LT6972B - Telemedicine system and method for monitoring and control of ventilator parameters - Google Patents

Abstract

The invention describes an artificial lung ventilator (ALV) parameter monitoring and control system comprising more than one ALV, a server, a remote ALV parameter monitoring and control device, and a two-way voice communication module. Each ALV has a patient identification device, and the server has a scheme for the layout of the ALV in premises, so this telemedicine system identifies each patient and the ALV. Ventilation modes, ALV parameters, alarms, ventilation mode and at least one ALV parameter can be monitored remotely. The server can be connected to the ALV and ALV parameter monitoring and control device via physical connections, wireless connection (wi-fi, Bluetooth) or mobile Internet. The ALV has an integrated or separate IoT block, in which case the connection in the system can be easily changed, e.g., from 4G to 5G. The invention also describes a telemedicine method for monitoring and controlling the ventilation modes, alarms and ALV parameters of more than one ALV.TELEMEDICINE SYSTEM AND METHOD FOR MONITORING AND CONTROL OF VENTILATOR PARAMETERSThe invention describes an artificial lung ventilator (DPV) parameter monitoring and control system comprising more than one DPV, a server, a remote DPV parameter monitoring and control device, and a two-way voice communication module. Each DPV has a patient identification device, and the server has a scheme for the layout of the DPV in premises, so this telemedicine system identifies each patient and the DPV. Ventilation modes, DPV parameters, alarms, ventilation mode and at least one DPV parameter can be monitored remotely. The server can be connected to the DPV and DPV parameter monitoring and control device via physical connections, wireless connection (wi-fi, Bluetooth) or mobile Internet. The DPV has an integrated or separate IoT block, in which case the connection in the system can be easily changed, e.g. from 4G to 5G. The invention also describes a telemedicine method for monitoring and controlling the ventilation modes, alarms and DPV parameters of more than one DPV.

Description

TECHNICAL FIELD

The invention belongs to the field of medical devices, and specifically, it is the remote control of artificial lung ventilators by means of telemedicine solutions.

STATE OF THE ART

An artificial lung ventilator (DPV) is a device that supplies a breathing gas mixture to the patient's airways to ensure oxygenation and removal of CO2 from the body. DPV is used in various clinical conditions, when acute or chronic respiratory failure occurs: lung diseases, head or spine injuries, stroke, sudden cardiac arrest, severe acute respiratory syndrome, pneumonia and others. During the COVID-19 pandemic, there has been a significant increase in the need for DPV, as 5% of patients with COVID-19 develop acute respiratory failure and require artificial lung ventilation. Pulmonary ventilation is divided into invasive and non-invasive. Applied ventilation modes can be mandatory or assisted depending on the patient's condition and respiratory function. The delivery of the breathing gas mixture to the patient's airway can be volume controlled, pressure controlled or mixed. In intensive care units, mechanical ventilators with controlled ventilation are used, which take over the control of the patient's breathing in full or partially control the patient's breathing. a tube is inserted into the patient's trachea, through which a mixture of breathing gases is supplied to the airways and carbon dioxide is removed. The disease caused by the COVID-19 virus manifests itself in a special airborne-droplet way. This leads to extreme working conditions for the medical staff who work directly with patients suffering from this disease. Patients with a contagious disease are usually treated in isolated areas, which are separated from rooms not infected with the COVID-19 virus. In the case of COVID-19 or other contagious diseases, medical personnel wear protective equipment in infected areas, such as: suits, goggles, respirators, gloves, gowns, etc. It takes 5-10 minutes to put on these equipment. The treatment of patients on mechanical ventilation requires special attention. This group of patients is characterized by multiple organ failure and a very dynamic course of the condition, often requiring quick decisions and changing the settings of devices that ensure vital functions. A delay in changing the modes and parameters of the DPV device can cause damage to the patient's health. Being in a clean area, the doctor not only cannot see the DPV parameters of a remote patient, but to make changes, he has to get to the patient, losing a lot of time due to wearing protective equipment, etc. When human resources allow having a doctor near all patients 24/7, this problem is not so big , excluding the fact that a long stay in an infected area increases the probability of the doctor becoming infected. However, with the lack of specialized doctors who are able to correctly operate DPV devices, this becomes a strong aggravating circumstance.

One of the solutions offered in the world to solve the mentioned problems is telemedicine, which provides remote solutions for patient monitoring or medical device management, thus reducing or completely avoiding contacts between the patient and the staff of the medical institution and shortening the time of performing an active medical action. Remote monitoring and management of DPV would reduce the chance of infection and affect the patient's health or even survival.

Patent application EP3624131A1 (published 2020-03-18) describes a solution that enables remote monitoring of DPV parameters. However, there is no possibility to change the parameters of DPV remotely, so, although less often, the staff of the medical institution still has to go to the patient. In addition, there is no possibility to combine many DPVs into a single system, so if there are many patients and DPVs, many descriptive DPV monitoring devices will be required, which is space-consuming, inconvenient and expensive.

