EP3509488A1 - Système d'échantillonnage commandé et sélectif d'air exhalé et procédure de fonctionnement correspondante - Google Patents
Système d'échantillonnage commandé et sélectif d'air exhalé et procédure de fonctionnement correspondanteInfo
- Publication number
- EP3509488A1 EP3509488A1 EP17787616.6A EP17787616A EP3509488A1 EP 3509488 A1 EP3509488 A1 EP 3509488A1 EP 17787616 A EP17787616 A EP 17787616A EP 3509488 A1 EP3509488 A1 EP 3509488A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- air
- exhaled air
- conduit
- machine learning
- fraction
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Withdrawn
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Classifications
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/08—Detecting, measuring or recording devices for evaluating the respiratory organs
- A61B5/097—Devices for facilitating collection of breath or for directing breath into or through measuring devices
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/72—Signal processing specially adapted for physiological signals or for diagnostic purposes
- A61B5/7235—Details of waveform analysis
- A61B5/7264—Classification of physiological signals or data, e.g. using neural networks, statistical classifiers, expert systems or fuzzy systems
- A61B5/7267—Classification of physiological signals or data, e.g. using neural networks, statistical classifiers, expert systems or fuzzy systems involving training the classification device
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
- A61B5/00—Measuring for diagnostic purposes; Identification of persons
- A61B5/74—Details of notification to user or communication with user or patient ; user input means
- A61B5/7475—User input or interface means, e.g. keyboard, pointing device, joystick
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- G—PHYSICS
- G16—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
- G16H—HEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
- G16H20/00—ICT specially adapted for therapies or health-improving plans, e.g. for handling prescriptions, for steering therapy or for monitoring patient compliance
- G16H20/40—ICT specially adapted for therapies or health-improving plans, e.g. for handling prescriptions, for steering therapy or for monitoring patient compliance relating to mechanical, radiation or invasive therapies, e.g. surgery, laser therapy, dialysis or acupuncture
-
- G—PHYSICS
- G16—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
- G16H—HEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
- G16H40/00—ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices
- G16H40/60—ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices for the operation of medical equipment or devices
- G16H40/63—ICT specially adapted for the management or administration of healthcare resources or facilities; ICT specially adapted for the management or operation of medical equipment or devices for the operation of medical equipment or devices for local operation
-
- G—PHYSICS
- G16—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
- G16H—HEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
- G16H50/00—ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics
- G16H50/20—ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics for computer-aided diagnosis, e.g. based on medical expert systems
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- G—PHYSICS
- G16—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
- G16H—HEALTHCARE INFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR THE HANDLING OR PROCESSING OF MEDICAL OR HEALTHCARE DATA
- G16H50/00—ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics
- G16H50/30—ICT specially adapted for medical diagnosis, medical simulation or medical data mining; ICT specially adapted for detecting, monitoring or modelling epidemics or pandemics for calculating health indices; for individual health risk assessment
Definitions
- the present application is concerned with a system, and corresponding method of operation, for selectively and controllably collect pre-determined fractions of exhaled air, for real time and on-line or posterior (offline) analysis of its composition .
- the detection and measurement of exhaled substances may be useful as a diagnostic and prognostic tool in a wide variety of medical conditions to assess different vital organ functions.
- concentration of the substances in the exhaled air varies depending on the respiratory origin of exhaled air to be analysed, including oral and nasal cavities, esophageal air and alveolar air.
- concentration of most of the VOCs present in the exhaled air is very low (parts per billion (ppb v ) or microgram per litre (pg/L) to parts per trillion (ppt v ) or nanogram per litre (ng/L) ) .
- the detection of such small amounts in fractions of exhaled air from different respiratory origins has revealed itself one of new challenges to overcome in the most recent pulmonary breath acquisition/monitor devices.
- Capnography defined as the method of monitoring the concentration or partial pressure of carbon dioxide (CO2) in the respiratory mixture of gases, has some limitations because it varies with (a) the inherent variation of breath composition and concentration of each constituent throughout the breathing cycle; (b) the speed of the breath, which affects the composition of the mixture between alveolar air and dead space air; (c) the depth and frequency of breathing, which control changes from autonomous to conscious breathing, when a person is asked to provide a sample of breath.
- CO2 carbon dioxide
- WO 2015/143384 Al introduces the imposition and control of the respiratory rate dependent on subject characteristics (sex and age) .
