RU2408254C1 - Information system of cardiologic rehabilitation department - Google Patents

Abstract

FIELD: medicine. ^ SUBSTANCE: invention relates to telemedical equipment, namely to means of automated control over condition of patients of cardiologic rehabilitation departments during post-operative or recovery period of treatment. Information system contains N sensors of electrocardiosignals, channels of communication, doctor on duty control unit. Additionally it contains central post unit and N units of patients' state monitoring, into each of which included are successively connected ADC, connected to corresponding elecrocardiosignal sensor, unit of information filtration and compression, shaper of alarm signals, shaper of alarm signal packets, modulator, commutator, radioreceiver-transmitter of patient's state monitoring unit and programmed shaper of time slots, start pulse generator, connected to ADC, reference frequency generator, connected to modulator, information packet shaper, connected with its inlet to second outlet of unit of information filtration and compression, and with its outlet - with second cummutator inlet, whose third inlet is connected with outlet of programmed shaper of time slots and controlling inlets of shapers of information packets and alarm signals. Central post (CP) unit includes successively connected CP radioreceiver-transmitter, CP commutator, doctor on duty control unit and generator-informer of acoustic alarm signal, central shaper of time slots, connected with CP radioreceiver-transmitter, CP commutator and doctor on duty control unit, and N sensors of alarm sensors, inlet of each of which is in parallel way connected with other outlet of CP commutator, and with outlet - with corresponding individual inlet of doctor on duty control unit interrupt, where N is number of beds in department of cardiologic rehabilitation. ^ EFFECT: invention allows to detect critical situations in controlled patients' state quickly and take medicinal measures in order to remove crisis manifestations in due time in situations when number of controlled patients is large. ^ 4 dwg

Description

The invention relates to telemedicine technology, in particular to means for automated monitoring of the condition of patients in cardiac rehabilitation departments during the postoperative or recovery period of treatment.

A well-known mobile telemedicine complex is described in the book by A. I. Grigoriev and others. “Space medicine”. - M .: “Slovo”, 2001, which is a set of programs and tools for receiving, digitizing and transmitting medical data from spacecraft to the Mission Control Center. The disadvantage of the system is the impossibility of using it in the departments of cardiac rehabilitation, since the system does not provide for the identification of critical health conditions of the patient.

Also known is the hardware-software station "Ambulance-071YS", which is an automated tool for consultative medicine, described in the book of the authors A.K. Blazhys and V.A. Dyuk. Telemedicine, St. Petersburg: SpetsLit. 2001, p. 43-45. The disadvantage of the system is the inability to quickly identify crisis situations of motor activity of the heart and mass use in clinical wards.

The closest in technical essence to the proposed technical solution is the "Information and analytical system in the field of telemedicine" containing workstations of remote users connected by communication channels to the control unit of a specialist consultant and a multiplexer that provides communication with the patient condition monitoring equipment and a unit for documenting the results diagnosis, adaptation unit for self-tuning and self-training, operational consultation unit and intelligent interface unit; moreover, the specialist consultant control unit contains an expert system, the workplace is connected to the smart interface unit, the specialist consultant unit is connected to the operational consult unit, the adaptation unit and the smart interface unit (RF Patent No. 2251965 C2, IPC A61B 5/0205, G06A, publ. . in Bul. No. 14 of 05.20.2005). The disadvantage of the system is the impossibility of using cardiac rehabilitation departments in order to increase the effectiveness of medical procedures by quickly identifying crisis situations and notifying the doctor on duty about this.

In the claims of the prototype, the indefinite concept “equipment for monitoring the patient’s condition” is used, which, judging by figure 1 of the prototype and the description of the system’s operation, includes block 6 cardiometer - a concept that is also widely interpreted. Therefore, hereinafter we will call the “equipment for monitoring the patient’s condition” as an electrocardiogram (EX) sensor and include it in the restrictive part of the formula of the invention. In addition, since the present invention uses N (and not one) ECS sensors according to the number of beds in the cardiological rehabilitation department, we will include N ECS sensors in the restrictive part of the formula of the invention. Further, the control unit of the specialist consultant for the prototype will henceforth be called the control unit of the doctor on duty.

The objective of the proposed technical solution is to create an information system for the department of cardiological rehabilitation in a clinic with a large number of patients served with the transmission of electrocardiograms (ECS) of a group of patients to the Central Post for monitoring electrocardiograms by medical staff on duty, as well as identifying crisis situations in the state of health of controlled patients and prompt notification of medical staff on duty in order to timely take medical measures to alleviate the crisis x manifestations.

