CN113730804A - Electric field system for treating tumor - Google Patents

Abstract

The present invention provides an electric field system for treating tumors, comprising: a voltage regulator: the voltage signal frequency is used for adjusting the voltage according to the voltage signal frequency of the tumor cells to generate a voltage suitable for generating a pulse electric field; an electromagnetic oscillator: the multi-band generator is used for generating a pulse electric field through electromagnetic oscillation and sending a generated pulse electric field signal to the multi-band generator; a multi-band generator: the frequency of the pulse electric field is converted into a damping pulse electric field frequency which can be matched with the specific frequency of the organism; high-frequency radio wave transmitter: the electromagnetic wave generator is used for converting electromagnetic wave signals generated by the electromagnetic oscillator into high-frequency electromagnetic waves to supply power to cells, so that the human body tumor can be treated by electric field energy vibration.

Description

Electric field system for treating tumor

Technical Field

The invention relates to the field of electromagnetism, in particular to an electric field system for treating tumors.

Background

At present, all metabolic and information processes of biological systems are essentially processes of expression of electric and magnetic fields and electromagnetic radiation. Living cells have electrical properties of resistance, capacitance and inductance, emit their own resonance frequency and receive electromagnetic radiation, and in every living system, especially inside the cell (and its nucleus), there are components of an electrical oscillator. These components consist of a structure capable of collecting electric charges (capacitance C) and conducting an induced component (L). If energy is input to the system from a nutrient compound or any other source, the system will start oscillating at its own characteristic frequency, since the biological system can sense the electromagnetic frequency and the external electromagnetic frequency will resonate with the biological system, according to which resonance can be used to treat the biological system

Disclosure of Invention

The present invention provides an electric field system for the treatment of tumors, diseases that cause the whole biological system or its elements to turn into a state of non-harmonic oscillation, these disturbances (if not sufficiently attenuated) will spread to adjacent parts, eventually leading to malfunction of the system (illness and death), the factors that cause the imbalance of oscillation are above all bacteria, which in essence (as organisms) produce their own electromagnetic signals, bad diet, environment and aging cause changes in the cell chemistry that disturb the electronic oscillation harmony of the organism.

An electric field system for treating a tumor, comprising:

a voltage regulator: the standard voltage is used for adjusting the voltage according to the voltage signal frequency of the tumor cells to generate a standard pulse electric field;

an electromagnetic oscillator: the multi-band generator is used for generating a pulse electric field through electromagnetic oscillation and sending a generated pulse electric field signal to the multi-band generator;

a multi-band generator: the frequency of the pulse electric field is converted into a damping pulse electric field frequency which can be matched with the specific frequency of the organism;

high-frequency radio wave transmitter: used for converting the electromagnetic wave signal generated by the electromagnetic oscillator into the high-frequency electromagnetic wave to supply power for the cells.

As an embodiment of the present invention: the voltage regulator is also used for carrying out multistage amplification on the received weak voltage signal of the tumor cell to generate standard voltage of a standard pulse electric field;

the standard voltage is regulated in a voltage stabilizing way, and a stable voltage for generating the standard pulse electric field is generated through a voltage stabilizer;

controlling the electromagnetic oscillator by using the stabilized voltage as a standard voltage.

As an embodiment of the present invention: the electromagnetic oscillator is composed of a pure capacitor and a pure inductor, and the electromagnetic oscillator generates a pulse electric field and comprises the following specific steps:

the method comprises the following steps: when the electromagnetic oscillator is in a power-on state, the pure capacitor receives standard current periodically changing based on the magnitude and direction of the standard voltage;

step two: controlling the charge of the standard current to periodically change on a capacitor plate;

step three: according to the marking current, continuously performing mutual conversion on the electric field energy stored in the pure capacitor and the magnetic field stored in the inductor under the action of the electrified current;

step four: by the mutual conversion, a standard pulse electric field and an electromagnetic wave are generated.

As an embodiment of the present invention: the multi-band generator receives a pulse electric field signal generated by the electromagnetic oscillator through electromagnetic induction, and tests and excites the amplitude characteristic, the frequency characteristic and the transmission characteristic of the standard pulse electric field frequency;

and according to the excitation test result and the excitation result, the multi-band generator generates various waveforms according to the frequency of the pulse electric field after test excitation, and stably outputs the generated waveform of the frequency of the damping pulse electric field to the cell.

