FR2741519A1 - Portable device for making intermittent measurements such as arterial pressure - Google Patents

Abstract

The medical monitoring device has at least a measuring device(1) which in response to a control signal provides measurement data, and has a control unit (2) for processing and recording data, which sends the control signal to the measuring device (1). The device has also a mercury type position detection system (3), connected to the control unit (2), which detects its own position and provides, as a function of its position, position data to the control unit (2). This position data is used by the control unit to ensure that the control signal (Mc, Mt, Md) has a periodicity which is a function of at least the last position data given by the position detector.

Description

"Portable apparatus and method for intermittently performing and recording recurring measurements, particularly on the human body, such as blood pressure measurements"
The invention relates to portable measurement devices with intermittent and recurrent operation with different periodicities, in particular apparatus for periodically making measurements relating to the physiological state of a living being, with periodicities predetermined by its behavior, such as sphygmomanometers intended to be worn by patients on an outpatient basis to take measurements of their blood pressure on a cycle of twenty-four hours or more. The invention also relates to a method of taking and recording measurements by means of such an apparatus.

 Indeed, in the medical field, it has been highlighted that the result of the measurements carried out on the patients, in particular of the blood pressure, is very linked to the level of activity of the subject at the time of these.

 More specifically, it has been found that the blood pressure is markedly different depending on whether the subject is active, or at rest, or passes from one of these states to the other.

 As moreover the pressures measured during these different phases and the variations of these pressures have an interest in the diagnosis of certain affections, it appeared necessary to equip certain patients permanently during a period of twenty-four hours , a portable sphygmomanometer intended to automatically measure their blood pressure at predetermined intervals throughout this period of time corresponding to a normal cycle of their usual activity, therefore in ambulatory mode, and to take into account, for each measurement , of the patient's condition, during the count; but in addition to the fact that the wearing of a sphygmomanometer is in itself restricting, the measurement operations are at the very least inconvenient for the subject, in particular the periodic inflation and deflation of the cuff during the measurements, and this discomfort is ill-supported when the subject seeks sleep or is disturbed by it during sleep; another disadvantage is that while the measurement of the pressure during the resumption of activity is significant, this measurement must so far be triggered by the subject himself because it is statistically futile to count on the fact that a automatic measurement will occur just after the start of the activity period, and thus the risks that this important measurement will not be triggered are significant.

 Thus, the need arises to distinguish measurements in the resting state from measurements in the active state, to space out the measurements when the subject is at rest, and to automatically trigger a measurement when it changes state and above all when it passes from the state of rest to the state of activity.

The object of the invention is therefore
- take into account the impact of activity or rest on the values of the results of measurements such as blood pressure measurements by offering an objective and sure means of determining the periods of activity and rest but also the passage of to each other, and
- to automate the measurement protocols which were hitherto arbitrarily fixed or "patient-dependent".

 The invention also aims to achieve these goals by causing minimal discomfort for the subject, and naturally by means of reliable equipment, easy to implement and operate, and as inexpensive as possible.

 To this end, the invention relates to a portable measurement device with intermittent and recurrent operation with different periodicities, of the type comprising at least one measurement device for performing a measurement in response to a control signal and providing significant measurement information of the result of the measurement, and a control, information processing and storage apparatus for supplying the control signal to the measurement device, processing the measurement information, and storing the information from the processing, connected to the measurement device, apparatus characterized in that it also comprises a position detection device connected to said apparatus, detecting its own position and supplying, as a function of this position, position information to this apparatus, so that the latter generates the control signal with a periodicity which either a function of at least the last position information given by the device position detection.

 Thanks to the fact that the apparatus includes a position detection device providing information which is a function of its own position, it is possible to carry out measurements with different periodicities depending on the position, and also measurements following position changes.

 According to a characteristic of the invention, when the apparatus is intended to carry out measurements on the human body, such as blood pressure measurements, advantageously the detection device is housed in a separate housing which can be secured to the body by adhesive, which brings minimal discomfort to the wearer and allows the device to be placed in the most appropriate place regardless of the condition of the subject.

