FR3076446A1 - METHOD FOR DETERMINING A QUANTITY OF GAS DELIVERED TO A PATIENT - Google Patents

Abstract

The invention relates to a method (10) for determining a quantity of gas delivered to a patient comprising at least one image acquisition step (110) of an indicator of a flow out of a distribution element. of gas via a communicating mobile device (6), a step of transmitting these images to an image processing module (200), said image processing module (200) comprising at least means image analysis system (210) and first computing means (220) configured to determine in at least one processing step (120, 130, 140) a gas outflow from the transmitted images. The method further comprises a calculation step (150), by second calculation means (300), of a quantity of gas delivered as a function of the outgoing flow rate and a duration of gas administration.

Description

The invention relates to the field of gas distribution and to gas distribution assemblies, in particular medical gases. It relates more particularly to the monitoring of quantities of medical gases administered to patients.

Medical gases are commonly packaged in gas storage containers equipped with a distribution element including in particular a member for regulating an outgoing gas flow.

When a gas administration is decided for a patient, for example within the framework of an oxygen therapy, an authorized member of the medical staff must first start the administration of the gas before noting, manually, the outgoing flow of this gas as well as the start time of the gas administration. In order to stop the treatment, the practitioner must first of all close the administration of the gas before noting, manually, the stop of the administration of gas, as well as the time of the stop of the administration or the total duration of this administration. Finally, he must report all of this data, taken for each patient, in a centralized database. This data gathering step can be carried out at once after stopping the treatment or in two stages, firstly when the treatment is started and then when the treatment is stopped.

Similarly, at each change of dosage, the practitioner modifies the outgoing flow rate thanks to the outgoing flow regulation member associated with the dispensing element before noting, manually, this modification and finally postponing everything, at the end of the tour. , in a central database.

Such monitoring has many drawbacks, such as, among other things, a lack of precision as to the quantities of gas actually administered to patients, due to the random accuracy of the information at the start and end of the administration. In addition, repeated human intervention can cause multiple errors, both when recording the start and end time of administration and the outgoing flow, or when reporting this information in the database. central data.

We understand that this lack of precision and this risk of errors is all the more damaging since these gas administrations are curative for patients. In addition, these gas administrations can enroll in a study program, for example a study program on the effects and effectiveness of oxygen therapy. The aim of such a study program is to gather data on the administration of oxygen to a plurality of patients for different durations and with different dosages, in order to draw general lessons from it, so that the precision and the rigor data taken into account is very important.

The present invention falls within this context and provides a method for determining a quantity of gas delivered to a patient which is simple to implement, efficient and centralized.

An object of the present invention thus relates to a method for determining a quantity of gas delivered to a patient comprising at least one step of acquiring images of an indicator of a flow rate exiting from a gas distribution element via a communicating mobile device, a step of transmitting these images to an image processing module, this image processing module comprising at least image analysis means and first means of calculation configured to determine an outgoing gas flow rate from the transmitted images, said method also comprising a step of calculation by second means of calculating an amount of gas delivered as a function of the outgoing flow rate and a duration of administration of the gas.

"Acquisition of images" is understood to mean a shot of the flow rate indicator leaving the gas distribution element, in the form of a plurality of photos and / or one or more video sequences. The image analysis means of the image processing module are then configured to analyze these images in order to detect flow information leaving the gas distribution element, this flow information finally being compared to a base. of data by the first calculation means in order to determine the output rate of this distribution element at a given time.

The method further comprises a step of launching the method by a user of this method via a man / machine interface. According to a characteristic of the invention, the man / machine interface by means of which the user initiates the process is embedded on the communicating mobile device used for the acquisition of images. In the foregoing, and as will be detailed below, the step of launching the method includes a step during which the user performs an action testifying to the intention to start the determination process, for example the opening of an application on the communicating mobile device, or the validation via the man / machine interface of the correct interpretation of the outgoing bit rate by the image processing module.

It will be understood that the second calculation means are then able to calculate the duration of administration of the gas by comparing the initial administration instant, that is to say the time at which the user of the process launched this method, at the final instant, that is to say the time at which this user wishes to know the quantity of gas administered, that this final instant corresponds to the end of the administration, to determine the total quantity of gas delivered to the patient, or at an intermediate time of administration, in order to have a real-time image of the quantity delivered.

