CN109394213B - Intelligent diagnosis and treatment system - Google Patents

Abstract

The invention discloses an intelligent diagnosis and treatment system, which comprises a diagnosis and treatment belt, wherein the diagnosis and treatment belt comprises a diagnosis and treatment layer, a graphene layer, a protection layer and an intelligent terminal; the diagnosis and treatment layer is tightly attached to the back of a human body, a plurality of diagnosis and treatment electrode groups are arranged in the diagnosis and treatment layer, each diagnosis and treatment electrode group comprises two diagnosis and treatment electrodes, and the diagnosis and treatment electrode groups are distributed according to meridian points of the back of the human body and are clung to the skin to form a detection loop; the diagnosis and treatment electrode group is respectively connected with the input end of a current detection circuit and the output end of a pulse conversion circuit; a graphene film is arranged in the graphene layer and is connected with a temperature control circuit; the current detection circuit, the pulse conversion circuit and the temperature control circuit are all connected with the intelligent terminal.

Description

Intelligent diagnosis and treatment system

Technical Field

The invention relates to an intelligent diagnosis and treatment system for 'disease-free' waist and back acupoints.

Background

The 'preventive treatment' project is mainly characterized in that constitution identification is carried out on high-risk groups at present, the basic principle of traditional Chinese medicine diagnostics is summarized as 'in the form of exterior and interior', the necessary connection exists between the human body appearance information (four diagnosis information) and the essence (symptoms) of the disease, abnormality is discovered early by the traditional inspection, smelling, inquiring and cutting diagnostic methods, and then the intervention of traditional therapies such as traditional Chinese medicine is carried out. However, both traditional Chinese medicine and modern medicine recognize that certain changes in the human body occur before the occurrence of early diseases and body symptoms and indexes (the current routine examination of Western medicine) are not abnormal, and many diseases in the human body (such as lung, heart, liver, spleen and kidney diseases) often first occur in some tissues and organs with imperceptible pathological metabolism and microcirculation changes, then gradually develop into substantial tissue organ focus and metabolic disorder, then obvious clinical symptoms appear, and the symptoms may be advanced to middle and late stages until the clinical symptoms can be clearly diagnosed, so that the opportunity of early healing is lost. The old traditional Chinese medicine with very rich experience can find out some spider marks through constitution identification and syndrome differentiation, however, early detection and diagnosis of diseases are still very difficult, people hope to give 'no disease' an intuitive standard with informationized digitalization, and the effect of 'no disease' in traditional Chinese medicine also needs a data comparison before and after traditional Chinese medicine intervention.

Disclosure of Invention

The invention aims to provide an intelligent diagnosis and treatment system which can diagnose and treat the visceral condition of a user, can keep healthy for non-ill patients, can keep healthy for sub-healthy patients, can prompt visceral disease positions for ill patients, and can propose further accurate examination and simultaneously can intervene in treating diseases.

In order to solve the technical problems, the invention provides an intelligent diagnosis and treatment system, which comprises a diagnosis and treatment belt, wherein the diagnosis and treatment belt comprises a diagnosis and treatment layer, a graphene layer, a protection layer and an intelligent terminal; the diagnosis and treatment layer is tightly attached to the back of a human body, a plurality of diagnosis and treatment electrode groups are arranged in the diagnosis and treatment layer, each diagnosis and treatment electrode group comprises two diagnosis and treatment electrodes, and the diagnosis and treatment electrode groups are distributed according to meridian points of the back of the human body and are clung to the skin to form a detection loop; the diagnosis and treatment electrode group is respectively connected with the input end of a current detection circuit and the output end of a pulse conversion circuit; a graphene film is arranged in the graphene layer and is connected with a temperature control circuit; the current detection circuit, the pulse conversion circuit and the temperature control circuit are all connected with the intelligent terminal.

Further, the system also comprises a cloud server in communication connection with the intelligent terminal and a data processing center in communication connection with the cloud server.

Further, the system also comprises a user service center in communication connection with the cloud server.

Further, the intelligent terminal comprises a processor electrically connected with the diagnosis and treatment electrode and the graphene film, and a storage unit and a wireless communication unit which are respectively connected with the processor, wherein the processor is in communication connection with the cloud server through the wireless communication unit.

Further, the intelligent terminal further comprises a display screen, a voice broadcasting unit and an LED indicator lamp which are connected with the processor respectively.

