WO2010027256A1 - Method and system for quantitative determination of a component in the air exhaled by a user - Google Patents

Method and system for quantitative determination of a component in the air exhaled by a user Download PDF

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Publication number
WO2010027256A1
WO2010027256A1 PCT/NL2009/050514 NL2009050514W WO2010027256A1 WO 2010027256 A1 WO2010027256 A1 WO 2010027256A1 NL 2009050514 W NL2009050514 W NL 2009050514W WO 2010027256 A1 WO2010027256 A1 WO 2010027256A1
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WO
WIPO (PCT)
Prior art keywords
air
component
percentage
user
exhaled
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Application number
PCT/NL2009/050514
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French (fr)
Inventor
Tom Johannes Marinus Maria Elsten
Marcus Benedictus Hoppenbrouwers
Merijn Wijnen
Original Assignee
Nederlandse Organisatie Voor Toegepast-Natuurwetenschappelijk Onderzoek Tno
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Priority claimed from EP08164033A external-priority patent/EP2163198A1/en
Application filed by Nederlandse Organisatie Voor Toegepast-Natuurwetenschappelijk Onderzoek Tno filed Critical Nederlandse Organisatie Voor Toegepast-Natuurwetenschappelijk Onderzoek Tno
Publication of WO2010027256A1 publication Critical patent/WO2010027256A1/en

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    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/08Detecting, measuring or recording devices for evaluating the respiratory organs
    • A61B5/097Devices for facilitating collection of breath or for directing breath into or through measuring devices
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B5/00Measuring for diagnostic purposes; Identification of persons
    • A61B5/08Detecting, measuring or recording devices for evaluating the respiratory organs
    • A61B5/083Measuring rate of metabolism by using breath test, e.g. measuring rate of oxygen consumption
    • AHUMAN NECESSITIES
    • A61MEDICAL OR VETERINARY SCIENCE; HYGIENE
    • A61BDIAGNOSIS; SURGERY; IDENTIFICATION
    • A61B2560/00Constructional details of operational features of apparatus; Accessories for medical measuring apparatus
    • A61B2560/02Operational features
    • A61B2560/0242Operational features adapted to measure environmental factors, e.g. temperature, pollution