The invention also relates to a method for taking and recording measurements, characterized in that
- periodically and depending on the position of a body, we create position information to which we give at least a first or a second shape depending on this position, and thus a train of position information whose evolution is revealing changes in body position,
- Measurements are carried out which are carried out at the rate of the signals of a train of measurement control signals which are spaced more than the position information which is created both during the measurements and between them. ci, with a first time interval when the position information constitutes an information train in the first form and with a second time interval when the position information constitutes an information train in the second form,
- when a transition, which is considered significant, of the form of the position information, from the first to the second form, is detected, the time interval between the transition and the instant when the signal of control of the measurement immediately following would have occurred in the absence of transition, with said second time interval, the smaller of these two time intervals is determined, and a command signal is sent at an instant which is space the transition through said smallest time interval.

 Thanks to the process which follows the detection of a transition estimated to be significant, a measurement result is obtained which gives an account of the immediate effect of this transition, even if normally no measurement was to be carried out at this time.

According to a characteristic of the invention, when the method is intended for taking and automatically recording measurements on a human body, such as blood pressure measurements, by means of the apparatus mentioned above,
- it is determined whether the body is in the supine or standing position,
- periodically triggering and recording of measurements may have a first or a second time interval between them depending on whether the body is estimated to be in the supine position or in the standing position,
- a measurement is also made following a transition (Tcd) between the lying position and the standing position if the time elapsed since the previous transition, from the standing position to the lying position, is greater than a time interval of predetermined length, with a time interval counted since the transition (Tcd), which is the smallest between the second time interval and the time interval between the transition and the instant when the immediately next measurement would have occurred in the absence of transition, and,
- after the measurements following a transition, if the position since the transition has remained unchanged, at least the following measurement is ordered with that of the two time intervals which is different from that used before the transition.

 Due to the fact that a transition measurement is only carried out if the prone position has been held for a certain time (for example at least one hour or at least two hours), a certain number of non-significant measurements are excluded. following extremely short but repeated periods of rest, the accomplishment of which would have embarrassed the subject.

Other characteristics and advantages of the invention will emerge from the description which follows of forms and embodiments of the invention given by way of nonlimiting examples and illustrated in the attached drawings in which
FIG. 1 is a block diagram of an embodiment of an apparatus according to the invention,
- Figures 2, 3 and 4 are diagrams showing the timing of the measurement control signals around a transition from a first to a second position of the detector in two different cases (Figures 2 and 3 respectively) and around a transition from the second to the first position (Figure 4),
FIG. 5 is a view schematically showing an apparatus according to the invention and a first mode of wearing of this apparatus by a patient whose physiological parameters such as arterial pressures must be measured,
FIG. 6 is a view diagrammatically showing an apparatus according to the invention and a second mode of wearing of this apparatus by a patient whose physiological parameters such as arterial pressures must be measured, and
- Figure 7 is a view schematically showing an apparatus according to the invention and a third mode of wearing of this apparatus by a patient whose physiological parameters such as arterial pressures must be measured.

 The apparatus shown diagrammatically in FIG. 1 is intended to carry out intermittent measurements of blood pressure on human beings for a relatively long period, for example twenty-four hours or more, and to process the significant information of the result of the measurement so that the information resulting from the processing can be stored and possibly viewed.

As it has been found that the fact that the subject is at rest or in activity has an impact on the result of the measurement, and that moreover the study of the result taking into account the state of rest or activity of the subject, provides interesting information on the state of health thereof, this apparatus is intended to take advantage of these recent findings, and, according to the invention, comprises a device for detecting "activity" intended to be attached to the body of the subject so that a correlation can be made between the results of the measurements and the state of activity thereof. For simplification, the active state has been assimilated to the standing position of the patient, and the state of rest in the lying position, so that the activity detection device can be in the form of a device. position detection; it has been observed that this simplification is not overly reductive, and that the results obtained under these conditions overlap well with those obtained in a diagnostic center in a hospital environment; just as in a hospital environment, and by means of a manual apparatus, the measurements carried out in the rest state and in particular during sleep can be spaced apart, the apparatus according to the invention makes it possible to space out the measurements carried out when the subject is in the supine position, assimilated to the state of sleep.

