RU2354289C2 - Method of personal continuous supervision (monitoring) of human state, related system and state-related measuring procedure - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to pulse-wave measuring signal processing technique for diagnostics and medical reflexological procedures. According to the method of organs and/or systems measuring signal processing in scheduling the therapeutic action, there is additionally reflected matrix time history representing difference of comparative element sequences measured before any corrective action on the patient organism and after to diagnose.

EFFECT: invention allows extending application of monitoring of both static and dynamic patient state.

11 cl, 4 dwg

Description

The invention relates to medicine, namely to methods and devices for measuring a pulse wave for the purpose of diagnosis and therapeutic reflexotherapy procedures.

A known method of personal observation of a person’s condition and a device for conducting reflexological measurements [patent EP 1408830, publ. March 14, 2007]. According to the method, reflexological measurements are carried out using a measuring sensor, the electrical signals from which are structured in combination and configured in the sequence corresponding to the BAT parameters, through the transduction system they are converted into an FTDB format matrix (Ferraro-Tkachenko database), which reflects all potential values of the measured parameters, and viewing the status of organs is carried out using a computer equipped with appropriate software. As the measured parameters of the BAP, the conductivity of biologically active points (BAP) is used, which reflect the state of the internal energies of the channels in accordance with the ideas of classical eastern medicine. For diagnosis, the sinusoidal graph of the configured sequences is divided into several phases, and a comparative analysis is carried out in phases. The device for carrying out reflexological measurements includes a measuring sensor, a transduction system, an electric signal converter, an FTDB format matrix, a potential meter of all possible parameters on the basis of a computer with software for examining the patient’s body. The disadvantages of the known method and device is that the matrix and graph used do not adequately reflect the balance of internal energies of the body, while a set of parameters based on point estimates of the measured parameters is sensitive to various secondary factors, which does not allow a reliable diagnosis, and the layout of the device It is bulky and difficult to operate.

Also known is a personal monitoring method and apparatus for diagnosing blood circulation [patent US 5730138, publ. March 24, 1998]. According to the method, the shape of the pulse wave of blood pressure in the patient’s artery is measured, the frequency components of the pulse wave are analyzed, and samples of each resonant component of the pulse wave are compared with a sample of a normal pulse wave to determine a possible imbalance in the patient’s blood distribution. In accordance with this imbalance, a diagnosis is made on the basis of the principles of Chinese traditional medicine, according to which each harmonic in the pulse wave corresponds to a certain meridian, including certain organs. The apparatus for diagnosing and monitoring blood circulation includes a sensor applied to the artery, an analog-to-digital converter, a frequency-spectral analyzer with an output to a printer, a storage device, a keyboard, a rectifier, and a processor with an output to the display. The disadvantages of the known method and apparatus is that the method of interpreting the measured parameters is more empirical, and identifying the relationship between pulse parameters and assessments of a person’s state presents a certain difficulty, while the concept of a “normal” pulse wave is relative, which makes the diagnosis unreliable, and the layout of the device is cumbersome and difficult to operate.

The closest in technical essence is the method of personal monitoring of a person’s state, processing of pulse wave signals and parameter measurement signals, as well as a device for processing pulse wave signals based on the “Computer Pulse Analytical System” (hereinafter referred to as the PAS system), based on the description of the basic laws Eastern philosophy used in traditional Chinese medicine [patent RU 2234241, publ. 08/20/2004]. According to the method, in the diagnostic cabinet of the PAS system using an amplitude-frequency acoustic sensor in a stationary state, the patient measures the electrical pulse wave signal for a short time, then the measured pulse wave signal, which is a group of sequential sinusoidal half-waves, is decomposed into even and odd components, determined energy of the measured signal or its components and carry out a comparative analysis to make a diagnosis by comparing the energies with stavlyayuschih each other and / or with the energies of the reference signal constituting the pulse wave corresponding to the normal state organs or body systems. The device for processing pulse wave signals includes an amplitude-frequency acoustic pulse wave sensor with positioning means, adapted for installation on a patient’s body surface above a vein or artery in a stationary position to generate an electric signal of a prescribed shape corresponding to the measured pulse wave, and means for correcting the signal generated by the acoustic sensor for receiving an electrical signal of a prescribed form, a processing module for processing electric signal and a registrar that records the processed electrical signal and allows you to visually display information about the achievement of a stable electrical signal of the prescribed form. The disadvantages of the known methods and devices is that they are designed to assess the condition of the patient’s body discretely, i.e. at certain intervals for a short time, which does not give a complete picture of the state of its individual organs and body systems, while the patient is placed in a hospital at the time of measuring the pulse wave, where he must be stationary in order to avoid distortion of measurements, which is not always the case suitable and convenient for the patient, as it does not take into account his lifestyle and activities.

