RU95419U1 - REMOTE PATIENT STATE MONITORING SYSTEM - Google Patents

Abstract

 1. A system for remote monitoring of a patient’s condition, consisting of at least one biomedical sensor connected in series, a biomedical signal pre-processing means and a first biomedical signal processing complex configured to interact with a digital data transmission medium and a digital data transmission medium, the second complex of processing a biomedical signal, equipped with a database and a means of automatically processing the incoming biomedical signal, you equipped with the ability to interact with the data transmission medium, and the terminal of the medical worker, characterized in that the first complex of processing the biomedical signal is additionally equipped with an integrated or remote interface configured to access the patient, and the terminal of the medical worker contains a unit for connecting to the digital data transmission medium and connected through the aforementioned medium to the second processing complex of the biomedical signal. ! 2. The system for remote monitoring of a patient’s condition according to claim 1, characterized in that contact electrodes for electrophysiological studies and / or electrocardiographic electrodes and / or electroencephalographic electrodes and / or electrodes for measuring bioimpedance are used as a biomedical sensor and / or optical single-frequency photoplethysmogram sensor, and / or optical two-frequency blood oxygenation sensor, and / or mechanical activity sensor, and / or acceleration sensor, and / or thermometric sensor, and / or sensor ik of movement of movement of the chest, and / or pressure sensor, �

Description

The utility model relates to the field of medical technology, and more specifically, to provide remote (telemedicine) monitoring of the patient’s functional state.

A well-known telemedicine service system for medical facilities and medical institutions, containing hardware and software systems for obtaining digitized information about the health status of patients by processing the primary biometric signal taken from it, a digital data transmission medium, a central server for processing the received medical information and an automatic medical information processing tool for the purpose of operational storage and archiving, for example, in the form of a relational database [1].

The disadvantage of the analogue is the impossibility of organizing individual monitoring of the patient's condition outside the walls of the medical institution (in parity, at home).

The closest in technical essence and the achieved result to the claimed device is the telemedicine system of the Russian Antarctic expedition [2]. The prototype system includes a biometric or a group of biometric sensors (sensors of medical devices), which are connected in series to the preliminary processing of biometric signals taken from the patient. The specified tool is part of the complex processing (processing) of the biometric signal, made in the form of a unified workstation of a doctor on the basis of a telemedicine laboratory (or a group of telemedicine laboratories). The mentioned Antarctic telemedicine laboratories contain access to the data transmission medium (in particular, to satellite communication channels), which allows them to exchange information both among themselves and with the consultative diagnostic center. In turn, the consultative and diagnostic center is equipped with a central server with a database and is equipped with a decision-making unit. The mentioned components of the consultative-diagnostic center of information and communication interact with each other and are connected by their input-output to the data transmission medium.

The disadvantage of the prototype is the impossibility of organizing individual monitoring of the patient's condition outside the walls of a medical institution (i.e., a telemedicine laboratory).

The task to which this technical solution is directed is to improve the quality of public health services through the organization of individual telemedicine monitoring of the patient’s health.

The technical result expected from the claimed utility model is to expand the functionality of the device to monitor the status of a particular patient outside the walls of a medical institution.

The claimed technical result is achieved by the fact that in the remote monitoring system of the patient’s condition, consisting of at least one biomedical sensor connected in series, the biomedical signal pre-processing means and the first biomedical signal processing complex, configured to interact with the digital data transmission medium, and also a digital data transmission medium, the second processing complex of a biomedical signal, equipped with a database and automatic processing the incoming biomedical signal, configured to interact with the data transmission medium, and the terminal of the medical worker, the first processing complex of the biomedical signal is additionally equipped with an integrated or remote interface configured to access the patient, and the terminal of the medical worker contains a unit for connecting to the transmission medium digital data and connected through the aforementioned medium with the second complex processing of the biomedical signal.

Preferably, the contact monitoring electrodes for electrophysiological studies, and / or electrocardiographic electrodes, and / or electroencephalographic electrodes and / or electrodes for measuring bio-impedance, and / or an optical single-frequency photoplethysmogram sensor, are used as a biomedical sensor in the remote patient monitoring system, and / or an optical dual-frequency blood oxygenation sensor, and / or a mechanical activity sensor, and / or an acceleration sensor, and / or a thermometric sensor, and / or a sensor chest movement movements, and / or a pressure sensor, and / or an electrochemical sensor, and / or a video camera, and / or an acoustic microphone, and / or a non-invasive blood pressure sensor.