As an embodiment of the present invention: the high frequency radio wave transmitter includes:

a frequency superposition unit: the electromagnetic wave generator is used for receiving electromagnetic waves generated from the electromagnetic oscillator, performing frequency superposition according to the received electromagnetic waves and generating a high-frequency radio electromagnetic wave signal;

a resonance unit: for outputting the generated high-frequency radio-electromagnetic wave signal to the cell receiving antenna, thereby generating high-frequency electromagnetic wave resonance with the resonance structure in the cell and supplying power to the cell.

As an embodiment of the present invention: the system further comprises an electromagnetic relay; wherein the content of the first and second substances,

the electromagnetic relay includes: the electromagnetic relay is used for controlling the on and off of the high-frequency radio wave generator;

the specific implementation steps of switching on and off the electromagnetic relay control circuit are as follows:

the method comprises the following steps: in the electrified state, the coil receives the electrified current to generate an electromagnetic effect;

secondly, under the action of electromagnetic force attraction generated according to the electromagnetic effect, the armature overcomes the tension of a return spring and is connected with the iron core under the action of the attraction;

step three: according to the fact that the armature iron overcomes the pulling force of the return spring and is connected with the iron core under the action of the suction force, the moving contact of the armature iron is driven to be attracted with the normally open contact;

step four: and the moving contact of the armature is communicated with the normally open contact actuation control circuit.

As an embodiment of the present invention: the system further comprises: a thermal infrared imager, the thermal infrared imager comprising: an infrared detector and an optical imaging objective lens;

the infrared detector is used for detecting and measuring tumor cell radiation, establishing mutual connection between the radiation and the cell surface temperature, and converting invisible infrared energy emitted by cells into visible thermal images;

the optical imaging objective lens is used for carrying out color marking according to elements on the thermal image, determining different temperatures corresponding to each color on a thermodynamic diagram of a measured object, and generating an overall temperature distribution diagram.

As an embodiment of the present invention: the specific detection imaging steps of the thermal infrared imager are as follows:

the method comprises the following steps: the thermal infrared imager transmits the infrared radiation energy of the detected tumor cells to an infrared detector;

step two: the infrared detector receives the infrared radiation energy of the target cell to be detected;

step three: reflecting the infrared radiation energy distribution diagram of the detected target cell by a photosensitive element of an infrared detector;

step four: and transmitting the infrared radiation energy distribution graph to an optical imaging objective lens so as to obtain an infrared thermal image.

As an embodiment of the present invention: the system further comprises a cell tracker; wherein the content of the first and second substances,

the cell tracker includes:

a tracking unit: the device is used for receiving the frequency of the electromagnetic wave of the cancerous cell and determining the frequency of the cancerous electromagnetic wave;

a marking unit: the frequency identification and storage are carried out according to the canceration electromagnetic wave frequency, and the canceration electromagnetic wave frequency is marked; wherein the content of the first and second substances,

the marker is a trace marker for cancer cells when they spread to other cells, and a range map of a specific body part where cancer cells spread is displayed by distribution of marker information.

As an embodiment of the present invention: the specific tracking steps of the cell tracker for tracking the cancerated cells are as follows:

the method comprises the following steps: receiving the electromagnetic wave frequency of the cancerous cells, screening the electromagnetic wave frequency according to the region, determining the frequency of the cancerous cell wave, and identifying and storing the frequency of the cancerous cell wave;

step two: identifying and storing according to the frequency, and marking the frequency of the cancer cells by color marks;

step three: tracking and positioning the cancer cells which are diffused in the human body through the frequency of the cancer cells marked by the color;

step four: and sending the tracked electromagnetic wave frequency of the cancerous cells to a thermal infrared imager, and displaying a specific body part distribution map of cancer cell diffusion through the thermal infrared imager.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and drawings.