The technical task for the solution of which this technical solution is proposed is the creation of a personal system for constant monitoring (monitoring) of the patient’s condition both in statics and dynamics, carrying out a continuous closed cycle of collecting information about the state of his individual organs and / or body systems, identifying deviations from norms, classification and identification of the state and the development of control actions, as well as their use for monitoring and correction of the patient's condition, which helps to improve the quality of be ordered medical services, the creation of patient comfort and ease of use.

The specified technical problem is solved by the proposed method of personal monitoring of a person’s condition, processing pulse wave signals, according to which an electrical signal corresponding to the measured pulse wave is recorded using at least one sensor mounted on the surface of the patient’s body, then the amplitude-frequency characteristic is corrected (AFC) ) of the electric signal to the prescribed form, the electric signal is processed and a comparative analysis is carried out by comparing the energy the components of the signal of the measured pulse wave between themselves and / or with the energies of the signal components of the reference pulse wave for diagnosis. What is new is that over the BAP, located on the patient’s arm, for an extended period of time, an autonomous wireless microcomputer pulse wave sensor is fixed and the pulse wave electric signal is recorded continuously, as well as continuous autonomous storage and display of recorded diagnostic data and their transmission through global networks that allows you to quickly manage the patient's condition. Also, it provides convenience to the patient and does not hinder his movements if a portable optical pulse wave sensor is fixed on his hand. To obtain objective information about the state of the body, it is better if the electrical signal of the patient’s pulse wave is continuously recorded for at least a day. Registered diagnostic data can be autonomously transferred to an expert advisory center for analysis of the condition and preparation of exposure options and / or to an information and methodological advisory center for the accumulation and storage of patient information. For operational interaction within the system, it is better if they independently display the recorded data and transfer it over the Internet. They can also display diagnostic data with local means of monitoring and correcting the state, and it is better if the state is corrected using biological feedback devices.

The proposed method is implemented by a system for processing pulse wave signals, including at least one amplitude-frequency pulse wave sensor mounted on the surface of the patient’s body above a vein or artery to generate an electrical signal corresponding to the measured pulse wave, a processing module for processing the electrical signal and comparative analysis of the energies of the signal components and a recorder that records the processed electrical signal. What is new is that the pulse wave sensor installed above the BAP located on the patient’s arm is autonomous wireless, with the possibility of continuous recording and local display of pulse wave signals, while the processing module is configured to display the recorded diagnostic data on local means, and the recorder configured to transmit recorded diagnostic data via global networks to an expert advisory center and / or methodological information center consultation center. It is more convenient for the patient if the pulse wave sensor is made optical with the ability to be worn on the arm. To obtain complete and objective information, it is better if the pulse wave sensor is configured to continuously register the pulse wave for at least a day. The registrar, in addition to the usual display of the analysis results on a computer monitor, can be configured to transmit recorded diagnostic data via the Internet. It is better if the expert-consulting and information-methodological consulting centers are equipped with local means for displaying state monitoring and means for correcting the state, while the means for correcting the state can be equipped with biofeedback devices.

