FR2651988A1 - Device for monitoring the spontaneous movement of a living being - Google Patents

Abstract

- Entirely autonomous monitoring device worn by the user. According to the invention, the device includes a belt (14a), a casing (12a) connected to the belt and enclosing all the components namely a movement sensor (13a), a part (122a, 122b) of which is connected to the belt. Application to the monitoring of mechanical (reflex, involuntary) ventilatory activity.

Description

 The invention relates to a device for monitoring the spontaneous movements of a living being, in particular its ventilatory activity resulting in a periodic dilation of its rib cage and / or its abdominal region.

 The invention more particularly relates to a fully autonomous device, easy to implement and capable of setting off an alarm in the event of prolonged apnea, in particular.

 It is known that any prolonged interruption of ventilatory activity (apnea) leads to cardiac arrest and therefore to an interruption in the transport of oxygen to the cells. It is generally accepted that when cardiac arrest occurs, there is only two to three minutes left before brain death occurs. Although apnea is not the only cause of cardiac arrest, it is responsible for a large number of fatal accidents. Surveillance devices are known which make it possible to prevent or to cope with cardiac arrest. Some of these devices are designed to detect such or such anomaly, consequence of apnea. This is the case, for example, of devices which measure the desaturation of oxygen in the blood following apnea. In addition to the fact that detection always takes place with a certain delay, devices of this type are generally not autonomous and require that the patient is connected, by conductors, to a control unit operating on battery and / or mains. They are therefore more specifically intended for use in hospitals.

 The invention is remarkable in that it makes it possible to react quickly by firstly monitoring the apnea itself and, possibly, other respiratory anomalies such as, for example, a polypnea (breathing too fast).

 An object of the invention is to provide a totally autonomous monitoring device that is easily supported by the user, to facilitate its use for extended periods of time and possibly outside any hospital context. The invention thus opens up new perspectives for monitoring certain "at risk" patients.

 In pediatrics, the invention can help prevent cardio-ventilatory arrest which is the cause of the phenomenon known as "sudden infant death syndrome".

 In this spirit, the invention therefore essentially relates to a device for monitoring spontaneous movements of a living being, in particular its ventilatory activity, characterized in that it comprises a housing, a displacement sensor coupled to a belt, harness or the like. arranged to be fixed in a loop around said living being, electronic means for controlling the signals delivered by said sensor and alarm means controlled by said electronic control means, said electronic control means and said alarm means being housed in said housing, itself carried by said belt or harness. This removes any wire connection.

The invention will be better understood and other advantages thereof will appear more clearly in the light of the following description of several embodiments of a device in accordance with its principle, given solely by way of example and made with reference to the accompanying drawings in which:
- Figure 1 is a general exploded perspective view of an embodiment of a device according to the invention;
- Figure 2 is a detail view showing the arrangement of the sensor of the device of Figure 1;
- Figure 3 is a general exploded perspective view of another embodiment of a device according to the invention;
- Figure 4 is a section IV-IV of the device of Figure 3, assembled; and
- Figure 5 is a block diagram of an electronic system capable of being housed in the housing of the device of Figure 1 or Figure 3, to be controlled by the sensor and develop alarm signals.

 The monitoring device 11 shown in Figure 1 mainly consists of a housing 12 (containing a displacement sensor 13 and electronic circuits) and a belt 14, harness or the like, connected to said housing. This belt includes attachment means, not shown, making it possible to fix it by forming a loop around the living space, in this case for a human being, around the rib cage or the abdomen so that the arrangement is sensitive to the spontaneous movement of the organism and more particularly to ventilatory activity. The belt has an elastic portion 16 to avoid any strangulation effect. When the device is thus put in place, thanks to the belt 14, the housing 12 rests on the body of the user without causing excessive discomfort since any connection by wire with a fixed installation is avoided. The box in fact contains a battery or a small rechargeable accumulator 18 and one of its faces carries a certain number of pushbuttons and indicator lights associated with control means and with alarm means, carried by a printed circuit 15, which will be described later with reference to FIG. 5. The box also contains an audible alarm means (“buzzer” type). Thus all the electronic detection, control and alarm means are housed in the housing itself.