 However, the advantage of being able to associate the result of a measurement with the position of the body, a living being or a simple object, on which the measurement has been made, goes far beyond the medical field, and the invention is therefore not limited to either measurement of blood pressure, or even in the medical field.

 Thus, in general, the apparatus shown diagrammatically in FIG. 1 is intended to carry out measurements intermittently and comprises, in addition to a measurement device 1, an apparatus 2 for controlling, processing information, and memorization, the whole being in portable form taking into account the duration of the investigation and the interest of carrying out this investigation over a long period and here a usual daily cycle of the patient; the measurements having to follow one another with a frequency of recurrence likely to take (at least) two values, a control signal is supplied by the apparatus 2 to the measuring device 1, with the corresponding periodicities; in response, the device 1, after having carried out the measurement, itself supplies the device 2 with significant information of the result of this measurement, which is then processed so that the information resulting from the processing can be stored and possibly viewed on the device 2, containing the various electrical circuits ensuring the control of the measurements, the processing of the measurement information, the storage of the information resulting from the processing, and the display of the results.

 According to the invention, the apparatus also includes a position detection device 3, detecting its own position and supplying information as a function of this position to the apparatus 2, so that the latter generates the control signal with a periodicity which is a function of at least the last position information given by this device 3.

 The detection device is a mercury ball switch; this switch is housed in a housing, and the state of the switch is periodically explored by the control device at a high recurrence frequency relative to the highest of the measurement frequencies, for example every five seconds; in this way, between two measurements, there is a large number of position information constituting a train of information whose evolution of the shape (for example state O or 1) is indicative of changes in the position of the device. detection 3, therefore of the body (human or object) to which this device 3 is attached.

 The device 2, the measuring device 1 and the position detection device 3 having to exchange information, they are connected in a conventional manner, by cable 4, 5, electrical or optical, or even by wireless link (radio link to the broad sense including infrared link); it is also possible to implement the two connection modes, for example one for the measurement device and the other for the detection device.

The diagrams as a function of time represented in FIGS. 2 to 4 show, for each figure, in the upper diagram, the moment of a transition Tcd from the lying position to the standing position (FIGS. 2 and 3), and the moment of a transition Tdc from the standing position to the lying position (Figure 4); before the transition Tcd in FIGS. 2 and 3, the "lying" information given by the detector device corresponds to a first form of the position information (for example state O), and afterwards, the "standing" information corresponds to the second form of position information (then, state 1); similarly, before the transition
Tdc of figure 4, the "standing" information corresponds to the second form (state 1) and the "lying" information to the first form (state O). On receipt of the position information, the device 1 responds by developing a measurement control signal shown in the diagram at the bottom of FIGS. 2 to 4; these are measurement control signals Mc spaced with a first time interval in response to position information in the first form (here lying position), and measurement control signals Md that are spaced with a second time interval in response to position information in the second form (here standing position). Advantageously, the rate of explorations of the state of the position detector, therefore of position information, is much higher than that chosen for the measurements, even the measurements which are the least spaced apart (train of signals Md corresponding to the standing position, and a fortiori train of signals Mc corresponding to the lying position). Thus, there is a large amount of position information between two successive measurements, and even during a measurement, which necessarily takes a certain time, in particular if it is a measurement of blood pressure ( a few tens of seconds); this large amount of information allows a relatively fine interpretation of the situation, and in particular to disregard erratic information due for example to artefacts, as will be seen below.

 Given the spacing of the measurement control signals, it would normally be highly unlikely that any of them would occur spontaneously immediately after a transition. However, we have seen, in the case of blood pressure measurements, the advantage of carrying out a measurement in the case of a transition from the lying position to the standing position.

Also, we choose to order such a measurement, under certain conditions which will be explained below, within a short time after the detection of a lying-standing transition Tcd. this delay is chosen by comparison of the time interval between the transition
Tcd and the instant when the next measurement command signal Mc (corresponding to the prone position) would have occurred in the absence of transition, with the time interval between the command signals Md (corresponding to the standing position) since the first control signal Md would normally have occurred with this interval after the transition. After the comparison, the shorter of these two time intervals is chosen as the time interval between the transition Tcd and the measurement signal Mt. Thus, the delay between the transition and the next measurement is at most equal to the time interval corresponding to the standing position (case of Figure 3), but it can be shorter (Figure 2); in the two figures, the control signal chosen is denoted Mt, and the signal discarded at the end of the comparison is shown diagrammatically in dotted lines.