Also proposed is a method of processing measurement signals of parameters reflecting the state of organs and / or systems of the body, according to which, using a measuring sensor mounted on the surface of the patient’s body above a vein or artery, they measure the pulse wave electric signals generated by the sensor, which are then presented as at least one matrix containing comparative sequences of elements used for diagnosis. What is new is that when preparing a therapeutic effect plan, they additionally reflect the dynamics of the matrix change, which is the difference between the values of the comparative sequences of elements measured before applying any corrective effect on the patient’s body and after its use, while in the matrix as compared elements when diagnosis using a set of vectors of deformation of qi elements, adopted in eastern traditional medicine. The dynamics of changes in the matrix, leading to a transition from a state to a corrective action to a state after a corrective action can be defined as controlling the state of the Qi channels of the body, aimed at changing it towards recovery. It is better if direct control of the Qi state of the body’s channels is used by correcting the effect on biologically active points (BAP) according to the Bu-Ce method adopted in eastern traditional medicine. It is better if a pulse wave signal is received from the matrix in an inverse way, solving the inverse problem, which carries information about the necessary corrective action, which is used to generate a biological feedback signal and which can be used for harmonizing wellness correction of the body condition.

The invention is illustrated in graphic materials. Figure 1 presents the diagram of the "System of personal state monitoring" (hereinafter PAS monitor); figure 2 presents an example of a display of a wearable local means of state monitoring in the form of a ring; figure 3 presents an example of a display of a wearable local means of correction of the state, also made in the form of a ring; figure 4 presents an algorithm explaining the dynamics of the matrix in the form of the difference in the values of the deformation vectors Qi elements and the dynamics of constructing the resulting matrix in the form of the sum of the correcting unit effects.

The proposed technical solution is illustrated by the example of "Personal Status Monitoring System" (hereinafter referred to as the PAS monitor).

The PAS-monitor system is designed for continuous continuous monitoring of the patient, detecting events occurring in him in the form of changes in the state of individual organs and / or systems of the body, monitoring external and / or internal influences on his body, and timely corrective intervention in these events in the form of an endless process changes in the state of a person bringing him closer to an ideal harmonious form.