It is desirable that in the system for remote monitoring of the patient’s condition, the connection of the biomedical sensor with the means of preliminary processing of the biomedical signal was made with the possibility of a connector.

It is desirable that in the system for remote monitoring of the patient’s condition, the means for preliminary processing of the biomedical signal be made in the form of an amplifier-converter.

It is desirable that in the system for remote monitoring of the patient's condition, the amplifier-converter should be equipped with a USB interface or a wireless communication interface.

It is desirable that in the system for remote monitoring of the patient’s condition, a Wi-Fi radio channel and / or a Bluetooth radio channel and / or a ZigBee radio channel should be used as a wireless communication interface.

It is desirable that in the system for remote monitoring of the patient’s condition, the amplifier-converter should be made in the form of a remote unit or a unit integrated into the first processing complex of a biomedical signal.

It is desirable that in a system for remote monitoring of the patient’s condition, a device from the series: a computer, a mobile phone, a communicator, should be used as the first complex for processing a biomedical signal.

It is desirable that in the system for remote monitoring of the patient’s condition, a stationary computer, or a laptop computer or laptop computer, is used as a computer.

It is desirable that in the system of remote monitoring of the patient's condition, a household or industrial model should be used as a computer.

It is desirable that in the system for remote monitoring of the patient’s condition, the interface be configured to visualize textual and graphic information, and / or to reproduce an audio signal, and / or to receive information tactilely.

It is desirable that in the system for remote monitoring of the patient’s condition, the Internet and / or a local computer network, preferably Ethernet, and / or switched communication lines, and / or dedicated communication lines, and / or mobile radio networks, be used as a digital data transmission medium, and / or relay communication channels and / or satellite communication channels.

It is desirable that in the system for remote monitoring of the patient’s condition, a server or a computer cluster should be used as a second complex for processing a biomedical signal.

It is desirable that in a system for remote monitoring of the patient's condition, the database would be a relational database.

It is desirable that in the system for remote monitoring of the patient’s condition, the terminal of the medical worker should be a personal computer, or a mobile phone, or a communicator.

The claimed utility model is illustrated in the figure. Figure 1 conditionally shows a system for remote monitoring of the patient.

The list of positions.

1. The patient.

2. Biomedical sensor.

3. Connector.

4. A means of pre-processing the biomedical signal.

5. The first complex of processing a biomedical signal.

6. The data transmission medium.

7. The second complex of processing a biomedical signal.

8. Means of automatic processing of the incoming biomedical signal.

9. Database.

10. The terminal of a medical professional.

11. Block connecting to a data medium.

In the claimed system of remote monitoring of the patient’s state 1, depending on the monitoring purposes, one or several biomedical sensors 2 are attached to it. As biomedical (biomedical) sensors, contact electrodes for electrophysiological studies [3], electrocardiographic electrodes [4], electroencephalographic electrodes can be used [5], electrodes for bioimpedance measurement [6], an optical single-frequency photoplethysmogram sensor [7], an optical two-frequency blood oxygenation sensor [8], mechanical activity sensor [9], acceleration sensor [10], thermometric sensor [11], chest movement movement sensor [12], pressure sensor [13], electrochemical sensor [14], video camera [15], acoustic microphone [16] , non-invasive blood pressure sensor [17]. Through connector 3 [18], said biomedical sensor 2 is connected in series to a means for preprocessing a biomedical signal 4. In known embodiments, said means 4 are either a direct converter of an analog signal recorded by a biomedical sensor 2 from patient 1 into a digital signal [19] or, the conversion of the original biomedical signal to digital form occurs after its amplification (or amplification and subsequent filtering) [20]. The output of the biomedical signal preprocessor 4 is equipped with a USB interface [21] or a wireless communication interface [22] (in particular, a Wi-Fi radio channel, a Bluetooht radio channel, a ZigBee radio channel, or a combination of the mentioned radio channels). The first complex of processing the biomedical signal 5 is a hardware-software complex based on a computer [23], a mobile phone [24] or a switch [25]. At the same time, a stationary computer is used as a computer, for example AMD Athlon 64, Processor 3000+, 1.81 GHz, 1.00 GB RAM, NVIDIA m / card, nForce 4 Ultra, GeForce 6600GT graphics card, 120 GB HDD, Windows HP, or a laptop computer PVCW21S1R / L, or Acer Aspire Revo laptop. Also, as a computer, in addition to household models, an industrial model can be used, for example, manufactured by Contron / Cyberchron. Through the built-in or external modem [26, 27], the first processing complex of the biomedical signal 5 is connected to the data transmission medium 6. The data transmission medium 6 can be made in the form of wired, wireless or combined (wired and wireless) data transmission channels [28, 29] . In particular, the Internet [30] and / or a local computer network, preferably Ethernet [31], and / or switched communication lines [32], and / or dedicated communication lines [33] can be used as a digital data transmission medium and / or mobile radio communication networks [34], and / or relay communication channels [35], and / or satellite communication channels [36].