 The displacement sensor 13 is here constituted by the association of at least one Hall effect cell 20 and at least one magnet 22, one of these two elements being integral with a mobile assembly 24 to which the belt 14 or harness. In the example described, two magnets 22a, 22b are in fact provided in the vicinity of at least one such fixed cell and respectively integral with two movable supports 25a, 25b of said movable equipment 24.

Advantageously, there are also two Hall effect cells 20 ~, 20b respectively arranged in the vicinity of the magnets.

The two cells 20a 20b are interconnected so that their output signals combine. Each of the mobile supports 25a 25b is connected to one end of the belt 14 or of the harness. Each support 25a 25b is here a flat element of non-magnetic metal in general L shape, pivotally mounted in its own plane on an axis 28a 28b respectively, fixed and provided on the edge of the housing. A loop 303, 30b is cut from each of these supports, the ends of the belt 14 or of the harness are passed through these loops and thus attached to the mobile assembly. Each support 25a 25b is associated with an elastic means 32a 32k which stresses towards a stable and predetermined rest position, thus determining the rest position of the elements relative to the cells. In addition, the elastic means of the two supports have different stiffnesses.

In the example shown, each elastic means consists of a flexible rod elastically mounted between the corresponding support and an anchoring structure 36, here common to the two rods. The latter are in fact aligned on either side of the anchoring structure formed by an extension of the housing in which a hole is made which receives the two rods. These rods can also be materialized by a single rod passing right through the anchoring structure 36. They are of unequal length, which gives the difference in stiffness mentioned above.

 This difference in stiffness makes it possible to have a greater range for adjusting the tension of the belt or the harness. If the tension is low, it is essentially the magnet secured to the support 25a which moves. On the contrary, if the tension is higher, the support 25a abuts against a plate 38 and the signal is then essentially due to the displacement of the magnet secured to the support 256.

 Of course other variants are possible. For example, the mobile assembly could simply consist of an open frame (a sort of transverse slot being made in the middle of one of the sides of this frame) comprising flexible branches. The magnets would then be arranged on either side of said slot in the frame. Similarly, the Hall effect sensor can be replaced by other types of displacement sensors, for example with strain gauge, photosensitive element and light source, etc.

 The device in FIGS. 3 and 4 is a variant comprising, as before, a box 12a containing a battery 18a or a rechargeable accumulator and a double printed circuit 15a carrying most of the electronic components constituting the control and alarm means which will be described further on with reference to FIG. 5. This embodiment differs from the previous one mainly by a functional combination between the belt 14a, harness or the like and the displacement sensor 13a. This belt has a section of elastic band 16a which extends through the housing. In the example, this section of elastic band is fixed to one side of the housing by a fixed loop 130a, made integral with the bottom wall of the housing. and thus serving as an anchoring means for one end of the elastic band section 16a. On the other side of the housing is a movable loop 130b, similar to the loop 130a connected to the other end of the section of elastic band 16a.

The latter therefore crosses the wall of the housing through a slot 19 thereof. At least one magnet is fixed to the section of elastic band 16a. In the example two such magnets 122a, l22b spaced from one another, are fixed, for example glued, to the section of elastic band 16a with the same direction of orientation NS, chosen parallel to the direction of elongation of the section of elastic band 16a. The magnets 122a 122b are of course part of the displacement sensor 13a. The latter is completed by two Hall effect cells 20a 20, carried by the printed circuit 15a and located near and approximately opposite the magnets 122a 122b, respectively. In fact, the initial positions of the magnets 122a 122b relative to the cells are determined when the device is placed on the user, taking into account a necessary initial elongation of the section of elastic band 16a which carries the magnets. In a simple manner, the section of elastic band 16a bears a transverse mark 23 in the vicinity of the slot 19 and the predetermined initial elongation is reached when, by tightening the belt 14 around the patient, the mark 23 appears through the slot 19, at outside the housing. Satisfactory results have been obtained by positioning the magnets so that, for this initial elongation, they are located between the two cells, each magnet being spaced from the corresponding cell by a distance approximately equal to third of the distance between the two cells. In this way, one obtains a kind of differential variation of the signals generated by the two cells, since, when the elongation of the elastic band varies, one of the magnets approaches the corresponding cell while the other does distant.