Thus, the method according to the invention makes it possible to know the outgoing flow of gas administered to the patient as well as the exact duration of this gas administration, and therefore to accurately determine the quantity of gas delivered to a patient, whether for final post-administration data or for real-time monitoring of the quantity of gas delivered.

It is understood that this process applies as well to the start of the administration of gas to the patient as in the event of modification of the outgoing flow. Likewise, when the practitioner stops the gas distribution, he adjusts the gas distribution element at a zero outflow and records the information according to the method of the invention. In other words, the authorized medical personnel can carry out one or more additional steps of the process which consist of an intermediate step of modifying the administration and a step of closing the process.

According to a characteristic of the present invention, the step of calculating by the second means of calculating the quantity of gas delivered can be preceded by a step of displaying on the man / machine interface the determined outgoing gas flow rate and by a validation step by the user of the process of this determined outgoing flow.

For example, as mentioned above, the man / machine interface is integrated into the communicating mobile device.

The second calculation means as well as the image processing module can be integrated into a server configured to send and receive data to and from the communicating mobile device. Alternatively, these second calculation means and the image processing module can be integrated into the communicating mobile device, insofar as such a communicating mobile device has the functionalities and the power necessary to enable their implementation.

It is understood that one of these two options can be preferred depending on the purposes of the process.

For example, if the user of the method wishes to carry out an individualized monitoring of each patient, the second calculation means and the image processing module are advantageously integrated into the mobile device communicating that the user of the method can permanently have with him , allowing in particular real-time monitoring of gas administration for each patient.

On the other hand, within the framework of a global study, for example to evaluate the effectiveness of the administration of certain types of gas or else to evaluate the effects of different dosages, the second means of calculation and the treatment module of images can be integrated into the server, allowing centralization of data concerning all the patients in a healthcare establishment and thus a global processing of the data thus acquired.

Advantageously, this centralization of information can also make it possible, within the framework of a health establishment equipped with a gas supply network common to each distribution element, to detect more quickly a problem of gas leakage, by comparing the quantity delivered to all patients with the quantity of gas actually removed from stocks.

According to the invention, the gas distribution element can comprise a distinctive pattern, for example positioned near or around the flow indicator leaving the gas distribution element, image analysis elements of this distinctive motif then being integrated into the image processing module. These distinctive pattern image analysis elements are configured to define a relative position of the communicating mobile device with respect to the rate indicator exiting the distribution element during image acquisition and to transmit data corresponding to this position relating to the image analysis means.

It is understood that this distinctive pattern makes it possible to determine an angle at which the images have been acquired, which facilitates the analysis of these images by the image processing module. This distinctive motif therefore makes the processing of these images more reliable and, in fact, the determination of the outgoing gas flow.

For example, the distinctive pattern can be a two-dimensional code. Among the known two-dimensional codes, one could for example choose a “QR” code corresponding to the English acronym “Quick Response”.

According to one aspect of the present invention, the image processing module performs a projective transformation of the images received. "Projective transformation" means an image processing method during which the image processing module transposes the images it receives from the communicating mobile device into a standardized reference in order to be able to analyze them.

Thus, the analysis of the distinctive pattern makes it possible, for example, to determine an outline in which or around which the information to be analyzed is located. The points of this distinctive pattern are transposed, by means of analysis, from a real plane to an image plane, just like the other points present on the image concerned. The analysis means are then configured to analyze the points contained in this image plane and to deduce therefrom a flow information item leaving the gas distribution element.

According to an example of the present invention, the gas distribution element is integrated into a gas distribution wall outlet.

According to another example of the present invention, the gas distribution element is positioned on a gas cylinder.

According to the invention, the gas distributed can for example comprise oxygen. The invention also relates to a communicating mobile device program comprising portions of program code and capable of being launched or downloaded on the communicating mobile device, for the execution of the method according to the present invention, the program being configured for pilot the implementation of a device allowing the acquisition of images, the transmission of the acquired images to an image processing module, the reception of information relating to an outgoing bit rate determined by this processing module images, and the display of this determined outgoing flow in order to allow validation of the latter by a user of the communicating mobile device and thus allow the launch of calculations making it possible to determine a quantity of gas delivered.