Patent application US20180082033A1 (published 2018-03-22) describes a device that remotely monitors and can automatically change some DPV parameters. However, this is an automatic control of only a few essential DPV parameters. The staff of the treatment facility cannot manage the selected DPV parameters remotely, they still have to get to the patient. In addition, each DPV has a separate monitoring and control machine, so if it is inconvenient and expensive to monitor many patients.

Patent application US20020120676A1 (published 2005-01-04) describes a DPV monitoring system for combining more than one DPV into a common system. This invention also has disadvantages because the system is only for monitoring the DPV parameters, there is no possibility to control the DPV parameters remotely.

The described invention solves these problems and does not have the above-mentioned disadvantages. The described DPV system has the following advantages:

- more than one DPV can be combined into a common system;

- there is two-way voice communication between DPV and DPV parameters monitoring and control system;

- each DPV has a patient identification device that allows easy identification of each patient and DPV;

- the monitoring and control device has two modules: the DPV parameters monitoring module and the DPV parameters monitoring and control module;

- integrated alarm system adapted for remote monitoring of DPV parameters.

ESSENCE OF THE INVENTION

The invention describes a remote monitoring and control system for artificial lung ventilator (DPV) parameters, ventilation modes and alarm signals, consisting of more than one DPV, a server, a remote DPV parameter monitoring and control device, and a voice communication module. Each DPV has a patient identification device, and the server has a diagram of the placement of DPVs in the premises, so this telemedicine system identifies each DPV and allows monitoring and changing the parameters of more than one DPV remotely, which reduces the possibility of contamination and saves time when visiting patients. The server with DPV and DPV parameter monitoring and control device can be connected by physical connections, wireless connection (wi-fi, Bluetooth) or mobile internet (2G/ 3G/ 4G or 5G). The DPV has a separate IoT unit, so the connection between the server and the DPV parameter monitoring and control device can be easily changed, e.g. from 4G to 5G. The connection is encrypted, and the connection requires authorization and identification, so outsiders cannot access the system and control the DPV parameters. The DPV parameter monitoring and control system can monitor ventilation modes and the following DPV parameters: oxygen concentration (FiO2), respiratory rate (RR), inspiratory time (Tinsp), expiratory time (Texp), inspiratory pressure (Pinsp), inspiratory-expiratory time ratio (I:E ratio), inspiratory single volume (VTinsp), maximum pressure (Pmax), positive end-expiratory pressure (PEEP), determination of spontaneous breathing sensitivity (Spont trigger), backup mode selection (Backup mode), pressure maintenance (Pressure support), total ventilation time, inspiratory minute volume (MVinsp), expiratory single volume (VTexp), expiratory minute volume (MVexp), respiratory gas leakage (Air leak), total respiratory frequency (Rtot), respiratory gas flow (Flow), lung tissue compliance (Compliance), peak pressure (Ppeak), pressure plateau index (Pplato), oxygen saturation (SpO2) and end-expiratory carbon dioxide (ETCO2), as well as DPV calculated s outputs, backup battery charge level, date and time, and alarms. The system can change ventilation modes and at least one of the following DPV parameters. The invention also describes a telemedicine method for monitoring and controlling parameters of more than one DPV, which allows combining multiple DPVs into a common system and remotely monitoring and changing selected DPV parameters.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1. Block diagram of the artificial lung ventilator parameter monitoring and control system. Here 1 - DPV, 1.1 - IoT unit, 1.2 - data input and output device, 1.3 - patient identification device, 1.4 - backup power battery, 1.5 - Internet service, 2 - server, 2.1 - virtual machine. 2.2 telemedicine software, 2.3 - database, 2.4 - layout diagram of DPV in premises, 3 - device for monitoring and controlling DPV parameters, 3.1 - module for monitoring DPV parameters. 3.2 - DPV parameter monitoring and control module, 4 - connection between DPV and server, 5 - connection between server and DPV parameter monitoring and control device, 6 - two-way voice communication module, 7 - alarm system.

THE BEST LIVING OPTIONS

The invention describes a telemedicine system for monitoring and controlling the parameters of an artificial lung ventilator (DPV) (1) and a method for combining more than one DPV (1) into a common telemedicine system and remotely monitoring and changing the parameters of the DPV (1). Fig. 1 is a block diagram of the DPV (1) parameter monitoring and control system. The said system consists of:

- VAT (1);

- server (2);

- DPV parameter monitoring and control device (3);

- two-way voice communication (6).

DPV (1) is a medical device designed to artificially ventilate the lungs of patients. During ventilation, a mask or tube is used, through which breathing gases are supplied to the patient's lungs: air, oxygen or a mixture of oxygen with other gases. The concentration of the supplied breathing gas mixture is determined by the FiO2 parameter, which is controlled in the DPV device. Artificial lung ventilation can be controlled in either volume or pressure modes. Mechanical DPV (1) is mostly used. DPV (1) consists of IoT unit (1.1), data input and output device (1.2), patient identification device (1.3), backup power battery (1.4) and accessories: non-invasive ventilation face mask or intubation tube, exhalation filter, breathing filter , patient circuit, exhalation valve, breathing gas supply line, DPV power cable and other standard accessories, thanks to which breathing gas of the required composition, pressure and volume is supplied to the patient's lungs. DPV (1) can be volume-controlled when the volume of air delivered to the lungs is controlled; pressure-controlled, where the pressure of the air supplied to the lungs is controlled; or mixed, controlled by volume and pressure. The ventilation modes required for DPV (1) can be selected and can be changed during intensive care. DPV (1) has physical connections to external devices. Such connections can be USB, HDMI, DVI, alarm outputs for connecting the device to an existing alarm system, and others.