The problem is solved in that the information system of the Department of cardiac rehabilitation, containing N sensors, electrocardiograms, communication channels, the control unit of the doctor on call, according to the invention, it further comprises a central unit and N units for monitoring the status of patients, each of which includes analogue connected in series -digital converter (ADC) connected to the corresponding electrocardiogram sensor, filtering and information compression unit, signal conditioner alarms, alarm packetizer, modulator, switch, radio transmitter / receiver of the patient condition monitoring unit and programmable time slot driver, triggering pulse generator connected to the ADC, reference frequency generator connected to the modulator, information packet generator, input connected to the second output of the node filtering and compressing information, and the output - with the second input of the switch, the third input of which is connected to the output of a programmable driver of time slots and control inputs data shapers and alarm packet shapers, and the central control unit (CPU) includes a series-connected radio transmitter / receiver, a CPU switch, an on-call doctor control unit and an acoustic alarm detector-generator, a central time slot driver connected to the transmitter-receiver The CPU, the CPU switch and the control unit of the doctor on duty, and N alarm detectors, the input of each of which is connected in parallel with the other output of the CPU switch, and the output, respectively individual interrupt input of the control unit of the doctor on duty, where N is the number of beds in the cardiological rehabilitation department.

Figure 1 presents the structural diagram of the claimed information system, figure 2 - the structure of the information packet, figure 3 - the structure of the alarm packets, figure 4 - the structure of time slots.

The information system of the cardiological rehabilitation department contains N sensors EX 1 ₁ , ..., 1 _N (according to the number of hospital beds), N blocks 2 ₁ ,. _.. , 2 _N patient condition monitoring (BMSP) and Central post 3. Each of the BMSP 2 ₁ , ..., 2 _N input is connected to the output of the corresponding sensor EX 1 ₁ , ..., 1 _N and contains a series-connected analog-to-digital converter (ADC) ) 4, information filtering and compression unit 5, information packet generator 6, patient condition monitoring unit 7 and radio transmitter-receiver 8 of the patient status monitoring unit, as well as an ADC start pulse generator 9 connected to the ADC 4, an alarm conditioner 10 connected with formov Telem 11 packages alarms, whose output is connected through a modulator 12 to the switch 7 patient monitoring unit, the second input of the modulator 12 is coupled to the reference frequency oscillator 13. The structure of each BMPS 2 ₁ , ..., 2 _N includes a programmable driver of 14 time slots, connected at the input to the output of the radio receiver-transmitter 8 of the BMPS, and at the output, with the control input of the switch 7 BMPS and the control inputs of the drivers of information packets 6 and signal packets alarm 11. Central post (CPU) 3 contains a series-connected radio transmitter-receiver 15 of the CPU, the switch 16 of the CPU, the control unit 17 of the doctor on call and the generator-detector 20 of the acoustic alarm connected to it. In addition, the Central post 3 contains a Central shaper 18 time slots connected to the radio transmitter 15 of the CPU, the switch 16 CPU and the control unit 17 of the doctor on call, and a group of detectors 19 ₁ , ..., 19 _N alarms, each of which is connected to the input in parallel to the output of the switch 16 of the CPU, and the output is connected to the corresponding individual interrupt input of the control unit 17 of the doctor on duty.

We will consider the operation of the information system using the example of one first sensor 1 ₁ EX with reference to many blocks where necessary.

The sensor 1 ₁ electrocardiogram generates an electrical signal corresponding to the work of the heart. The ADC trigger pulse generator 9 generates an infinite sequence of quantizing pulses. The analog-to-digital converter 4 is started from the ADC start-up pulse generator 9 and converts the analog signal from the output of the EX-sensor 1 ₁ into a sequence of multi-bit binary numbers (digital samples). In the node 5 filtering and compressing information, filtering unwanted interference components, including artifacts and noise; the signal is converted by encoding in order to minimize the amount of information transmitted. At the output of node 6, a packet of information of the first kind is formed in the composition shown in figure 2. In fields 7 and further, digitized and processed in block 5 EX from various leads are included. In order to reduce the load of the radio link between the BMPS 2 ₁ , ..., 2 _N and the Central post 3, the identification signs in italics (figure 2) are not transmitted in the first kind packet, but are included in the packet at the Central post 3. Here: flag - a unique bit number that provides information synchronization of the transmitting and receiving nodes. The methods of batch (frame) synchronization using flags are described in detail, for example, in the book of B. Sklyar. Digital communication. 2003. The durations of all fields are fixed and, as a rule, are expressed in bytes, so there is no confusion at the receiving end. The second field of the package is the number of the workplace, the third and fourth identification signs of the patient. Then the fields of date, time and number of leads follow. It is possible to quickly make additions or changes to the package structure.

Shaper 10 alarms removes information from the node 5 filtering and compressing information and, according to certain, predetermined signs, generates one or more alarms. Each critical situation detected by the alarm driver 10 is assigned a serial number. This can significantly reduce the amount of data transmitted in alarm packets. The format of the alarm packet is shown in Fig.3. Packets of the first and second kind are transmitted in accordance with the structure of the time slots indicated in figure 4. The operation of the switch 7 of the patient condition monitoring unit and shapers of information packets 6 and alarm packets 11 is synchronized by the signal from the output of the programmer shaper 14 time slots. As a result of this, packets pass through the switch 7 to the input of the transmitter, which is part of the radio transmitter 8, only at the allotted time points in accordance with Fig. 4.