- these systems and methods do not comprise an intelligent control software that 'learns' and adapts according with the respiratory characteristics of the subject, as the technology now developed contains.
- it enables a simultaneous analysis of multiple compounds of the exhaled air instead of analysing a single compound at a time as suggested by the mentioned documents.
- the referred documents disclose the possibility of measurement of the temperature of the air of the respiratory airways, the possibility to assess the degree of inflammation of the respiratory airways it is not provided, as it is disclosed in the present application.
- US 2006/0200037 Al and US 2015/065901 Al disclose a physical process of acquisition of exhaled air, comprising a sensor (which measures a characteristic of the exhaled air) , valves and a control module. These components provide a feedback mechanism to assess the state of the operation or a processor to measure the acceptability of the breath signal.
- the technology now developed comprises an intelligent control software that allows the definition of global variables of the process, imposes a respiratory rate to the subject (according to the characteristics of the subject), and synchronizes the breath cycle of the subject with a representative and modelled respiratory cycle, which learns and adapts to the subject's breathing characteristics. Therefore, the precision in the prediction of the instants of exhaled air sampling is increased. Additionally, the technology now developed also allows the analysis of exhaled air compounds in real time, by coupling the device to an analytic analyser .
- the system developed includes a heating element of the exhaled air conducting tubes in order to prevent the adsorption of compounds to the walls of the device; and also includes the assessment to the degree of inflammation of the respiratory airways based on the measurement of the temperature of the exhaled air.
- the present application describes a system for controlled and selective sampling of exhaled air comprising:
- a portable sampling device comprising at least one air sensor and a diverter valve
- a hardware module connected to the portable sampling device, configured to receive, process and transmit data from the at least one air sensor, and to actuate the diverter valve;
- the portable sampling device has a t-shaped internal cavity formed by:
- a longitudinal conduit comprising an air sensor conduit in its inlet port wherein the at least one air sensor is installed, and an elimination air conduit in its outlet port;
- a vertical conduit connected to the longitudinal conduit, comprising an air sampling conduit wherein the diverter valve is installed, and wherein the outlet of the vertical conduit is connected to air collected means;
- the portable sampling device comprises a heating component covering the internal surfaces of the air sensor conduit air, the elimination air conduit and the air sampling conduit.
- the air collected means are of a reservoir type or analyser type.
- a disposable non- rebreathable mouthpiece is attached to the longitudinal inlet port .
- the air sensor is a temperature sensor.
- the hardware module comprises:
- a signal condition circuit configured to receive and process the signal from the air sensor
- a processing and communication unit configured to manage the acquisition and the signal communication to the processing device;
- An automatic flow switching circuit configured to operate the diverter valve of the portable sampling device.
- the present application also describes a method of operating the system for controlling and selective sampling of exhaled air previously described, characterized by being independent of the subject's C02 metabolic production and comprising the following steps :
- step b) Acquisition of exhaled air through disposable and non- rebreathable mouthpiece, for at least one respiratory cycle and until it is regular, according with a rhythm previously defined by the said machine learning algorithm and demonstrated by a graphical interface, based on the said subject-related variables, collected in step b) ;
- Said unit actuates on a valve of the device that when closed conducts the exhaled air fraction of interest to an elimination outlet of said portable sampling device, and when open conducts the exhaled air fraction of interest to a sampling outlet of said device;
- the exhaled air fraction of interest to be collected has several origins, namely mouth, nasal, esophageal and alveolar air.
- the exhaled air fraction of interest is collected and derived from a single respiratory cycle being available for real time analysis by the analytical equipment.
- the exhaled air fraction of interested is collected and derived from multiple respiratory cycles being conducted to a sample reservoir.
- the present application also describes the use of the system now developed for collecting the exhaled air fraction of interest for analysis of its chemical composition.
- the present application also describes the use of the system now developed for detection of the inflammatory state of the respiratory airways through the measurement of the temperature of the exhaled air by the temperature sensor during a respiratory cycle.
- the present application relates to a system and respective method of operation, for selectively and controllably collect exhaled air from different respiratory origins, namely, but not limited to, oral cavity, esophageal air and alveolar air, independently of the subject's metabolic production of CO2.
- the air fraction is available for real time analysis of its chemical composition or simply collected for future analysis.
- the system is comprised by two attachable modules: the portable sampling device and the hardware module, controlled by a machine learning software loaded on a processing device.