The second processing complex of the biomedical signal 7 is connected to the data transmission medium 6. As the aforementioned (ie, the second) processing complex, a server [37] or a computer cluster [38] can be used. Processing of information coming into the second processing complex of biomedical signals 7 is carried out on a hardware-software complex formed by a server (or at least one computer from a computer cluster) and a program installed on it [39]. The results of automatic processing of biomedical signals and the information supplementing them (for example, a private or collegial opinion of medical specialists issued as a result of an additional review of the mentioned information) are stored in a database, for example, based on HDD [40]. Database 9 is performed, as a rule, in the form of a relational database [41]. To prepare a conclusion by medical specialists, the workplace of the latter is equipped with a terminal for a medical worker 10. Well-known tools can be used as the mentioned terminal for a medical worker (doctor) [42-44]. Connection to the data transmission medium of terminal 10 is carried out by means of block 11, which in hardware implementation is a modem [45-47].

Using the claimed system of remote monitoring of the patient's condition is as follows.

Example 1

Patient 1, 35 years old, has an acute respiratory illness that occurs with high fever. It is cured at home with the prescription of a pastel regime. In this case, the medically significant monitoring parameter is the temperature of his body; therefore, an electronic thermometer was used as a biomedical sensor 2 [48]. Via the Nakamichi PCA connector 3, the biomedical sensor 2 is connected in series with the SADC-PCI (Russia) 4 analog-to-digital converter, the output of which is connected via the USB interface to the first complex for processing the biomedical signal 4 in the form of a TOSHIBA Satellite Pro L300 laptop, on which installed the Windows XP program. Through the Internet channel (provider "AKADO"), which acts as a data transmission medium 6, digitalized biomedical signals characterizing the patient’s current body temperature 1 are sent to the HP Proliant ML 110 G6 model server of the second processing complex of the biomedical signal 7. Automatic processing of incoming biomedical signal 8 (ie microprocessor) of this server, under the control of the BodyScan program additionally installed on the server, process information on patient 1 and place it in the relational database 9. The change in the patient’s body temperature 1 during monitoring is presented in the form of a conditional graph T = f (t), where T is the patient’s body temperature 1 (in ° С) as a function of time t. When the current value of the patient’s body temperature 1 exceeds the limits set in advance from the terminal of the medical worker 10, the means for automatically processing the incoming biomedical signal 8 is activated, which sends the corresponding warning signal to the interface (in this case, the built-in LCD computer screen) through the data transmission medium 6 of the first complex processing a biomedical signal 5. A visualized warning signal can be duplicated by an audio signal, for example, in the form of a voice message speech electronic informant. In parallel with the mentioned warning signal from the second processing complex of the biomedical signal 7 through the data transmission medium 6 and the connection unit 11 of the terminal of the medical worker 10, the doctor is remotely monitored for the condition of the patient 1. If necessary, the treating doctor can, for example, via Skype using the program organize a videoconference connection with patient 1 and state the last necessary instructions for the course of treatment.

