DE102019127041A1 - Clinical monitoring device - Google Patents

Abstract

The invention relates to a device (1) for clinical monitoring of patients, with at least one sensor (2) for detecting physiological parameters, at least one electronic device (3) for controlling the sensor (2) and for reading, recording and / or transmitting the data recorded by the sensor (2), the device (1) comprising a module carrier (4, 5), the sensor (2) and the electronic device (3) being designed as module elements which can be arranged modularly on the module carrier (4) are.

Description

The invention relates to a device for clinical monitoring of patients, with at least one sensor for recording physiological parameters, at least one electronic device for controlling the sensor and for reading, recording and / or transmitting the data recorded by the sensor.

For clinical monitoring of patients and for triggering medical imaging, such as computed tomography or magnetic resonance tomography, it is necessary to record various physiological parameters. These include breathing, heartbeat or oxygen saturation. The disadvantage of the monitoring devices known for this purpose is that errors often occur when the sensors are applied to record the parameters. In addition, different devices are necessary depending on the required application, since the equipment is designed differently depending on the field of application of the device. A simple possibility of adaptation is not provided in known devices, so that a specially adapted device for clinical monitoring is designed and offered for each area of application.

It is therefore the object of the invention to provide an improved device for the clinical monitoring of patients, which offers a simple and quick adaptation option to the respective field of application and thus enables flexible changes to the equipment and adaptation to the field of application.

This object is achieved by a device with the features of claim 1.

Because the device comprises a module carrier, the sensor and the electronic device being designed as module elements which can be configured in a modular manner on the module carrier, the device can be adapted quickly and easily to the respective field of application. This means that the equipment can be flexibly changed in order to adapt the device to the intended area of application. For this purpose, the required module elements can simply be arranged in a modular manner on the module carrier. With different module elements, the device can be easily adapted for clinical monitoring of patients by selecting the suitable module elements and simply arranging them on the module carrier. With modular elements that include sensors, the desired physiological parameters can be recorded on the patient. To control the sensors, to read out, record and / or transmit the parameter data acquired by the sensors, electronic devices can also be arranged as module elements on the module carrier, depending on the application. The modular design of the device makes it possible to integrate the different sensors in a modular way, depending on the required application. This also enables fast, customer-specific production and manufacture of the device. Standardized plugs are preferably used to connect the module elements to the module carrier. In addition, the device is preferably compatible with magnetic resonance tomography. In addition to signal amplification and digitization, the electronic device also offers signal processing.

Advantageous refinements and developments of the invention emerge from the dependent claims. It should be pointed out that the features listed individually in the claims can also be combined with one another in any desired and technologically sensible manner and thus show further embodiments of the invention.

According to an advantageous embodiment of the invention it is provided that the module carrier is designed as a chest strap. Depending on the equipment and area of application, the belt can be designed as a single-use product or for multiple use, in which case only the electrodes of the sensors need to be replaced for each patient. A chest strap is also advantageous for the clinical monitoring of premature babies or newborns, since the attachment of conventional sensors can be problematic in this case, as this is often associated with the formation of hematomas due to the sticking of electrons. The proposed chest strap, in conjunction with an adapted sensor system, offers a significant improvement over conventional devices. In order to avoid errors when applying the sensors and to reduce the effort required for this, the sensors are preferably integrated in the chest strap. In a preferred embodiment, the module carrier designed as a belt is to be attached to the patient in a manner similar to a headband, a Klippon band or a trouser leg clip. The strap, which can be clamped to the patient to be monitored, is easy to put on and prevents slipping and hematoma formation when the module carrier is removed.

Particularly preferred is an embodiment which provides that the module carrier is designed as a patch that can be attached to the patient in an adhesive and / or adhesive manner. The advantage of a module carrier designed as a patch is that the integrated design enables the clinical workflow to be optimized. Instead of sticking on all sensors and electrodes individually, as was previously the case, the patch can be attached in a single work step and the device can be applied with it. This is a incorrect attachment of the electrodes is practically impossible. In order to avoid errors when applying the sensors and to reduce the effort required for this, the sensors are preferably integrated in the patch. The patch can be designed as a film with electrodes for the measuring points. In this case, only one connector would be required, via which the electronic device is preferably connected. With the integration of the sensors in the film of a patch, the position of the module elements on or in the module carrier can already be predetermined during development and manufacture, which minimizes the risk of incorrect positioning of the sensors. The module carrier preferably adheres to the patient by means of adhesion or static attraction, so that the attachable patch adheres to the skin of the patient to be monitored. The module carrier can also adhere adhesively to the patient via a cream or a gel layer or a liquid film. Secure fixation can be achieved via the adhesive fastening of the module carrier and, at the same time, hematoma formation can be effectively prevented when the module carrier is removed. The module carrier designed as a patch can have different sensor assignments depending on the application. For example, the module carrier for monitoring babies can be equipped with sensors for a 3-channel EKG, pulse oximetry and thermometry or, for example, for monitoring adults with a 12-channel EKG and for use in imaging with trigger sensors for movement correction be. The structure of the module carrier remains the same in both applications, with only the size and sensor assignment of the module carrier being adapted.

A particularly advantageous embodiment of the invention relates to the fact that the module carrier comprises a rail system on which the module elements can be displaceably arranged. Using the rail system, the sensors and electrodes can be easily positioned on the module carrier for each individual patient. As a result, the arrangement of the module elements on the module carrier can be optimized specifically for the patient to be monitored. The rail system advantageously offers quick fixation for the module elements. The modular elements can be easily arranged in various additional positions using the rail system. The rail system is preferably formed by flexible plastic strips, the module elements being attached to them in a displaceable manner.