 On the other hand, in the case of the transition Tdc between standing position and lying down position, it was not considered useful to proceed in the same way, because the previous measurement control signals being closely spaced, one necessarily occurs, shortly after the transition.

 In all three cases, the measurement control signal Mt immediately following a transition gives the start of the counting of the subsequent time intervals, under certain conditions which will be seen below.

 However, in order not to disturb the patient by repeated measurements each time he goes from the lying position to the standing position, if this lying position did not correspond to a real rest, and to not have to take taking into account insignificant measurements, it is planned not to trigger a measurement at each down-to-stand transition.

More precisely, the measurement will only be triggered following a change of form of the position information, if the lying position has been held for a time at least equal to a predetermined duration, for example one hour or two hours , with a quasi-certainty, that is to say if during this predetermined period, at least one predetermined rate (for example at least 90W) of position information was in the same form corresponding to the lying position, which makes it possible to s free from any artifacts. In other words, when a transition in the shape of the position information is detected, from "lying down" to "standing", the time elapsed between this transition and the previous one is measured in the opposite direction, it is compared with a time interval of predetermined length, and the lessons given by a measurement just after the transition are considered interesting if this elapsed time is at least equal to the time interval of predetermined length; moreover, the measurement is only triggered if the position information during the time interval of predetermined length (here, one hour, or two hours) is at least 90k from the information corresponding to the lying position.

 Furthermore, this measurement according to the prone-to-upright transition, like all the other transitions, is only validated as corresponding to the position here standing, if at least a predetermined percentage of the position information received while it is carried out, correspond actually at this position.

The predetermined percentage from which a measurement is validated as undoubtedly corresponding to a standing or lying position can be chosen for example equal to 90% or 99 of position information in the same form.

 Likewise, to guard against the fact that the timing of the measurement command signals would be erroneous if a patient changed position, thereby initiating a measurement process, and returned to its original position even before the measurement was made, the cadence of the measurement control signals is changed, following a transition in the form of the position information, only if, in the time interval between the transition and the subsequent control signal, at least one rate predetermined position information remains identical to the position information that triggered the measurement (for example at least 90%).

In summary, periodically and depending on the position of the body,
- We create position information to which we give at least a first or a second shape according to this position (respectively lying or standing), and thus we create a train of position information whose evolution is indicative of changes in the position of the horn, so that the position of the body can be determined,
- measurements are made and recorded at the rate of the signals of a train of measurement control signals more spaced than the position information (which scroll both during the measurements and between them), with a first time interval ( rather long) when the position information scrolls in the first form (lying position)
- when a transition in the form of the position information is detected, from the first to the second form (prone position in standing position), and under certain conditions, the time interval between the transition and the instant is compared where the immediately following measurement control signal would have occurred in the absence of transition, with the second time interval, the smaller of these two time intervals is determined, and a measurement control signal is sent at a spaced instant of the transition by the smaller of these two time intervals, so as to then carry out a measurement. Furthermore, when a transition in the shape of the position information is detected, from the second to the first shape (standing position in the supine position), the following control signal is sent at an instant spaced from the previous control signal, always with the second time interval (the one corresponding to the standing position).

In both cases, it is only under the condition mentioned above, that the cadence is subsequently rendered equal to that which corresponds to the transition which triggered the measurement, i.e. say different from the cadence used before the transition.

 On the material level, the device 2 for controlling, processing information and memorizing, is housed in a box, which can be, in the case of a medical device, hung or suspended from the belt of a patient or any other clothing accessory.