Accordingly, patient 1 (using, in particular, the same Skype program) can proactively contact the mentioned doctor and get the necessary explanations and recommendations related to his painful condition. Other schemes of remote interaction between the doctor and the patient are possible (as part of the remote monitoring of the patient's condition 1), some of which are highlighted, for example, in the source [50].

Thus, in comparison with the prototype, the proposed device allows you to expand the functionality of the claimed system to monitor the condition of a particular patient (in this case, his body temperature), located outside the walls of a medical institution. When using the claimed device, the presence of a doctor next to the patient is not required. These circumstances give reason to claim the achievement of the claimed technical result.

Example 2

Patient 1, 62 years old, suffers from a severe form of coronary heart disease. He lives in a small village in a remote rural area without a stationary feldsher-midwife station. Accordingly, there are no medical workers in his village. The nearest hospital with a cardiologist is at a distance of 105 km. The village is supplied with electricity, i.e. a power line is connected to it. Due to the seasonal deterioration of the condition of patient 1, he is connected to a remote monitoring system for the period of exacerbation of the disease and, in accordance with the monitoring results, takes a course of drug treatment. In this case, patient 1 is supplied with a computerized hardware-software complex “Cardiovisor-6C” [51]. The biomedical sensors 2 of the aforementioned complex are four electrodes of the article EUROCLAMP 12917 (Italy), fixed by patient 1 to the limbs. Through the connectors 3, the electrodes are connected to the means for processing the biomedical signal 4, made in the form of an amplifier-converter KARDi 2/4 (Russia). Using the USB interface, the CARDi 2/4 is connected to the Acer Aspire M1641 personal computer with the main software (software) Windows XP and additional software “CardioVisor-06s” [52].

Through a channel created through the use of a power line (Sibirtelecom provider), which acts as a data transmission medium 6, the electrocardiogram signals of patient 1, digitized, are sent to the HP Proliant ML 110 G6 model server of the second biomedical signal processing unit 7. Automatic processing of incoming biomedical signal 8 (ie microprocessor) of this server under the control of the BodyScan program installed additionally on the server and CardioVisor-06s program [52] produce processing information on patient 1 and placing its results in a relational database 9.

The processed electrocardiogram of patient 1 during monitoring can be presented (visualized) in the form of a gallery of “portraits of the heart”, each of which is accompanied by a medical report automatically generated by CardioVisor-06s [52]. When the parameters of the patient’s electrocardiogram 1 exceed the permissible limits, the automatic processing of the incoming biomedical signal 8 is triggered, which sends the corresponding warning signal to the interface (in this case, an external LCD screen of a personal computer) through the data transfer medium 6 of the first processing complex of the biomedical signal 5. Visualized the warning signal can be duplicated by an audio signal, for example, in the form of a voice message of electronic voice inform torus. In parallel with the above-mentioned warning signal from the second processing complex of the biomedical signal 7 via the data transmission medium 6 (for example, the Internet) and the unit for connecting to it 11 of the terminal of the medical worker 10, the doctor is remotely monitoring the condition of patient 1. If necessary, the doctor through, for example , Skype programs are able to organize a videoconference connection with patient 1 and explain to the latter the necessary adjustments as part of the prescription for the course of treatment.

Accordingly, patient 1 (using a similar Skype program) can proactively contact the attending physician and get the necessary explanations and recommendations related to his current painful condition. Other schemes of remote interaction between the attending physician and patient 1 are possible (within the framework of remote monitoring of the condition), some of which are highlighted, for example, in the source [50].

Thus, in comparison with the prototype, the proposed device allows you to expand the functionality of the claimed system to monitor the condition of a particular patient (in this case, his body temperature), located outside the walls of a medical institution. When using the claimed device, the presence of a doctor next to the patient is not required. These circumstances give reason to claim the achievement of the claimed technical result.

Example 3

Patient 1, 48 years old, prone to manifestations of frequent hypertensive crisis. He lives in a remote mountainous area (Altai) without a stationary feldsher-midwife station. For this reason, there are no medical workers in the locality of his residence. The nearest FAP with a paramedic is at a distance of 62 km. The locality is supplied with electricity from autonomous sources of electric energy (based on diesel generators). Due to the periodic fluctuation of blood pressure in this patient 1, he is connected to a remote non-invasive monitoring system for blood pressure for the period of exacerbation of the disease and, in accordance with the monitoring results, takes a course of drug treatment.