A particularly advantageous embodiment of the invention provides that the rail system comprises at least one displaceable module element connection for connecting module elements. Via the displaceable module element connection, the module elements can be very easily positioned on the module carrier individually for each patient, so that the module elements connected to the module carrier can be arranged in a way that is tailored to the patient. The device preferably has a device for receiving the electrodes.

An advantageous embodiment of the invention provides that a module element is designed as an interface for transmitting the captured and / or recorded sensor data from the electronic device to an external data processing unit. With the transmission of the sensor data, an external data processing unit can easily be integrated for evaluating and displaying the recorded physiological parameters. The interface for integrating the external data processing unit is also advantageously designed as a modular element and can be supplemented in a modular manner depending on the area of application and the data processing unit to be integrated.

An embodiment that provides that the interface enables wireless and / or wired transmission of the sensor data is particularly advantageous. In addition to a wired transmission of the sensor data, the interface should also enable a wireless transmission, which simplifies the use of the device.

An advantageous embodiment provides that at least one module element is a sensor for pulse oximetry, thermometry, impedance pneumography, respiration measurement, gyrometry, electrocardiography and / or impedance plethysmography. With module elements that have appropriate sensors for recording the physiological parameters required for this, the device can be flexibly equipped for the application of the above-mentioned monitoring and examination methods.

According to a preferred embodiment of the invention it is provided that at least one sensor is designed as a capacitive electrode. Such a sensor system offers a significant improvement, especially in connection with the chest strap as a module carrier.

• 1 erfindungsgemäße Vorrichtung als Brustgurt und
• 2 erfindungsgemäße Vorrichtung als Patch.

Further features, details and advantages of the invention emerge on the basis of the following description and on the basis of the drawings which show exemplary embodiments of the invention. Objects or elements that correspond to one another are provided with the same reference symbols in all figures. Show it:

• 1 inventive device as a chest strap and
• 2 Device according to the invention as a patch.

In the 1 with the reference number 1 denotes a device according to the invention is shown schematically. The device 1 is with one as a chest strap 4th trained module carrier provided, which is simply placed around the chest of the patient to be monitored. The sensors 2 the one on the module carrier 4th arranged modular elements 2 then record the physiological parameters. That also on the module carrier 4th arranged electronic device 3 controls the sensors 2 and is used to read, record and transmit the data from the sensors 2 collected data. Via an indicated interface 6th the acquired and recorded sensor data 2 from the electronic device 3 to an external data processing unit 7th transmitted wirelessly.

With 2 is a device 1 shown schematically as a patch. This device 1 has a module carrier designed as a patch 5 , which is simply adhesively attached or glued to the chest of the patient to be monitored. The module carrier 5 preferably has the double-L-shaped contour shown, since this is the contour of the module carrier 5 the sensors 2 can be optimally positioned on the patch to monitor the patient. Similar to a defibrillator patch is a pattern for arranging the sensors 2 thereby on the module carrier 5 specified, which simplifies the positioning. The sensors 2 the one on the module carrier 5 arranged modular elements 2 then record the physiological parameters. The electronic device 3 , which is also a module element on the module carrier 5 is arranged controls the sensors 2 and is used to read, record and transmit the data from the sensors 2 collected data. Via an indicated interface 6th the captured and recorded sensor data are from the electronic device 3 to an external data processing unit 7th transmitted wirelessly.

In particular, when monitoring premature babies, the use of a module carrier designed as a patch or belt offers great advantages, since the numerous individual cables for connecting individual sensors pose a great risk to the newborns. In order to wrap the premature infants, these individually cabled sensors also have to be regularly separated from glued-on electrodes and clipped on again, which currently leads to the formation of hematomas and a high expenditure of time for the nursing staff. To this end, the described invention offers considerable improvements. All electrodes connected to sensors are therefore preferably integrated in a patch or belt.

List of reference symbols

1

contraption

2

sensor

3

Electronic device

4th

Module carrier (chest strap)

5

Module carrier (patch, plaster)

6th

interface

7th

Data processing unit

Claims (9)

Device (1) for clinical monitoring of patients, with - at least one sensor (2) for recording physiological parameters, - at least one electronic device (3) for controlling the sensor (2) and for reading, recording and / or transmitting the data from the sensor (2) recorded data, characterized in that the device (1) comprises a module carrier (4, 5), the sensor (2) and the electronic device (3) being designed as module elements which can be arranged in a modular manner on the module carrier (4) are trained. Device (1) according to Claim 1 , characterized in that the module carrier is designed as a chest strap (4). Device (1) according to Claim 1 , characterized in that the module carrier is designed as a patch (5) that can be attached to the patient. Device (1) according to one of the preceding claims, characterized in that the module carrier (4, 5) comprises a rail system on which the module elements can be displaceably arranged. Device (1) according to Claim 4 , characterized in that the rail system comprises at least one displaceable module element connection for connecting module elements. Device (1) according to one of the preceding claims, characterized in that a module element is designed as an interface (6) for transmitting the captured and / or recorded sensor data from the electronic device (3) to an external data processing unit (7). Device (1) according to Claim 6 , characterized in that the interface (6) enables wireless and / or wired transmission of the sensor data. Device (1) according to one of the preceding claims, characterized in that at least one module element is a sensor (2) for pulse oximetry, thermometry, impedance pneumography, respiration measurement, gyrometry, electrocardiography and / or impedance plethysmography. Device (1) according to one of the preceding claims, characterized in that at least one sensor (2) is designed as a capacitive electrode.

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