Further, a filling layer is arranged between the diagnosis and treatment layer and the graphene layer.

Further, the interval between the diagnosis and treatment electrode groups is adjustable.

Further, the current detection circuit comprises a detection signal amplifying circuit and an AD sampling circuit; the input end of the detection signal amplifying circuit is electrically connected with the diagnosis and treatment electrode, the output end of the detection signal amplifying circuit is connected with the input end of the AD sampling circuit, and the output end of the AD sampling circuit is connected with the input end of the processor.

Further, the pulse conversion circuit comprises a pulse generator P2, a pulse transformer T1 connected with the output end of the pulse generator P2, and a first pulse signal amplifying circuit and a second pulse signal amplifying circuit which are respectively connected with the output end of the pulse transformer T1;

the first output end of the pulse generator P2 is respectively connected with a pin 5 and a pin 6 of the pulse transformer T1, the second output end of the pulse generator P2 is connected with one end of a resistor R58, the other end of the resistor R58 is connected with a pin 7 of the pulse transformer T1, a filter circuit is connected between the first output end of the pulse generator P2 and the other end of the resistor R58, and the filter circuit comprises a resistor R52 and a capacitor C41 which are connected in series and a resistor R53 which is connected at two ends of the resistor R52 and the capacitor C41 in parallel;

the first pulse signal amplifying circuit comprises a triode Q4 and a triode Q7, the pin 4 of the pulse transformer T1 is connected with the emitting electrode of the triode Q4, the base electrode of the triode Q4 is connected with the collecting electrode of the triode Q7 through a resistor R42, a resistor R39 is connected in parallel between the emitting electrode of the triode Q4 and the base electrode of the triode Q4, the emitting electrode of the triode Q7 is grounded, and the base electrode of the triode Q7 is connected with one diagnosis and treatment electrode of the diagnosis and treatment electrode group through a resistor R51; the pin 4 of the pulse transformer T1 is also connected with a first resonant circuit, the first resonant circuit comprises a resistor R40 and a capacitor C36 which are connected in series, the other end of the resistor R40 is connected with the pin 4 of the pulse transformer T1, and the other end of the capacitor C36 is grounded;

the second pulse signal amplifying circuit comprises a triode Q8 and a triode Q10, the pin 1 of the pulse transformer T1 is connected with the emitter of the triode Q8, the base electrode of the triode Q8 is connected with the collector of the triode Q10 through a resistor R56, a resistor R60 is connected in parallel between the emitter of the triode Q8 and the base electrode of the triode Q10, the emitter of the triode Q10 is grounded, and the base electrode of the triode Q10 is connected with the other diagnosis and treatment electrode of the diagnosis and treatment electrode group through a resistor R61; the pin 1 of the pulse transformer T1 is also connected with a second resonant circuit, the second resonant circuit comprises a resistor R59 and a capacitor C43 which are connected in series, the other end of the resistor R59 is connected with the pin 1 of the pulse transformer T1, and the other end of the capacitor C43 is grounded;

the pin 2 and the pin 3 of the pulse transformer T1 are respectively connected with one end of the resistor R46 and the positive polarity end of the capacitor C46 after being short-circuited, and then are connected with the processor; the other end of the resistor R46 is connected with the negative end of the capacitor C46 and then is respectively connected with the collector of the triode Q4, the collector of the triode Q8 and a 5V direct current power supply.

Further, the temperature control circuit includes a dual voltage comparator.

The beneficial effects of the invention are as follows: when the diagnosis electrode set works, the current of 3V/1mA is applied to one diagnosis electrode in the diagnosis electrode set, then the current of the other diagnosis electrode in the diagnosis electrode set is detected through the current detection circuit, related diseases can be primarily diagnosed through obtaining the change condition of the electric conduction quantity of meridian points, and the whole-body visceral diseases can be treated in a segmented mode through the change quantity of the electric conduction quantity; when detecting that the conductivity of the meridian point is abnormal, the processor can control the pulse conversion circuit and the temperature control circuit to respectively control the diagnosis and treatment electrode and the graphene film to work, and the treatment is carried out by adopting two modes of low-frequency pulse and electrothermal moxibustion; the low-frequency pulse is to stimulate nerve and muscle of the lesion part with pulse current of specific frequency amplitude to excite the nerve and muscle and to produce contraction reaction, so as to promote blood circulation of the lesion part and reach the therapeutic effect. The thermal moxibustion mainly adopts far infrared rays emitted after the electric heating of graphene to perform moxibustion on meridian points of the back corresponding to the upper, middle and lower triple energizer.