In this case, patient 1 is provided with a computerized Lekard complex of LeptaMed company (Russia) [17]. Biomedical sensors 2 of the aforementioned complex are non-invasive sensors of a sphygmasser and bar annex. Through the connectors 3, the electrodes are connected to the means for processing the biomedical signal 4, made in the form of an amplifier-converter KARDi 2/4 (Russia). Using the Bluetooth interface, KARDi 2/4 is connected to the Acer Aspire M1641 personal computer with the main software (software) Windows XP and additional software “KARDI.RU” [53].

Biomedical signals are transmitted to the server through the channel created by using a computerized satellite VSAT terminal (equipped with a Ka-band antenna), which is part of the data transmission medium 6. From the patient’s personal computer 1 Acer Aspire M1641, digitalized barometric signals of the patient’s blood pressure 1 are received on the VSAT terminal via the Wi-Fi radio channel of the Ethernet network of the locality in which the patient lives 1. Then, through the satellite communication channel from the VSAT terminal, the mentioned signals Arograms are sent to the server of the HP Proliant ML 110 G6 model of the second complex for processing the biomedical signal 7. The automatic processing of the incoming biomedical signal 8 (ie, microprocessor) of this server is controlled by the additional BodyScan program [39] and the KARDI program .RU ”[53] process the information received by the patient 1 and place its results in a relational database 9.

The processed barogram of patient 1 during monitoring can be presented (visualized) in tabular form. When the characteristics of the barogram of patient 1 go beyond the permissible limits established by the attending physician (for example, 200 mm Hg), the automatic processing of the incoming biomedical signal 8 is triggered, which sends a corresponding warning signal to the interface via the data transmission medium 6 (in this case, an external LCD personal computer screen) of the first complex for processing a biomedical signal 5. A visualized warning signal can be duplicated by an audio signal, for example, in PME electronic voice message voice informant. In parallel with the mentioned warning signal from the second complex of processing the biomedical signal 7 through the data transmission medium 6 (for example, the Internet) and the unit for connecting to it 11 of the terminal of the medical worker 10, the doctor is remotely monitoring the condition of patient 1. If necessary, the attending physician by, for example, Skype programs are able to organize a videoconference connection with patient 1 and explain to the latter the necessary adjustments as part of the prescription for the course of treatment.

Accordingly, patient 1 (using a similar Skype program) can proactively contact the attending physician and get the necessary explanations and recommendations related to his current painful condition. Other schemes of remote interaction between the attending physician and patient 1 are possible (within the framework of remote monitoring of the condition), some of which are highlighted, for example, in the source [50].

Thus, in comparison with the prototype device, the proposed device allows you to expand the functionality of the claimed system to high-tech medical monitoring of the condition of a particular patient outside the walls of a medical institution. When operating the claimed device, the presence of the attending physician next to the patient is not required. These circumstances together give reason to claim the achievement of the claimed technical result.

The proposed systems for remote monitoring of the patient’s condition can be implemented (as can be seen from the “Information Sources” section) on the basis of well-known technical and software tools, which allows us to consider it consistent with the eligibility requirements of the utility model of “industrial applicability”.