We understand that it is necessary, immediately after launching the application or at least before image acquisition is carried out, that the user of the process selects, for example by clicking on a dedicated icon of the program. of a communicating mobile device, the step at which the patient is, that is to say that the user must define whether it is the start of a treatment by gas administration, a modification the dosage of an administration already in progress or the discontinuation of such treatment. The invention also relates to a system for determining a quantity of gas delivered to a patient comprising a container containing gas and equipped with at least one element for distributing this gas and with an organ for regulating an outgoing flow. of this gas distribution element, the determination system comprising: - means for acquiring images of the distribution element, - an image processing module comprising at least means for analyzing images and first calculation means, this image processing module being configured to determine an outgoing flow of gas from the distribution element, - a man / machine interface capable of displaying the determined outgoing flow, - second calculation means d '' a quantity of gas delivered as a function of the outgoing flow and a duration of gas administration. Other details, characteristics and advantages will emerge more clearly on reading the detailed description given below by way of indication in relation to the various embodiments illustrated in the following figures: - Figure 1 schematically represents an environment in which can be implemented the method according to the invention; - Figure 2 is a schematic representation of a mobile device communicating after the completion of an image acquisition step according to the method of the present invention; - Figure 3 is a schematic representation of the steps of the method according to the present invention.

FIG. 1 schematically illustrates a room 1 of a medical establishment comprising at least part of a system for determining a quantity of gas administered according to the present invention. A bed 2 and a distribution element 3 for medical gases are thus represented there, in this case produced by a wall outlet connected to a gas distribution network of the medical establishment.

Alternatively, this wall outlet can be replaced by a cylinder, if necessary connected to the gas distribution network of the medical establishment.

As illustrated in FIGS. 1 and 2, the wall outlet comprises a supply nozzle 8 to which is connected a tube 12 by which the gas is conveyed from this supply nozzle to the patient. The dispensing element 3 also includes a distinctive pattern 80 which advantageously makes the process according to the invention more reliable and which will be described more fully below.

When a practitioner 4 decides to administer a medical gas to a patient, for example dioxygen, he selects an outflow of this gas directly on the distribution element 3, for example via a regulating member 5 of this outgoing flow, notably visible in FIG. 2. In order to facilitate this adjustment, the regulating member 5 of the outgoing flow is standardized and makes it possible to display, on an indicator 7 for the outgoing gas flow, a number, a letter or symbol, corresponding to a predetermined outgoing flow.

Once this adjustment has been made, the practitioner 4 can, using a communicating mobile device 6, carry out an acquisition of images of the flow indicator 7 leaving the dispensing element 3 of medical gases. This acquisition of images may for example correspond to a series of photos or to a video of the distribution element 3. In the embodiment described here, the practitioner 4 must launch an application, or more precisely a program comprising portions of program code, on his mobile device communicating 6 and he can, within the framework of the execution of a process via this program, carry out the acquisition of images via this application, if necessary after having specified, by example by clicking on a dedicated icon of the application, it is a launch of oxygen therapy.

FIG. 1 also illustrates an identification element 81 of the patient, for example produced by a bar code positioned on the patient's bed 2, it being understood that this identification element could take another form without departing from the context of the invention, and for example be positioned on a patient bracelet or close to the dispensing element 3.

In order to identify the practitioner 4 user of the determination system according to the invention, and thus ensure that the person who will carry out and validate the acquisition of images with a view to determining the outgoing rate is indeed a person authorized to to do so, the practitioner 4 can wear an identification badge or else this identification can be carried out directly as a function of the communicating mobile device 6 used, each practitioner 4 then having a mobile communicating device 6 which is specific to him.

The images thus acquired are then transmitted to an image processing module 200 which comprises at least image analysis means and first calculation means. According to an example illustrated in FIG. 2, this image processing module 200 can for example be integrated into a server 11 configured to receive and send information from and to the communicating mobile device 6. As schematically illustrated in the figure 2, these images can for example be transmitted via a Bluetooth connection, or via a Wi-Fi connection. It is understood that any other known means of wireless data transmission can also be implemented, without departing from the context of the invention. Alternatively, this image processing module 200 can be integrated into the communicating mobile device 6, insofar as the latter is powerful enough to integrate such a function.

