WO2017099571A1

WO2017099571A1 - Wireless modular physiological monitoring system with user interface

Info

Publication number: WO2017099571A1
Application number: PCT/MX2015/000168
Authority: WO
Inventors: José Antonio PACHECO SANCHEZ
Original assignee: Pacheco Sanchez José Antonio
Priority date: 2015-12-11
Filing date: 2015-12-11
Publication date: 2017-06-15

Abstract

The invention relates to a system for remote monitoring of physiological parameters by means of cloud processing. The system comprises a user interface in the doctor-patient cloud, to which telemetric information concerning the condition of the patient is downloaded by means of a hub in wireless communication with third-party medical devices.

Description

WIRELESS MODULAR PHYSOLOGICAL MONITORING SYSTEM WITH INTERFACE

OF USER

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a method for monitoring the health of people with different types of disease using electronic sensors interconnected to a wireless user interface via a hub.

BACKGROUND

The invention described herein refers to the measurement of physiological signals and more particularly to physiological signal measuring devices that can measure said physiological signals more conveniently by distributing modules according to the functions.

As the interest in health increases, healthcare is ubiquitous, medical technology and IT technology as a whole are attracting a lot of attention.

An important aspect for providing satisfactory care to patients is monitoring different biological indicators used to diagnose medical conditions. For example, careful monitoring of blood pressure, heart rate, and ECG can help determine the patient's current health and future chances of recovery. Traditionally, this monitoring has been achieved using the placement of sensors to a patient and then the connection of these sensors to control the units that show the sensor readings.

A cable has been the simplest and most reliable means of connecting these sensors with a patient monitor nearby. However, these cables become easily entangled, limit the patient's distance from the monitor and can be damaged over time.

More recently, wireless communication methods have been used between the sensor and the patient monitor, overcoming many of the disadvantages presented by traditional cable systems. Some typical examples of these wireless systems can be seen in US5748103, US5862803, US6441747, US6544174 and US6850788; whose contents are incorporated here by reference. In general, medical wireless communications systems have included two popular types of system architectures: simple independent systems that transmit directly from sensor to a monitor, such as US5862803, and the most complex telemetry systems in the entire hospital that have networks of sensors throughout a hospital, such as US6544174. Simple wireless sensor systems often include sensors that transmit medical data from specialized monitors near the patient. However, these systems are designed for use with only a few sensors and therefore tend to use bandwidth inefficiently. In addition, the use of many of these units within a hospital can lead to interference between transmissions from nearby systems.

The most complex medical telemetry systems often include wireless receivers throughout the hospital that connect to a central server, allowing sensors to transmit data at almost any location within the hospital. In addition, these wireless transmission systems are often designed to have more efficient use of the designated bandwidth so they are less likely to cause interference with nearby units. However, the size and complexity of these systems dramatically increases the expense for a hospital. In addition, such complexity tends to reduce the reliability of data transmissions, as well as the overall System Skill.

What is needed is a wireless communication medical sensor system that combines the Skill of the simplest wireless communication sensor systems with the efficiency and reduced interference found in the most complex telemetry systems.

BRIEF DESCRIPTION OF FIGURES

Figure 1 Schematic of the layered architecture of the system's web platform.

Figure 2 Illustrates the technology components involved and their functional relationships.

Figure 3 shows the general structure of the combination of software platform and hardware devices forming the complete system.

DETAILED DESCRIPTION OF THE INVENTION

Conventional physiological measurement systems are limited by the cable connection between the patient's sensor and monitor. A patient should be placed in the immediate vicinity of the monitor. In addition, patient relocation requires either the disconnection of surveillance equipment and a corresponding loss of measurements or an uncomfortable simultaneous movement of patient, equipment and cables. Several devices have been proposed or applied to provide wireless communication links between sensors and monitors, freeing patients from the patient cable tie strap. These devices, however, are not able to work with the large installed base of existing monitors and sensors, caregivers and medical institutions require expensive wireless updates. It is desirable, therefore, to provide a communications adapter that is compatible with existing sensors and monitors and that implements a replacement wireless link for the cable.