- the portable sampling device is comprised by a T-shaped internal cavity which can be sized and shaped to enclose at least an air sensor and a diverter valve. Moreover, the portable sampling device can enclose various air conduits, such as, but not limited to, an air sensor conduit, an elimination air conduit, and an air sampling conduit.
- a disposable non-rebreathable mouthpiece is attached to a longitudinal inlet of the portable sampling device.
- the said air sensor of the portable sampling device is configured to directly or indirectly detect the different phases of the respiratory cycle of a subject, by using several types of sensors, such as, but not limited to, flow sensors, airway pressure sensors, capnometers, breath sound sensors and thermal sensors. Due to the possibility of correlating the variation of temperature of the exhaled air with the air flow of exhaled air and, since the temperature is a marker of pathological factors and important as a measure of physiological events, the portable sampling device can comprise a sensor of temperature. Depending on the variation of temperature of the exhaled air recorded in the sensor of temperature of the portable sampling device a different output will be produced. It is also configured to be capable of being connected to the portable sampling device in the air sensor conduit and its replacement is allowed after a significant number of utilizations, in order to maintain the full capacities of the system.
- sensors such as, but not limited to, flow sensors, airway pressure sensors, capnometers, breath sound sensors and thermal sensors. Due to the possibility of correlating the variation of temperature of the exhaled air with the air flow of
- the valve of the portable sampling device can be configured to be responsive to a gate signal transmitted by the hardware module, indicated by the machine learning software, and to automatically change its position according to such gate signal.
- the type of automatic valve which can be used for this purpose may vary. Since the hardware module of the system is an electronic device, a solenoid valve can be electromechanically actuated by controlling an electric current flowing through a coil, which switches the output of the exhaled air flow between two valve ports. It can be appreciated that this technology is not limited in this regard and any suitable electrical or mechanical valve can be used to divert the exhaled air in the portable sampling device. By default, the flow is directed to the normally open port when the said valve is not operated.
- the said valve can selectively conduct a predetermined fraction of the flow of exhaled air passing through the longitudinal elimination air conduit to the respective elimination outlet of the portable sampling device, or through the air sampling conduit to the vertical outlet.
- the valve is in position a, the flow of exhaled air which circulates through the sensor air conduit, is then directed through the longitudinal conduit and exits through the longitudinal elimination outlet of the portable sampling device. Also if the valve is in position a, the flow of exhaled air passing by the sampling air conduit, bellow the valve, is inexistent.
- the flow of exhaled air circulates through the sensor air conduit and is then diverted through the sampling air conduit vertically disposed, where the fraction of the flow of exhaled air can either be collected in the air sample reservoir or directly and real-time analyzed in the analytical analyser coupled to the system.
- the analytical analyzer can be selected from the group of: chemical, electrical, optical and chromatographic analyzers. It can be noted that the system is not limited in this regard and any suitable analyzer can be used to precisely determine the chemical composition of exhaled air samples.
- the portable sampling device also comprises a heating component covering its internal surface.
- the said heating component is configured to actuate during the overall process of acquisition of exhaled air in order to avoid particle condensation and the adsorption of exhaled air constituents to the internal walls of the air conduits of the portable sampling device.
- the hardware module is configured to control the overall system by modeling the signal acquired by the air sensor and determining the actions to be taken in order to affect the direction of the exhaled air, controlled by the position of the valve.
- the said hardware module is, thus, responsive to the air sensor and to the machine learning software of the system since it receives, processes and transmits signals between the remaining components of the system.
- This hardware module comprises:
- a signal conditioning circuit configured to receive and process the signal from the air sensor of the said portable sampling device, in order to allow a better use of the analog digital converter (ADC) by obtaining an amplified signal;
- ADC analog digital converter
- a processing and communication unit which manages the acquisition and the signal communication to the processing device where the machine learning software is loaded;
- the processing and communication unit is configured to create a gate signal when the digital output of the ADC transitions to a high logical level, becoming the transistor of the automatic flow switching circuit in saturation, allowing the passage of current to the valve and causing the flow of air to pass through the air sampling conduit. If the ADC digital output is at a low logical level, the transistor is cut and there is no current flow to the valve, which implies that the air flow exits through the elimination air conduit.
- the system also includes a machine learning software which is responsive to the hardware module and comprises a graphical interface to interact with the sub ect/operator, allowing the definition of global features and assessment of the state of the operation.
