FR3060291A1 - CONTROL APPARATUS AND METHOD FOR DETERMINING THE STATUS OF A MENSTRUAL CYCLE AND SYSTEM FOR IMPLEMENTING IT - Google Patents

Abstract

A method (300) for determining the state of a menstrual cycle using a body tissue spectrometric analysis (190), method (300) comprising at least the following steps of: - emitting (310) radiation electromagnetic device (120) for irradiating body tissue (190), - recording (320) spectrogram data (145), these data representing the spectrogram generated with electromagnetic radiation (130) reflected by body tissue (190), - compare (340) the spectrogram data (145) recorded to reference data, the reference data representing at least one state of the menstrual cycle, and - providing (650) an information signal (265) according to the result of the comparing, the information signal (265) representing an indication of the state of the menstrual cycle.

Description

Holder (s): ROBERT BOSCH GMBH.

Extension request (s)

Agent (s): CABINET HERRBURGER.

LÔ4J CONTROL APPARATUS AND METHOD FOR DETERMINING THE STATE OF A MENSTRUAL CYCLE AND SYSTEM FOR ITS IMPLEMENTATION.

FR 3 060 291 - A1 (5 / y Method (300) for determining the state of a menstrual cycle using a spectrometric analysis of body tissue (190), method (300) comprising at least the following steps consists in:

- emitting (310) electromagnetic radiation (120) to irradiate the body tissue (190),

- recording (320) spectrogram data (145), these data representing the spectrogram generated with the electromagnetic radiation (130) reflected by the body tissue (190),

- comparing (340) the spectrogram data (145) recorded with reference data, the reference data representing at least one state of the menstrual cycle, and

- providing (650) an information signal (265) as a function of the result of the comparison, the information signal (265) representing an indication concerning the state of the menstrual cycle.

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Field of the invention

The present invention relates to a method for determining the state of a menstrual cycle by spectrometric analysis of body tissue and a device for carrying out the method.

State of the art

To determine the state of a female menstruation cycle one can, for example, use a measurement of hormones in a urine sample, a measurement of the base temperature of the body or similar operations.

Presentation and advantages of the invention

The subject of the present invention is a method for determining the state of a menstrual cycle using a spectrometric analysis of body tissue, comprising at least the following steps consisting in: emitting electromagnetic radiation to irradiate body tissue, recording spectrogram data, this data representing the spectrogram generated with the electromagnetic radiation reflected by the body tissue, comparing the spectrogram data recorded with reference data, the reference data representing at least one state of the menstrual cycle and, providing a information signal according to the result of the comparison, the information signal representing an indication concerning the state of the menstrual cycle.

According to embodiments, it is possible in particular to determine the state of the female cycle by spectroscopy by a spectrometer, in particular a micro-spectrometer. A non-invasive process thus makes it possible to determine the state of the female cycle. For this, a characteristic property or a variation in property of the tissue of the female breast is detected for example by enriching the female breast with water after ovulation during the cycle by measuring a diffuse reflection of the electromagnetic radiation emitted by a spectrometer, in particular a micro spectrometer.

Advantageously, according to embodiments, the accuracy of the determination of the state of the menstrual cycle is increased, for example by comparison, for example, of the measurement of hormones or of the measurement of the base temperature of the body. .

The measurement can also be done at any desired time, for example, not only in the morning directly after getting up or after urinating. In addition, the measurement is done in a non-invasive manner and thus without risk and in a comfortable manner for the user. In particular, after a learning phase carried out over one or more cycles, the measurement or determination of the state of the menstrual cycle can be carried out quickly and reliably, quickly in particular in a few seconds.

The method according to the invention as recalled above is implemented, for example, in a program or in a circuit or in a combination of a program and a circuit for example in a control apparatus. Body tissue is, for example, the tissue of the female breast. Body tissue can be skin tissue or subcutaneous tissue. Electromagnetic radiation is radiation in the infrared or near infrared spectrum. The reflected electromagnetic radiation is reflected by a diffuse reflection. The information signal is supplied to be transmitted by an output interface. The information signal produces an acoustic, optical or in addition or alternatively haptic emission of the indication by the output interface. The indication is an indication of a certain condition of the menstrual cycle and in addition or alternatively of at least one other indication. This other indication may mean a request to continue irradiation, a supply of accuracy of determination or the like.