Definitions

  • the present invention refers to quantitative determination of a component like oxygen (O2), carbon dioxide (CO2) etc. in the air exhaled by a user, e.g. an athlete, often indicated as ergospirometry.
  • a component like oxygen (O2), carbon dioxide (CO2) etc.
  • Ergospirometry tests relate to concentrations of components such as oxygen (O2) and carbon dioxide (CO2), from in- and expired breath, to the physical capacities of e.g. an athlete. Many tests are done under laboratory conditions. Measuring an athlete under sport specific conditions would of course give more representative results.
  • O2 oxygen
  • CO2 carbon dioxide
  • An embodiment of a portable breathing monitor is known from EP 0 196 396.
  • the known portable breathing monitor comprises a control module adapted for realizing sampling of the breathing volume and of the oxygen content and a transmitter unit adapted for sending the signals to a suitable central processing unit.
  • One aim of this invention is to provide maskless measuring by means of a novel method and system for sampling and processing the expired air of a user (e.g. a sportsman/ woman) which enables the use of a dedicated housing for capturing the expired air. In this way various breathing properties of an athlete can be measured while performing real sports activities.
  • a user e.g. a sportsman/ woman
  • Another aim is to provide a maskless (e.g.) O2/CO2 measurement system that can accurately measure breath gas concentrations while moving at a speeds of up to 15 m/s; the system aims to be able to account for head winds of up to wind force 4 (6 m/s).
  • a maskless (e.g.) O2/CO2 measurement system that can accurately measure breath gas concentrations while moving at a speeds of up to 15 m/s; the system aims to be able to account for head winds of up to wind force 4 (6 m/s).
  • Yet another aim is to provide a compact and convenient system in order to minimize any restrictions to the athlete.
  • the invention is largely based on the understanding that when a mixture of exhalation air and ambient air (“false air”) could be used for sensing the relevant air component (O2 or CO2) and the mixture relation of the collected exhalation air and ambient air (or, in other words, the percentage of exhalation air in the air mixture) could be determined, this would open the possibility to use a maskless exhalation air collector, i.e. an air collector which does not need to be protected against inflow of ambient air.
  • said mixture relation of the exhalation and ambient air or percentage of exhalation air in the air mixture is derived from the measured relative humidity (RH) of the air mixture, where the RH of the exhalation air and the RH of the ambient air are estimated or measured (presumed or predetermined) beforehand.
  • RH relative humidity
  • the RH of the exhalation air has a rather constant value, lying at about 100% (exact values are known from the literature) while the RH of the ambient air can easily be measured.
  • the present invention thus refers to a method for quantitative determination of a component (e.g.
  • RHa is the measured or predetermined relative humidity of the ambient air
  • Cs is the determined percentage of said component in the air sample
  • Ca is the presumed or predetermined percentage of the component in the ambient air.
  • Figure 1 shows an exemplary embodiment in two views of a system which is arranged to perform the method according to invention.
  • the exemplary embodiment of the system for performing the method discussed above comprises collection means for collecting an air sample containing air exhaled by a user and ambient air in an unknown ratio.
  • those air sample collection means are formed by an air collector (or air sampler) 1 which can be put before the user's mouth/nose area (not shown), at a certain distance, thus preventing that the collector hinders the user's breathing.
  • At least a substantial part of the user's exhalation air is collected by the collector 1. Due to air turbulences etc. the air collector does not only collect the user's exhalation air, but also some ambient air; so the air sample contains an unknown percentage of air exhaled by the user and an unknown percentage of ambient air in an unknown ratio.
  • the collector 1 comprises means for determining the relative humidity RHs of the collected air sample, formed by an RH sensor 2.
  • RHa is the predetermined or measured relative humidity of the ambient air ( ⁇ 20%) and RHe is the presumed relative humidity of the exhaled air ( ⁇ 100%).
  • RHa is the predetermined or measured relative humidity of the ambient air ( ⁇ 20%) and RHe is the presumed relative humidity of the exhaled air ( ⁇ 100%).
  • RH value could be determined beforehand, either by means of the same air collector 1 or another one, after which the RHa and RHe values could be input into the processor 3.
  • the collector 1 moreover, comprises means for determining (measuring) the percentage Cs of CO2 in the air sample, which is formed by a CO2 sensor 4.
  • the requested CO2 percentage in the exhaled air is determined based on the measured RH and the CO2 percentage of the air sample, which is a mixture of exhalation air and ambient air.
  • the thus determined CO2 percentage in the exhaled air could be transmitted (since the athlete will be running, cycling etc.) by means of a radio transmitter 5 to a logging and/or processing system in e.g. a following car.
  • the O2 percentage or percentage of other components in the exhalation air can be determined in the same way.
  • the CO2 sensor 4 has to be replaced by an O2 sensor or an O2 sensor 6 is added to the collector 1, as shown in figure 1.
  • Processing of the O2 related values can also be performed by the processor 3. It is presumed that the O2 percentage in ambient air (Cs for O2) is 20%). Of course by adding other gas sensors, other breath components can be measured.
  • the measured relative humidity of the air sample is 60%;
  • the measured relative humidity of the air sample is 100%
  • the exemplary collector 1 comprises an exhalation inlet 7, in operation to be placed about in front of the user's mouth/nose, preferably in a position wherein the user will be least hindered by the collector.
  • exhalation outlets 8 are provided, connected to the exhalation inlet 7 via connection members 9.
  • the exhalation outlets 8 preferably point into the same direction, (see figure) contrary to the user's movement direction, causing that the flow of exhalation air through the collector is promoted by the draught which occurs at the outlets 8 due to the slip stream of the ambient air during movement of the user/athlete.
  • a small exhaust fan or the like could be provided to support or boost the flow of exhalation air.

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  • Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Biomedical Technology (AREA)
  • Heart & Thoracic Surgery (AREA)
  • Pulmonology (AREA)
  • Physics & Mathematics (AREA)
  • Veterinary Medicine (AREA)
  • Biophysics (AREA)
  • Pathology (AREA)
  • Engineering & Computer Science (AREA)
  • Public Health (AREA)
  • Physiology (AREA)
  • Medical Informatics (AREA)
  • Molecular Biology (AREA)
  • Surgery (AREA)
  • Animal Behavior & Ethology (AREA)
  • General Health & Medical Sciences (AREA)
  • Emergency Medicine (AREA)
  • Obesity (AREA)
  • Investigating Or Analysing Biological Materials (AREA)