The Central shaper 18 of the time slots forms an infinite periodic sequence of slots and pauses, shown in Fig.4. Each slot is designed to transmit an electrocardiogram from only one BMPS 2 ₁ , ..., 2 _N assigned to it. This ensures a uniform view of all patients on treatment at the Central ECG post on duty at the Central ECG post. During pauses, it is possible to transmit alarm packets. All BMPS 2 ₁ , ..., 2 _N have the ability to transmit an alarm at the time of a pause closest to the crisis event detected by the alarm generator 10. Therefore, collisions are possible when an alarm is simultaneously generated by several BMPS. To avoid this, alarm transmission is used with separation of the BMSP 2 ₁ , ..., 2 _N alarm signals according to the carrier frequency, at which the reference frequency generator 13 of each of the BMSP 2 ₁ , ..., 2 _{N is} initially tuned to a dedicated carrier frequency that does not coincide with the frequencies generators 13 other BMPs. The modulator 12 transfers the encoded alarm signal (s) to the carrier frequency generated by the reference frequency generator 13. This allows you to split the alarms coming from different BMPS 2 ₁ , ..., 2 _N to the Central post 3 at the same time. Alarms are encoded with ordinal numbers in accordance with the table, which is placed in the generator of alarms 10 BMPS and can be edited as necessary by authorized specialists. The coding of alarms was introduced in order to reduce the time spent on transmitting alarms over the radio link between the BMPS and Central Post 3.

The transmission of information packets and alarms from the BMPS 2 ₁ , ..., 2 _N is as follows.

The programmable shaper 14 slots on the signal received by the BMSP radio transmitter-transmitter 8 over the radio channel from the radio receiver-transmitter 15 of the Central post 3, forms the radio channel availability time slot for a particular BMSP 2 ₁ , ..., 2 _N , as indicated in Fig. 4. This provides a separation of the signals from various BMPS in time. The BMPS switch 7 connects the output of the information packetizer 6 to the input of the BMPS transmitter 8 for the duration of the slot allowing the radio channel to occupy information from the current BMPS 2 ₁ , ..., 2 _N by supplying a resolution potential that is generated by the programmed slot former 14. For each pauses between slots switches 7 in each BMPS 2 ₁ , ..., 2 _N connect the output of each modulator 12 with the input of the radio receiver-transmitter 8 BMPS. This allows the simultaneous transmission of alarms by all BMPS 2 ₁ , ..., 2 _N.

The control unit 17 of the doctor on call is a personal computer, with which all the steps for programming the system (making changes to the composition of patients, etc.) are performed, the system is controlled, the ECG received is indicated on the display of the personal computer, and the visual indication of alarms in decoded form. The acoustic alarm detector generator 20 starts when any alarm is received. The work of the Central post 3 is as follows.

The central shaper 18 time slots transmits radio pulses of time — slots — to synchronize the operation of the programmable shapers 14 time slots included in the BMPS 2 ₁ , ..., 2 _N , and controls the operation of the switch 16 of the Central post 3. The control consists in switching the output of the radio receiver the transmitter 15 of the Central post either to the input of the control unit 17 of the doctor on duty during the operation of the slots, or to the inputs of the group N of detectors 19 ₁ , ..., 19 _N alarms during all pauses. In the state of normal operation in the absence of alarms, the received ECGs are displayed in a visual form on the display screen of the control unit of the doctor on duty 17 according to the program set by the doctor on duty. For example, the doctor selects some patients for priority observation, as a result of which the ECG of these patients is indicated continuously or more often relative to the ECG of other patients.

Alarms are detected during pauses by the alarm detectors 19 ₁ , ..., 19 _N , the inputs of which are connected in parallel to the output of the switch 16. Each alarm detector emits a signal at the carrier frequency corresponding to one of the MBMS.

The effectiveness of the proposed technical solution lies in the fact that the collection of electrocardiological signals and their presentation on the Central post display in the form of traditional ECGs is carried out from all patients in the clinical department of cardiac rehabilitation with the identification of crisis deviations of the ECG parameters from normal ones and prompt notification of the medical staff on duty.

Claims (1)

The cardiology rehabilitation department information system, containing N electrocardiogram signals sensors, communication channels, a doctor’s on-site control unit, characterized in that it additionally contains a central post unit and N patient condition monitoring units, each of which includes a series-connected analog-to-digital converter (ADC) ) connected to the corresponding electrocardiogram sensor, information filtering and compression unit, alarm driver, signal packetizer in alarm, a modulator, a switch, a radio transmitter of a patient condition monitoring unit and a programmable driver of time slots, a trigger pulse generator connected to the ADC, a reference frequency generator connected to a modulator, an information packet generator, an input connected to the second output of the information filtering and compression unit , and the output - with the second input of the switch, the third input of which is connected to the output of the programmable driver of the time slots and the control inputs of the packetizer information and alarms, and the central control unit (CPU) includes a series-connected radio transmitter / receiver, a CPU switch, an on-call doctor control unit and an acoustic alarm detector-detector, a central time slot driver connected to a radio transmitter / receiver, and a CPU switch and the control unit of the doctor on duty, and N alarm detectors, the input of each of which is connected in parallel with the other output of the CPU switch, and the output - with the corresponding individual node interrupt input reign doctor on duty, where N - number of beds in the department of cardiac rehabilitation.

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