According to one embodiment, in the production stage, electromagnetic radiation can be emitted in the near infrared. The spectrogram data can represent a measurement of a diffuse reflection in the near infrared on the tissue of the human body. Electromagnetic radiation in the near infrared has a wavelength between 650 nanometers and 1350 nanometers. In this area, water has a characteristic absorption band around 900 nanometers. Such an embodiment offers the advantage that the range of wavelengths of the near infrared increases the depth of penetration of electromagnetic radiation into the tissue of the human body, for example, the skin or at least makes this radiation the most strong. We can also consider other wavelength ranges.

In the comparison step we use data analysis with multiple variants. This analysis of data with multiple variants comprises an analysis of principal components and in addition or as a variant an analysis by regression. Such an embodiment offers the advantage that by using a multivariate data analysis algorithm, after a learning phase, the spectra measured in the different phases of the menstrual cycle and for example can be classified in a reliable and rapid manner. provide a graphical indication to the user.

In addition, in the registration step, user input data is saved. Thus, in the execution stage of the comparison, it is possible to use the stored user data. In particular, user input data may represent data relating to a date of a menstruation and in addition or alternatively a base body temperature. Such an embodiment has the advantage that with other data added by the user such as, for example, the days of menstruation or a measurement of the base temperature, it will be possible to have an even more precise forecast. In addition, one can consider the possibility of a hormonal measurement, for example by a urine sample.

According to one embodiment, in the execution step there is a cross validation of the result of the comparison. Such an embodiment offers the advantage of obtaining an indication concerning the security of the comparison or classification.

The method in the modification step can relate to the reference data using the result of the comparison made in the execution step. Such an embodiment has the advantage of allowing a training phase or a learning phase to improve the result of the comparison and to provide better accuracy of determination and, where appropriate, continuous adaptation or improvement. This allows the use of a self-learning effect algorithm.

The method may further include a step of using spectrometer data to determine the property of the body tissue, which depends on the state of the menstrual cycle. In particular, in the exploitation stage, the spectrogram data can be exploited to obtain, as a property of the fabric, the water content, the fat content and, in addition or alternatively, the ratio between the water content and the content. as body tissue fat. This embodiment has the advantage of being able to safely determine the state of the menstrual cycle. Indeed, the state of the menstrual cycle can depend not only on the base temperature of the body but also on the composition of the tissue of the breast. Depending on the woman, the water content can vary up to several percent and in the second part of the cycle the water accumulates to be eliminated during menstruation. In addition, the ratio of water content to fat content may vary. This can translate for each woman into a characteristic variation in optical properties, for example, the spectral reflection coefficient or the absorption coefficient.

Thus, in the exploitation stage, a cross validation of the determined data of the tissue is carried out. Such an embodiment has the advantage of making it possible to obtain information concerning the reliability of the operation. In addition or alternatively, the method may include a step of modifying the reference data using the property of the fabric obtained in the operating step. Such an embodiment has the advantage of allowing at least one training phase or a learning phase to improve the result of the comparison and the accuracy of the determination and, where appropriate, also continuous adaptation or improvement. This allows the use of a self-learning algorithm.

The invention also relates to a control device for executing the steps of a variant of the process as presented in appropriate installations, for controlling them and for applying the process. This variant of the process of the invention in the form of a control device makes it possible to quickly and effectively solve the problem underlying the invention.

Thus, the control apparatus comprises at least one computing unit for processing the signals or the data, at least one memory for recording the signals or the data, at least one interface to a sensor or at least one actuator for recording the signals from the sensor or to send control signals to the actuator and / or at least one communication interface for recording or transmitting data, which are integrated into the communication protocol. The calculation unit is in particular a signal processor, a microcontroller or the like and the calculation unit comprises a flash memory, an EEPROM or a magnetic memory. The communication interface is made to record or transmit data wirelessly and / or connected by lines and the communication interface, the data connected to lines will thus be recorded or transmitted. Data, for example, electrical or optical data can come from a certain data transmission line or be carried out in a corresponding data transmission line.