- Said machine learning software also includes an internal algorithm to control the device functioning and to determine the precise moment for selectively sampling exhaled air, through a machine learning process.
- the algorithm implemented in the machine learning software of the system comprises a digital filter in order to acquire the signal obtained from the air sensor with as minimal noise as possible, ensuring, at the same time, no loss of information.
- the algorithm is configured to: - Measure the respiratory flow, and to identify the endogenous fraction of the exhaled air, independently of the carbon dioxide metabolism of the subject, through the air sensor's processed signal, thereby calculating the flow of exhaled air ;
- the machine learning process related with the system is based on the continuous calculation and saving of the average time of expiration values, allowing the prediction of the time of occurrence of a new expiration and, consequently, the prediction of the precise time-frame for the acquisition of the fraction of exhaled air to sample.
- This ability coupled with the synchronization mechanism, makes said system capable of interpreting different breathing rhythms from subject to subject and allows a more precise and less time consuming acquisition of the predetermined portion of exhaled air.
- the machine learning software is configured to transmit that information to the hardware module which operates on the valve, through a gate signal, as described above.
- the graphical interface of the machine learning software can be used to define the global operating variables such as, but not limited to, the fraction of exhaled air to collect/analyze, the percentage of aperture of the valve and the number of cycles used to determine the average time of expiration.
- Said graphical interface of the machine learning software (16) also allows defining subject-related variables, such as, but not limited to genre, age and physiological conditions (seated, lying down or under effort trial), to start and stop the acquisition process and to save data for later analysis.
- the graphical interface also provides simultaneously feedback indicators for communicating with the subject/operator. Said feedback indicators represent a central part of the present technology, since the breathing rhythm can be followed by the subject, according to the global subject- related variables previously defined, and the state of functioning of the valve (open or closed) .
- This information can be displayed in an animated way (for the breath cycle synchronization) or graphically, such as the treated signal obtained by the air sensor, that can be used as a feedback indicator.
- this technology is not limited in this regard and other types of indicators can be used with this purpose.
- the operator first defines the global operating and the subject-related variables.
- the global operating variables include, but are not limited to, the selection of the fraction of exhaled air to collect/analyze (mouth, nasal, esophageal or alveolar air) ; the percentage of aperture of the valve; and the number of respiratory cycles for determining the average time of expiration by the algorithm.
- the said subject- related variables include, but are not limited to, the genre, age and subject physiological conditions (seated, lying down or under effort trial) . The subject is then asked to exhale into the non- rebreathable mouthpiece, which is already attached to the portable sampling device.
- the operator must verify that the subject's breathing rhythm follows a regular behavior, according to the breathing pace, previously defined by the subject-related variables, and displayed in the graphical interface.
- the electrical signal produced by the air sensor is then processed and transmitted by the hardware module to the machine learning algorithm.
- Said algorithm determines a set of parameters, through the analysis of the signal produced by the air sensor and transmitted by the hardware module.
- the said parameters are critical for the procedure of sampling the exhaled air fraction of interest and include (i) the respiratory flow, with identification of the endogenous fraction of exhaled air independently of carbon dioxide metabolism of the subject; (ii) the exhaled air flow; (iii) the breathing frequency and (iv) the average time of the respiratory cycle, which comprises the inspiratory and expiratory phases.
- the synchronization between the breath cycle of the subject and a representative and modeled breath cycle of the algorithm is evaluated by the machine learning algorithm. If this synchronization does not occur during three completed respiratory cycles, the subject is informed by the graphical interface so that the subject corrects his breathing cycle, by imposing a breathing rhythm. As soon as the said synchronization occurs, the average time of expiration is calculated by the machine learning algorithm, for the previously predefined number of cycles, enabling the process of machine learning and the prediction of the exact moments for exhaled air fraction collection. The prediction of said exact moments for the collection of the fraction of interest of exhaled air is related with the region of interest, of the subject's respiratory signal, during exhalation.
- regions of interest for collection of the exhaled air fraction of interest are defined according with a percentage of the subject's exhalation during its respiratory cycle.
- the feedback indicator "state of aperture of the valve (closed or open) " is communicated to the operator.
- the machine learning algorithm then transmits the moments of exhaled air acquisition to the processing and communication unit of the hardware module, which actuates on the automatic flow switching circuit by generating and transmitting a gate signal to the valve, for a period of time dependent on the fraction of interest of exhaled air to collect.
- the valve can then selectively gate the fraction of interest of the exhaled air flow.