INFORMATION SOURCES

1. Utility model of the Russian Federation No. 544445, G06F 19/00, publ. 06/27/2006, bull. Number 18.

2. Utility model of the Russian Federation No. 64888, G06F 19/00, publ. July 27, 2007, Byul. No. 21. (prototype)

3. The invention of the Russian Federation No. 2230483, A61B 5/0476, publ. June 20, 2004

4. Utility model of the Russian Federation No. 30547, АВВ 5/0478, publ. 07/10/2003

5. The invention of the Russian Federation No. 2294135, A61B 5/0408, publ. 02/27/2007, bull. No. 6.

6. The invention of the Russian Federation No. 2318435, A61B 5/053, publ. 03/10/2008, bull. Number 7.

7. Copyright certificate of the USSR No. 786983, publ. 12/15/1980, Bull. No. 46.

8. The invention of the Russian Federation No. 2040912, AB 5/14, publ. 08/09/1995,

9. The invention of the Russian Federation No. 2111133, BKK 28/06, publ. 05/20/1998

10. Utility model of the Russian Federation No. 15609, G01P 15/08, publ. 10/27/2000

11. The invention of the Russian Federation No. 2058019, G01K 7/14, publ. 04/10/1996

12. The invention of the Russian Federation No. 2297605, G01K 1/00, publ. 04/20/2007, Bull. No. 11.

13. The invention of the Russian Federation No. 2169912, G01L 9/04, publ. 06/27/2001

14. Utility model of the Russian Federation No. 37224, G01N 27/26, publ. 04/10/2004

15. The invention of the Russian Federation No. 2311113, A61B 3/10, publ. November 27, 2007, Byul. No. 33.

16. The utility model of the Russian Federation No. 62762, H04R 9/08, publ. April 27, 2007, Byul. No. 12.

17. Utility model of the Russian Federation No. 86429, АВВ 5/021, publ. September 10, 2009, Byul. Number 25.

18. The invention of the Russian Federation No. 2167686, A61H 39/00, publ. May 27, 2001

19. The invention of the Russian Federation No. 2339159, H03M 1/66, publ. November 20, 2008, Byul. Number 32.

20. Utility model of the Russian Federation No. 83179, A61B 8/12, publ. May 27, 2009, Byul. No. 15.

21. The invention of the Russian Federation No. 2345401, G06F 3/00, publ. January 27, 2007, Byul. Number 3.

22. The invention of the Russian Federation No. 2369033, H04L 29/06, publ. 09/27/2009 Bul. Number 27.

23. Utility model of the Russian Federation No. 80104, A61B 5/00, publ. January 27, 2009, Byul. Number 3.

24. Utility model of the Russian Federation No. 63200, АВВ 5/0402, publ. May 27, 2007, Byul. No. 15.

25. Utility model of the Russian Federation No. 71849, N01K 9/00, publ. March 20, 2008, Byul. No. 8.

26. Utility model of the Russian Federation No. 2017, G01S 7/00, publ. 10/20/2001 g.

27. Utility model of the Russian Federation No. 79734, H04L 15/00, publ. 01/10/2009, bull. No. 1.

28. Utility model of the Russian Federation No. 62265, G06F 19/00, publ. March 27, 2007, Byul. No. 9.

29. Utility model of the Russian Federation No. 72775, G06F 19/00, publ. 04/27/2008, Byup.№12.

30. The invention of the Russian Federation No. 2159955, G06F 15/163, publ. 11/27/2000

31. The invention of the Russian Federation No. 2368085, H01L 12/28, publ. September 20, 2009, Byul. No. 26.

32. Utility model of the Russian Federation No. 39767, H04J 3/08, publ. 08/10/2004

33. Application for invention of the Russian Federation No. 99125327, Н04В 7/216, publ. 09/27/2001

34. The invention of the Russian Federation No. 2369011, H04B 7/24, publ. September 27, 2009, Byul. Number 27.

35. The invention of the Russian Federation No. 2194365, H04J 11/00, publ. 12/10/2002

36. The invention of the Russian Federation No. 2373647, H04B 7/185, publ. November 20, 2009, Byul. Number 32.

37. The invention of the Russian Federation No. 2350046, H04W 92/00, publ. 03/20/2006, bull. No. 8.

38. Application for inventions of the Russian Federation No. 2005101735, G06F 1/00, publ. 07/10/2006

39. Certificate on state registration of the computer program of the Russian Federation No. 2009616070 "BodyScan", registered November 2, 2009