Drawings

The accompanying drawings, where like reference numerals refer to identical or similar parts throughout the several views and which are included to provide a further understanding of the present application, are included to illustrate and explain illustrative examples of the present application and do not constitute a limitation on the present application. In the drawings:

FIG. 1 is a schematic diagram of one embodiment of the present invention;

FIG. 2 is a schematic structural view of a medical garment according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a diagnosis and treatment belt according to an embodiment of the present invention;

FIG. 4 is a graph showing the distribution of acupoints on the back of a human body according to one embodiment of the present invention;

FIG. 5 is a schematic diagram of a smart terminal according to an embodiment of the present invention;

FIG. 6 is a schematic circuit diagram of a current sense circuit according to one embodiment of the present invention;

FIG. 7 is a schematic circuit diagram of a pulse conversion circuit according to an embodiment of the present invention;

fig. 8 is a schematic circuit diagram of a temperature control circuit according to an embodiment of the present invention.

Wherein: 1. a medical garment; 2. a diagnosis and treatment belt; 3. a diagnosis and treatment layer; 31. a diagnosis electrode; 4. a filling layer; 5. a graphene layer; 6. and (3) a protective layer.

Detailed Description

An intelligent diagnosis and treatment system shown in fig. 1 comprises a diagnosis and treatment belt 2 arranged on a diagnosis and treatment suit 1 (shown in fig. 2). As shown in fig. 3, the diagnosis and treatment belt 2 comprises a diagnosis and treatment layer 3, a graphene layer 5, a protection layer 6 and an intelligent terminal; wherein, the cloth of the diagnosis and treatment suit 1 can be made of rubber material with high elasticity so as to enable the diagnosis and treatment band 2 to be clung to the vertebra of a human body, and the protective layer 6 can be made of pure cotton cloth as an outer layer. The diagnosis and treatment layer 3 is tightly attached to the back of the human body, a plurality of diagnosis and treatment electrode groups are arranged in the diagnosis and treatment layer 3, and each diagnosis and treatment electrode group comprises two diagnosis and treatment electrodes 31 (stainless steel probes can be adopted); the diagnosis and treatment electrode groups are distributed and arranged according to meridian points on the back of a human body, and the two diagnosis and treatment electrodes 31 are clung to the skin to form a detection loop; as shown in fig. 3, the diagnosis electrode set is respectively connected with the input end of a current detection circuit and the output end of a pulse conversion circuit; a graphene film is arranged in the graphene layer 5 and is connected with a temperature control circuit; the current detection circuit, the pulse conversion circuit and the temperature control circuit are all connected with the intelligent terminal.

During operation, the related diseases can be primarily diagnosed by applying 3V/1mA current to one diagnosis electrode 31 in the diagnosis electrode group, then detecting the current of the other diagnosis electrode 31 in the diagnosis electrode group through the current detection circuit, and the related diseases can be treated in a segmented manner through the change of the electric conduction quantity by acquiring the change of the electric conduction quantity of the meridian points; when detecting that the conductivity of the meridian point is abnormal, the processor can control the pulse conversion circuit and the temperature control circuit to respectively control the diagnosis and treatment electrode 31 and the graphene film to work, and the treatment is performed by adopting a low-frequency pulse mode and an electrothermal moxibustion mode; the low-frequency pulse is to stimulate nerve and muscle of the lesion part with pulse current of specific frequency amplitude to excite the nerve and muscle and to produce contraction reaction, so as to promote blood circulation of the lesion part and reach the therapeutic effect. The thermal moxibustion mainly adopts far infrared rays emitted after the electric heating of graphene to perform moxibustion on meridian points of the back corresponding to the upper, middle and lower triple energizer.

Wherein the current detection is provided with five areas in total, and the detection area 1 is: T1-T5, corresponding to the lung of human body, the detection area 2 is: T4-T8, corresponding to the heart of the human body, the detection area 3 is: T7-T10, corresponding to liver (gall bladder) of human body, the detection area 4 is: T9-T12, corresponding to spleen (stomach) of human body, the detection area 5 is: T11-L5, corresponding to kidney of human body, the acupoints map is shown as 4.