A control device according to the invention is an electrical device which processes the signals from the sensors and provides control signals and / or data signals as a function thereof. The control unit has an interface in the form of a program and / or a circuit. In the case of an embodiment in the form of a circuit, the interfaces are, for example, part of the ASIC system which has different functions of the control unit. But it is, however, possible that the interfaces are integrated circuits, clean or which are at least partly made up of discrete components. According to an implementation by program, the interfaces are program modules which exist, for example, on a microcontroller alongside other program modules.

According to an advantageous development, the control device determines the state of the cycle using spectrometric analysis of the body tissue. The controller uses, for example, sensor signals from at least one spectrometer device to provide spectrogram data and optionally, in addition to user data, from at least one input interface. The emission takes place through interfaces such as display devices, light emitting diodes, speakers, vibrating units or the like.

The invention also relates to a system having the following characteristics:

an embodiment of the control apparatus as defined above, at least one radiation source for emitting electromagnetic radiation and, a spectrometry device providing the spectrogram data, the control apparatus, the radiation source and the spectrometry device being connected for exchanging signals.

In conjunction with the system, one embodiment of the above-mentioned control device is advantageously used to control the determination of the state of the menstrual cycle using spectroscopic analysis of body tissue. The spectrometric device can be produced to capture the electromagnetic radiation emitted by at least one radiation source and this same reflected electromagnetic radiation and this by using the captured radiation to generate the spectrogram data.

According to one embodiment, the spectrometric device is a microspectrometer, in particular a static Fourier transform spectrometer, for example based on a Savart polariscope, a Fabry-Pérot interferometer, a linear variable filter and / or a spectrometer based on a diffraction grating. Such an embodiment has the advantage of very small dimensions and thus allows comfortable use. In addition, a spectrometer of any type of construction allows rapid and precise reliable determination of the state of the menstrual cycle.

Likewise, the radiation source and the spectrometry device of the system are in the form of a portable device or part of such a portable device. The portable device is a commonly used electronic device, a mobile phone, a SmartPhone or the like. Such an embodiment has the advantage of using in addition a device having a high computing power, provided by the system; one can, for example, have self-learning algorithms which provide spectra measured according to the quality and in case of good quality, have an extended database position for the following measurements in addition or as a variant to be able to render the indications regarding forecast security. If, for example, a Smartphone equipped with a micro-spectrometer is used, a moderately competent user may already have an appropriate measurement circuit, so as to reduce the costs of the user.

The system further includes an input interface for storing user data. The advantage of such an embodiment is that it makes it possible to determine more precisely and with greater certainty the state of the cycle with other data added by the user, such as, for example, the days of menstruation or the measurement of the base temperature.

Advantageously, the invention also relates to a computer program product with a program code recorded on a memory readable by a machine such as a semiconductor memory, a hard disk or an optical memory and which can be used to apply the method according to the embodiments described above when the computer program product is executed by a computer or a computer.

Drawings

The present invention will be described below, in more detail with the aid of examples shown in the accompanying drawings in which:

FIG. 1 is a diagram of an exemplary embodiment of a system, FIG. 2 is a diagram of another exemplary embodiment of a system, FIG. 3 is a flowchart of a method applying the example of production.

Description of embodiments of the invention

Before describing exemplary embodiments with reference to the figures, the background and the bases of the exemplary embodiments will be briefly described.

The female cycle is broken down into three phases: the menstruation phase, the proliferation phase and the secretion phase. The secretion phase begins as soon as ovulation occurs. At this time the woman is fertile. Knowledge of the current state of the cycle thus makes it possible, in the event of desire for maternity, to determine the fertile phase and in the case of contraception, to determine the non-fertilizable phase after ovulation. Conventional methods of natural contraception without hormones or of determining fertility use, for example, the measurement of hormones (for example luteinizing hormone LH) with a urine sample because this content increases strongly at the beginning of the ovulation. Another method is to measure basal body temperature directly after waking up. This temperature is in the secretion phase, for example, about 0.3 ° C up to 0.4 ° C above the temperature during the proliferation phase. In this process, the difference in temperature to be measured is too small so that it requires very great execution discipline because the temperature must be measured consistently in the morning before the temperature is influenced by bodily stress (such as that the sunrise) and, moreover, for example, that it is not distorted by temperature variations linked to an illness or to constraints.

