A ceramic antenna unit 120 and an infrared sensor unit 130 are provided in a cylindrical body 110 formed with an information transmitting unit 111 and a printed circuit board 150 is provided on one side of the body 110, As being in contact with the diagnosis unit 20,
A light sensor part 140 provided on the other side of the body 110 for detecting whether the body 110 is exposed to external light and identifying whether the other side of the body 110 is in contact with the breast of the pierced terminal, And a phantom for early diagnosis of breast disease. The method according to claim 1,
A guide means 11 is provided so as to be movable above the case 10 and the test piece 30 is coupled to a vertical guide shaft 34 so that the height of the vertical guide shaft 34 can be adjusted, Is fixed to the guide means (11) by a fixing member (11a) formed on the guide means (11). 3. The method of claim 2,
And a horizontal guide shaft 35 protruding from the lower end of the vertical guide shaft 34 in one horizontal direction is provided so that the tested portion 30 is bound to the end of the horizontal guide shaft 35. [ Phantom for early diagnosis. 3. The method of claim 2,
A horizontal rail 12 and a vertical rail 13 are provided on the upper portion of the case 10 so that the guide means 11 can be moved back and forth and left and right by the horizontal rail 12 and the vertical rail 13 Phantom for Early Diagnosis of Breast Disease. The method according to claim 1,
Wherein the diagnosis unit (20) is formed of an elastic member and expands hemispherically by the fluid contained in the case (10). The method according to claim 1,
Characterized in that the to-be-tested portion (30) is provided with a spherical central body (31) having a spherical shape and a buffer member (32) is provided so as to surround the central body (31) Phantom. The method according to claim 1,
Wherein the fluid supplied to the case (10) and the test piece (30) is an electrolyte fluid. The method according to claim 1,
Wherein the phantom (P) is provided with a first heater (40) to supply the test piece (30) with a fluid having a temperature corresponding to the temperature of the breast disease tissue. 9. The method of claim 8,
The phantom P is provided with an auxiliary case 50 for exchanging fluids with the first heater 40 and the test piece 30 exchanges fluid with the auxiliary case 50. [ Phantom for Early Diagnosis of Breast Disease. 10. The method of claim 9,
An internal supply pipe 33a for injecting fluid from the auxiliary case 50 into the test piece 30 and an internal discharge pipe 33b through which the fluid is discharged to the auxiliary case 50 through the test piece 30, And a circulation pipe (33) are provided on the outer surface of the phantom. 10. The method of claim 9,
An external supply pipe 41a for injecting fluid from the first heater 40 to the auxiliary case 50 and an external discharge pipe 41b for discharging fluid from the auxiliary case 50 to the first heater 40, And an external circulation pipe (41). The method according to claim 1,
Wherein the phantom (P) is provided with a second heater (60) to supply a fluid having a temperature corresponding to body temperature to the case (10). 13. The method of claim 12,
And the second heater (60) exchanges fluids with the case (10).

Images