ITUA201690329U1 - NON INVASIVE PORTABLE TONOMETRIC DEVICE. - Google Patents

Description

DESCRIPTION OF THE UTILITY MODEL HAVING THE TITLE:

"NON-INVASIVE TONOMETRIC HANDHELD DEVICE"

TEXT OF DESCRIPTION:

The invention object of the present invention relates to a non-invasive tonometric device.

The present invention refers to the field of the art comprising non-invasive devices for tonometry.

In particular, it refers to a portable, non-invasive device for continuous monitoring of the Sphygmic Wave.

Tonometry is the measurement of tone or pressure which, in the case in question, refers to the sphygmic wave, or the blood pressure wave that is generated as a result of cardiac contraction.

The shape and the values connected to it are the mirror of cardio-circulatory functioning. The wave analysis, especially the continuous one, allows to highlight numerous diagnostic parameters useful both in the clinic and in competitive sport or body care.

The importance of this signal in the clinic lies in the fact that a lot of information can be deduced from it.

Primarily blood pressure, systolic pressure, during the contraction phase, and diastolic pressure, during the resting phase and mean pressure. These values are information of primary importance because too low or too high blood pressure is an indication of sometimes very serious problems and it is therefore important that it remains within predetermined values both with respect to sex, man or woman, both age and the physiological conditions of the subject, or subject in good health or suffering from pathologies.

The sphygmic wave is the result of the superposition of direct waves and reflected waves, the temporal superposition of these two waves morphologically defines the wave, the waves travel along the arteries and, depending on the arterial stiffness, it is possible to observe different temporal superimpositions. The speed at which the waves propagate depends on arterial stiffness. When the subject has a high arterial stiffness, the reflected wave propagates with high speed, this causes a temporal overlap that produces an increase in pressure known as AP Augmentation pressure, a phenomenon also known as Hypertension. The importance of the morphological analysis of the wave lies precisely in the fact that it is possible to establish whether the subject has high arterial stiffness based on the morphology of the wave, and to even be able to estimate its entity by measuring the speed of the sphygmic wave or PWV, Pulse Wave Velocity.

From the analysis of the sphygmic wave it is then possible to derive other fiducial points, such as the dicrotia point, the average pressure, analyze the heart rhythm, and perform clinical investigations on artery segments, observing two or more sampling points along a artery and analyzing the variations.

Furthermore, through a non-invasive analysis of the sphygmic wave on the radial artery, it is also possible to obtain the value of the central pressure through a transfer function.

Continuous monitoring of the sphygmic wave allows you to observe cardio-circulatory functioning during the usual daily activities, during psychophysical stress or during sports activities.

A continuous investigation of portable medical systems allows to observe the physiological behavior of the subject in different situations, improves the acceptability of the diagnostic examination and allows the subject to monitor the physiological parameters even for purposes other than purely clinical, such as for competitive sporting purposes or body care.

To date, the sphygmic wave can be recorded with different invasive and non-invasive methods:

With regard to invasive methods, the sphygmic wave can be measured with an intra-arterial transducer, or by inserting a catheter inside an artery and recording the corresponding pressure values. The invasive methods are very precise and reliable, but they have the drawback of being dangerous as there are risks of infection and multiple risks due to the invasive method, such as haemorrhages due to the fact that an artery has to be perforated. the intervention of specialized personnel and sterilized equipment and sterilized and suitable environments is required and to carry out the examination, such as operating theaters.

It is then possible to carry out non-invasive investigations: tonometric, piezoelectric, Doppler, impedance analysis. The most frequently used technique is the tonometric one. Applanation tonometry is a simple and reproducible technique of sphygmic wave analysis, which consists in the slight compression, applanation, of a superficial artery against the underlying bone plane by means of a pressure sensor, tonometer. The waveform obtained with a high-fidelity tonometer is virtually identical to that recorded with an intra-arterial transducer.

They are less dangerous, there are different methods, for example one of them involves the use of pen pressure transducers that are placed on the reference artery and, following calibration with pressure measurement using standard equipment, are able to detect and measure the sphygmic wave and perform an analysis of the detected data. Also in this case, the intervention of specialized personnel is required.