In the following description of more advantageous examples of the invention, identical or analogous references will be used in the different figures and for elements with similar effects and these elements will not be described again.

Figure 1 is a schematic representation of a system 100 according to an exemplary embodiment. System 100 allows you to determine and / or monitor the state of a menstruation cycle. According to the exemplary embodiment shown in FIG. 1, the system 100 is a portable device or a part of a portable device. This portable device is, for example, a device in the field of household electronics, in particular a dedicated cycle monitoring device or a Smartphone. According to another exemplary embodiment, it is also possible to produce only the parts of the system 100 as a portable device or a part of a portable device.

FIG. 1 shows, by way of example only, the parts of the system 100 such as the radiation source 110 generating the electromagnetic radiation 120, the spectrometry device 140 for capturing the reflecting electromagnetic radiation 130 and a control device 150. Thus, the system 100 comprises at least the radiation source 110, the spectrometry device 140 and the control device 150. The radiation source 110, the spectrometry device 140 and the control device 150 are connected in the direction signal transmission or data transmission.

The radiation source 110 emits the electromagnetic radiation 120 as a function of a control signal 155 supplied by the control apparatus 150. According to the embodiment presented in FIG. 1, the radiation source 110 emits electromagnetic radiation in the near infrared.

The spectrometry device 140 supplies a spectrogram signal 130 or spectrogram data 145 corresponding to the reflected electromagnetic radiation 130. The spectrometry device 140 supplies the spectrogram data 145 to the control device 150. According to the embodiment presented in FIG. 1, the spectrometric device 140 is a micro-spectrometer, for example a micro-spectrometer applying the Fourier transform based on a Savart polariscope, a Fabry-Pérot interferometer, tuned, a linear variable filter and / or a diffraction grating spectrometer.

The controller 150 determines the state of the menstrual cycle using spectrometric analysis of the body tissue 190 or controls the determination of the latter. In the representation of FIG. 1, the system 100 is installed near a female chest 190 which represents the body tissue 190. The electromagnetic radiation 120 is thus reflected by the chest 190 and at least part of the reflected electromagnetic radiation 130 arrives on the spectrometric device 140. The control device 150 will be described in more detail below with particular reference to FIG. 2. In other words, FIG. 1 shows a measurement geometry for applying a micro-spectrometer 140 to a female chest 190.

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Figure 2 is a schematic representation of an exemplary embodiment of a system 100. The system 100 corresponds to or is close to the system of Figure 1. The system 100 of Figure 2 thus corresponds to the system of Figure 1 to l except that the control unit 150 is shown in detail and that the system 100 additionally comprises an input interface 270 and an output interface 280.

According to the embodiment of FIG. 2, the control device 150 has a generation installation 251, a recording installation 252, an operating installation 254, an execution installation 256 and a supply installation 258 The 251 generation facility generates electromagnetic radiation to irradiate body tissue. More specifically, the generation installation 251 generates electromagnetic radiation using a radiation source 110. For this, the generation installation 251 emits the control signal 155 from the radiation source 110. The installation recording 252 records the spectrogram data 145 supplied by the spectrometry device 140. The spectrogram data 145 represents electromagnetic radiation reflected by the body tissue and which the spectrometry device 140 generates. The recording installation 252 transmits the spectrogram data 145 to the execution installation 256 and / or to the operating installation 254.

The operating facility 254 uses the spectrogram data 145 to determine the characteristics of the body tissue. Furthermore, the operating installation 254 transmits the spectrogram data 145 and / or the determined property of the tissue, for example, in the form of an emission signal or an operating signal to the installation. 256. The execution facility 256 compares the recorded spectrogram data 145 and / or the determined property of the tissue with reference data. This data thus represents the reference data of a state of the menstrual cycle or of at least one property of tissue associated with a state of the menstrual cycle. The execution installation 256 transmits a result signal which represents the result of the comparison to the generation installation 258. The generation installation 258 provides an information signal 265 according to the result of the comparison made by the execution facility 256. The information signal 265 represents an indication relating to the state of the menstrual cycle.