Abstract

Method for quantitative determination of a component, e.g. CO2 and/or O2 in the air exhaled by a user, comprising collecting an air sample containing the exhaled air and ambient air and determining the relative humidity RHs of the air sample. Next, assessing a factor p according to the formula (I) p = (RHs – RHa) / (RHe – RHa), where RHs is the determined humidity of the air sample, RHa is the presumed humidity of the ambient air and RHe of the exhaled air. Then determining the percentage Cs of said component in the air sample, followed by assessing the percentage Ce of said component to be assigned to the exhaled air by applying the formula (II) Ce = ((Cs – Ca) / p) + Ca, where Cs is the determined percentage of said component in the air sample and Ca is the presumed percentage of the component in the ambient air. A system for performing the method comprises collection means (1) for collecting an air sample containing exhaled air and ambient air, means (2) for determining the humidity RHs of the collected air sample, means (3) for assessing said factor p according to formula I, means (4, 6) for determining the percentage Cs of said component in the air sample, and means (3) for assessing the percentage Ce of said component to be assigned to the exhaled air from formula II. The collection means (1) may comprise an exhalation inlet (7), to be placed about in front of the user's mouth, and one or more exhalation outlets (8), pointing into the same direction as the exhalation inlet.

Description

Title: Method and system for quantitative determination of a component in the air exhaled by a user
The present invention refers to quantitative determination of a component like oxygen (O2), carbon dioxide (CO2) etc. in the air exhaled by a user, e.g. an athlete, often indicated as ergospirometry.
Ergospirometry tests relate to concentrations of components such as oxygen (O2) and carbon dioxide (CO2), from in- and expired breath, to the physical capacities of e.g. an athlete. Many tests are done under laboratory conditions. Measuring an athlete under sport specific conditions would of course give more representative results.
Mobile measurement systems exist; their limitation is the fact that they use a mask or mouth piece to capture and analyze the in- and expired air. Masks (i.e. largely the user's mouth/nose) are considered to be awkward and restrain an athlete in his natural breathing pattern.
An embodiment of a portable breathing monitor is known from EP 0 196 396. The known portable breathing monitor comprises a control module adapted for realizing sampling of the breathing volume and of the oxygen content and a transmitter unit adapted for sending the signals to a suitable central processing unit.
It is a disadvantage of the known portable breathing monitor that it is conceived to be mounted on a mask, which may be inconvenient in some circumstances and may unnecessary increase production costs.
One aim of this invention is to provide maskless measuring by means of a novel method and system for sampling and processing the expired air of a user (e.g. a sportsman/woman) which enables the use of a dedicated housing for capturing the expired air. In this way various breathing properties of an athlete can be measured while performing real sports activities.
Another aim is to provide a maskless (e.g.) O2/CO2 measurement system that can accurately measure breath gas concentrations while moving at a speeds of up to 15 m/s; the system aims to be able to account for head winds of up to wind force 4 (6 m/s).
Yet another aim is to provide a compact and convenient system in order to minimize any restrictions to the athlete. The invention is largely based on the understanding that when a mixture of exhalation air and ambient air ("false air") could be used for sensing the relevant air component (O2 or CO2) and the mixture relation of the collected exhalation air and ambient air (or, in other words, the percentage of exhalation air in the air mixture) could be determined, this would open the possibility to use a maskless exhalation air collector, i.e. an air collector which does not need to be protected against inflow of ambient air. According to the invention said mixture relation of the exhalation and ambient air or percentage of exhalation air in the air mixture is derived from the measured relative humidity (RH) of the air mixture, where the RH of the exhalation air and the RH of the ambient air are estimated or measured (presumed or predetermined) beforehand. An interesting point regarding to this is that the RH of the exhalation air has a rather constant value, lying at about 100% (exact values are known from the literature) while the RH of the ambient air can easily be measured. The present invention thus refers to a method for quantitative determination of a component (e.g. (O2 or CO2) in the air exhaled by a user, comprising next steps: collecting an air sample containing air exhaled by the user and ambient air (surrounding the user) in an unknown ratio, - determining the relative humidity RHs of the collected air sample; assessing a factor p representing the relative contribution of the exhalation air in the collected air sample, based on relative humidity values according to formula I: p = (RHs - RHa) / (RHe - RHa) where RHs is the determined relative humidity of the air sample,
RHa is the measured or predetermined relative humidity of the ambient air and
RHe is the presumed or predetermined relative humidity of the exhaled air; determining (e.g. measured by a relevant sensor) the percentage (or amount) Cs of said component in the air sample; assessing the percentage Ce of said component to be assigned to the air exhaled by the user from formula II: Ce = ((Cs - Ca) / p) + Ca where
Cs is the determined percentage of said component in the air sample,
Ca is the presumed or predetermined percentage of the component in the ambient air.
So, in short, the percentage p of exhalation air in the air mixture is determined by p = (RHs - RHa) / (RHe - RHa) (I), where RHs is measured (e.g. by a sensor in the air collector), RHe is presumed (e.g. equal to ~100%) or predetermined while RHa is measured. Then the amount (or percentage) of the relevant component (e.g. O2 or CO2) assigned to the exhalation air can be calculated by Ce = ((Cs - Ca) / p) + Ca (II) where Cs is measured (e.g. by an O2 or CO2 sensor respectively). Ca is estimated or measured (presumed or predetermined) beforehand as - like the values for RHe and RHa - the value for Ca has a rather constant value (ambient air contains about 0% CO2 and about 20% O2).