The technical solution of the present invention is further described in detail by the accompanying drawings and embodiments.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

FIG. 1 is a schematic diagram of an electric field system for treating tumors in accordance with an embodiment of the present invention;

FIG. 2 is a circuit diagram of an electromagnetic relay of an electric field system for treating tumors in accordance with an embodiment of the present invention;

fig. 3 is a schematic diagram of an infrared thermal imager of an electric field system for treating tumor according to an embodiment of the present invention.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Example 1:

as shown in fig. 1, 2 and 3, an embodiment of the present invention provides an electric field system for treating a tumor, comprising:

a voltage regulator: the standard voltage is used for adjusting the voltage according to the voltage signal frequency of the tumor cells to generate a standard pulse electric field;

an electromagnetic oscillator: the multi-band generator is used for generating a pulse electric field through electromagnetic oscillation and sending a generated pulse electric field signal to the multi-band generator;

a multi-band generator: the frequency of the pulse electric field is converted into a damping pulse electric field frequency which can be matched with the specific frequency of the organism;

high-frequency radio wave transmitter: used for converting the electromagnetic wave signal generated by the electromagnetic oscillator into the high-frequency electromagnetic wave to supply power for the cells.

The working principle of the technical scheme is as follows: in an electric field system for treating tumors, a voltage regulator is connected with an electromagnetic oscillator, cell current and voltage signals input by a positive electrode are regulated, an input voltage signal is regulated, the voltage signal of the input signal is converted into voltage suitable for generating a pulse electric field, the electromagnetic oscillator is connected with a multi-band generator and a high-frequency radio wave emitter, the electromagnetic oscillator generates the pulse electric field through electromagnetic effect and sends the generated pulse electric field signal to the multi-band generator, and the multi-band generator converts the frequency of the received pulse electric field into the frequency of a damping pulse electric field which can be matched with the specific frequency of an organism; the high-frequency radio wave transmitter receives an electromagnetic wave signal generated by the electromagnetic oscillator and converts the electromagnetic wave signal into a high-frequency electromagnetic wave to supply power to the cells; the frequency of the pulse electric field is damped to achieve balance

The beneficial effects of the above technical scheme are: the electric field system for treating tumor has several connected work devices and the mutual action of the work devices produces electromagnetic wave frequency for treating tumor, and the pulse electric field produced by the electromagnetic oscillator is converted into damping pulse electric field frequency matched with the unique frequency of organism via the multiband generator to complete the treatment of tumor via the electric field system.

Example 2:

in one embodiment, the voltage regulator is further used for performing multi-stage amplification on the received weak voltage signal of the tumor cell to generate a standard voltage of a standard pulse electric field;

the standard voltage is regulated in a voltage stabilizing way, and a stable voltage for generating the standard pulse electric field is generated through a voltage stabilizer;

controlling the electromagnetic oscillator by using the stabilized voltage as a standard voltage.

The working principle of the technical scheme is as follows: the voltage regulator regulates the received input voltage, firstly, the received weak voltage signal is amplified in multiple stages, which is used for ensuring the accuracy of the signal and finally realizing the stable control of the magnetic oscillator. When the signal is not yet connected, the current and voltage states of the three electrodes of the transistor are called quiescent states, also called "quiescent operating points". Generally, only a value of the voltage between the collector current and the collector emission is required.

The beneficial effects of the above technical scheme are: the received weak cell voltage can be amplified and regulated by the voltage regulator, so that the voltage reaches the voltage capable of generating a pulse electric field, and the voltage regulator continues to perform voltage stabilization operation on the voltage after amplifying the voltage, so that continuous and stable voltage can be generated.

Example 3:

in one embodiment, the electromagnetic oscillator is composed of a pure capacitor and a pure inductor, and the electromagnetic oscillator generates the pulsed electric field by the following specific steps:

the method comprises the following steps: when the electromagnetic oscillator is in a power-on state, the pure capacitor receives standard current periodically changing based on the magnitude and direction of the standard voltage;

step two: controlling the charge of the standard current to periodically change on a capacitor plate;

step three: according to the marking current, continuously performing mutual conversion on the electric field energy stored in the pure capacitor and the magnetic field stored in the inductor under the action of the electrified current;

step four: by the mutual conversion, a standard pulse electric field and an electromagnetic wave are generated.