The method of processing pulse wave signals is an integral part of the PAS technology, presented in the form of a mobile personal monitoring system for the status of the PAS monitor 1 (see figure 1). Given the physiological characteristics of the patient and his lifestyle and activities, they decide to conduct continuous monitoring of changes in his condition in everyday conditions for five days. To measure pulse wave 3, a personal clothes microprocessor-based self-contained optical sensor 2 of the “clothespin” type (pulse oximetric sensor manufactured by South Korea) with local display means is attached to the wrist of the patient’s left hand. In the block 4 for receiving a signal using the signal microprocessor of the sensor 2, an analog-to-digital converter (ADC) is initiated, a registration timer and a continuous, sequential stream of digitized data 5 are generated, amplify it and correct the amplitude-phase frequency characteristics (AFC). In block 6 for extracting the period of the pulse wave and statistical processing, the periods of the pulse wave are separated by means of a discriminator, cutting off noise and other non-periodic signals, and in the statistical processing system, the reliability of the pulse wave, the stability of the series of pulse waves and the quality of positioning of the sensor 2 are selected, highlighting pulse waves 3 with the given quality parameters 7. In block 8 of the PAS analysis of pulse waves 3, by detecting the deformation of the local space, the deformation vector Qi of the elements is obtained, which is 9. The result of the analysis block 10 is treated with the preparation of diagnostic information analysis 9, converting them into useful for display and transmission of diagnostic data 11. The transformed information through the Internet is introduced into the PAS system for processing to diagnosis. The final results of the diagnostic data 11 are transmitted to the expert advisory center 12 and / or accumulated in the database of the information and methodological consulting center 13. The therapeutic effect is to regulate the body's Qi energy circulation with the restoration of Yin-Yang balance. In the expert advisory center 12, a constantly working group of experts in traditional Chinese medicine (TCM) processes the obtained data 11 to obtain a complete and reliable picture of the patient’s condition, understandable to the end user, develops specific recommendations for improving the patient’s condition, prescribes the components of therapeutic effects 14, makes up recipes, diets and transfers to medical treatment institutions 15 for their implementation and / or directly to the patient through biological feedback channels 16, 17, 18. Diagnostic data 11 accumulated in the information and methodological consultation center 13 is also used to develop recipes based on technical elements of biological feedback 16: laser, electrodes, thermocouples, vibrators, radios, etc., which combine with wearable local devices installed above the BAP of the patient’s body surface. Using stationary and local means of imaging, the experts monitor the patient’s condition and, if necessary, correct it, for which the condition correction means is equipped with biofeedback devices 16, 17, 18. The patient carries the local imaging means with him, for which they are paired with various devices, such as cell phones, clips, watches, rings (see figure 2 and 3). On the local display means 18 of the personal PAS monitor, a hexagram 21 is shown along the edges of which control buttons 19 are located. Hexagram 21 consists of six vertical positions corresponding to the sign of the deformation vector in the sequence in the row of state matrices 22 and 23 (see Fig. 4). A continuous line indicates positive deformations, and a broken line indicates negative or equal to zero deformations. On the local device for correcting the state of PAS 16, red and green signal lights 20 and control buttons 19 are located. Using the current state matrices 22 and 23, the single action matrices 24-29 and the total resultant action matrix 30, state changes are performed using control actions, for example in the form of light waves of various frequencies. Local tools are equipped with the following means of monitoring and displaying information that correspond to state matrices 22 and 23: stability level - the value of the residual harmony of qi, the level of disharmony - the sum of the deformations of qi, pathological types of qi (having maximum and minimum deformations), the level of qi - SIN area , spatial hexagrams according to laws 1 and 2 of the U - SIN, circulation hexagrams according to the rules of Qi circulation in time, the structure of Qi deformations according to the elements and interaction. Any effects on the human body, such as medicines, procedures, massage, nutrition, etc., have a complex effect and are elements of the human body. After a course of therapeutic treatment, the obtained treatment results are monitored and / or corrected via feedback channels through a pulse wave signal, which is again recorded by a self-contained wireless microprocessor self-correcting optical sensor 2 and the whole process is repeated first, and continues until the patient's condition reaches the required results.

The system for personal monitoring of the state of the PAS monitor 1 is an integral part of the PAS technology and consists of four blocks (see Fig. 1): a signal receiving unit 4, a pulse wave extraction unit 6, a PAS analysis unit 8 and a diagnostic information preparation unit 10. The receiving unit Signal 4 provides receiving a pulse wave 3 signal from an autonomous optical sensor 2 mounted on the patient’s hand, digitizing the pulse 3 signal, controlling an analog-to-digital converter (ADC), amplifying signal 3, and correcting its amplitude-phase frequency s characteristics (AFC). The pulse wave period extraction and statistical processing unit 6 extracts the pulse waves 3 using the pulse wave 3 discriminator, which extracts the periods of the pulse waves 3 from the signal, cutting off noise and other non-periodic signals. The statistical processing system evaluates the reliability of the pulse wave, the stability of the series of pulse waves and the quality of the positioning of the sensor 2, highlighting the pulse waves 3 with the specified quality parameters 7. The PAS analysis unit 8 of the pulse waves 3 by detecting deformation of the local space receives the deformation vector, which is the main result of the analysis 9 The unit for preparing diagnostic information 10 processes the results of analysis 9, converting them into convenient diagnostic data for display and transmission 11. Converting This information is entered via the Internet into the PAS system for processing for the purpose of making a diagnosis. The end result is diagnostic data 11, which is transmitted to the expert advisory center 12 and / or accumulated in the database of the information and methodological advisory center 13. In the expert advisory center 12 a group of experts in traditional Chinese medicine (TCM) works on an ongoing basis. Here, the data are processed to obtain a picture of the human condition that is understandable to the end user, specific recommendations are made to improve the human condition, treatment courses 14 and preventive measures are prescribed, recipes, diets are prepared and transferred to medical treatment institutions 15 for implementation. Diagnostic data 11 accumulated in the information and methodological consultation center 13 is used to generate signals via biological feedback channels 16, 17, 18. The advantage of using such centers is high service efficiency and wide possibilities with strict quality control. At the same time, the costs of providing experts are significantly lower than if each expert worked separately. Also, when working in a group of experts of various specializations, a comprehensive data analysis is provided. The expert consulting 12 and the information and methodological consulting 13 centers are equipped with state monitoring display devices and state correction tools that are equipped with biofeedback elements such as a laser, electrodes, thermocouples, vibrators, radios, etc. Local devices are wearable and paired with various devices, such as cell phones, clips, watches, rings (see figure 2 and 3).

