Patent Description:
The invention also concerns a method for measuring at least three parameters of a patient by using said device according to claim <NUM>.

The diagnosis of respiratory diseases is done by pulmonary auscultation using a stethoscope and functional tests. Currently, the tool that is most frequently used by physicians to perform auscultation is a traditional stethoscope, invented by Dr. Laennec <NUM> years ago.

However, these examinations require significant expertise and can only be conducted by a physician. It requires strong medical expertise and long training to detect clinical sound by ear.

Various approaches exist to improve the existing auscultation tools and facilitating the acquisition of patient parameters such as chest sound.

One of the most promising and popular approach concerns digital or electronic stethoscopes that allow viewing and recording chest sound.

In this respect, the document <NPL> illustrates that a key element of any electronic stethoscopes stands in the microphone. This document describes the effect of the microphone air cavity, notably the width, shape and venting in the acquisition of sound spectra and the use of a single electret with a variety of plastic coupler.

Respiratory diseases are often characterized by multiple clinical signs or symptoms, for instance abnormal chest sound associated with increased respiratory rate and fever. It is known that the screening of respiratory disease is improved if several physiological parameters such as blood oxygen saturation are taken into account to diagnose the disease and determine its severity. During auscultation, physician generally uses a specific tool to evaluate each symptom separately which could be time consuming and could significantly negatively impact the efficiency of the diagnosis.

Overall, when it comes to acquire multiple parameters in a patient in an efficient manner, notably time efficient manner, and reliable manner, the existing stethoscopes do not provide satisfying solutions. One of the reasons is that the existing stethoscopes do not allow to record or monitor several parameters in a reliable and time efficient manner.

Prior art documents <CIT>, <CIT> and <CIT> disclose stethoscopes that acquire multiple parameters in a patient.

The above problems are solved by the device and the method according to the present invention as defined in independent claims <NUM>, <NUM> and <NUM>.

In a first aspect, the invention concerns a device for measuring at least one parameter of a patient, the device comprising a casing equipped with at least three sensors, each sensor being configured for measuring one distinct parameter of the patient, said three sensors are a temperature sensor to measure a temperature of the patient, a sound sensor to record a body sound of the patient, preferably pulmonary sound and/or heart sound, and an oximeter sensor to measure an oxygen blood level of the patient and/or the patient's heart rate,
said three sensors being mounted in the casing so that when the device is in contact with the skin of the patient, at least the three sensor are able to measure three distinct parameters simultaneously. The casing comprises two opposite externals faces namely a first main face and a second face, the first main face comprising at least the oximeter sensor, and the second main face comprising at least the temperature sensor and the sound sensor.

In a second aspect, the invention concerns a method for measuring at least three parameters of a patient by using a device according to the present invention, the method comprising :.

characterized in that step i) to step iii) are performed simultaneously.

In a third aspect, the invention relates to a computer implemented method for remotely operating a device according to the present invention, the method comprising:.

In a fourth aspect the invention relates to the use of an apparatus, for instance computer device such as a smartphone or another mobile device, comprising means for carrying out the computer implemented method according to the present invention.

In a fifth aspect the invention concerns a computer program, for instance a software executed on a smartphone or mobile device, comprising instructions which, when the program is executed by a computer, cause the computer to carry out the computer implemented method according to the present invention.

The invention concerns a device for measuring at least one parameter of a patient, the device comprising a casing equipped with at least three sensors, each sensor being configured for measuring one distinct parameter of the patient.

Said three sensors are a temperature sensor to measure a temperature of the patient, a sound sensor to record a body sound of the patient, preferably pulmonary sound and/or heart sound, and an oximeter sensor to measure an oxygen blood level of the patient and/or the patient's heart rate, said three sensors being mounted in the casing so that when the device is in contact with the skin of the patient, at least the three sensors are able to measure three distinct parameters simultaneously.

Advantageously, in the present invention, a plurality of parameters is acquired simultaneously in the patient. This allows to reduce the steps needed to measure several parameters in a patient and to improve diagnostic reliability and disease severity grading.

Overall, the present invention addresses the time or duration required to diagnose a disease, in particular a respiratory disease, by reducing the duration required to acquire relevant parameter's measurements.

Advantageously, measuring simultaneously the body sound, for instance lung and heart sound, the blood oxygen saturation, patient the patient heart rate and/or respiratory rate, and the body temperature will greatly improve the classification and the severity of diseases. Computing all these parameters simultaneously offer a diagnostic advantage over multiple parameters measured at different time points.

A disease is rarely characterised by only one feature like fever or increased respiratory rate or lung sound. Combining several features allows the distinction between different diseases, thus improves the precision of the diagnosis and the quality of care.

According to the invention, the casing comprises two opposite externals faces namely a first main face and a second face, the first face comprising at least the oximeter sensor, and the second face comprising at least the temperature sensor and the sound sensor.