The working principle of the technical scheme is as follows: the electromagnetic oscillator transmits received voltage and current signals to the pure capacitor which is also an original signal under the condition of switching on a power supply, then the pure capacitor receives current with periodically changed magnitude and direction, and charges in the electrified current also periodically change on a capacitor plate; the electric field energy stored in the capacitor and the magnetic field stored in the inductor are continuously converted into each other under the action of the electrified current, and the conversion is also a real-time conversion process and is also used for eliminating signal clutter; the capacitor and the inductor are mutually converted under the action of the electrifying current to generate a pulse electric field and electromagnetic waves;

the beneficial effects of the above technical scheme are: the electromagnetic oscillator of the invention can generate a pulse electric field capable of resonating with a cell oscillation structure through the internal electromagnetic oscillation effect, thereby forming an electromagnetic wave frequency capable of generating loss on tumor cells.

Example 4:

in one embodiment, the multi-band generator receives a pulse electric field signal generated by an electromagnetic oscillator through electromagnetic induction, and tests and excites the amplitude characteristic, the frequency characteristic and the transmission characteristic of a standard pulse electric field frequency;

and according to the excitation test result and the excitation result, the multi-band generator generates various waveforms according to the frequency of the pulse electric field after test excitation, and stably outputs the generated waveform of the frequency of the damping pulse electric field to the cell.

The working principle of the technical scheme is as follows: the main component of the multi-band generator signal generator of the invention is provided with a frequency generating unit, and after receiving the frequency of the pulse electric field generated by the electromagnetic oscillator, the frequency generating unit excites the frequency of the received pulse electric field so as to generate the frequency waveform of the damping pulse electric field.

The beneficial effects of the above technical scheme are: the multi-band generator can excite the pulse electric field frequency received from the electromagnetic oscillator to generate the damping pulse electric field frequency which is a resonance frequency and can be convenient for improving the conversion of the electromagnetic wave frequency for treating the tumor.

Example 5:

in one embodiment, the high frequency radio wave transmitter includes:

a frequency superposition unit: the electromagnetic wave generator is used for receiving electromagnetic waves generated from the electromagnetic oscillator, performing frequency superposition according to the received electromagnetic waves and generating a high-frequency radio electromagnetic wave signal;

a resonance unit: for outputting the generated high-frequency radio-electromagnetic wave signal to the cell receiving antenna, thereby generating high-frequency electromagnetic wave resonance with the resonance structure in the cell and supplying power to the cell.

The working principle of the technical scheme is as follows: the high-frequency radio wave transmitter of the invention superposes the frequency of the received electromagnetic wave to achieve the purpose of expanding the frequency of the electromagnetic wave, thereby generating the high-frequency radio electromagnetic wave, and the radio transmitter can control the transmitting time to send the expanded superposed high-frequency radio electromagnetic wave to the cell receiving antenna according to the preset transmitting time and generate the high-frequency electromagnetic wave vibration phenomenon with the resonance structure in the cell; during the treatment, the resonance is mainly a high frequency resonance.

The beneficial effects of the above technical scheme are: the high-frequency radio wave emitter can not only expand the frequency of electromagnetic waves so as to generate high-frequency radio electromagnetic waves, but also generate vibration phenomena through the electromagnetic waves emitted by the high-frequency radio wave emitter and the resonance structure in cells so as to achieve the aim of treating tumors.

Example 6:

in one embodiment, the system further comprises an electromagnetic relay; wherein the content of the first and second substances,

the electromagnetic relay includes: the electromagnetic relay is used for controlling the on and off of the high-frequency radio wave generator;

the specific implementation steps of switching on and off the electromagnetic relay control circuit are as follows:

the method comprises the following steps: in the electrified state, the coil receives the electrified current to generate an electromagnetic effect;

secondly, under the action of electromagnetic force attraction generated according to the electromagnetic effect, the armature overcomes the tension of a return spring and is connected with the iron core under the action of the attraction;

step three: according to the fact that the armature iron overcomes the pulling force of the return spring and is connected with the iron core under the action of the suction force, the moving contact of the armature iron is driven to be attracted with the normally open contact;

step four: and the moving contact of the armature is communicated with the normally open contact actuation control circuit.

