NL1015410C2 - Band placed about person's chest to monitor breathing rate and depth whilst exercising and hence determine fitness - Google Patents

Abstract

A band placed around the rib cage monitors changes in its girth. Breathing frequency increases with exertion. The point (upper arrow) where frequency rises rapidly, coincident with the point (lower arrow) where breathing becomes shallower, shows the instant at which the transition from aerobic to anaerobic 'burning' of oxygen occurs.

Description

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Method and device for measuring the condition of an individual.

The present invention relates to a method and apparatus for measuring the condition of an individual.

To measure the condition of individuals, such as, for example, (top) athletes, it is known to subject the individual to an exercise test, whereby, for example, a spiro-ergometer measures the complete ventilation, oxygen uptake and carbonation production during increasing exercise load. This then looks at the moment at which the individual "sours" with increasing exertion. By "acidification" is meant the transition from aerobic combustion to anaerobic combustion. The better the condition of an individual, the longer it will take for the acidification to occur. For the condition measurement, the individual must be connected to the spiro-ergometer via a mouthpiece and / or mask. However, breathing with a mask or through a mouthpiece is unnatural and unpleasant for the individual concerned and thereby causes unusual breathing patterns. In this way, generally poorly reproducible and therefore not very reliable results are therefore obtained. In addition, the mouthpieces must be thoroughly cleaned and sterilized after each use before they can be used again. It is also known to determine the condition of an individual at the time of acidification based on the concentration of lactate in the blood. However, for this purpose blood samples must be taken at different times.

The object of the present invention is to provide a method for measuring the condition of an individual, wherein the aforementioned drawbacks are solved.

This object is accomplished by the invention by providing a method for measuring the condition, comprising subjecting the individual to an exercise load for a predetermined period of time from a resting state, including a breath pattern of 1015410 2 during a predetermined period of time. the individual, continuously determining the value of at least one condition parameter on the basis of the breath pattern, and determining the moment of occurrence of a predetermined change in the value during the time period.

The method according to the invention makes it possible to collect reliable data in a simple and much more comfortable manner for the individual, which can be used for measuring the condition of the individual concerned.

To measure the condition, the individual is first subjected to an exercise load from a resting state for a given period of time. For this purpose use can be made of per se known exercise tests in which the individual 20 is subjected to an increasing effort, such as for instance a bicycle or walk test in the gym.

However, the individual can also be exposed to a constant exercise load. During the determined time period, the individual's breathing pattern is increased. The values of one or more condition parameters are then determined from the breath pattern. By continuously determining the values of those condition parameters, changes in the values of those condition parameters can be monitored during the (increasing) effort. By continuous is meant here both the continuous monitoring of the value in time and the determination of the value at regular moments during the determined period of time. By determining the moment of occurrence of a predetermined change in the value during the time period, in relation to the maximum power, the condition of the individual is then measured, that is, depending on the condition of the the individual will be 1015410 3 at that time earlier or later in the time period, that is, closer to the maximum power.

Since, according to the invention, changes in the value of a certain condition parameter 5 relative to an initial value of that condition parameter are registered in the same individual, the method according to the present invention has the advantage that no calibration has to take place in advance.

Preferably, the breathing pattern is recorded by measuring the size of the subject's chest. The size of the chest changes during the respiratory cycle. The chest size increases when you breathe in, and it decreases when you breathe out. The breathing pattern can thus be easily recorded from the changes in the size of the chest. The size of the chest can be measured, for example, by placing a band around the chest, with which the size of the chest is measured using, for example, a pressure pad fitted in the band or by measuring the elongation of the band. Such a band around the chest is known per se for measuring the respiratory frequency in, for example, sleep studies and respiratory therapy at rest. However, its use in exercise testing to measure the fitness of, for example, 25 athletes has not been previously described.

According to a particularly suitable preferred embodiment of the method, the condition parameter to be measured comprises the respiration frequency, the predetermined change being a greater than an even increase in the respiration frequency. During the exercise test, an individual will generally breathe faster with increasing exertion. The increase in the breath rate can then be read from the breath pattern. For example, as described above, if the breathing pattern is recorded by measuring changes in the size of the chest, as the breathing rate increases, these changes will occur more quickly. Generally, the breath rate 1015410 4 will increase steadily during a first predetermined period of time on exertion. At some point, however, a sudden additional increase, that is, a much stronger than the first uniform increase in respiratory rate, will be observed in each individual. This is the moment when the individual • 'becomes acidic'. The moment of the sudden sharp increase in the respiratory rate depends on the condition of the 'individual. The better the condition, the later the moment of acidification, and thus the sharp increase in the respiratory rate will occur, thus an indication of the condition of the individual concerned can be obtained in a simple manner from the respiratory pattern.

According to another particular embodiment of the method according to the invention, the condition parameter comprises the tidal volume, the predetermined change being a decrease in the tidal volume. With increasing exertion, the tidal volume will initially increase slightly and then remain more or less the same for * a certain period of time. At some point, however, the tidal volume in each individual decreases. This is the moment when the individual is souring. The time of occurrence of tidal volume decrease depends on the condition of the individual. The better that condition, the later the tidal volume decrease will be observed. In this way, too, the condition of the individual in question can simply be measured on the basis of the breathing pattern.

According to the invention, the value of at least two condition parameters is preferably determined. By determining at least the values of two condition parameters, the condition of the individual can be measured in a very reliable, yet still simple manner.

If the value of at least two condition parameters is determined, the value of the respiratory rate and tidal volume is preferably determined, and the predetermined change concerns the substantially simultaneous occurrence of the greater than a regular increase in the respiratory rate and the decrease in tidal volume. The moment of acidification is thus read from the moment when the respiratory frequency 5 suddenly increases more strongly and the tidal volume decreases substantially simultaneously.