According to the invention, three sensors are mounted in the casing so that when the device is in contact with the skin of the patient, the temperature sensor, the sound sensor and the oximeter sensor operate simultaneously so that at least the temperature of the patient, the body sound of the patient and the oxygen blood level of the patient and/or the patient's heart rate are measured simultaneously. Thus, the three sensors are mounted in the casing to allow a simultaneous measurements of three distinct parameters, each acquired by one sensor.

In a preferred embodiment, the oximeter sensor is a reflection pulse oximeter. Contrary to transmission pulse oximeter which must be adapted to the morphology of the finger, reflection pulse oximeter it can be adapted to all finger morphologies. Thus, it is not necessary to change the measuring head of the oximeter. This allows to have a more compact and ergonomic device.

Preferably, the oximeter is configured for contacting the patient finger. This allows to place the oximeter on a face of the device which is not in contact with the patient's chest.

In a preferred embodiment, the oximeter is a reflection pulse oximeter placed on one main face of the device while the temperature sensor and the sound sensor are placed on the opposite main face of the device preferably configured for contacting the patient's chest, for instance circular main faces. Thus, this particular design allows to measure oximetry with the fingertip and measuring the breath sounds with the sensor placed on the chest at the same time, preferably these simultaneous measurements of the three parameters is done by the patient him/herself. This allows to measure three parameters in one step and to save time during the parameters acquisition.

Preferably, the sound sensor comprises body sensor, for instance a pulmonary and cardiac sensor, for recording body sound, for instance lung and heart sound, of the patient. The sound sensor further comprises an ambient sensor for recording ambient sound, or in other words cancelling ambient noise. The body sensor and the ambient sensor being configured for recording data simultaneously. The presence of the ambient sensor allows to filter or sort out the recorded pulmonary sound to discard noise or sound unrelated to the patient or not relevant for monitoring body sound. The ambient sensor measurement is correlated with the body sound measurement to improve the quality of the body sound, for instance pulmonary and cardiac sound, and thus their reading and interpretation.

Preferably, the pulmonary sensor comprises a resonance chamber designed for being coupled to a microphone, said chamber comprising a membrane configured for contacting the patient's skin. This configuration allows to optimize the acoustic transmission and to amplify the sound level in the desired frequency ranges.

Preferably, the casing is a cylinder volume extending between the first main circular face and the second main circular face, the first face comprising at least one sensor, preferably the oximeter sensor, and the second face comprising at least two sensors, preferably the temperature sensor and the sound sensor. The overall cylinder shaped provides a device that is easy to handle for the user. The cylinder casing can be handled in secure manner in the hand of the user.

Preferably, the oximeter sensor comprises an optical sensor configured for measuring oximetry upon contact with the patient's skin, preferably the patient's finger.

In a preferred embodiment, the oximeter sensor is received in an opening, preferably a blind hole, arranged in the first main face of the device so that when a finger of the patient is inserted or placed in front the opening, said finger contacts the oximeter sensor to allow an oximetry measurement. This configuration allows to adapt to all the morphologies of fingers and facilitates its use by the patient.

In a preferred embodiment, the device comprises at least five sensors, said sensors comprising.

The combination of these five sensors makes allows to optimize the parameters which are acquired on the patient compared to a device comprising three sensors. This allows to improve the reliability and the quality of the data acquired.

Using two sound sensors, for instance two microphones, allows to make an active noise reduction and thus improves the quality of the audio signal. For instance, the microphone recording lung sounds is integrated into a sound box equipped with a membrane. This configuration improves acoustic transmission between the patient's skin and the microphone.

Using two temperature sensors allows a differential temperature measurement of the patient. In other words, measuring the temperature in two points of contact allows a more precise and reliable measurement. The sensors are preferably located on the face of the device comprising the sound sensor (s), which makes it possible to record body sounds and measure the temperature simultaneously upon contacting the patient's skin.

Preferably, the device further comprises a memory for saving at least one measure of each parameter.

Preferably, the body sound comprises sound measurements recorded at various locations on the patient skin, for instance from two to ten locations, in particular from four to ten locations, for example from six to eight locations. Recording sound at multiple locations allow to better localize a disease in a specific location, for instance specific location of the lung or the heart, or inform if the disease involves the entire organ.

In a preferred embodiment, the device is a stethoscope.

In another aspect, the invention concerns a method for measuring at least three parameters of a patient by using a device according to the invention, the method comprising :.

The particular advantages of the method are similar to the ones of the device according to the invention and will thus not be repeated here.

In another aspect, the invention relates to a computer implemented method for remotely operating a device according to the invention, the method comprising:.

Advantageously, the device according to the present invention can be controlled or operated in a remote manner by a control unit. For instance, the control unit comprises electronic component to execute a program to control the device.

The control unit is connected on the one hand with the device and on the other hand with a server or another storage component. The signals emitted by the control unit allow to control the device notably to ensure the transfer of the parameter's measurements from the device to the server.

In another aspect, the invention relates to the use of an apparatus, for instance computer device such as a smartphone, comprising means for carrying out the computer implemented method according to the invention.