There are also portable and wearable devices able to perform an analysis of the data collected on board the devices themselves, they do not need intervention by specialized personnel but have the disadvantage of having high energy consumption compared to the category considered, calibration practices complex for the user and sometimes excessive dimensions and weight for body application, especially if a continuous use is considered, such as the one presented in the patent document with publication number EP2775905A1.

Data processing on board the device is absolutely disadvantageous for several reasons. The first is that these processes are often complex and therefore have a considerable consumption of hardware resources, with a consequent high energy demand for the battery, one of the fundamental parameters to be taken into account when considering a portable device, since it reduces the time of use or increases the size and cost of the same.

A second reason is that the processing assumes that additional hardware elements are inserted on the support, also in this case the weight of the device increases, the complexity of the device and therefore also increases the risk of malfunction, and the cost.

The signal analysis operations can in fact be entirely delegated to an external device.

The purpose of the invention, object of the present invention, is to have a portable, non-invasive, lightweight device of as small size as possible, simple to use, with reduced battery consumption, for continuous monitoring of the sphygmic wave.

The object of the invention, object of the present invention, is therefore to have a device with reduced dimensions capable of being applied by means of a support (1) similar to a plaster Tab. 1 Fig. 1, Tab. 2 Fig. 3.

According to another object, the object of the present invention is to have a device capable of communicating with a mobile device (6) so as to exploit the high computing capacity of this mobile device (6) to carry out the analysis of the data without burdening the wearable device Table 2 Fig. 3, Table 3 Fig. 4.

The invention object of the present invention intends to have a device with reduced energy consumption since it sends data analysis to a mobile device (6) Table 2 Fig. 3, Table 3 Fig. 4.

According to yet another object, the invention object of the present invention intends to have a device that does not overheat since it sends the data analysis to a mobile device (6) such as a smartphone, tablet or the like, and therefore does not absorb additional energy to perform such data analysis. According to yet another object, the invention object of the present invention intends to have a device capable of sending data to medical personnel by exploiting the internet communication capacity of the mobile device (6) of the smartphone, tablet or similar type Table 2 Fig. 3, Table 3 Fig. 4.

According to yet another object, the invention object of the present invention intends to have a device that is easy to use since the instructions for use can be communicated to the user by means of a mobile device (6) such as a smartphone, tablet or the like Table 2 Fig. 3 , Table 3 Fig. 4.

According to yet another object, the invention object of the present invention intends to have a device which exploits a mobile device (6) of the smartphone, tablet or similar type to easily update the software necessary to carry out the data analysis and to interface with the user Table 2 Fig 3, Table 3 Fig. 4.

The invention object of the present invention achieves the intended purposes as it is a non-invasive portable tonometric device, comprising:

- a support (1) to be affixed to the human body, which can be positioned on one or more points of sampling of the sphygmic wave Table 1 Fig. 1 and Fig. 2, Table 2 Fig. 3, Table 3 Fig. 4;

- at least one piezoresistive sensor (2) arranged along the support (1) which reads the pressure signal from the artery (7) Table 1 Fig. 1 and Fig. 2;

- an electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal from the piezoresistive sensor (2) Tab.

1 Fig. 1 and Fig. 2;

- a wireless data transmission unit (5) which sends the data acquired by the electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal to a mobile device (6) such as a smartphone, tablet or similar Table 2 Fig. 3, Table 3 Fig. 4;

- a battery (3) for powering the electronic unit (4), the piezoresistive sensor (2) and the wireless data transmission unit (5) Table 1 Fig. 1 and Fig. 2;

The analysis of the pressure signal, acquired by the piezoresistive sensor (2) through the electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal and sent through the wireless data transmission unit (5) to the mobile device (6) of the smartphone, tablet or similar type, is carried out entirely by the mobile device (6) of the smartphone, tablet or similar type, without having any unit for transforming the pressure signal into diagnostic information on the support (1); delegating this transformation to the processing algorithm present on the mobile device (6) such as smartphone, tablet or similar without ever weighing on the wearable device Table 2 Fig. 3, Table 3 Fig. 4, Table 4 Fig. 5.

Furthermore, since the support (1) is of the band type, the bracelet can be easily positioned on one or more sampling points of the human body. Table 1 Fig. 2, Table 3 Fig. 4.

Considering the fact that it does not require a data processing unit on board the device, the support (1) can be so small as to take the form of a plaster or the like. Tab. 1 Fig. 1, Tab. 2 Fig. 3.