Determining the value of the condition parameter and the predetermined change in that value on the basis of the breath pattern can take place immediately, already during the stress test. During the period of time in which the individual is subjected to an exercise test on, for example, a treadmill, the value of the condition parameter (s) can then be continuously determined and the changes thereof recorded. In a particularly preferred embodiment of the method, however, the value of the condition parameter is determined continuously on the basis of the breath pattern and the moment of occurrence of the predetermined change in the value is determined only after the determined period of time. For example, while the individual is exerting himself on the bicycle, ice rink or running track, only the breathing pattern is recorded, while the recorded breathing pattern is only analyzed later. The recording of the breath pattern and the analysis thereof thus take place separately in time. For example, a supervisor of a top athlete who is temporarily abroad can measure the condition of that athlete afterwards. For example, the breath pattern can be recorded using a minidisk or data card for later analysis.

In a further particularly preferred embodiment of the method, the recorded breath pattern is transmitted and the time of occurrence of the predetermined change in the value of the condition parameter is determined elsewhere. The recording of the breathing pattern and its analysis therefore take place in different places. In this way, for example, the supervisor of the top athlete who is abroad 1015410 6 can measure the condition of his athlete directly, or possibly afterwards, while the athlete is in a different location. For sending the recorded pattern, use can easily be made, for example, of a mobile phone or "walky talky". The value of the condition parameter (s) and the predetermined change of that value can then be determined remotely from the breath pattern transmitted via, for example, the mobile phone. The breathing pattern can hereby first be recorded and then sent elsewhere where it will be analyzed later, but it is also possible to send the breathing pattern directly during the effort, so that the attendant can measure the athlete's condition directly during the effort. . Such a measurement of the condition "at a distance" is not possible with the already known methods of measuring the condition, such as for instance with the spiro-ergometer or by determining the concentration of lactate in the blood.

The invention further relates to and provides an apparatus for measuring the condition of an individual, comprising means for recording a breath pattern, which are connectable with analysis means for continuously determining the value of at least on the basis of the breath pattern a condition parameter and registering a predetermined change in the value over a given period of time.

With the device according to the method, the condition of an individual can be measured in a very simple and reliable manner.

In a suitable preferred embodiment of the device according to the invention, the breath pattern recording means comprise means for measuring the size of the chest of the subject.

These means can be designed in any suitable manner, for example in the form of a band to be arranged around the chest, with an air cushion 1015410 7 or a silicone band for observing the changes in the size.

The analysis means for determining the value of the condition parameter and recording can be carried out in any suitable manner. Preferably, they comprise an electronic processing unit which is programmed in such a way that it can continuously determine the value of a condition parameter on the basis of the breath pattern and register the predetermined change of the value.

Except the. condition parameters φ already mentioned, such as the respiration frequency and the tidal volume, can also be used to determine other condition or respiration parameters with the method and device according to the invention, such as, for example, the ratio expiration time / inspiration time. Ideally, this ratio is greater than 1. In individuals with, for example, hyperventilation, stress or chronic fatigue syndromes, this ratio is often less than 1, that is, the expiration time is shorter than the inspiration time. By measuring this ratio with the aid of the method and device according to the invention, it is thus easy to obtain an indication of any disturbances in the breathing of these persons.

The invention is further elucidated with reference to the appended figure, in which the values of two condition parameters determined on the basis of the breath pattern are shown graphically in time. As can be seen from this figure, the respiration rate 30 initially increases almost uniformly during increasing exertion (shown in Watts). On a certain moment.

I.e., at the time of acidification, the respiratory rate suddenly increases much more strongly, while at the same time a decrease in the tidal volume (breath) is observed. This is the turning point, indicated by the arrow in fig. 1. In the case shown in the figure, the turning point is reached after about 20 minutes.

1015410

Claims (11)

A method for measuring the condition of an individual, comprising subjecting the individual to an exercise load for a certain period of time from a resting state, recording a breathing pattern of the individual during that specific period of time, continuously by means of determining the breath pattern of the value of at least one condition parameter, and determining the time of occurrence of a predetermined change in the value during the time period. A method according to claim 1, characterized in that the breathing pattern is recorded by measuring the size of the individual's chest. 3. Method according to claim 1 or 2, characterized in that the condition parameter comprises the respiration frequency, wherein the predetermined change concerns a greater than an even increase in the respiration frequency. Method according to claim 1 or 2, characterized in that the condition parameter comprises the tidal volume, the predetermined change being a decrease in the tidal volume. Method according to any one of claims 1-4, characterized in that the values of at least two condition parameters are determined. 6. A method according to claim 5, characterized in that d values of the respiration frequency and the tidal volume are determined, and the predetermined change concerns the substantially simultaneous occurrence of the stronger than a regular increase in the respiratory frequency and the decrease of the tidal volume. A method according to any one of claims 1-6, characterized in that the value of the condition parameter is determined continuously on the basis of the breath pattern and the moment of occurrence of the predetermined change in the value after the determined time period occurs. 1015410 Method according to any one of claims 1-7, characterized in that the recorded breath pattern is transmitted and the moment of occurrence of the predetermined change in the value of the condition parameter is determined elsewhere. 9. Apparatus for measuring the condition of an individual, comprising means for recording a breath pattern, which are connectable with analysis means for continuously determining the value of at least one on the basis of the breath pattern. condition parameter and recording a predetermined change in the value during a given time period. 10. Device according to claim 9, characterized in that the breath pattern recording means comprise means for measuring the size of the chest of the subject. 11. Device as claimed in claim 9 or 10, characterized in that the analysis means comprise an electronic processing unit which is programmed in such a way that it can continuously determine the value of a condition parameter on the basis of the breath pattern and the predetermined change in value. Register. 1015410