According to one embodiment of the application, as shown in fig. 1, the system further comprises a cloud server in communication connection with the intelligent terminal and a data processing center in communication connection with the cloud server, wherein the data analysis center is mainly responsible for three functions of user profiling, case analysis, report generation and the like. The profiling is mainly used for establishing a detailed file for each user using the governor vessel intelligent diagnosis treatment clothes and is used for rear-end case analysis. Meanwhile, analyzing and summarizing the collected big data through an advanced artificial intelligence algorithm, finding the corresponding relation between the case and the data of each patient, generating a related report, and sending the related report to related users.

According to one embodiment of the application, the system further comprises a user service center in communication connection with the cloud server, wherein the user service center can establish information sharing with the community hospital and the third party service organization so as to enable the community hospital and the third party service organization to acquire measurement results and treatment results of the user at regular time so as to take advanced treatment. The community hospitals and the third party service institutions can also check whether the disease is improved through treatment according to the treatment information, if the disease is abnormal, the users are informed to seek medical attention to the relevant hospitals in time.

According to one embodiment of the present application, as shown in fig. 5, the intelligent terminal includes a processor electrically connected to the diagnosis and treatment electrode 31 and the graphene film, and a storage unit and a wireless communication unit respectively connected to the processor, where the processor is communicatively connected to the cloud server through the wireless communication unit. The processor can adopt an STM32F4 microprocessor, the STM32F4 is an ARM-based high-performance microcontroller which is pushed out by ST, a 90nm technology is adopted, the working frequency can reach 180MHz/225DMIPS, and the processor comprises 1MB flash and 192Kb SRAM, so that various complex algorithms can be processed.

The intelligent terminal comprises the functions of data collection, reporting, broadcasting and the like, and meanwhile, detection and treatment data on the diagnosis and treatment suit 1 can be obtained in real time through 433M wireless, and the detection and treatment data are synchronized to a cloud server through a 4G network. By adopting the SX1212 radio frequency chip, the communication distance between the diagnosis and treatment suit 1 and the intelligent terminal can reach about 100 meters, and the user can be ensured to stably acquire data at any place in the home. The intelligent terminal can also communicate with the mobile phone through BLE4.0, and a user can directly connect with the intelligent terminal through the mobile phone to inquire various information.

According to one embodiment of the application, the intelligent terminal further comprises a display screen, a voice broadcasting unit and an LED indicator lamp which are connected with the processor respectively. Wherein, the display screen can adopt a 1.3 inch blue character LCD display screen for various displays of equipment working information and feedback results,

after the server analyzes the big data, the result is returned to the intelligent terminal, and the intelligent terminal can inform the user through the voice broadcasting unit and the display screen.

According to an embodiment of the application, a filling layer 4 is arranged between the diagnosis and treatment layer 3 and the graphene layer 5, and soft sponge can be used for filling, so that the tightness of contact between the detection point and the skin is ensured.

According to an embodiment of the present application, the interval between the diagnosis and treatment electrode sets is adjustable, and the position of the diagnosis and treatment electrode 31 can be adjusted according to users with different heights during use, so as to be suitable for users with different heights.

According to one embodiment of the present application, as shown in fig. 6, the current detection circuit includes a detection signal amplifying circuit and an AD sampling circuit; the input end of the detection signal amplifying circuit is electrically connected with the diagnosis and treatment electrode 31, the output end of the detection signal amplifying circuit is connected with the input end of the AD sampling circuit, and the output end of the AD sampling circuit is connected with the input end of the processor. The detection signal amplifying circuit comprises an amplifier (such as AD 8628) and a corresponding peripheral circuit, and the AD sampling circuit comprises an AD converter (such as AD 7705) and a corresponding peripheral circuit.

In operation, the acupoint current detection circuit amplifies the current signal obtained from the diagnosis and treatment electrode 31 by the signal detection amplification circuit, and converts the amplified current signal into a digital signal by the AD sampling circuit and transmits the digital signal to the processor. The processor then adopts a related algorithm to carry out smooth filtering on the data and calculate the acupoint current.

By applying a current of 3V/1mA to one of the diagnosis electrodes 31 in the diagnosis electrode group, and then detecting a current of the other diagnosis electrode 31 in the diagnosis electrode group by a current detection circuit, related diseases can be primarily diagnosed by acquiring a change in the electrical conductivity of meridian points,

according to one embodiment of the present application, as shown in fig. 7, the pulse conversion circuit includes a pulse generator P2, a pulse transformer T1 connected to an output terminal of the pulse generator P2, and a first pulse signal amplifying circuit and a second pulse signal amplifying circuit connected to output terminals of the pulse transformer T1, respectively; the pulse conversion circuit converts DC5V into acupuncture wave with frequency of 1KHZ and voltage amplitude of 30-60V, and treats acupoints by the acupuncture wave.