The working principle of the technical scheme is as follows: the electromagnetic relay related to the invention is composed of an iron core, a coil, an armature and a contact reed, and is also a universal structure, but the electromagnetic relay has certain improvement, mainly the improvement of a contact, and in the prior art, a normally open contact is electrically connected with a normally open contact; the present invention electrically connects the normally open contact with the movable contact. After the electric shock is improved, as long as certain voltage is applied to the two ends of the coil, certain current flows in the coil, so that an electromagnetic effect is generated, the armature iron overcomes the pulling force of the return spring and is attracted to the iron core under the attraction effect of the electromagnetic force, and the movable contact of the armature iron is driven to be attracted with the normally open contact; when the coil is powered off, the electromagnetic attraction force disappears, the armature returns to the original position under the counterforce of the spring, so that the movable contact is attracted with the original normally closed electric shock, and the attraction and the release are carried out, thereby achieving the effects of conducting and cutting off in the circuit;

the beneficial effects of the above technical scheme are: the electromagnetic relay can be connected with a circuit to ensure normal and stable operation of current and voltage in the circuit, and can be disconnected when circuit problems occur at each part in the circuit, so that the safety of the circuit is protected, and the electromagnetic relay does not need a cooling fin, is more energy-saving and has no leakage current.

Example 7:

in one embodiment, the system further comprises: a thermal infrared imager, the thermal infrared imager comprising: an infrared detector and an optical imaging objective lens;

the infrared detector is used for detecting and measuring tumor cell radiation, establishing mutual connection between the radiation and the cell surface temperature, and converting invisible infrared energy emitted by cells into visible thermal images;

the optical imaging objective lens is used for carrying out color marking according to elements on the thermal image, determining different temperatures corresponding to each color on a thermodynamic diagram of a measured object, and generating an overall temperature distribution diagram.

However, in the prior art, because the infrared image has the problems of concentrated gray levels and poor layering, the invention improves the aspect and adopts the equalization algorithm to process, so that the gray levels can be pulled apart as much as possible to achieve the effect of contrast enhancement, and the specific image contrast enhancement algorithm calculation steps are as follows:

first the invention will calculate the distribution in each gray level set:

wherein n is the total number of pixels of the image, and r represents the level of the gray level;

l represents the total gray level of the pixel; r is_iRepresents a gray level of an ith pixel; p (r)_i) Representing the probability of the occurrence of the ith gray level; i represents the ith pixel, and i is a positive integer; f (r)_i| r) is a filter function, when the i-th pixel has a gray level of r, F (r)_i|r)＝1。

A transformation function T (r) for equalizing each gray level according to its distribution_i)

Is expressed as:

wherein S is_iExpressed as a transformation function T (r)_i) Is used to generate the discrete function of (1).

After the discrete state is determined, the coordinates of each pixel, h (x), are determined from the discrete state_i，y_i)；

The linear transformation is realized through coordinates, the main effect is to expand the gray level range to [ A, B ], the gray level range of the transformed image is expected to be expanded to [ C, D ], and the linear transformation expression is as follows:

K(x_i，y_i)＝[(D-C)/(B-A)]h(x_i，y_i)+U

u is a constant number, and is for K (x)_i，y_i) Will not equal 0; k (x)_i，y_i) Representing an extended gray level range of [ C, D]The gray level in between.

The expression of the enhanced gray level image is as follows:

and according to the enhanced gray level image, carrying out heat marking.

From the enhanced images, the heating of each point in each image is also determined, so that it is possible to choose whether to continue or stop the treatment.