- the said fraction of interest of the exhaled air flow can be stored in an air collection reservoir or directly analyzed in the analytical analyzer.
- the presence of chemical compounds in the fraction of interest of exhaled air can be detected, whether offline or in real time. Then, the operator can optionally write comments that have elapsed during the acquisition process and save them along with the acquisition data.
- FIGURES 1 and 2 illustrate a schematic view of the system for controlled and selective sampling of exhaled air, in which (1) represents the system, (2) the mouthpiece, (3) the portable sampling device which comprises: the inlet (4), the air sensor (5), the air sensor conduit (6) , the elimination air conduit (7) , the elimination outlet (8) , the valve (9) , the air sampling conduit (10) and the sampling outlet (11) .
- the hardware module of the device (12) comprises: the signal conditioning circuit (13), the processing and communication unit (14) and the automatic flow switching circuit (15) .
- the machine learning software (16) the analytical analyzer (17) , the collection reservoir (18) and the heating component (19) .
- FIGURE 3 illustrates a schematic view of the method for selectively collecting exhaled air, wherein the reference signs represents the steps of:
- FIGURE 4 shows a representative graph of the synchronization between an acquired respiratory signal of a subject with a normal breathing rhythm (32) , with the signal of the representative and modeled respiratory cycle (33) by the machine learning software (16) algorithm, obtained by the subject's breathing pace imposition and the machine learning mechanism.
- FIGURE 4 and as example, it is also represented the time-frame related with alveolar air collection (34) .
- the present application relates to a system (1) and respective method of operation, for selectively and controllably collect exhaled air coming from different respiratory origins, namely, but not limited to, oral and nasal cavities, esophageal air and alveolar air, independently of the metabolic production of CO2.
- the exhaled air fraction of interest is available for real time analysis of its chemical composition or simply collected for future analysis, without adapting the configuration of the system.
- the system (1) is comprised by two attachable modules: the portable sampling device (3) and the hardware module (12) , controlled by a machine learning software (16) loaded on a processing device.
- the portable sampling device (3) includes a T-shaped internal cavity which can be sized and shaped to enclose at least an air sensor (5) and a diverter valve (9) . Moreover, the portable sampling device (3) can enclose various air conduits, such as, but not limited to, an air sensor conduit (6) , an elimination air conduit (7) , and an air sample conduit (10) .
- a disposable non- rebreathable mouthpiece (2) is attached to a longitudinal inlet
- the said air sensor (5) of the portable sampling device (3) is configured to indirectly detect a flow of exhaled air from a subject, trough temperature.
- the said air sensor (5) of the portable sampling device (3) is configured to indirectly detect a flow of exhaled air from a subject, trough temperature.
- (5) can be, but is not limited to, a coated precision solid state temperature sensor, able to read temperatures ranging from 0° to 70°C.
- the valve (9) of the portable sampling device (3) can be configured to be responsive to a gate signal transmitted by the hardware module (12) by indication of the machine learning software (16) and to automatically change its position according to such gate signal.
- the portable sampling device (3) comprises a solenoid valve (9) which has a common input and two outputs: one normally closed and another normally open. By default, the flow is directed to the normally open port when the said valve (9) is not operated.
- the intelligent software (16) algorithm determines the change of position of said valve (9) , from the position a (closed) to the position b (open) , the said valve (9) can selectively conduct a predetermined fraction of the flow of exhaled air passing through the longitudinal elimination air conduit (7) to the respective sampling outlet (8) of the portable sampling device (3) or through the air sampling conduit (10) to the vertical outlet (11) .
- the valve (9) is in position a, the flow of exhaled air which circulates through the sensor air conduit (6) , is then directed through the longitudinal conduit (7) and exits through the longitudinal elimination outlet (8) of the portable sampling device (3) .
- valve (9) is in position a, the flow of exhaled air passing by the sampling air conduit (10), bellow the valve (9), is inexistent.
- the valve (9) is in position £>, the flow of exhaled air circulates through the sensor air conduit (6) and is then diverted through the sampling air conduit (10) vertically disposed, where the fraction of the flow of exhaled air can either be collected in the air sample reservoir (18) or directly and real-time analyzed in the analytical analyser (17) coupled to the system (1) .
- the portable sampling device (3) also comprises a heating component (19) covering its internal surface.
- the said heating component (19) is configured to actuate during the overall process of acquisition of exhaled air.