In one embodiment of the invention, the DPV (1) operates when the DPV (1) parameter monitoring and control system has a standard breathing gas pressure. In another embodiment of the invention, DPV (1) operates when the operating pressure of the central breathing gas supply system in the DPV (1) parameter monitoring and control system is lower than required by the standard. This is important in the event of a pandemic or other disaster, when a large number of DPV (1) are connected to the DPV (1) parameter monitoring and control system, and there is not enough gas supply to maintain high pressure. For example, when the standard pressure is 2.8 bar, the DPV (1) can also operate at a pressure of 2 bar. This ensures reliable operation of the DPV (1) in case of an overloaded central breathing gas supply system.

The Internet of Things unit (1.1) is a device thanks to which the DPV (1) maintains a connection with the server (2). More than one DPV (1) can be connected to the DPV parameter monitoring and control system (3) (Fig. 1). In one embodiment of the described invention, the DPV (1) parameter monitoring and control system consists of 20 DPV (1) or more. There are two possible options for connecting the IoT unit (1.1) to the DPV (1). In the first case, the IoT unit (1.1) is integrated into the DPV (1). In this case, DPV (1) is compact, convenient to use, does not require wiring. Otherwise, the DPV (1) has a replaceable IoT unit (1.1) which is available as a separate attachment. In this case, the advantage is that when communication transmission technologies change, it is possible to easily replace one connection with another without changing the DPV itself (1). Changing the IoT unit (1.1) can easily change the internet connection, e.g. from 4G to 5G.

The data input and output device (1.2) is one or more devices, thanks to which it is possible to monitor and change the parameters of the DPV (1), the ventilation modes used, and to monitor the alarm signals in the presence of direct proximity to the DPV (1) and the patient. The data input and output device (1.2) can be a computer, tablet, mobile phone or other device that has a screen for monitoring the parameters of the DPV (1) and a multifunction knob, keyboard, mouse or touch screen for changing the parameters of the DPV (1). The data input and output device (1.2) has a microphone, a speaker, a video camera or other means necessary for the transmission of voice and video data. Thanks to the data input and output device (1.2), it is possible to set parameters of the DPV (1) mode, alarm limits and enter patient data.

In one embodiment, the patient identification device (1.3) determines the location of each DPV (1) with the help of wi-fi technology, which allows monitoring and positioning of the DPV (1) location. In another embodiment, when a wired connection is used, the location of the DPV (1) is determined by the routing table, gateway numbers, and other addresses.

The DPV (1) also has a backup power battery (1.4) that can ensure the functionality of the DPV (1) without an external power source.

In a separate case, the DPV (1) additionally has an Internet service (1.5), which allows the DPV (1) to be connected directly to the DPV parameter monitoring and control device (3). In this case, the DPV (1) parameter monitoring and control system consists of the DPV (1) and the DPV parameter monitoring and control device (3), and the server (2) is not included in the system. When the DPV (1) has an Internet service (1.5), accessing the Internet service (1.5) remotely, the DPV (1) web page with the DPV (1) parameters monitoring and control is opened in the browser window of the DPV parameter monitoring and control device (3) functionality. This is a convenient and cheap way to manage DPV (1) remotely, when the medical institution acquires only one or several DPVs (1), since in this case there is no need to purchase a server (2).

As the patient's condition changes, it is necessary to monitor and change ventilation parameters and/or ventilation modes accordingly. In the case of the described invention, the following DPV (1) parameters are monitored, which can be changed directly by DPV (1) or remotely: oxygen concentration (FiO2), respiratory rate (RR), inspiratory time (Tinsp), inspiratory pressure (Pinsp), inspiratory -expiratory time ratio (I:E ratio), inspiratory single volume (VTinsp), maximum pressure (Pmax), positive end-expiratory pressure (PEEP), determination of spontaneous breathing sensitivity (Spont trigger), selection of backup mode (Backup mode) and pressure pressure support. DPV (1) also has the following parameters, the values of which cannot be changed, but which are displayed during artificial lung ventilation: total ventilation time, inspiratory minute volume (MVinsp), expiratory single volume (VTexp), expiratory minute volume (MVexp), expiratory minute volume (MVexp), gas leakage (Air leak), total breathing frequency (Rtot) (equal spontaneous frequency + mechanical breathing frequency), flow of breathing gas (Flow), continuity of lung tissue (Compliance), peak pressure (Ppeak), pressure plateau index (Pplato), oxygen saturation/pulse oximetry (SpO2), end-expiratory carbon dioxide (ETCO2), respiratory gas flow, pressure-volume curves, pulse oximetry and CO2 curves.