 Alternatively, one can also imagine that the belt carrying the magnets is independent of the housing containing the other components, the latter simply coming to be attached to the belt, around the area carrying the magnets, after the said belt has been put in place.

 Referring more particularly to FIG. 5, we will now describe the electronic circuits associated with the displacement sensors. The Hall effect cell or cells are connected to a cascade arrangement, consisting of a low-pass filter 40, a high-pass filter 41 and a threshold comparator 42. The assembly constitutes means of setting in the form of signals delivered by the Hall effect cell or cells.

More precisely, the two Hall effect cells 20a 20k have their supply circuits connected in series and this common supply branch is subjected to a DC reference voltage VO while the measurement outputs of each cell are respectively connected to the two inputs of a corresponding differential amplifier 25a 25b. The outputs of these two amplifiers are connected to the input of the low-pass filter 40 via two respective resistors R ~, Rb, defining a summing circuit. At the output of the comparator 42, there are pulses representative of the movements transmitted by the belt or the harness, that is to say representing the ventilatory activity. This output is connected to time measurement means 43 essentially constituted by a cascade arrangement of two monostables, successively a monostable for the control of polypnea 44 and a monostable for the control of apnea 45. The output thereof is connected, via an AND gate 46 and a test circuit 48 to an audible alarm means 50. The output of the monostable 45 is also connected to an alarm light L1 (a light-emitting diode) via the door 46 and a memory 55. The monostable 44 is of the retrigger type set for a period one second fallout. The monostable 45 is also of the retrigger type set to a fallout period of 18 seconds. The fallout periods indicated above are, of course, given for information only.

 A monostable 56 is connected to the output of the shaping means. This monostable has a short fallout period, for example 0.2 seconds. It therefore delivers pulses of predetermined duration, representative of the movements to be monitored. These pulses are used to control an L2 monitoring indicator light and / or the audible alarm means 50 via AND gates 58, 60 respectively, also receiving validation signals from a flip-flop 61 controlled by two push-buttons BP1 , for controlling the audible alarm means 50 and BP2 for controlling the indicator light L2. An OR gate 62 is inserted between the AND gate 60 and the audible alarm means 50. It has two other inputs respectively connected to the output of the AND gate 46 and to a circuit 64 for controlling the voltage of the accumulator 18 The latter is connected to a charging circuit 65 capable of being connected to an external power source. The operation of this charging circuit is displayed by an indicator light L3. The state of charge of the battery is displayed by an indicator light L4 controlled by circuit 64. Too low a voltage triggers the audible alarm via the OR gate 62. The system also includes a commissioning control circuit comprising a flip-flop 68 whose output Q is connected to the other input of the AND gate 46 (the latter has only two inputs). An input S of this flip-flop is connected to the output of an AND gate 70, the two inputs of which are respectively connected to the push-buttons BP1 and BP2.

An input R of the flip-flop 68 is connected to the output of an OR gate 71, one input of which is connected to the load circuit 65 and another input to the output of an AND gate 72 with two inputs. One of them is connected to the push button BP1 and the other to a push button BP3 also connected to an input forcing the memory 55. The indicator lights L1, L2 and the audible alarm means 50 are controlled by respective amplification circuits A1, A2, A3.