The position detection device 3 is also housed in a housing, outside the housing of the device 2; here this case can be secured to the patient's body by means of an adhesive patch provided with a connector of the repositionable electrode connector type, for example at the level of the sternum (FIG. 5); in Figure 6 is shown an apparatus for which the housing of the detection device 1 is secured to an electric cable 6 for collecting an electrocardiography signal on one or more channels, carrying adhesive electrodes 7, 8, 9 of electrocardiography, for example an electrode 7 above the housing at the level of the sternum, and an electrode 8 below, a third electrode 9 being approximately at the base of the heart; in FIG. 7, the detection device 3 is housed in a box carried by the device 2, for example being plugged into it by means of sockets or connectors, the device 2 being carried by a belt surrounding the size of the patient, or more randomly, by a strap surrounding his arm. In the case shown in the figures, the measuring device 1, which is a sphygmomanometer, is conventionally placed around the patient's arm.

 The apparatus 2 for controlling, processing information and memorizing, outside of which the measuring device 1 and the position detection device 3 are placed, comprises a keyboard 21 accessible from the outside to select the modes of operation of the apparatus and a display device 22 visible from the outside to display the indication of the selected operating mode and possibly the result of the measurements and the activity status and position of the patient at the time of the measurements. the selectable modes can be for example four in number: the auscultatory mode "AUSC" when a doctor examines the patient, the oscillometric mode "OSCI", the automatic mode "AUTO" for measurements over a long period, and the mode "TEST" calibration before the launch of any measurement or series of measurements, consisting in "zeroing" the apparatus when the detection device 3 is in the vertical position, therefore when, here, the patient is standing.

 In this way, when the angle formed by the patient's body with the vertical exceeds a certain number of degrees "X", the sensor sends, for example, no information, and as soon as the angle becomes less than "X", the sensor sends information "1".

 Thus, it is determined whether the body is in a lying position or in a standing position, periodically it is triggered and recorded measurements may have a first or a second time interval between them depending on whether the body is estimated to be in the lying position or in the standing position , a measurement is also carried out following a transition between the lying position and the standing position if the time elapsed since the previous transition, from the standing position to the lying position, is greater than a time interval of predetermined length, with a third time interval counted since the transition, which is the smallest between the second time interval and the time interval between the transition and the instant when the immediately next measurement would have occurred in the absence of transition, and , after the measurements following a transition, if the position since the transition has remained unchanged, at least the following measurement is ordered, a with that of the two time intervals which is different from that used before the transition.

Thanks to these characteristics, it is possible to know precisely
- the position and therefore the relative level of activity of the patient at the time of the measurement, which makes it possible to explain certain variations in pressure; in particular, information can be crucial in the problems of orthostatic hypertension
- the patient's hours of getting up and going to bed, which is considered fundamental in the study of blood pressure profiles during the circadian cycle.

It is also possible
- trigger a measurement or a series of measurements automatically at certain times considered critical, such as lifting the patient
- to automate the passage of the measurement intervals from night to those of day and vice versa, whereas with known devices, it was necessary to program them before monitoring on the basis of information given by the patient on his hours of get up and sleep.

 Finally, in the context of more detailed investigations, we can carry out an analysis, in addition to the position of the mercury ball, of its movements, in order to draw information on the physical activity of the patient, these movements being a good indication of this activity.

 Of course, the invention is not limited to the forms and modes described and claimed, and we can provide others without departing from its scope.

Claims (15)