The working principle of the technical scheme is as follows: the method is characterized in that photoelectric equipment is used for detecting and measuring radiation, mutual relation is established between the radiation and the surface temperature, all objects higher than absolute zero (-273 ℃) can emit infrared radiation, an infrared thermal imager receives an infrared radiation energy distribution pattern of a detected target by an infrared detector and an optical imaging objective and reflects the infrared radiation energy distribution pattern on a photosensitive element of the infrared detector, so that an infrared thermal image is obtained, the thermal image corresponds to a thermal distribution field on the surface of the object, the infrared thermal imager is popular and converts invisible infrared energy emitted by the object into visible thermal images, and different colors on the thermal images represent different temperatures of the detected object. By checking the thermal image, because the thermal image has the phenomenon of picture blurring, a clearer thermal image can be obtained by enhancing the gray scale contrast of the image in the principle, so that the overall temperature distribution condition of the detected target can be observed, the heating condition of the target can be researched, and the next work can be judged;

the beneficial effects of the above technical scheme are: the thermal infrared imager can sense the thermal radiation emitted by an object higher than absolute zero, and then the distribution condition of the tumor cells is determined according to the thermal radiation, so that the image analysis of specific parts of the tumor cells of a body is facilitated, and the image distribution information can be more accurately provided for treating the tumor cells.

Example 8:

in one embodiment, the specific detection imaging steps of the thermal infrared imager are as follows:

the method comprises the following steps: the thermal infrared imager transmits the infrared radiation energy of the detected tumor cells to an infrared detector;

step two: the infrared detector receives the infrared radiation energy of the target cell to be detected;

step three: reflecting the infrared radiation energy distribution diagram of the detected target cell by a photosensitive element of an infrared detector;

step four: and transmitting the infrared radiation energy distribution graph to an optical imaging objective lens so as to obtain an infrared thermal image.

The working principle of the technical scheme is as follows: in the electric field system for treating tumor of the present invention, the principle of thermal imaging is that all objects in nature have temperature higher than absolute zero and will have infrared radiation, because as a result of the thermal movement of the molecules inside the object, the radiation energy is proportional to the fourth power of the temperature itself, and the radiated wavelength is inversely proportional to the temperature. Infrared imaging techniques are based on the amount of radiant energy detected from an object. The thermal image of the target object is converted by the system processing and displayed in gray level or pseudo color, and the temperature distribution of the detected target is obtained, so that the state of the object is judged;

the beneficial effects of the above technical scheme are: human beings can detect infrared radiation all the time, and the nerve ending in the human skin can respond to the difference in temperature as low as +/-0.009 ℃, so can be through the internal heat that the skin of organism distributes out by the thermal infrared imager induction heat radiation to judge according to the different positions of organism and whether in the heat radiation of human normal within range, thereby reflect the thermal imaging distribution map of tumour position.

Example 9:

in one embodiment, the system further comprises a cell tracker; wherein the content of the first and second substances,

the cell tracker includes:

a tracking unit: the device is used for receiving the frequency of the electromagnetic wave of the cancerous cell and determining the frequency of the cancerous electromagnetic wave;

a marking unit: the frequency identification and storage are carried out according to the canceration electromagnetic wave frequency, and the canceration electromagnetic wave frequency is marked; wherein the content of the first and second substances,

the marker is a trace marker for cancer cells when they spread to other cells, and a range map of a specific body part where cancer cells spread is displayed by distribution of marker information.

The working principle of the technical scheme is as follows: the cell tracker in the electric field system for treating tumor receives the electromagnetic wave frequency of tumor cell from the positive electrode, stores and identifies the electromagnetic wave frequency of tumor cell, tracks the tumor cell with spread according to the stored electromagnetic wave frequency, and displays the specific distribution range of spread tumor cell;

the beneficial effects of the above technical scheme are: the cell tracker is favorable for tracking and positioning the tumor cells of the human body, thereby being convenient for observing the diffusion degree of the tumor cells and the distribution condition of the tumor cells in the human body.

Example 10:

in one embodiment, the specific tracking steps of the cell tracker for tracking the cancer cells are as follows:

the method comprises the following steps: receiving the electromagnetic wave frequency of the cancerous cells, screening the electromagnetic wave frequency according to the region, determining the frequency of the cancerous cell wave, and identifying and storing the frequency of the cancerous cell wave;

step two: identifying and storing according to the frequency, and marking the frequency of the cancer cells by color marks;

step three: tracking and positioning the cancer cells which are diffused in the human body through the frequency of the cancer cells marked by the color;

step four: and sending the tracked electromagnetic wave frequency of the cancerous cells to a thermal infrared imager, and displaying a specific body part distribution map of cancer cell diffusion through the thermal infrared imager.