- the hardware module (12) is configured to control the overall system (1) by modeling the signal acquired by the temperature sensor (5) and determining the actions to be taken in order to affect the direction of the exhaled air, controlled by the position of the valve (9) .
- the said hardware module (12) is, thus, responsive to the temperature sensor (5) and to the machine learning software (16) of the system (1) since it receives, processes and transmits signals between the remaining components of the system (1) .
- This hardware module (12) comprises:
- a signal conditioning circuit (13) configured to receive and process the signal from the temperature sensor (5) of the said portable sampling device (3) , in order to allow a better use of the analog digital converter (ADC) by obtaining an amplified signal;
- a processing and communication unit (14) which manages the acquisition and the signal communication to the processing device where is loaded the machine learning software (16) ;
- the processing and communication unit (14) is configured to create a gate signal when the digital output of the ADC transitions to a high logical level, becoming the transistor of the automatic flow switching circuit (15) in saturation, allowing the passage of current to the valve (9) and causing the flow of air to pass through the air sampling conduit (10) . If the ADC digital output is at a low logical level, the transistor is cut and there is no current flow to the valve (9) , which implies that the air flow exits through the elimination air conduit (7) .
- the hardware module (12) also includes a connection with the portable sampling device (3) and with the processing device where the corresponded machine learning software (16) is loaded.
- the system (1) also includes a machine learning software (16) which is responsive to the hardware module (12) and comprises a graphical interface to interact with the subject/operator, allowing the definition of global features and assessment of the state of the operation, and an internal algorithm to control the system (1) functioning and to determine the precise moment for selectively sampling exhaled air.
- a machine learning software (16) which is responsive to the hardware module (12) and comprises a graphical interface to interact with the subject/operator, allowing the definition of global features and assessment of the state of the operation, and an internal algorithm to control the system (1) functioning and to determine the precise moment for selectively sampling exhaled air.
- the algorithm implemented in the machine learning software (16) of the system (1) comprises a digital filter in order to acquire the temperature signal with as minimal noise as possible, ensuring, at the same time, no loss of information.
- the algorithm is configured to:
- the machine learning process related with the system (1) is based on the continuous calculation and saving of the average time of expiration values, allowing the prediction of the time of occurrence of a new expiration and, consequently, the prediction of the precise time-frame for the acquisition of the fraction of exhaled air to sample.
- the machine learning software (16) is configured to transmit that information to the hardware module (12) which operates on the valve (9), through a gate signal, as described above .
- the graphical interface of the machine learning software (16) can be used to define the global variables of the operation such as, but not limited to,
- the graphical interface of the machine learning software (16) also allows defining subject variables, such as, but not limited to genre, age and physiological conditions (seated, lying down or under effort trial), to start and stop the acquisition process and to keep data for later analysis.
- the graphical interface also provides simultaneously feedback indicators for communicating with the subject/operator, either showing the breath cycle synchronization animation or the treated signal obtained by the temperature sensor (5) .
- the operation procedure starts by connecting all components to a processing device where the machine learning software (16) is loaded.
- the graphical interface of the machine learning software (16) must then be initiated.
- the operator first defines the global operating and sub ect-related variables (20).
- the global operating variables include the selection of the fraction of exhaled air to collect/analyze (mouth, nasal, esophageal or alveolar air), the percentage of aperture of the valve (9) and the number of respiratory cycles for determining the average time of expiration by the algorithm.
- the subject-related variables include genre, age and subject physiological conditions (seated, lying down or under effort trial) . The subject is then asked to exhale (21) into the non-rebreathable mouthpiece (2) , which is already attached to the portable sampling device (3) .
- the operator must verify that the subject's breathing rhythm follows a regular behavior, according to the breathing pace, previously defined by the subject-dependent variables, and displayed in the graphical interface of the machine learning software (16) .
- the temperature of the exhaled air is sensed by the temperature sensor (5) in the form of an electrical signal (22) which is then processed and transmitted by the hardware module (12) to the machine learning software (16) .
- the algorithm of the machine learning software (16) determines a set of parameters (23) , through the analysis of the signal produced by the sensor of temperature (5) and transmitted by the hardware module (12) .
- the said parameters are critical for the procedure of sampling the exhaled air fraction of interest and include (i) the respiratory flow, with identification of the endogenous fraction of exhaled air independently of carbon dioxide metabolism of the individual; (ii) the exhaled air flow; (iii) the breathing freguency and (iv) the average time of the respiratory cycle which comprises the inspiratory and expiratory phases .