The DPV (1) parameter monitoring and control system has a server (2) which is connected to the DPV (1) and the DPV parameter monitoring and control device (3), so that the server (2) receives data from more than one DPV (1) and forwards the data to the DPV parameter monitoring and control device (3). The server (2) can be stationary, located e.g. on the premises of a treatment facility or service provider, or a virtual one located e.g. in the virtual cloud.

In the described case, the DPV (1) parameter monitoring and control system has a physical server (2) containing a virtual machine (2.1) with telemedicine software (2.2), a database (2.3) and a DPV indoor layout scheme (2.4) (Fig. 1). The database (2.3) stores data about patients, DPV (1), different parameters and parameter settings of DPV (1), accessories used in DPV (1), alarm history and other related data. The telemedicine software (2.2) controls the reception and forwarding of data to/from the DPV (1) and the DPV parameter monitoring and control device (3), and the recording and retrieval of data from the database (2.3). The scheme of placement of DPVs in the premises (2.4) collects data on the location of each DPV (1) in the treatment facility and provides a general diagram that shows the layout of all DPVs (1) in the system. The layout scheme (2.4) of the DPV in the premises can be of several levels - a diagram showing the reanimation stations, a drawing of the ward of the reanimation stations or interactive icons of the DPV. It is possible to choose that the DPV indoor layout diagram (2.4) shows several desired DPV (1) parameters or alarms next to each DPV (1). For example, critical parameters, their values and alarms can be displayed. The layout scheme of DPV in premises (2.4) is interactive: after pressing the icon of a specific DPV (1), other parameters and other related information of this specific DPV (1) appear on the screen of the DPV parameter monitoring and control device (3).

In another embodiment of the described invention, the physical server (2) may not be present, instead a virtual server (2) may be present. In one embodiment, a server (2) located in a private virtual cloud is used.

In another embodiment, a server (2) located in the virtual cloud of the service provider is used.

The DPV (1) parameter monitoring and control system may have more than one server (2). In the latter case, different system servers (2) can be connected to different DPVs (1), or all system servers (2) can be connected to all DPVs (1) in the system.

The connection (4) between the DPV (1) and the server (2) can be realized both by physical connections and by wireless connection. In one embodiment, the DPV (1) and the server (2) are connected to a common internal network of the medical institution by physical connections. In another embodiment, the DPV (1) and the server (2) are connected via a mobile internet connection (eg 2G/3G, 4G or 5G), wireless connection (eg Wi-Fi, Bluetooth) or other wireless transmission technologies. When connected via a mobile Internet connection, the DPVs (1) may be physically distant from each other, e.g. DPV (1) can be located in different buildings of the treatment facility or in different cities. The monitoring and control system of DPV parameters allows to combine even very distant DPVs (1), so DPV parameters can be monitored and managed remotely by competent personnel of the medical institution, and DPV (1) can be serviced by a lower-qualified doctor. This is especially true in the case of a pandemic, with a shortage of doctors.

The DPV parameter monitoring and control device (3) is a computer, tablet, mobile phone or other smart device connected to the server (2) and capable of monitoring and controlling the DPV (1) parameters remotely. Therefore, the user can monitor and control the parameters of many DPVs (1) from the "clean zone" where the DPV parameter monitoring and control device (3) is located. There is no need to go to the patient's ward, which reduces the chance of infection and saves time, which can be critical to the health of patients. The DPV parameter monitoring and control device (3) consists of the DPV parameter monitoring module (3.1) and the DPV parameter monitoring and control module (3.2).

The DPV parameter monitoring module (3.1) enables three-level data monitoring in the DPV parameter monitoring and control device (3). The first level data provides information about the DPV (1) parameter monitoring and control system itself. This can display: the amount of DPV (1) in the system, the location of DPV (1) in the treatment facility, the mode of DPV (1) in use, the charge level of the backup power battery (1.4), date and time, alarms, event history, two-way voice communication module (6) activation icon, menu icon, breathing gas data or other data.

The second level data provides the patient card and the parameters of the specific DPV (1). The patient card registration window is filled every time a new patient is connected to the DPV (1). As an example, the following patient information may be summarized: patient type, gender, height, weight, intubation tube used or not, if used, its diameter, which is required to calculate automatic air resistance compensation, etc.

Level 3 data is for the DPV (1) service. The service user can monitor wear parts status, system settings, event log, etc.

The DPV parameter monitoring module (3.1) remotely provides information about the DPV (1) parameter monitoring and control system itself, the patient card and all DPV (1) parameters that are visible directly to the DPV (1). Since changes in even one parameter of the DPV (1) can significantly affect the performance of artificial ventilation and the safety of the patient, all essential parameters of the DPV (1) must be represented in the device for monitoring and controlling the DPV parameters (3). Remotely displayed DPV (1) parameters can be: oxygen concentration (FiO2), respiratory rate (RR), inspiratory time (Tinsp), expiratory time (Texp), inspiratory pressure (Pinsp), inspiratory-expiratory time ratio (I :E ratio), inspiratory single volume (VTinsp), maximum pressure (Pmax), positive end-expiratory pressure (PEEP), determination of spontaneous breathing sensitivity (Spont trigger), selection of backup mode (Backup mode) and pressure support (Pressure support), total ventilation time, inspiratory minute volume (MVinsp), expiratory single volume (VTexp), expiratory minute volume (MVexp), respiratory gas leakage (Air leak), total respiratory rate (Rtot), respiratory gas flow (Flow), lung tissue continuity (Compliance), peak pressure (Ppeak), pressure plateau indicator (Pplato), oxygen saturation (SpO2), carbon dioxide content at the end of exhalation (ETCO2), respiratory gas flow, pressure and volume curves, pulse oximetry its and CO2 curves. The DPV parameter monitoring module (3.1) also remotely displays ventilation modes and alarms.