First, the image analysis means are configured to determine information concerning the outgoing speed, in this case to determine which figure, letter or symbol - corresponding to this outgoing speed - is indicated on the indicator 7 flow leaving the distribution element 3.

In order to make this analysis more reliable, the distribution element 3 may include a distinctive pattern 80, for example shown in FIGS. 1 and 2. This distinctive pattern 80 is advantageously a two-dimensional code, such as for example a “QR” code of the English acronym "Quick Response", and it is positioned near the indicator 7 for outflow. This distinctive pattern 80 in fact makes it possible to overcome the relative position of the mobile device communicating 6 with respect to this indicator 7 of flow leaving the distribution element 3 during the acquisition of the images. The image processing module can thus include image analysis elements of this distinctive pattern 80.

As described above, the moment when the determination process is launched, and therefore the time from which the calculations for determining the quantity of gas delivered start, can correspond to the launch of the application on the communicating mobile device, or correspond to a positive command from the practitioner validating the launching of the process for example during a question asked to the practitioner on the man / machine interface of the program, or application, of the communicating mobile device.

The image processing module 200, and more particularly the image analysis means of this image processing module 200, is for example configured to process the images that it receives by projective transformation. By "projective transformation" is meant the fact that these analysis means are configured to position points of the image being processed in a real coordinate system and to transform them into an image coordinate system in order to analyze them.

The distinctive pattern 80 advantageously allows these analysis means to have a reference point on the acquired images. Thus, the analysis of the distinctive pattern 80 makes it possible for example to determine a contour in which or around which the information to be analyzed is located. The points of this distinctive pattern 80 are transposed, by appropriate image analysis elements, from the real plane to the image plane, just like the other points present on the image concerned. The analysis means are then configured to analyze the points contained in this image plane and to deduce therefrom flow information leaving the gas distribution element 3. In other words, this distinctive pattern 80 allows the analysis means to project the figure, the letter or the symbol corresponding to the outgoing flow rate from the distribution element 3 into a standard coordinate system, and thus to overcome, for example, a a reflection which would make the data resulting from a value analysis false from certain angles of view.

Thus, the analysis of the distinctive pattern 80 advantageously makes it possible to correctly position each image in order to ensure reliable reading by the image analysis means of the image processing module.

The image processing module further comprises first calculation means capable of comparing the number, letter or symbol detected by the image analysis means with a database in order to determine an outgoing gas flow rate. the distribution element 3. This determined outgoing flow can then be displayed on the man / machine interface formed by the application launched on the communicating mobile device, in order to ensure the correct interpretation of the outgoing flow by the module image processing. The practitioner 4 is then led to take cognizance of the number, the letter or the determined symbol and to validate that this or this is indeed that physically present on the regulating member associated with the gas distribution element. . As will be described below with reference to FIG. 3, this validation step by the practitioner 4 may be prior to the launching of the calculation by the method.

The determination system also comprises second calculation means capable of determining an amount of gas delivered as a function of the determined outgoing flow rate and a duration of administration of the gas. As mentioned above, a step of launching or validating the launching of the process by the practitioner 4 makes it possible to record a start time for the gas administration. Thus, at any time, the second calculation means are able to calculate what total amount of gas has been administered to a given patient. In other words, the determination system advantageously makes it possible to determine, in real time or at the end of an administration operation, the quantity of gas delivered to a given patient.

When the practitioner decides to modify the outgoing flow, he only has to repeat the operations described above, after having modified this outgoing flow by means of the regulating member 5 of the outgoing flow of the dispensing element 3, so that an update is carried out and this modification is taken into account. Similarly, at the end of the treatment, the practitioner selects an outgoing flow equal to 0 and repeats the same operations. Thus, the monitoring of the quantity of gas administered is carried out throughout this administration of gas and allows precise and real-time monitoring of this quantity of gas administered. It is understood that in these two situations, the practitioner must, before carrying out the acquisition of images, record information according to which it is a change in dosage or a discontinuation of the treatment, for example by clicking on a dedicated application icon.