40. The invention of the Russian Federation No. 23808552, H04N 5/91, publ. 06/20/2009, Bull. Number 3.

41. Utility model of the Russian Federation No. 36907, G06F 17/30, publ. 03/27/2004

42. Application for invention of the Russian Federation No. 2006119637, G06Q 10/00, publ. 02/10/2008

43. The invention of the Russian Federation No. 2308760, G06Q 50/00, publ. 10.20.2007, Bull. No. 29.

44. Application for invention of the Russian Federation No. 2002122512, Go6F 59/00, publ. 02/20/2004

45. The invention of the Russian Federation No. 2109332, G06F 13/40, publ. 04/20/1998

46. Application for invention of the Russian Federation No. 2005138737, G06F 17/00, publ. 06/20/2007

47. The invention of the Russian Federation No. 2147791, H04L 5/14, publ. 04/20/2000

48. Utility model of the Russian Federation No. 339, G01K 7/22, publ. 04/16/1995 g.

49. Utility model of the Russian Federation No. 36819, B64D 47/00, publ. 03/27/2004

50. The invention of the Russian Federation No. 2308760, G06Q 50/00, publ. 10.20.2007, Bull. No. 29.

51. Utility model of the Russian Federation No. 55266, АВВ 5/0402, publ. 08/10/2006, bull. Number 22.

52. Certificate of official registration of the computer program No. 20066612820 "CardioVisor-06C", registered on August 09, 2006.

53. Certificate of state registration of the computer program of the Russian Federation No. 20099616423 "KARDI.RU", registered November 20, 2009

54. Utility model of the Russian Federation No. 75775, G06F 19/00, publ. 04/27/2008

Claims (15)

1. A system for remote monitoring of a patient’s condition, consisting of at least one biomedical sensor connected in series, a biomedical signal pre-processing means and a first biomedical signal processing complex configured to interact with a digital data transmission medium and a digital data transmission medium, the second complex of processing a biomedical signal, equipped with a database and a means of automatically processing the incoming biomedical signal, you equipped with the ability to interact with the data transmission medium, and the terminal of the medical worker, characterized in that the first complex of processing the biomedical signal is additionally equipped with an integrated or remote interface configured to access the patient, and the terminal of the medical worker contains a unit for connecting to the digital data transmission medium and connected through the aforementioned medium to the second processing complex of the biomedical signal. 2. The system for remote monitoring of a patient’s condition according to claim 1, characterized in that contact electrodes for electrophysiological studies and / or electrocardiographic electrodes and / or electroencephalographic electrodes and / or electrodes for measuring bioimpedance are used as a biomedical sensor and / or optical single-frequency photoplethysmogram sensor, and / or optical two-frequency blood oxygenation sensor, and / or mechanical activity sensor, and / or acceleration sensor, and / or thermometric sensor, and / or sensor infrared movements of the movement of the chest, and / or a pressure sensor, and / or an electrochemical sensor, and / or a video camera, and / or an acoustic microphone, and / or a non-invasive blood pressure sensor. 3. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that the connection of the biomedical sensor with the means for pre-processing the biomedical signal is made with the possibility of a connector. 4. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that the means for preliminary processing of the biomedical signal is made in the form of an amplifier-converter. 5. The system for remote monitoring of the patient’s condition according to claim 4, characterized in that the amplifier-converter is equipped with a USB interface or a wireless communication interface. 6. The system for remote monitoring of the patient’s condition according to claim 5, characterized in that a Wi-Fi radio channel and / or a Bluetooth radio channel and / or a ZigBee radio channel are used as a wireless communication interface. 7. The system for remote monitoring of the patient’s condition according to claim 4, characterized in that the amplifier-converter is made in the form of a remote unit or a unit built into the first processing complex of a biomedical signal. 8. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that the device from the series: computer, mobile phone, communicator is used as the first complex for processing a biomedical signal. 9. The system for remote monitoring of the patient’s condition according to claim 8, characterized in that a stationary computer, or a laptop computer, or a laptop computer is used as a computer. 10. The system for remote monitoring of the patient’s condition according to claim 8, characterized in that a household or industrial model is used as a computer. 11. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that the interface is configured to visualize text and graphic information and / or reproduce an audio signal and / or receive information tactilely. 12. The remote patient monitoring system according to claim 1, characterized in that the Internet and / or a local computer network, preferably Ethernet, and / or switched communication lines, and / or dedicated communication lines, are used as a digital data transmission medium. / or mobile radio networks, and / or relay channels, and / or satellite channels. 13. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that a server or a computer cluster is used as the second complex for processing the biomedical signal. 14. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that the database is a relational database. 15. The system for remote monitoring of the patient’s condition according to claim 1, characterized in that the terminal of the medical worker is a personal computer, or a mobile phone, or a communicator.