The parameters of DPV (1) can be represented by numerical expressions or graphs. The DPV parameters monitoring module (3.1) can display both static values of DPV (1) parameters and changes of DPV (1) parameters over time. The values of the DPV (1) parameters seen by the DPV (1) directly are duplicated in the DPV parameter monitoring and control device (3) in real time.

The DPV parameter monitoring and control module (3.2) allows you to remotely change selected DPV (1) parameters, lung ventilation modes and alarm settings. The ventilation mode and at least one of the following DPV (1) parameters can be changed remotely: oxygen concentration (FiO2), respiratory rate (RR), inspiratory time (Tinsp), expiratory time (Texp), inspiratory pressure (Pinsp), inspiratory- expiratory time ratio (I:E ratio), inspiratory unit volume (VTinsp), peak pressure (Pmax), positive end-expiratory pressure (PEEP), determination of spontaneous breathing sensitivity (Spont trigger), selection of backup mode (Backup mode) and pressure maintenance (Pressure support), total ventilation time, inspiratory minute volume (MVinsp), expiratory single volume (VTexp), expiratory minute volume (MVexp), respiratory gas leakage (Air leak), total respiratory frequency (Rtot), respiratory gas flow (Flow ), lung tissue compliance (Compliance), peak pressure (Ppeak), pressure plateau index (Pplato), oxygen saturation (SpO2) and end-expiratory carbon dioxide content (ETCO2). When more than one DPV(1) parameter is changed, only one DPV(1) parameter is changed at a time, which can change another DPV(1) parameter. After changing one DPV (1) parameter remotely, a certain time interval is given to confirm or cancel the changes. In one embodiment, it is recommended to wait at least 3 min, during which the DPV (1) parameter monitoring and control system indicates that the change is valid, no alarms were generated after the change. The alarm settings of the selected DPV (1) or the alarm settings of any DPV (1) in the system can be changed remotely. When changing the DPV (1) parameters remotely, the control commands of the DPV parameters monitoring and control device (3) must reach the DPV (1) as soon as possible.

In one embodiment, the DPV parameter monitoring and control device (3) sends data and control commands to the server (2) and receives from the server (2) using a web browser. IP+TCP+MQTT data transfer model can be used for data transfer. HTTP, HTTPS, FTP, SMTP or other protocols may be used on a case-by-case basis. In a common case, in medical institutions, in order to save a computer program on a computer, it is necessary to contact the IT department. In this case, all DPVs in the system can be easily and remotely accessed without having to write a computer program (1).

In another embodiment, the DPV parameter monitoring and control device (3) sends to the server (2) and receives data and control commands from the server (2) with the help of a program recorded in the DPV parameter monitoring and control device (3). In this case, DPV (1) parameters have greater monitoring and control functionality.

The DPV (1) parameter monitoring and control system may have more than one DPV parameter monitoring and control device (3). For example, a doctor can monitor DPV (1) remotely from a stationary, main device for monitoring and controlling DPV parameters (3). In a separate case, the DPV parameter monitoring and control device (3) can be a mobile phone or other mobile device.

The server (2) and the DPV parameter monitoring and control device (3) can be connected by physical connections, wireless connection (e.g. wi-fi, Bluetooth connection) or mobile Internet connection (e.g. 2G/3G, 4G or 5G), or other wireless transmission technologies. The connection (5) between the server (2) and the DPV parameter monitoring and control device (3) is duplicated. In an emergency, when connection (5) becomes unstable or disappears altogether, connection (5) is automatically replaced by backup connection (5). For example, when the Wi-Fi wireless connection (5) between the server (2) and the monitoring and control device (3) is lost, the connection (5) is automatically replaced by the internal network connection of the medical facility with physical connections or a mobile Internet connection.

In one embodiment, the maximum delay in transmitting signals between the DPV (1) and the remote DPV parameters monitoring and control device (3) is no more than 3 s.

The connection (5) between the server (2) and the monitoring and control device (3) is encrypted. SSL/TLS/HTTPS protocols and SSL certificates, AES-256 encryption, or other data security and encryption protocols can be used for data transmission. When data is transmitted, it is inaccessible to outsiders, so the monitoring and management system of DPV parameters is safe and reliable.

The connection (5) between the server (2) and the monitoring and control device (3) requires authorization and identification. The user of the system must create his own account, and in order to log in, he must enter a username, password or other means of identification, so outsiders cannot remotely monitor or change the DPV (1) parameters.