The practitioner 4 can also carry out another acquisition of images, this time from the patient's bed 2. As shown in FIG. 1, this bed 2 can in fact include an identification element 81 which contains information relating to the patient. Thus, the practitioner 4 performs the acquisition of images of this identification element 81 arranged on the bed 2 via the communicating mobile device 6 which then transmits these images to the image processing module 200 which is then configured to analyze these images and deduce information relating to the patient concerned. Thus, the information relating to the outgoing flow rate can be automatically associated with the corresponding patient. Alternatively, this identification element 81 can be positioned on a bracelet worn by the patient.

Advantageously, the information concerning all the patients is collected and recorded on a single server 11. This centralization of the data makes it possible for example to carry out studies on large scales on the one hand on different therapies, and on the other hand, on different dosages of the same treatment.

Advantageously, this centralization of the data also makes it possible to detect a gas leak more quickly. We understand that by comparing the total amount of gas administered to all patients in a hospital department or an entire hospital with an amount of gas actually removed from inventory, it is easy to detect a leak at an early stage and thus re-mesh in order to limit the damage, both in terms of economic losses and physical risks depending on the type of gas in question.

FIG. 3 summarizes a plurality of steps of the method 10 implemented by the determination system according to the invention in synoptic form. Thus, the practitioner, after having manually defined an outgoing flow via the outgoing flow regulation member associated with the gas distribution element, performs a step 100 of launching the process, in this case by launching a application downloaded beforehand on a mobile device communicating 6 which is specific to it. When launching the application, the practitioner must indicate, for example by clicking on dedicated icons, whether it is a start of a treatment by gas administration, a change in the dosage of a treatment in progress or of a stop of such treatment.

Once this launching step has been carried out, the practitioner performs a step of acquiring images 110 of this gas distribution element, and more particularly of the flow indicator leaving this gas distribution element, for example at using the communicating mobile device 6.

The acquired images are then transmitted to the image processing module 200, whether it is installed in a remote server 11 or in the communicating mobile device 6 which has been used for carrying out the preliminary steps, which includes the analysis means 210 of these images and first calculation means 220 configured to determine as described above an outgoing gas flow from the transmitted images.

In a first processing step 120, and as previously mentioned, the analysis means 210 are configured to analyze the images they receive and deduce therefrom information on the outgoing gas flow, this information then being compared in a second processing step 130 by the first calculation means 220 to a database to determine the outgoing gas flow.

If necessary, the image processing module 200 can include analysis elements 230 of the distinctive pattern carried by the gas distribution element, and in a third processing step 140, the analysis elements communicate with the means 210 to retrieve images acquired by the practitioner, to process them and to return data allowing, as previously mentioned, to make the analysis of the images acquired from the flow indicator more reliable by the analysis means 210 of these images.

This image processing module 200 is thus configured to determine the actual outgoing flow of gas and to transmit this determined outgoing flow to second calculation means 300. These second calculation means 300 then calculate, in a calculation step 150, the quantity of gas administered as a function of the determined outgoing flow rate and of a duration during which the gas is administered to the patient. It is understood that this duration is calculated as a function of the start and end times of gas administration recorded by the determination system during validation by the practitioner of these steps.

The method according to the present invention may further comprise an additional step 160 of validation, by the practitioner, of the outgoing rate determined by the image processing module 200, preceded by a step of displaying this outgoing rate determined on the 'Human Machine Interface. The practitioner having adjusted this outgoing flow, he can easily and quickly validate the outgoing flow determined by the image processing module 200, making the method according to the invention more reliable. It is understood that it is therefore necessary to choose means of implementation allowing the fastest possible communication with the practitioner. It is indeed important that the latter receives a confirmation request in real time, which implies that the image processing is almost immediate. To this end, depending on the communicating mobile devices available to medical personnel and the communication network, we will choose to integrate the image processing module and the first calculation means with the communicating mobile device or to relocate them to a remote server.

Advantageously, each practitioner has a mobile communication device of their own in order to be able to keep track of the operations performed by each of them and thus improve the monitoring of the care administered to each patient. Alternatively, a communicating mobile device can be assigned to several practitioners who then have an identification means, for example a badge, which they simply need to register in the communicating mobile device in order to ensure this monitoring.