The working principle of the technical scheme is as follows: after receiving the electromagnetic wave frequency of the tumor cells, the cell tracker identifies the frequency of the tumor electromagnetic wave frequency and stores the tumor electromagnetic wave frequency in the cell tracker, then the cell tracker marks the frequency of the identified and stored tumor cells, the cell tracker tracks and positions the tumor cells which have diffused in a human body through the marked frequency of the tumor cells, then the tracked frequency of the tumor cell electromagnetic wave is sent to a thermal infrared imager, and a specific body part distribution map of the diffusion of the tumor cells is displayed through the thermal infrared imager;

the beneficial effects of the above technical scheme are: the cell tracker can identify the special electromagnetic wave frequency of the tumor cells, not only can grasp the spreading parts of the tumor cells, but also can feed the tracked information back to the thermal infrared imager through tracking treatment, so that the specific conditions of the tumor cells can be conveniently observed.

In one embodiment, the present invention also uses this profile to determine where the treatment is abnormal, such as:

firstly, establishing a total distribution model according to distribution points of a body part distribution map:

wherein N is_lA location parameter indicating the ith distribution point; q_lRepresents the temperature of the ith distribution point; g_lRepresenting the gray level of the ith distribution point. L belongs to L and is a positive integer; l represents the total number of distribution points.

In the step, the invention introduces three parameters of position, temperature and gray level through the distribution diagram of the body part, once the distribution model is visualized, the temperature, the position and the gray level of each distribution point can be clearly distinguished;

after determining the distribution model, a preset temperature threshold value T is introduced, and whether an abnormality occurs is judged:

when Y is more than or equal to 0, the temperature threshold value is not exceeded, namely no abnormity exists; when Y < then, it indicates that the temperature threshold is exceeded, i.e., an anomaly is present.

The second step, very simple, is to introduce the temperature, judge every distribution point; when a negative value appears at the ith distribution point, the temperature of the ith distribution point is abnormal; at the moment, the treatment can be stopped, the reason can be found, and the damage to the human body can be prevented.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (10)

1. An electric field system for treating a tumor, comprising:

a voltage regulator: the standard voltage is used for adjusting the voltage according to the voltage signal frequency of the tumor cells to generate a standard pulse electric field;

an electromagnetic oscillator: the multi-band generator is used for generating a pulse electric field through electromagnetic oscillation and sending a generated pulse electric field signal to the multi-band generator;

a multi-band generator: the frequency of the pulse electric field is converted into a damping pulse electric field frequency which can be matched with the specific frequency of the organism;

high-frequency radio wave transmitter: used for converting the electromagnetic wave signal generated by the electromagnetic oscillator into the high-frequency electromagnetic wave to supply power for the cells.

2. The electric field system for treating tumor according to claim 1, wherein said voltage regulator is further configured to amplify the received weak voltage signal of tumor cell in multiple stages to generate a standard voltage of a standard pulsed electric field;

the standard voltage is regulated in a voltage stabilizing way, and a stable voltage for generating the standard pulse electric field is generated through a voltage stabilizer;

controlling the electromagnetic oscillator by using the stabilized voltage as a standard voltage.

3. The electric field system for treating tumor according to claim 1, wherein said electromagnetic oscillator is composed of pure capacitor and pure inductor, and said electromagnetic oscillator generates pulsed electric field by the specific steps of:

the method comprises the following steps: when the electromagnetic oscillator is in a power-on state, the pure capacitor receives standard current periodically changing based on the magnitude and direction of the standard voltage;

step two: controlling the charge of the standard current to periodically change on a capacitor plate;

step three: according to the marking current, continuously performing mutual conversion on the electric field energy stored in the pure capacitor and the magnetic field stored in the inductor under the action of the electrified current;

step four: by the mutual conversion, a standard pulse electric field and an electromagnetic wave are generated.

4. The electric field system for treating tumor according to claim 1, wherein the multi-band generator receives the pulsed electric field signal generated by the electromagnetic oscillator through electromagnetic induction, and tests and excites the amplitude characteristic, the frequency characteristic and the transmission characteristic of the standard pulsed electric field frequency;

and according to the excitation test result and the excitation result, the multi-band generator generates various waveforms according to the frequency of the pulse electric field after test excitation, and stably outputs the generated waveform of the frequency of the damping pulse electric field to the cell.