Figure 1 shows an exemplary embodiment in two views of a system which is arranged to perform the method according to invention.
The exemplary embodiment of the system for performing the method discussed above comprises collection means for collecting an air sample containing air exhaled by a user and ambient air in an unknown ratio. In figure 1 those air sample collection means are formed by an air collector (or air sampler) 1 which can be put before the user's mouth/nose area (not shown), at a certain distance, thus preventing that the collector hinders the user's breathing. At least a substantial part of the user's exhalation air is collected by the collector 1. Due to air turbulences etc. the air collector does not only collect the user's exhalation air, but also some ambient air; so the air sample contains an unknown percentage of air exhaled by the user and an unknown percentage of ambient air in an unknown ratio.
In order to be able to determine the CO2 percentage of (only) the exhalation air in the air sample, the collector 1 comprises means for determining the relative humidity RHs of the collected air sample, formed by an RH sensor 2. Processing means, in the form of a processor 3, are provided for assessing a factor p, representing the relative contribution of the exhalation air in the collected air sample, based on relative humidity values according to the formula (I) p = (RHs - RHa) / (RHe - RHa), where RHs is the determined relative humidity of the air sample, i.e. measured by the RH sensor 2. RHa is the predetermined or measured relative humidity of the ambient air (~20%) and RHe is the presumed relative humidity of the exhaled air (~100%). Instead of using presumed RH values for the ambient this RH value could be determined beforehand, either by means of the same air collector 1 or another one, after which the RHa and RHe values could be input into the processor 3.
The collector 1, moreover, comprises means for determining (measuring) the percentage Cs of CO2 in the air sample, which is formed by a CO2 sensor 4. The processor 3 is also used as means for assessing the CO2 percentage Ce which has to be assigned to the air exhaled by the user, based on the RH of the air sample, measured by RH sensor 2, and the predetermined/presumed RHa and RHe values, according to the formula (II) Ce = ((Cs - Ca) / p) + Ca, where Ce is the calculated CO2 percentage in the exhaled air, Cs is the determined (measured) CO2 percentage in the air sample and Ca is the presumed or predetermined (e.g. measured beforehand using the same CO2 sensor 4 or another CO2 sensor) CO2 percentage in the ambient air (which is about 0% under most conditions).
In this way the requested CO2 percentage in the exhaled air is determined based on the measured RH and the CO2 percentage of the air sample, which is a mixture of exhalation air and ambient air. The thus determined CO2 percentage in the exhaled air could be transmitted (since the athlete will be running, cycling etc.) by means of a radio transmitter 5 to a logging and/or processing system in e.g. a following car.
The O2 percentage or percentage of other components in the exhalation air can be determined in the same way. In that case the CO2 sensor 4 has to be replaced by an O2 sensor or an O2 sensor 6 is added to the collector 1, as shown in figure 1. Processing of the O2 related values can also be performed by the processor 3. It is presumed that the O2 percentage in ambient air (Cs for O2) is 20%). Of course by adding other gas sensors, other breath components can be measured.
Some examples will be given below: Hereinafter, the relative humidity of the ambient air, RHa, is presumed to be 20%, while the relative humidity of the exhaled air, RHe, is presumed to be 100%.
A. The measured relative humidity of the air sample is 60%; Formula L p = (60 - 20) / (100 - 20) = 40/80 = % (i.e. 50% exhalation air is present in the air sample);
Measured by sensor 4: 15% CO2 in the air sample Formula II: Ce = (15 - 0) / 1A + 0 = 30% CO2 in the exhalation air. Measured by sensor 6: 18% O2 in the air sample
Formula II: Ce = (18 - 20)/ 1A + 20 = -4 + 20 = 16% O2 in the exhalation air.
B. The measured relative humidity of the air sample is 80%; Formula L p = (80 -20) / (100 - 20) = 60/80 = 3A (i.e. 75% exhalation air is present in the air sample);
Measured by sensor 4: 15% CO2 in the air sample (same as in A). Formula II: Ce = (15 - 0) / 3A + 0 = 20% CO2 in the exhalation air.
Measured by sensor 6: 18% O2 in the air sample (same as in A). Formula II: Ce = (18 - 20)/ 3A + 20 = -I1A + 20 = 181A % O2 in the exhalation air.
C. The measured relative humidity of the air sample is 100%;
Formula L p = (100 - 20) / (100 - 20) = 1 (i.e. 100% exhalation air is present in the air sample);
Measured by sensor 4: 15% CO2 in the air sample (same as in A). Formula IL Ce = (15 - 0) / 1 + 0 = 15% CO2 in the exhalation air.
Measured by sensor 6: 18% O2 in the air sample (same as in A). Formula IL Ce = (18 - 20)/ 1 + 20 = -2 + 20 = 18 % O2 in the exhalation air.
Note: In example C there is apparently no inflow of ambient air; as a result of this the measured CO2 and O2 percentages by the sensors rightly are fully assigned to the exhalation air.
In figure 1 the exemplary collector 1 comprises an exhalation inlet 7, in operation to be placed about in front of the user's mouth/nose, preferably in a position wherein the user will be least hindered by the collector. To prevent breathing restriction one or more exhalation outlets 8 are provided, connected to the exhalation inlet 7 via connection members 9. The exhalation outlets 8 preferably point into the same direction, (see figure) contrary to the user's movement direction, causing that the flow of exhalation air through the collector is promoted by the draught which occurs at the outlets 8 due to the slip stream of the ambient air during movement of the user/athlete. If desired, a small exhaust fan or the like could be provided to support or boost the flow of exhalation air.
It will be appreciated that while specific embodiments of the invention have been described above, that the invention may be practiced otherwise than as described without departing from the scope of the appended claims.