According to the exemplary embodiment of FIG. 2, the generation installation 258 supplies the information signal 265 to allow its transmission by the transmission interface 280. The transmission interface 280 receives the information signal 265 or save it. In addition, the transmission interface 280 provides, as a function of the information signal 265, an indication concerning the state of the menstrual cycle in optical and / or haptic acoustic form.

The input interface 270 receives input from a user. The input interface 270 is, for example, a keyboard, a touch keyboard, a touch display, or the like.

FIG. 3 shows a flow diagram of an exemplary embodiment of method 300. Method 300 determines the state of the menstrual cycle using spectrometric analysis of the body tissue. The method 300 is applied to the determination using the control device of FIG. 1 or of FIG. 2 or a similar control apparatus and / or in combination with the system according to FIG. 1 or FIG. 2 or of a analogous system.

According to the determination method 300 in a step 310 an electromagnetic radiation is emitted which irradiates the body tissue. Then, in step 320 we save the spectrogram data. The spectrogram data recorded in the recording step 320 represents a spectrogram obtained using the electromagnetic radiation reflected by the body tissue.

Then, in step 340, the recorded data of the spectrogram is compared with reference data. The reference data thus represent in particular a state of the menstrual cycle. In addition, the method 300 also includes a step 350 of supplying an information signal as a function of the result of the comparison. The information signal is an indication of the state of the menstrual cycle.

The determination method 300 comprises, according to an exemplary embodiment, also a step 330 of exploiting the spectrogram data recorded in the recording step 320 to determine the characteristic of the tissue. In particular, the determination method 300 uses in the exploitation step 330 spectrogram data, to determine as a characteristic of the fabric the water content, the fat content and / or the ratio between the water content and the content as body tissue fat. According to an exemplary embodiment, in the determination method 300, in step 310 an electromagnetic radiation is emitted in the near infrared. According to another exemplary embodiment, in the execution step 340, the comparison is carried out using an analysis of multivariate data. Multivariate data analysis includes, for example, a principal component analysis and / or a regression analysis.

According to an exemplary embodiment, in the recording step 320 in particular user input data is recorded. In execution step 340, the comparison is carried out using the stored user input data. User input data includes data relating to a menstrual date and / or a basal body temperature.

According to an exemplary embodiment, in the operating step 330, a cross validation of the property of the tissue thus determined is made. In addition or as a variant, in execution step 340, a cross validation of the result of the comparison is made.

According to another exemplary embodiment, the determination method 300 also includes a modification step 360 for modifying the reference data by using the property of the tissue determined in the operating step 330 and / or by using the result of the comparison performed in step 340.

With reference to FIGS. 1 to 3, the following are examples of embodiments briefly and / or in summary and in other words the description will be repeated.

According to an exemplary embodiment, the variations of the optical properties of the tissue of the breast 190 are measured in a non-invasive manner by a diffuse reflection in the near infrared in combination with an analysis of multivariate data and the result is used as an indication of the cycle state. The basic measurement operation works, for example, as follows: with the radiation source 110 or a wideband infrared radiation source 110, integrated, the chest 190 is examined. The diffused reflected light 130 is analyzed, for example, with a Savart polariscope or a Fabry-Pérot interferometer or a variable linear filter or a diffraction grating, using the control apparatus 150 to determine its spectral composition. . As the water content contributes significantly to the spectrum measured, the spectra differ depending on the phase of the cycle. A classification into phases of the cycle is made by comparison using the control unit 150 using a multivariate data analysis algorithm based on spectra previously measured as reference data. For this, chemometrics can be applied such as the principle component analysis (PCA) or the regression method (PLS: "partial least squares"). In addition, by a cross validation one can obtain information concerning the security of the classification.