The DPV parameter monitoring and control device (3) has a two-way voice communication module (6) that provides voice communication between the DPV (1) and the DPV parameter monitoring and control device (3). The two-way voice communication module (6) uses data transmission channels different from those used by the DPV (1) to transmit data between the DPV (1) and the DPV parameter monitoring and control device (3). In a separate case, the two-way voice communication module (6) is implemented with a mobile Internet connection. The two-way voice communication module (6) consists of an interactive data monitoring and transmission device.

In one embodiment, the two-way voice communication module (6) is integrated into the DPV parameter monitoring and control device (3) and each DPV (1). Both the DPV (1) and the DPV parameter monitoring and control device (3) have a two-way voice communication module (6) icon, which, when pressed, generates a two-way voice communication between the DPV (1) and the DPV parameter monitoring and control device (3). The two-way voice communication module (6) additionally has visual means to inform with which DPV (1) a two-way voice communication is established. The system user located at the DPV (1) and the patient can communicate directly with other doctors located at the DPV parameter monitoring and control device (3), so a real-time remote consultation or consultation can be requested. In this way, a doctor with less competence can be present at the DPV (1) and the patient and work remotely under the supervision of a more experienced doctor. Only one audio call is possible with the DPV parameter monitoring and control device (3) at a time.

In another embodiment, the two-way voice communication module (6) is one or more separate mobile stations not integrated into the DPV (1). In this case, the user carries the two-way voice communication module (6) station with him when visiting patients. The mobile station may have a wireless headset that transmits data between the DPV (1) and the mobile station. The data is transmitted through different channels than the channels for data transmission between the DPV (1) and the DPV parameter monitoring and control device (3). The advantage of the mobile station is that the two-way voice communication signal is free from extraneous interference from breathing gas pumps, ventilators, other device signals or patient noise.

In another embodiment, the two-way voice communication module (6) consists of a headset and a microphone with direct uninterrupted communication with remote audio devices. In this case, the doctor has a headset and a microphone, and these devices maintain continuous communication with the remote audio facilities located in the DPV (1). Therefore, the doctor can maintain voice communication with the DPV parameter monitoring and control device (3) not only when he is close to the DPV (1), but also at a distance from the DPV (1).

In a preferred embodiment of the described invention, the two-way voice communication module (6) is integrated into the DPV (1), and the voice communication between the DPV (1) and the DPV parameter monitoring and control device (3) is transmitted through the server (2). In another embodiment, the two-way voice communication module (6) is also integrated into the DPV (1), and the voice communication between the DPV parameter monitoring and control device (3) and the DPV (1) is direct without using a server (2).

In one embodiment, the server (2) is additionally connected to the alarm system (7) of the medical facility. Integration with the alarm system is realized through open collector outputs or relays. The server (2) with the alarm system (7) can be connected by a wired connection according to the HL7 standard. If the DPV (1) parameters exceed the limit values, the server (2) automatically sends an alarm signal to the alarm system (7), DPV (1) and DPV parameter monitoring and control device (3). The alarm system (7) generates messages of different levels according to the importance of the patient's condition, these messages of different levels are presented by different audio and/or visual signals. When the alarm system (7) has more than one alarm station (7.1), the alarm signal from the server (2) is sent to the nearest alarm station (7.1) to the patient. If the alarm does not disappear, it is sent to further alarm stations (7.1). If the alarm still persists, it is sent to further alarm stations (7.1). The alarm signal is forwarded to other alarm stations (7.1) after a certain period of time, which may affect the patient's health or life, depending on the importance of the DPV (1) parameters, the patient's condition, age or other parameters.

In another embodiment, there is no central alarm system (7) in the DPV (1) parameter monitoring and control system. In this case, if the DPV (1) parameters exceed the limit values, the server (2) automatically sends an alarm signal to the DPV (1). Since the DPV parameter monitoring and control device (3) reproduces the images seen on the DPV (1), the DPV parameter monitoring and control device (3) will also display alarms. The user can change the parameters of DPV (1) both directly at the patient and remotely. After changing the required parameters of the DPV (1), the alarm on both the DPV (1) and the DPV parameter monitoring and control device (3) disappears. Therefore, the user can monitor and change the parameters of the DPV (1) and monitor patient changes both directly on the DPV (1) and remotely via the DPV parameter monitoring and control device (3).

The DPV (1) parameter monitoring and control method has the following steps:

- data transfer between DPV (1) and server (2);

- data transfer between the server (2) and the DPV parameters monitoring and control device (3);

- remote monitoring of ventilation modes, alarms and all DPV (1) parameters from the DPV parameter monitoring and control device (3);

- changing the ventilation modes or at least one DPV (1) parameter remotely from the DPV parameter monitoring and control device (3).

Data transfer between DPV (1) and server (2)

In one embodiment, the DPV (1) parameter monitoring and control system comprises more than one DPV (1), a server (2) and one DPV parameter monitoring and control device (3). When the DPV (1) and the server (2) are connected to the common internal network of the medical institution by physical connections, the data is transferred by physical connections. In another embodiment, the data between the DPV (1) and the server (2) is transmitted via a mobile internet connection (e.g. 2G/3G, 4G or 5G), wireless connection (e.g. wi-fi, Bluetooth) or other wireless transmission technologies . Data transmission is redundant: in the event of failure or interruption of the main data transmission connection, the backup data transmission connection is automatically activated.