Claims

Claims
1. Method for quantitative determination of a component in the air exhaled by a user, comprising the following steps:
- collecting an air sample containing air exhaled by the user and ambient air in an unknown ratio, - determining the relative humidity RHs of the collected air sample;
- assessing a factor p representing the relative contribution of the exhalation air in the collected air sample, based on relative humidity values according to formula I: p = (RHs - RHa) / (RHe - RHa) where
RHs is the determined relative humidity of the air sample,
RHa is the measured or predetermined relative humidity of the ambient air and
RHe is the presumed or predetermined relative humidity of the exhaled air;
- determining the percentage Cs of said component in the air sample;
- assessing the percentage Ce of said component to be assigned to the air exhaled by the user from formula II: Ce = ((Cs - Ca) / p) + Ca where
Cs is the determined percentage of said component in the air sample,
Ca is the presumed or predetermined percentage of the component in the ambient air.
2. Method according to claim 1, said component being CO2.
3. Method according to claim 1, said component being O2.
4. System for performing the method according to claim 1, comprising collection means (1) for collecting an air sample containing air exhaled by the user and ambient air in an unknown ratio, means (2) for determining the relative humidity RHs of the collected air sample, means (3) for assessing said factor p according to said formula I, means (4, 6) for determining the percentage Cs of said component in the air sample, and means (3) for assessing the percentage Ce of said component to be assigned to the air exhaled by the user from said formula II.
5. System according to claim 4, said collection means (1) comprising an exhalation inlet (7), in operation to be placed about in front of the user's mouth, and one or more exhalation outlets (8), connected to the exhalation inlet and pointing into the same direction as the exhalation inlet.
PCT/NL2009/050514 2008-09-04 2009-08-27 Method and system for quantitative determination of a component in the air exhaled by a user WO2010027256A1 (en)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
EP08163683.9 2008-09-04
EP08163683 2008-09-04
EP08164033.6 2008-09-10
EP08164033A EP2163198A1 (en) 2008-09-10 2008-09-10 Method and system for quantitative determination of a component in the air exhaled by a user

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WO2010027256A1 true WO2010027256A1 (en) 2010-03-11

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Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0196396A1 (en) * 1985-04-01 1986-10-08 COSMED S.r.l. Portable breathing monitor for telemetric measurement by a central processing station
WO1998053732A1 (en) * 1997-05-27 1998-12-03 Cosmed S.R.L. Portable system with telemetric data transmission for the measurement of metabolic parameters

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0196396A1 (en) * 1985-04-01 1986-10-08 COSMED S.r.l. Portable breathing monitor for telemetric measurement by a central processing station
WO1998053732A1 (en) * 1997-05-27 1998-12-03 Cosmed S.R.L. Portable system with telemetric data transmission for the measurement of metabolic parameters

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