General structure:

The proposed system consists of a platform as a service (SaaS), based on database technologies and cloud servers.

It has a 3-layer structure as shown in Figure 1, which allows you to decouple the user interface with the rest of the operating logic, facilitating the development of simple clients for mobile devices, desktop applications, web applications and likewise , allows communication with third-party medical devices.

The system uses SQL Azure as a database handler. It also uses node.js as the basis for the development of the Back ~ end and the corresponding REST services; for have the ability to develop servers in JavaScript with high performance and low resource usage, in addition to being compatible with a wide variety of server operating systems. The web user interface is in HTML5, CSS3, Bootstrap 3, Angular.js and JavaScript, as illustrated in Figure 2,

Functioning:

The system works as an information manager not only for the doctor, but also for the patient who uses it. Information is entered into the system, it is processed, interpreted, stored and displayed for display on computers and mobile devices as illustrated in Figure 3. The information entered can be in the form of electronic text, image, sound documents , video, 3D representations of human body models with relevant information; among other types of files containing data on the patient's health status.

In addition, digital signals that are the product of monitoring vital signs and other quantifiable variables of the patient's body are stored and interpreted in the system. In this process of collecting information directly from the patient's body, specialized hardware elements come into action. Consisting, the latter, in a set of sensors capable of measuring the body's variables; same that are of great importance when monitoring the state and progress of the health of the patient user of the device.

The variables that can be measured using said hardware, and that can be introduced into the system are: temperature, weight, blood pressure and oxygenation, heart rate, respiratory rate, glucose levels, triglycerides and co-cholesterol in the blood and forced exhalation respiratory volume (FEV6 and FEV1 / FEV6, useful for people with any respiratory disease). But in addition, the system has the modularity and flexibility necessary to establish communication with more specialized devices, such as:

* Ultrasound device, for pregnant women who wish to monitor the health of the baby in their womb.

* Sensors for ECG (Electrocardiogram), for people with any heart condition.

* Sensors for EEG (Encephalogram), to monitor people with mental illnesses or disorders.

The system, upon detecting an imminent or possible emergency in the state of health of the monitored person, notifies via the web or through telephone networks, both the treating physician of the patient and relatives linked to the system, who can act quickly to avoid damage to the health of it. All through a system of alerts, based on real data obtained periodically by the continuous use of the system by the patient. The alerts will be displayed on computers, mobile devices such as tablets and smartphones, which are linked to the system, belonging to both the doctor and the patient and their families. The set of the proposed system, formed by the cloud platform and the specialized hardware devices linked to the system are combined.

Claims

1. A modular physiological monitoring system consists of a software platform as a SaaS server, based on database technologies and cloud servers, characterized by:

to. A 3-layer structure that allows decoupling the user interface with the rest of the operating logic, facilitating the development of simple teeth for mobile devices, desktop applications, web applications and likewise, allows communication with third-party medical devices,

b. Measurable variables that can be introduced into the system are: temperature, weight, blood pressure and oxygenation, heart rate, respiratory rate, glucose levels, triglycerides and cholesterol in the blood, and forced expiratory volume on exhalation (FEV6 and FEV1 / FEV6) .

C. It has the medularity and flexibility necessary to establish communication with more specialized devices, such as: Ultrasound device, electrocardiogram sensors, encephalogram sensors.

2. The system of claim 1 using SQL Azure as a database handler.

3. The system of claim 1 using node.js as the basis for the development of the Back-end and the corresponding REST services; to have the capacity of development of servers in JavaScript of high performance and low use of resources.

4. The system of claim 1 which is compatible with a wide variety of server operating systems.

5. The system of claim 1 characterized in that the user interface on the Web is in HTMLS, CSS3, Booístrap 3, Angular.js and JavaScript.