Data transfer between the server (2) and the DPV parameter monitoring and control device (3) Data between the server (2) and the DPV parameter monitoring and control device (3) can be transferred either by physical connections or by wireless connection (e.g. wi-fi, Bluetooth), or mobile internet connection (e.g. 2G/3G, 4G, 5G) or other wireless transmission technologies. The data being sent is encrypted, so the system is protected against unauthorized access to the system during data transmission. Additionally, the connection (5) between the DPV parameter monitoring and control device (3) and the server (2) requires authorization and identification. Only a registered user can remotely connect to the system - outsiders, without a login account and passwords, cannot connect to the DPV (1) parameter monitoring and management system. Data transmission is redundant: in the event of failure or interruption of the main data transmission connection, the backup data transmission connection is automatically activated.

Remote monitoring of ventilation modes, alarms and all DPV (1) parameters from the DPV parameter monitoring and control device (3)

The DPV parameter monitoring and control device (3) remotely displays information about the DPV (1) parameter monitoring and control system itself, ventilation modes, patient card, alarms and all DPV (1) parameters that are visible directly on the DPV (1). The DPV parameter monitoring and control device (3) receives data from the server (2) and displays it on the screen. Three levels of data are displayed. The first level data provides data on the monitoring and control system of the DPV (1) parameters itself: the amount of DPV (1) in the system, the location of the DPV (1) in the treatment facility, the DPV (1) mode used, the charge level of the backup power battery (1.4), the date and time, alarms, event history, two-way voice module (6) activation icon, menu icon, breath gas data, etc. The second level data provides information about the patient card, the parameters of the selected DPV (1) and the change of parameters over time. The user can view the desired DPV (1) parameters remotely. Level 3 data is for DPV (1) service: automatic settings can be changed remotely, software can be updated and other changes can be made. The data between the DPV (1) and the DPV parameter monitoring and control device (3) are displayed in real time.

In one embodiment, the DPV (1) parameter monitoring and control system consists of a DPV (1), a server (2) and a DPV parameter monitoring and control device (3). The server (2) forwards data between the DPV (1) and the DPV parameter monitoring and control device (3), so it is possible to remotely monitor the parameters of the DPV (1) and other related information about the DPV (1) in real time.

In another embodiment, the DPV (1) is directly connected to the DPV (1) parameter monitoring and control device (3) without using a server (2). In this case, the DPV (1) has an Internet service (1.5), which provides direct communication between the DPV (1) and the DPV (1) parameter monitoring and control device (3). In this case, the user receives the DPV (1) parameter data directly from the DPV (1).

Changing ventilation modes and at least one DPV (1) parameter remotely from a DPV parameter monitoring or control device (3)

In one embodiment, the DPV (1) parameter monitoring and control system consists of a DPV (1), a server (2) and a DPV parameter monitoring and control device (3). To change the DPV (1) parameter values, the user enters the desired DPV (1) parameter values into the DPV (1) parameter monitoring and control device (3), which sends control commands to the server (2), and the server (2) forwards the control commands to DPV (1). Yes, DPV (1) parameters or ventilation mode can be changed remotely. It is possible to change the parameters of more than one DPV (2). As an example, a system can have 20 DPVs (1), so the parameters of 20 DPVs (1) can be changed remotely.

In another embodiment, when the DPV (1) is directly connected to the DPV (1) parameter monitoring and control device (3), without using a server (2), the DPV (1) has an Internet service (1.5). In this case, the user can change the data of the DPV (1) parameters with direct communication between the DPV (1) and the DPV (1) parameter monitoring and control device (3) without using the server (2). The user sends control commands from the DPV (1) to the DPV parameter monitoring and control device (3).

The DPV parameter monitoring and control device (3) has two-way voice communication (6) with the DPV (1), so the user at the DPV (1) can consult with colleagues at the DPV (1) parameter monitoring and control device (3) ).

In order to illustrate and describe this invention, the above description of the most suitable embodiments is of a general nature - the description provides the measurements of the parts that make up the DPV (1) parameter monitoring and control system, the materials, the method of connection, the amount of the parts themselves and other parameters, and the method of use and purpose of the devices can to differ - the description should be viewed as an illustration and not as a limitation. This is not an exhaustive or limiting description intended to determine a precise form or embodiment. Modifications may be made to embodiments described by those skilled in the art without departing from the scope of the present invention as defined below.