Using the information signal 265 and depending on the information desired, the result can be delivered in graphical form. This can either correspond to a successful classification or in the case of poor quality of the measured spectrum, request a repeat.

According to an exemplary embodiment, a learning phase is provided during which the user performs, for example, daily a measurement and introduces at least the start of menstruation as user input data 275 via the interface. input 270. The larger the database, the more secure the forecast will be by a multivariate data analysis algorithm. After the learning phase, and during regular use, it will also be possible to record the new spectra received or the spectrogram data 145 with successful classification for example, in a database and to continue improving this information. Optionally, the spectroscopic data can be supplemented with other data or user input data 275 entered by the user such as menstruation or basic body temperature to have a larger database. .

140 microspectrometers as opto-electromechanical micro5 components measure the distribution of the spectral intensity of light or electromagnetic radiation. Thanks to their small footprint, they can also be adapted to the field of home electronics, in the form of hand-held devices, or by integration into smartphones.

Claims (14)

1 °) Method (300) for determining the state of a menstrual cycle using a spectrometric analysis of body tissue (190), this method (300) comprising at least the following steps consisting in: emitting (310) electromagnetic radiation (120) to irradiate body tissue (190), recording (320) spectrogram data (145), this data representing the spectrogram (145) generated with the electromagnetic radiation (130) reflected by the body tissue (190), comparing (340) the spectrogram data (145) recorded with reference data, the reference data representing at least one state of the menstrual cycle, and providing (350) an information signal (265) according to the result of the comparison, the information signal (265) representing an indication concerning the state of the menstrual cycle. 2 °) Method (300) according to claim 1, characterized in that the emission (310) of the electromagnetic radiation (120) is done in the near infrared. 3) Method (300) according to one of the preceding claims, characterized in that the comparison step (340) is carried out using an analysis of data with multiple variants, this analysis of data with multiple variants consisting of a main component analysis and / or a regression analysis. 4 °) Method (300) according to one of the preceding claims, characterized in that the recording step (320) consists in recording user input data (275), the comparison (340) consisting in comparing using the stored user input data (275), particularly the user input data (275) representing a menstrual date and / or a basal body temperature. 5 °) Method (300) according to one of the preceding claims, characterized in that in step (340) there is a cross validation of the result of the comparison. 6 °) Method (300) according to one of the preceding claims, characterized by a step (360) of modification of the reference data using the result of the comparison made in the execution step (340). 7 °) Method (300) according to one of the preceding claims, characterized by a step of processing (330) spectrogram data (145) to determine a property of the body tissue (190), in particular in the step (330 ) of exploitation one uses the spectrogram data (145) to determine as property of the tissue, the water content, the fat content and / or the ratio between the water content and the fat content of the body tissue (190) . 8 °) Method (300) according to claim 7, characterized in that in the operating step (330) a cross validation of the determined property of the fabric is carried out and / or characterized by a step (360) of modification of the reference data using the fabric property obtained in the processing step (330). 9 °) control apparatus (150) for carrying out the steps of the method (300) according to any one of claims 1 to 8, in corresponding units (251, 252, 254, 256, 258). 10 °) system (100) comprising at least the following characteristics: the control apparatus (150) according to one of the preceding claims, at least one radiation source (110) for emitting electromagnetic radiation (120), and a spectrometry device (140) providing the spectrogram data (145), the controller (150), the radiation source (110) and the spectrometry device (140) being connected to exchange signals. 11 °) system (100) according to claim 10, characterized in that the spectrometry device (110) is in the form of a microspectrometer, in particular a static spectrometer applying the Fourier transform based on a polariscope of Savart, a tunable Fabry-Pérot interferometer, a variable linear filter and / or a diffraction grating filter. 12 °) system (100) according to one of claims 10 to 11, characterized in that at least the radiation source (110) and the spectrometry device (140) of the system (100) are produced in the form of '' a portable device or part of a portable device. 13 °) System (100) according to one of claims 10 to 12, characterized by an input interface (270) for entering user input data (275). 14 °) computer program for the implementation of the method (300) according to any one of the preceding claims and memory medium readable by a machine containing the recording of the program. 1/2 100