5. An electric field system for treating tumors as set forth in claim 1, wherein said high frequency radio wave transmitter comprises:

a frequency superposition unit: the electromagnetic wave generator is used for receiving electromagnetic waves generated from the electromagnetic oscillator, performing frequency superposition according to the received electromagnetic waves and generating a high-frequency radio electromagnetic wave signal;

a resonance unit: for outputting the generated high-frequency radio-electromagnetic wave signal to the cell receiving antenna, thereby generating high-frequency electromagnetic wave resonance with the resonance structure in the cell and supplying power to the cell.

6. The electric field system for treating a tumor according to claim 1, wherein said system further comprises an electromagnetic relay; wherein the content of the first and second substances,

the electromagnetic relay includes: the electromagnetic relay is used for controlling the on and off of the high-frequency radio wave generator;

the specific implementation steps of switching on and off the electromagnetic relay control circuit are as follows:

the method comprises the following steps: in the electrified state, the coil receives the electrified current to generate an electromagnetic effect;

secondly, under the action of electromagnetic force attraction generated according to the electromagnetic effect, the armature overcomes the tension of a return spring and is connected with the iron core under the action of the attraction;

step three: according to the fact that the armature iron overcomes the pulling force of the return spring and is connected with the iron core under the action of the suction force, the moving contact of the armature iron is driven to be attracted with the normally open contact;

step four: and the moving contact of the armature is communicated with the normally open contact actuation control circuit.

7. The electric field system for treating a tumor according to claim 1, wherein said system further comprises: a thermal infrared imager, the thermal infrared imager comprising: an infrared detector and an optical imaging objective lens;

the infrared detector is used for detecting and measuring tumor cell radiation, establishing mutual connection between the radiation and the cell surface temperature, and converting invisible infrared energy emitted by cells into visible thermal images;

the optical imaging objective lens is used for carrying out color marking according to elements on the thermal image, determining different temperatures corresponding to each color on a thermodynamic diagram of a measured object, and generating an overall temperature distribution diagram.

8. The electric field system for treating tumor according to claim 7, wherein the thermal infrared imager has the following steps:

the method comprises the following steps: the thermal infrared imager transmits the infrared radiation energy of the detected tumor cells to an infrared detector;

step two: the infrared detector receives the infrared radiation energy of the target cell to be detected;

step three: reflecting the infrared radiation energy distribution diagram of the detected target cell by a photosensitive element of an infrared detector;

step four: and transmitting the infrared radiation energy distribution graph to an optical imaging objective lens so as to obtain an infrared thermal image.

9. The electric field system for treating a tumor according to claim 1, wherein said system further comprises a cell tracker; wherein the content of the first and second substances,

the cell tracker includes:

a tracking unit: the device is used for receiving the frequency of the electromagnetic wave of the cancerous cell and determining the frequency of the cancerous electromagnetic wave;

a marking unit: the frequency identification and storage are carried out according to the canceration electromagnetic wave frequency, and the canceration electromagnetic wave frequency is marked; wherein the content of the first and second substances,

the marker is a trace marker for cancer cells when they spread to other cells, and a range map of a specific body part where cancer cells spread is displayed by distribution of marker information.

10. The electric field system for treating tumor according to claim 9, wherein the tracking of cancer cells by said cell tracker comprises the following steps:

the method comprises the following steps: receiving the electromagnetic wave frequency of the cancerous cells, screening the electromagnetic wave frequency according to the region, determining the frequency of the cancerous cell wave, and identifying and storing the frequency of the cancerous cell wave;

step two: identifying and storing according to the frequency, and marking the frequency of the cancer cells by color marks;

step three: tracking and positioning the cancer cells which are diffused in the human body through the frequency of the cancer cells marked by the color;

step four: and sending the tracked electromagnetic wave frequency of the cancerous cells to a thermal infrared imager, and displaying a specific body part distribution map of cancer cell diffusion through the thermal infrared imager.

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