The first output end of the pulse generator P2 is respectively connected with a pin 5 and a pin 6 of the pulse transformer T1, the second output end of the pulse generator P2 is connected with one end of a resistor R58, the other end of the resistor R58 is connected with a pin 7 of the pulse transformer T1, a filter circuit is connected between the first output end of the pulse generator P2 and the other end of the resistor R58, and the filter circuit comprises a resistor R52 and a capacitor C41 which are connected in series and a resistor R53 which is connected at two ends of the resistor R52 and the capacitor C41 in parallel.

The first pulse signal amplifying circuit comprises a triode Q4 and a triode Q7, the pin 4 of the pulse transformer T1 is connected with the emitting electrode of the triode Q4, the base electrode of the triode Q4 is connected with the collecting electrode of the triode Q7 through a resistor R42, a resistor R39 is connected in parallel between the emitting electrode of the triode Q4 and the base electrode of the triode Q4, the emitting electrode of the triode Q7 is grounded, and the base electrode of the triode Q7 is connected with one diagnosis and treatment electrode 31 of the diagnosis and treatment electrode group through a resistor R51; the pin 4 of the pulse transformer T1 is also connected with a first resonant circuit, the first resonant circuit comprises a resistor R40 and a capacitor C36 which are connected in series, the other end of the resistor R40 is connected with the pin 4 of the pulse transformer T1, and the other end of the capacitor C36 is grounded; the second pulse signal amplifying circuit comprises a triode Q8 and a triode Q10, the pin 1 of the pulse transformer T1 is connected with the emitter of the triode Q8, the base electrode of the triode Q8 is connected with the collector of the triode Q10 through a resistor R56, a resistor R60 is connected in parallel between the emitter of the triode Q8 and the base electrode of the triode Q10, the emitter of the triode Q10 is grounded, and the base electrode of the triode Q10 is connected with the other diagnosis and treatment electrode 31 of the diagnosis and treatment electrode group through a resistor R61; the pin 1 of the pulse transformer T1 is also connected with a second resonant circuit, the second resonant circuit comprises a resistor R59 and a capacitor C43 which are connected in series, the other end of the resistor R59 is connected with the pin 1 of the pulse transformer T1, and the other end of the capacitor C43 is grounded; the pin 2 and the pin 3 of the pulse transformer T1 are respectively connected with one end of the resistor R46 and the positive polarity end of the capacitor C46 after being short-circuited, and then are connected with the processor; the other end of the resistor R46 is connected with the negative end of the capacitor C46 and then is respectively connected with the collector of the triode Q4, the collector of the triode Q8 and a 5V direct current power supply.

According to one embodiment of the present application, the temperature control circuit includes a dual voltage comparator machine peripheral circuit, as shown in fig. 8. When the device works, the temperature control circuit can be controlled to generate heat to realize thermal moxibustion by the temperature control circuit, wherein the device mainly adopts a graphene film with a wide frequency spectrum of 5-25 um, the temperature is controllable at 35-55 ℃, and the heating only needs about 10S. Compared with common carbon fiber, the graphene film has the characteristics of more uniform heating, quicker conduction, better flexibility, no fracture in a twisting and knotting state and the like.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered by the scope of the claims of the present invention.

Claims (8)

1. The intelligent diagnosis and treatment system is characterized by comprising a diagnosis and treatment belt, wherein the diagnosis and treatment belt comprises a diagnosis and treatment layer, a graphene layer, a protection layer and an intelligent terminal; the diagnosis and treatment layer is tightly attached to the back of a human body, a plurality of diagnosis and treatment electrode groups are arranged in the diagnosis and treatment layer, each diagnosis and treatment electrode group comprises two diagnosis and treatment electrodes, and the diagnosis and treatment electrode groups are distributed according to meridian points of the back of the human body and are clung to the skin to form a detection loop; the diagnosis and treatment electrode group is respectively connected with the input end of a current detection circuit and the output end of a pulse conversion circuit; a graphene film is arranged in the graphene layer and is connected with a temperature control circuit; the current detection circuit, the pulse conversion circuit and the temperature control circuit are all connected with the intelligent terminal;