 1 - Portable measurement device with intermittent and recurring operation with different periodicities, of the type comprising at least one measurement device (1) for performing a measurement in response to a control signal and providing significant measurement information of the measurement result , and a control, information processing and storage apparatus (2) for supplying the control signal to the measurement device, processing the measurement information, and storing the information from the processing, connected to the measurement device, apparatus characterized in that it also comprises a position detection device (3) connected to said device (2), detecting its own position and supplying, as a function of this position, position information to this device, so that the latter generates the signal command (Mc, Mt, Md) with a periodicity which is a function of at least the last position information given by the device position detection.  2 - Apparatus according to claim 1, characterized in that the position detection device (3) comprises a ball of mercury.  3 - Apparatus according to claim 1, characterized in that the apparatus (2) for control, information processing, and storage, is housed in a housing, and the measuring device (1) and the device position detection (3) are outside this housing, and in that the housing includes a keyboard (21) accessible from the outside to select between several operating modes of the apparatus and a display device (22 ) visible from the outside to display the indication of the operating mode selected and possibly the result of the measurements.  4 - Apparatus according to claim 1, characterized in that the apparatus (2) for control, information processing, and storage, is connected to at least one of said devices (1, 3) respectively for measuring and position detection, by electrical or optical cable (4, 5).  5 - Apparatus according to claim 1, characterized in that the apparatus (2) for control, information processing, and storage, is connected to at least one of said devices (1, 3) respectively for measuring and detection by a radio link.  6 - Apparatus according to claim l, characterized in that the measuring device (1) is a sphygmomanometer.  7 - Apparatus according to claim 1 for performing measurements on the human body, such as blood pressure measurements, characterized in that the position detection device (3) is housed in a housing adapted to be secured to the human body at using an adhesive pad.  8 - Apparatus according to claim 1 for performing measurements on the human body, such as blood pressure measurements, characterized in that the detection device (3) is housed in a housing secured to an electric cable (6) carrying electrocardiography adhesive electrodes (7, 8, 9).  9 - Apparatus according to claim 1, for performing measurements on the human body, such as blood pressure measurements, characterized in that the detection device (3) is housed in a housing carried by the device (l) of control, information processing and storage.  10 - Method for taking and recording measurements, characterized in that  - periodically and depending on the position of a body, we create position information to which we give at least a first or a second shape depending on this position, and thus a train of position information whose evolution is revealing changes in body position,  - measurements are carried out which are carried out at the rate of the signals of a train of signals (Mc, Mt, Md) of measurement control which is space more than the position information which is created as well during the measurements only between them, with a first time interval when the position information constitutes an information train in the first form and with a second time interval when the position information constitutes an information train in the second form,  - when a transition (Tcd) is detected, which is considered significant, from the form of the position information, from the first to the second form, we compare the time interval between the transition and the instant when the immediately following measurement control signal would have occurred in the absence of transition, with said second time interval, the smaller of these two time intervals is determined, and a control signal is sent at a time that the we space the transition by said smallest time interval.  it - Method according to claim 10, characterized in that, if a transition (Tdc) of the form of the position information is detected, from the second to the first form, the following control signal is sent at a time that one space of the previous control signal, with the second time interval.  12 - Method according to claim 10, characterized in that, when a transition (Tcd) of the shape of the position information is detected, from the first to the second shape, the time elapsed between this transition and the previous one is measured transition (Tdc) from the second to the first form, this elapsed time is compared with a time interval of predetermined length, and the transition (Tcd) from the first to the second form is considered significant if the said elapsed time is at least equal said time interval of predetermined length.  13 - Method according to claim 10, characterized in that only validates, as corresponding to a position, the measurements during which at least a predetermined rate of position information were indicative of this position.  14 - Method according to claim 10, characterized in that one controls the passage of said first time interval to said second time interval, or vice versa, between the measurement control signals, following a transition (Tcd, Tdc) of the form of the position information, only if, in the time interval between the transition and the next control signal, a predetermined rate of position information remains identical to the position information which triggered the measurement.  15 - Method for taking and automatically recording measurements on a human body such as blood pressure measurements by means of the device according to any one of claims 1 to 9, characterized in that  - it is determined whether the body is in the supine or standing position,  - periodically triggering and recording of measurements may have a first or a second time interval between them depending on whether the body is estimated to be in the supine position or in the standing position,  - a measurement is also made following a transition (Tcd) between the lying position and the standing position if the time elapsed since the previous transition, from the standing position to the lying position, is greater than a time interval of predetermined length, with a time interval counted since the transition (Tcd), which is the smallest between the second time interval and the time interval between the transition and the instant when the immediately next measurement would have occurred in the absence of transition, and, after the measurements following a transition, if the position since the transition has remained unchanged, at least the following measurement is ordered with that of the two time intervals which is different from that used before the transition.  16 - Method according to claim 10, wherein the position information is provided by a position detection device (3) of the body of a living being, in the form of a mercury ball switch, characterized in that analyze the movements of the mercury ball and deduce information about the physical activity of this living being.