In another aspect, the invention relates to a computer program comprising instructions which, when the program is executed by a computer, cause the computer to carry out the computer implemented method of the invention.

The embodiments describe for the device also apply to the methods and program according to the present invention mutatis mutandis and vice versa.

Further particular advantages and features of the invention will become more apparent from the following non-limitative description of at least one embodiment of the invention which will refer to the accompanying drawings, wherein.

The present detailed description is intended to illustrate the invention in a non-limitative manner since any feature of an embodiment may be combined with any other feature of a different embodiment in an advantageous manner.

<FIG> represent a device <NUM> according to a first embodiment of the present invention but the invention is not limited to this first embodiment.

The device <NUM> represented on the figures comprises is a stethoscope S comprising a casing <NUM> shaped as a cylinder volume extending between a first main circular face <NUM> and a second main circular face <NUM> opposite the first main circular face <NUM>. The casing <NUM> is divided in two parts namely a cover <NUM> and body <NUM>, the being fitted or embedded in the cover <NUM>. In other words, the body <NUM> could be considered as the lower part of the casing <NUM> comprising the first main circular face <NUM> whereas the cover <NUM> is the upper part of the casing <NUM> comprising the second main circular face <NUM>. For instance, the cover <NUM> is fixed to the body <NUM> by using a bayonet locking system.

In the embodiment represented on <FIG>, the casing has the following dimensions:.

The device <NUM> comprises three sensors, namely a temperature sensor <NUM>, a sound sensor <NUM> and an oximeter sensor <NUM>.

The temperature sensor <NUM> comprises four thermocouples <NUM> placed on the first main circular face <NUM>. Each thermocouple <NUM> is coupled with a thermal insulation <NUM> as shown in <FIG>.

The sound sensor <NUM> comprises a body sensor <NUM> for recording body sound of the patient and an ambient sensor <NUM> for recording ambient noise, the body sensor <NUM> and the ambient sensor <NUM> being configured for recording data simultaneously.

the body sensor <NUM> in the present embodiment is configured for recording pulmonary sound but in other embodiment (not shown here), the body sensor <NUM> is configured for recording pulmonary sound and cardiac sound.

The body sensor <NUM> comprises an ensemble of circular elements <NUM> embedded one another toward the first main circular face <NUM>, said ensemble comprising :.

The ensemble of circular element <NUM> is further coupled to a first microphone <NUM> whereas the ambient sensor comprises a second microphone <NUM> for recording ambient noise.

The oximeter sensor <NUM> the oximeter sensor is received in an opening <NUM>, here a blind hole <NUM>, arranged in the first main face <NUM> of the device <NUM>. An optical sensor <NUM> is placed in the bottom of the blind hole <NUM> (not shown in <FIG>) so that when a finger of the patient is inserted in the opening <NUM> and reaches the bottom of the blind hole <NUM>, the finger contacts the optical sensor <NUM> to allow an oximetry measurement.

The three sensors of the device <NUM> are mounted in the casing <NUM> so that when the device <NUM> is in contact with the skin of the patient, two distinct parameters namely the body sound and the temperature are measured simultaneously :.

In this embodiment, the design of the device <NUM> has been developed so that the user can hold it in one hand to perform the measurement of body sound and temperature simultaneously. The oximetry measurement is carried out in a second step by placing the finger in the housing provided for this purpose.

<FIG> illustrates the computer implemented method according to the invention where the device <NUM> is connected to a control unit <NUM>, for instance a smartphone <NUM> that is further connected to a computation unit <NUM> located for instance on a sever <NUM>. The smartphone <NUM> may comprised a computer program, for instance an application or another software, and the software, when executed, is configured for controlling in a remote manner the device <NUM>.

An example of the computer implemented method is described below and represented in <FIG>:.

The output provided by the method according to the present invention allows to or are taken into account to diagnose a disease. Advantageously, it allows to or is taken into account to determine the severity of the disease.

Claim 1:
Device (<NUM>) for measuring at least one parameter of a patient, the device (<NUM>) comprising a casing (<NUM>) equipped with at least three sensors, each sensor being configured for measuring one distinct parameter of the patient, said three sensors are a temperature sensor (<NUM>) to measure a temperature of the patient, a sound sensor (<NUM>) to record a body sound of the patient, and an oximeter sensor (<NUM>) to measure an oxygen blood level of the patient and/or the patient's heart rate, said three sensors being mounted in the casing (<NUM>) so that when the device (<NUM>) is in contact with the skin of the patient, at least the three sensors are able to measure three distinct parameters simultaneously, each parameter acquired by one sensor, characterized in that the casing (<NUM>) comprises two opposite externals faces namely a first main face (<NUM>) and a second face (<NUM>), the first main face (<NUM>) comprising at least the oximeter sensor (<NUM>), and the second main face (<NUM>) comprising at least the temperature sensor (<NUM>) and the sound sensor (<NUM>).