the pulse conversion circuit comprises a pulse generator P2, a pulse transformer T1 connected with the output end of the pulse generator P2, and a first pulse signal amplifying circuit and a second pulse signal amplifying circuit which are respectively connected with the output end of the pulse transformer T1;

the first output end of the pulse generator P2 is respectively connected with a pin 5 and a pin 6 of the pulse transformer T1, the second output end of the pulse generator P2 is connected with one end of a resistor R58, the other end of the resistor R58 is connected with a pin 7 of the pulse transformer T1, a filter circuit is connected between the first output end of the pulse generator P2 and the other end of the resistor R58, and the filter circuit comprises a resistor R52 and a capacitor C41 which are connected in series and a resistor R53 which is connected at two ends of the resistor R52 and the capacitor C41 in parallel;

the first pulse signal amplifying circuit comprises a triode Q4 and a triode Q7, the pin 4 of the pulse transformer T1 is connected with the emitting electrode of the triode Q4, the base electrode of the triode Q4 is connected with the collecting electrode of the triode Q7 through a resistor R42, a resistor R39 is connected in parallel between the emitting electrode of the triode Q4 and the base electrode of the triode Q4, the emitting electrode of the triode Q7 is grounded, and the base electrode of the triode Q7 is connected with one diagnosis and treatment electrode of the diagnosis and treatment electrode group through a resistor R51; the pin 4 of the pulse transformer T1 is also connected with a first resonant circuit, the first resonant circuit comprises a resistor R40 and a capacitor C36 which are connected in series, the other end of the resistor R40 is connected with the pin 4 of the pulse transformer T1, and the other end of the capacitor C36 is grounded;

the second pulse signal amplifying circuit comprises a triode Q8 and a triode Q10, the pin 1 of the pulse transformer T1 is connected with the emitter of the triode Q8, the base electrode of the triode Q8 is connected with the collector of the triode Q10 through a resistor R56, a resistor R60 is connected in parallel between the emitter of the triode Q8 and the base electrode of the triode Q10, the emitter of the triode Q10 is grounded, and the base electrode of the triode Q10 is connected with the other diagnosis and treatment electrode of the diagnosis and treatment electrode group through a resistor R61; the pin 1 of the pulse transformer T1 is also connected with a second resonant circuit, the second resonant circuit comprises a resistor R59 and a capacitor C43 which are connected in series, the other end of the resistor R59 is connected with the pin 1 of the pulse transformer T1, and the other end of the capacitor C43 is grounded;

the pin 2 and the pin 3 of the pulse transformer T1 are respectively connected with one end of the resistor R46 and the positive polarity end of the capacitor C46 after being short-circuited, and then are connected with the processor; the other end of the resistor R46 is connected with the negative end of the capacitor C46 and then is respectively connected with the collector of the triode Q4, the collector of the triode Q8 and a 5V direct current power supply;

the temperature control circuit includes a dual voltage comparator.

2. The intelligent diagnostic system of claim 1, further comprising a cloud server in communication with the intelligent terminal and a data processing center in communication with the cloud server.

3. The intelligent diagnostic system of claim 2, further comprising a user service center communicatively coupled to the cloud server.

4. A system according to claim 3, wherein the intelligent terminal comprises a processor electrically connected to the diagnosis and treatment electrode and the graphene film, and a storage unit and a wireless communication unit respectively connected to the processor, and the processor is communicatively connected to the cloud server through the wireless communication unit.

5. The intelligent diagnosis and treatment system according to claim 4, wherein the intelligent terminal further comprises a display screen, a voice broadcasting unit and an LED indicator lamp which are respectively connected with the processor.

6. The intelligent diagnosis and treatment system according to claim 1, wherein a filling layer is arranged between the diagnosis and treatment layer and the graphene layer.

7. The intelligent diagnostic system of claim 1, wherein the spacing between the diagnostic electrode sets is adjustable.

8. The intelligent diagnostic system of claim 1, wherein the current detection circuit comprises a detection signal amplification circuit and an AD sampling circuit; the input end of the detection signal amplifying circuit is electrically connected with the diagnosis and treatment electrode, the output end of the detection signal amplifying circuit is connected with the input end of the AD sampling circuit, and the output end of the AD sampling circuit is connected with the input end of the processor.