- the synchronization between the breath cycle of the subject (32) and a representative and modeled breath cycle (33) of the algorithm is evaluated (24) by the machine learning software (16) . If this synchronization does not occur during three completed respiratory cycles, the subject is informed by the graphical interface (25) so that the subject corrects his breathing cycle, by imposing a breath rhythm. As soon as the said synchronization occurs, the average time of expiration is calculated (26) by the algorithm of the machine learning software (16) for three respiratory cycles enabling the process of machine learning and the prediction of the exact moments for exhaled air fraction acquisition (26) . As example, the prediction of said exact moments for alveolar air collection is related with the region of interest (34) of the subject's respiratory signal (32), during exhalation.
- the feedback indicator "state of aperture of the valve" (close or open) is communicated to the operator.
- the machine learning software (16) then transmits the moments of exhaled air acquisition to the processing and communication unit (14) of the hardware module (12) which actuates on the automatic flow switching circuit (15) by generating and transmitting a gate signal to the valve (9) for a period of time dependent on the fraction of exhaled air to collect (27) .
- the valve (9) can then selectively gate the fraction of interest of the exhaled air flow.
- the said fraction of interest of the exhaled air flow can then be stored in an air collection reservoir (29) , or directly analyzed in the analytical analyzer (30) .
- the presence of chemical compounds in the fraction of interest of exhaled air can be detected (31) whether offline (29) or in real time (30) . Then, the operator can optionally write comments that have elapsed during the acquisition process and save them along with the acquisition data .
- compositional analysis of exhaled air fraction samples maybe linked to a broad diversity of diseases that include: chronic inflammatory respiratory and lung diseases, cancer, diabetes, kidney dysfunction, liver impairment, intoxications, viral or bacterial infections, intestinal diseases among others.
- the evaluation of temperature of the exhaled air during a single or multiple respiratory cycles allows the detection of the inflammatory state of the respiratory airways of the sub ect .
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Abstract
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
PT109617A PT109617A (pt) | 2016-09-12 | 2016-09-12 | Sistema para recolha controlada e seletiva de ar exalado e respetivo método de operação |
PCT/IB2017/055322 WO2018047058A1 (fr) | 2016-09-12 | 2017-09-05 | Système d'échantillonnage commandé et sélectif d'air exhalé et procédure de fonctionnement correspondante |
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EP3509488A1 true EP3509488A1 (fr) | 2019-07-17 |
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EP17787616.6A Withdrawn EP3509488A1 (fr) | 2016-09-12 | 2017-09-05 | Système d'échantillonnage commandé et sélectif d'air exhalé et procédure de fonctionnement correspondante |
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EP (1) | EP3509488A1 (fr) |
PT (1) | PT109617A (fr) |
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US12029548B2 (en) * | 2018-07-02 | 2024-07-09 | Purdue Research Foundation | Device for selective collection and condensation of exhaled breath |
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US7308894B2 (en) * | 1998-06-03 | 2007-12-18 | Scott Laboratories, Inc. | Apparatuses and methods for providing a conscious patient relief from pain and anxiety associated with medical or surgical procedures according to appropriate clinical heuristics |
EP1099102B1 (fr) * | 1998-06-19 | 2008-05-07 | California Institute Of Technology | Utilisation d'une olfactometrie artificielle pour detecter le niveau de presence de substances a analyser |
US20060200037A1 (en) | 2005-03-02 | 2006-09-07 | Falasco Marianne R | System and method for selectively collecting exhaled air |
US7914460B2 (en) * | 2006-08-15 | 2011-03-29 | University Of Florida Research Foundation, Inc. | Condensate glucose analyzer |
MX2015008838A (es) | 2013-01-08 | 2015-12-15 | Capnia Inc | Seleccion de respiracion para analisis. |
SG11201601440QA (en) | 2013-08-30 | 2016-03-30 | Capnia Inc | Universal breath analysis sampling device |
US20150265184A1 (en) | 2014-03-20 | 2015-09-24 | Capnia, Inc. | Selection, segmentation and analysis of exhaled breath for airway disorders assessment |
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2016
- 2016-09-12 PT PT109617A patent/PT109617A/pt unknown
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- 2017-09-05 WO PCT/IB2017/055322 patent/WO2018047058A1/fr unknown
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WO2018047058A1 (fr) | 2018-03-15 |
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