The processing of measurement signals of parameters reflecting the state of organs and / or systems of the body is performed as follows. The acoustic signal of a pulse wave 3 is converted into an electrical signal by an optical sensor 2 of a serial production of the “clothespin” type (pulse oximetric sensor manufactured by South Korea). The optical sensor 2 is fixed over the BAP on the patient’s wrist and continuously measure the electrical signals of the pulse wave 3, which are first presented in the form of a state matrix 22 before the corrective action is applied, and then in the form of a state matrix 23 after the corrective effect on the patient’s body is applied (see figure 4). In matrices 22 and 23, the set of deformation vectors of the element element Chi adopted in eastern traditional medicine is used as elements for making a diagnosis. Subtracting the results of the measurements of the matrix 22 before applying the corrective action from the results of the measurements of the matrix 23 after applying the corrective action, we obtain a single action matrix 24, which is the inverse sign of the difference between the state matrices 22 and 23. The single action matrices 24-29 are the components of the corrective therapeutic effect prescription on the patient’s body, the total effect of which is determined by the resulting action matrix 30 (see figure 4). Using the diagnostic system PAS-monitor, the patient and the doctor can at any time find out the state of the body and evaluate the effectiveness of the actions taken. For example, the state matrix 22 reflects the state of the body before the patient takes aspirin, and the state matrix 23 reflects the state of the body after the patient takes aspirin, resulting in a single action matrix 24, for example from a pharmacopeia. A similar method is used to obtain other individual action matrices in the form of an action matrix 25 from phyto, aroma, color, etc. therapy, and / or action matrix 26 from Zhen-Tszyu therapy, and / or action matrix 27 from physiotherapy, and / or action matrix 28 from sociotherapy, and / or action matrix 29 from any other therapies. The obtained values in rows and columns are added, and as a result, a matrix of total action 30 is obtained (see Fig. 4). From the total matrix of action 30 in an inverse way, solving the inverse problem, one obtains a pulse wave signal 3, which carries information about the necessary corrective action, which is used to generate a biological feedback signal for harmonizing wellness correction of the body in a given mode and in real time. Using the inversion of the analysis mechanism, a pulse wave signal is obtained that carries information about the necessary action, which is used in biological feedback mechanisms on various physical bases: sound, light, color, smell, mechanical or physical action, electrical or radio wave signals performed on local devices. Local devices are equipped with technical means of monitoring and displaying information and technical elements of biological feedback, for example in the form of a laser, electrodes, thermocouples, vibrators. Local devices are wearable and are paired with various devices, such as cell phones, watches, clips or rings (see FIGS. 2 and 3).