Claims (15)

The system for monitoring and controlling parameters of an artificial lung ventilator (DPV), consisting of a DPV (1), a server (2) and a device for monitoring and controlling DPV parameters (3), differs in that: the system consists of more than one DPV (1); - each DPV (1) has a patient identification device (1.3), - the server (2) has a DPV layout scheme (2.4) and has a connection with a DPV parameter monitoring and control device (3) and more than one DPV (1); - the DPV parameter monitoring and control device (3) is remote, has a DPV parameter monitoring module (3.1) and a DPV parameter monitoring and control module (3.2); - the system has two-way voice communication (6) between the DPV (1) and the DPV parameter monitoring and control device (3); therefore, the user can remotely monitor and change the ventilation mode, DPV parameters or alarms of more than one DPV (1) using the DPV parameter monitoring and control device (3). The DPV parameter monitoring and control system according to claim 1, characterized in that the connection (4, 5) between the DPV (1), the server (2) and the DPV parameter monitoring and control device (3) is optionally one of the following: an internal network with physical connections, wireless connection (wi-fi, Bluetooth), mobile Internet connection (2G/ 3G/ 4G or 5G) or other wireless communication technologies. The DPV parameter monitoring and control system according to points 1-2, is different in that the Internet of Things unit (1.1) is either integrated into the DPV (1) or is available as a separate attachment, connected to the DPV (1) by external connections; when the IoT unit (1.1) is a separate attachment, it is easily replaceable, so one wireless communication technology can be easily replaced by another wireless communication technology in the system. DPV parameter monitoring and control system according to clauses 1-3, except that DPV (1) has an Internet service (1.5), in this case DPV (1) DPV parameter monitoring and control system according to points 1-4, characterized in that the DPV parameter monitoring and control system (1) has a two-way voice communication module (6); the two-way voice communication module (6) is integrated into the DPV parameter monitoring and control device (3) and each DPV (1); or the two-way voice communication module (6) is one or more separate mobile stations not integrated into the DPV (1); or the two-way voice communication module (6) is a headset and microphone with direct uninterrupted communication with remote audio devices located in the DPV (1). The DPV parameter monitoring and control system according to claim 5, characterized in that the two-way voice communication module (6) uses data transmission channels different from those used by the DPV (1) to transmit data between the DPV (1) and the DPV parameter monitoring and control device (3). The DPV parameter monitoring and control system according to points 1-6 differs in that the DPV parameter monitoring and control device (3) sends data and control commands to the server (2) and receives from the server (2) using a web browser or to the DPV parameter monitoring and the control device (3) with the help of a recorded computer program. The DPV parameter monitoring and control system according to claims 1 to 7, characterized in that the connection (5) between the server (2) and the DPV parameter monitoring and control device (3) is coded. The DPV parameter monitoring and control system according to points 1 to 8 differs in that the connection (5) between the server (2) and the DPV parameter monitoring and control device (3) requires authorization and identification. The DPV parameter monitoring and control system according to claims 1 to 9, characterized in that the connection (5) between the server (2) and the DPV parameter monitoring and control device (3) is duplicated. The DPV parameter monitoring and control system according to points 1-10, but differs in that the DPV parameter monitoring module (3.1) remotely and in real time provides information about the DPV (1) parameter monitoring and control system itself, the patient card, the used ventilation mode and all DPV (1) parameters that are visible directly in DPV (1). DPV parameter monitoring and control system according to point 11, which differs in that the DPV parameter monitoring module (3.1) DPV parameter monitoring and control device (3) provides three levels of data: the first level data provides information about the DPV parameter monitoring and control system itself, the second level data provides information about the patient card, parameters and ventilation mode of a specific DPV (1), while level three data is for DPV (1) service. DPV parameter monitoring and control system according to points 1-12, but differs in that the DPV parameter monitoring and control module (3.2) can remotely change ventilation modes and at least one of the following DPV (1) parameters: oxygen concentration (Fi02), respiratory rate (RR), inspiratory time (Tinsp), expiratory time (Texp), inspiratory pressure (Pinsp), inspiratory-expiratory time ratio (1:E ratio), inspiratory unit volume (VTinsp), peak pressure (Pmax), positive expiratory end pressure (PEEP), determination of spontaneous breathing sensitivity (Spont trigger), selection of backup mode (Backup mode) and pressure support (Pressure support), total ventilation time, inspiratory minute volume (MVinsp), expiratory single volume (VTexp), expiratory minute volume (MVexp), respiratory gas leakage (Air leak), total respiratory rate (Rtot), respiratory gas flow (Flow), lung tissue continuity (Compliance), peak pressure (Ppcak), pressure p lat index (Pplato), oxygen saturation (Sp02) or end-expiratory carbon dioxide content (ETC02). . DPV parameter monitoring and control system according to points 1-13, which differs in that an alarm system (7) adapted for remote monitoring of DPV parameters is integrated into the DPV parameter monitoring and control system, and alarms are generated when DPV (1) parameters exceed limit values signals; when the medical facility does not have an alarm system (7), the server (2) sends the alarms directly to the DPV (1). A method for remotely monitoring and controlling DPV (1) parameters, ventilation modes, and alarms, comprising the following steps: - data transfer between DPV (1) and server (2); - data transfer between the server (2) and the DPV parameters monitoring and control device (3); - remote monitoring of ventilation modes, alarms and all DPV (1) parameters from the DPV parameter monitoring and control device (3); - changing the ventilation modes or at least one DPV (1) parameter remotely from the DPV parameter monitoring and control device (3).