The transformation of the pressure signal acquired by the piezoresistive sensor (2) through the electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal and sent through the wireless data transmission unit (5) to the mobile device (6) of the smartphone, tablet or similar type, is processed by the mobile device (6) of the smartphone, tablet or similar type that will perform the following functional steps:

- extraction of the amplitude of the continuous and non-continuous component of the pressure signal Table 4 Fig. 5;

- comparison of the ratio of the amplitudes of the continuous and non-continuous component with a reference range Table 4 Fig. 5;

-feedback of correct positioning of the support (1) on one or more sampling points of the sphygmic wave Table 4 Fig. 5;

- transformation of the sphygmic wave signal into diagnostic information by processing the said sphygmic wave signal by means of the algorithm present on the mobile device (6) of the smartphone, tablet or similar type Table 4 Fig. 5. Other characteristics and advantages of the invention they will be evident upon reading the following description of an embodiment of the invention provided by way of non-limiting example, with the aid of the drawings 11 in the attached tables.

Anyone in the trade will be able to better understand the invention, from a detailed description of the drawings, as follows:

Table 1 Fig. 1: Perspective view of the invention with support (1) in the form of plaster. The view schematizes the essential components that make up.

Table 1 Fig. 2: Perspective view of the invention with support (1) in the shape of a bracelet. The view schematizes the essential components that compose it.

Table 2 Fig. 3: Perspective view of the application of the invention with support (1) in the form of a patch placed on the artery (7) of a woman who, through her smartphone (6), continuously monitors her Wave Sphygmic. Table 3 Fig. 4: Perspective view of the application of the invention with support (1) in the shape of a bracelet placed on the artery (7) of a woman who, through her smartphone (6), continuously monitors her Wave Sphygmic. Table 4 Fig. 5: Block diagram of the operation of the portable device

Claims (4)

CLAIMS OF THE UTILITY MODEL HAVING THE TITLE: "NON-INVASIVE TONOMETRIC PORTABLE DEVICE" TEXT OF THE CLAIMS 1. Non-invasive portable tonometric device, comprising: - a support (1) to be affixed to the human body, which can be positioned on one or more points of sampling of the sphygmic wave; -at least one piezoresistive sensor (2) arranged along the support (1) which reads the pressure signal of the alien (7); - an electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal from the piezoresistive sensor (2); - a wireless data transmission unit (5) which sends the data acquired by the electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal to a mobile device (6) such as a smartphone, tablet or similar ; - a battery (3) for powering the electronic unit (4), the piezoresistive sensor (2) and the wireless data transmission unit (5); characterized by the fact that -analysis of the pressure signal, acquired by the piezoresistive sensor (2) through the electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal and sent through the wireless data transmission unit (5) to the mobile device (6) of the smartphone, tablet or similar type, is carried out entirely by the mobile device (6) of the smartphone, tablet or similar type, without having any unit for transforming the pressure signal into diagnostic information on the support (1), delegating this transformation to the processing algorithm present on the mobile device (6) of the smartphone, tablet or similar type. 2. Non-invasive portable tonometric device, according to claim 1, characterized in that the transformation of the pressure signal acquired by the piezoresistive sensor (2) through the electronic unit (4) for conditioning, amplification, filtering, control and storage of the signal and sent via the wireless data transmission unit (5) to the mobile device (6) of the smartphone, tablet or similar type, it is processed by the mobile device (6) of the smartphone, tablet or similar type which will perform the following functional steps: - extraction of the amplitude of the continuous and non-continuous component of the pressure signal; - comparison of the ratio of the amplitudes of the continuous and non-continuous component with a reference range; -feedback of correct positioning of the support (1) on one or more sampling points of the sphygmic wave; - transformation of the sphygmic wave signal into diagnostic information by processing the said sphygmic wave signal using the algorithm present on the mobile device (6) such as smartphone, tablet or similar. 3. Non-invasive portable tonometric device, according to claim 1, characterized in that the support (1) to be affixed to the human body, which can be positioned on one or more points of sampling of the sphygmic wave, can be of the band, bracelet, or similar. 4. Non-invasive portable tonometric device, according to claim 1, characterized in that the support (1) to be affixed to the human body, which can be positioned on one or more sphygmic wave sampling points, can be of the patch type or the like.