The dynamics of the state matrix 22 before the corrective action to the state matrix 23 after the corrective action determine how to control the state of Qi energy of the body’s channels, aimed at changing it towards recovery, using direct control of the state of Qi of the body’s channels by correcting the effect on the BAP on the body surface the patient according to the Bu-Ce method (concentrate - disperse), reflecting the basic properties of the law of conservation of energy and adopted in the eastern traditionally medicine, where for the correction of a person’s state they change the sign and magnitude of Qi deformations and get a prescription for harmonizing the human condition. The Bu-Xie method is a global principle of controlling the state of the human body at any level of its existence. For example, the psycho-conscious level of control includes various kinds of psycho-actions in the form of self-action and / or external influences. These include rhythmotherapy, symmetry therapy and color therapy in the form of auto-training, extrasensory perception, raja yoga, religious practices, Yang Shen practice (body nutrition), certain aspects of Qi-gong, etc. The physical level of control includes all external influences on the human body and the nature of activity in the form of location and movement in the space of the human body itself. These include exposure to heat-cold, dryness-humidity, sparseness-saturation, sharpness-smoothness in the form of mud and other bathtubs, various types of showers, steam baths, all types of massage, all types of exposure to medical devices, surgery, zhenju therapy, gymnastics martial arts etc. The chemical level of control includes the consumption of environmental products, their processing and the formation of complex Qi energy and the process of throwing waste into the environment. These include the consumption of food products, including drugs, water and oxygen contained in the inhaled air, the digestive process and the body's nutrition with processed components, the discharge of digestive waste into the environment in the form of pharmaceuticals, dietetics, sanitation and hygiene, breathing exercises, aromatherapy. Each of the means and methods of controlling the human condition, depending on the degree and duration of exposure, has a corrective effect on individual organs and / or systems of the body at its own level, depending on the degree and duration of exposure, at the same time leads to harmonization of the whole organism. Based on the action matrixes of both unit 24-29 and the resulting 30, taking into account the vector nature of the elements, a multidimensional topographic map of the state space (not shown) is constructed, on which individual states are displayed in the form of a state matrix 22 and / or 23, like points in space event cards; display the dynamics of their state in the form of a route on an event map; display the topographic position of stable states, like contours in the space of an event map. In the PAS monitor, the dynamics of the state is interpreted as an event having a complex structure corresponding to the dimension of the card. Using a map, they solve the problems of identifying the state of an object or process, classify events that are complex in dynamics and time, and also design routes for changing the state, taking into account the given factors and the set goal, which are used to make a diagnosis, draw up a treatment plan and prescribe a prescription.

The PS-monitor system solves the tasks of dynamic, autonomous control and provides the ability to control the human condition. In combination with modern information transfer technologies, thanks to the miniaturization of devices, their autonomy, and the emergence of local information display facilities, it became possible to create remote centers for receiving and processing monitoring data, which is one of the most promising areas in telemedicine.

Claims (11)

1. A method of processing signals measuring pulse wave parameters reflecting the state of organs and / or body systems, according to which, using a measuring sensor mounted on the surface of the patient’s body, they measure the pulse wave electric signals generated by the sensor, the parameters of which reflect the components of the body’s internal energy, which represent during processing in the form of a matrix containing comparative sequences of elements obtained by comparing the energies of the components of the signal the measured pulse wave between itself and / or with the energies of the components of the signal of the reference pulse wave for diagnosis, characterized in that the measurement additionally reflects the dynamics of the matrix in the form of a matrix of the difference in the values of the comparative sequences of elements included in the matrix according to the measurement results before corrective action on organism and into the matrix according to the measurement results after such a corrective action. 2. The method according to claim 1, characterized in that as a corrective action use an action selected from the group: the effect on biologically active points; exposure to medicines, procedures, massage or nutrition. 3. The method according to claim 2, characterized in that the procedures include exposure to an electric or radio wave signal, sound, light, color and / or smell. 4. The method according to claim 1, characterized in that the measurement is carried out continuously. 5. The method according to claim 4, characterized in that they use an autonomous wireless sensor. 6. The method according to claim 4, characterized in that the measurement is carried out at least during the day. 7. The method according to claim 5, characterized in that the processed measurements are displayed by local control means. 8. The method according to claim 7, characterized in that they use portable local means of control. 9. The method according to claim 5, characterized in that the effect of local means of correction of the state. 10. The method according to claim 9, characterized in that they use portable local portable means for correcting the condition. 11. The method according to claim 5, characterized in that the measurement data is transmitted via the Internet for processing in the corresponding system.

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