As mentioned above, the application, or program comprising portions of program code, for the execution of the determination method must be launched or downloaded on each mobile device communicating with which the practitioners wish to implement the method. according to the invention. This application can for example be downloaded via a download platform. According to the example described above, the practitioner must manually launch this application, for example by clicking on a dedicated icon on the communicating mobile device or by voice command. According to another example not described here, the application can be configured to launch automatically from the image acquisition step.

It will be understood from the above that the present invention thus allows effective, reliable and precise monitoring of the quantities of gas administered to each patient of the same establishment or of the same service of this establishment. Advantageously, the present invention also allows faster detection of possible leaks of these gases which can have serious consequences. The invention cannot however be limited to the means and configurations described and illustrated here and it also extends to any equivalent means and configuration and to any technically effective combination of such means. In particular, the gas distribution element and the tool allowing the acquisition of images and the transmission of these images can be modified without harming the invention insofar as they fulfill the functionalities described in this document.

Claims (10)

1. Method (10) for determining a quantity of gas delivered to a patient comprising at least one step of acquiring images (100) of an indicator (7) of a flow rate exiting from a distribution element (3) of gas via a mobile communicating device (6), a step of transmitting these images to an image processing module (200), this image processing module (200) comprising at least less image analysis means (210) and first calculation means (220) configured to determine in at least one processing step (120, 130, 140) an outgoing gas flow from the transmitted images, and a calculation step (150), by second calculation means (300), of a quantity of gas delivered as a function of the outgoing flow rate and of a duration of administration of the gas. 2. Method (10) according to the preceding claim, in which the step of calculation by the second calculation means (300) of the quantity of gas delivered is preceded by a step of displaying the outgoing gas flow rate determined on an interface man / macbine and by a validation step (160) by the user (4) of the method (10) of this determined outgoing flow. 3. Method (10) according to the preceding claim, wherein the man / machine interface is integrated with the communicating mobile device (6). 4. Method (10) according to any one of the preceding claims, in which the second calculation means (300) as well as the image processing module (200) are integrated into a server (11) configured to send and receive data to and from the communicating mobile device (6). 5. Method (10) according to any one of the preceding claims, in which the gas distribution element (3) comprises a distinctive pattern (80), for example positioned near or around the indicator (7) of flow leaving the gas distribution element (3), and in which image analysis elements (230) of this distinctive pattern (80) are integrated into the image processing module (200), these elements of image analysis (230) of the distinctive pattern (80) being configured to define a relative position of the communicating mobile device (6) with respect to the indicator (7) for flow leaving the distribution element ( 3) during the acquisition of images (100) and for transmitting data corresponding to this position relating to the image analysis means (210). 6. Method (10) according to the preceding claim, wherein the distinctive pattern (80) is a two-dimensional code. 7. Method (10) according to any one of the preceding claims, in which the image processing module (200) performs a projective transformation of the images received. 8. Method (10) according to any one of the preceding claims, in which the gas distribution element (3) is integrated into a gas distribution wall outlet. 9. communicating mobile device program (6) comprising portions of program code launched or downloaded on the communicating mobile device (6), for the execution of the method (10) according to any one of the preceding claims, the program being configured to control the implementation of an apparatus allowing the acquisition of images, the transmission of the acquired images to an image processing module (200), the reception of information relating to a determined outgoing bit rate by this image processing module (200), and the display of this determined outgoing bit rate in order to allow validation (160) of the latter by a user (4) of the communicating mobile device (6) and thus allow launching calculations to determine the quantity of gas delivered. 10. System for determining a quantity of gas delivered to a patient comprising a container containing gas and equipped with at least one distribution element (3) of this gas and with a regulating member (5) of a flow leaving this gas distribution element (3), the determination system comprising: image acquisition means (6) of the distribution element (3), an image processing module (200) comprising at least image analysis means (210) and first calculation means (220), the image processing module (200) being configured to determine a flow rate leaving the distribution element (3) , a man / machine interface capable of displaying the determined outgoing flow rate, second calculation means (300) of a quantity of gas delivered as a function of the outgoing flow rate and of a duration of administration of the gas.