 The operation is as follows. The device is put in place on the patient, for example, by fastening the belt around the rib cage and by exerting a certain initial tension so that the dilations of the rib cage are reflected at the level of the sensor by a relative displacement between the or the magnets and the Hall effect cell (s). The system is put into service by simultaneously pressing the buttons BP1 and BP2, which validates the AND gate 70 and positions the flip-flop 68 which controls one of the inputs of the AND gate 46. From this moment, the system is operational to detect both a polypnea (that is to say a too high respiratory rate which can precede malaise) by the use of monostable 44 that a prolonged apnea, by the use of monostable 45 which " drops out "after 18 seconds if no signal from the monostable 44 re-triggers it in time. In either case, the audible alarm means are triggered as well as the LI indicator light. Pressing the BP1 button allows auditory control of the respiratory rate, by issuing short-lived sound signals, developed from the signal delivered by the monostable 56. On the other hand, pressing the BP2 button changes the state of the flip-flop 61 and eliminates the sound control in favor of a light control, by flashing the light L2. If breathing resumes spontaneously after an audible alarm is triggered, the latter disappears but the L1 indicator remains lit until the acknowledgment (memory 55).

The L1 indicator light can be turned off by pressing the BP3 push button. If the battery 18 is insufficiently charged or defective, the circuit 64 triggers an audible alarm via the OR gate 62 and a specific light signaling, by the indicator light L4.

Claims (16)

 1- A device for monitoring spontaneous movements of a living being, in particular its ventilatory activity, characterized in that it comprises a housing (12, l2a), a displacement sensor (13, l3a) coupled to a belt (14, 14a), harness or the like arranged to be fixed in a loop around said living being, electronic means for controlling the signals delivered by said sensor and alarm means (50) controlled by said electronic control means, said electronic control means and said alarm means being housed in said housing itself carried by said belt or harness.  2- Survival device according to claim 1, characterized in that said displacement sensor is constituted by the association of at least one effect cell Hall (20) and at least one magnet (22), one of these two elements being connected to said belt or harness.  3- monitoring device according to claim 1, characterized in that said element connected to the belt is mounted on a movable assembly (25).  4- monitoring device according to claim 3, characterized in that said sensor comprises two such magnets (22a, 22k} arranged in the vicinity of said cell and respectively integral with two movable supports (25a, 25b) of said movable equipment, each of these supports being connected to said belt, harness or the like.  5- monitoring device according to claim 3, characterized in that said sensor comprises two such magnets (22a, 22k) and two such cells (20a, 20k) respectively arranged in the vicinity of the magnets, the latter being respectively secured to two movable supports (25a, 25b) of said movable assembly, each of these supports being connected to one end of said belt, harness or the like.  6- Monitoring device according to claim 4 or 5, characterized in that each support (25a 25b> is a flat element pivotally mounted on an axis of said housing, in that it comprises a loop (30a, 3Ob> for attaching said belt or harness and in that it is urged by an elastic means (32a 32b) towards a predetermined rest position.  7- Monitoring device according to claim 6, characterized in that the elastic means (32a, 32k) of the two supports have different stiffnesses.  8- Monitoring device according to claim 7, characterized in that each elastic means is constituted by a flexible rod (32a, 32>) elastically, mounted between a corresponding support and an anchoring structure defined in said housing.  9- Monitoring device according to claim 8, characterized in that the rods (32a, 32b) are of unequal lengths and are aligned on either side of a common anchoring structure.  10- Monitoring device according to claim 2, characterized in that said displacement sensor (13a) comprises at least one magnet (122> directly fixed on a section of elastic band (16a) connected to said belt.  11- Monitoring device according to claim 10, characterized in that said displacement sensor comprises two such magnets (122a, 122b) fixed on said section of elastic band and in that these magnets are at respective predetermined distances from two cells to corresponding Hall effect (20a 20b), when said section of elastic band has a predetermined initial elongation, said cells being housed in said housing.  12- Monitoring device according to claim 11, characterized in that said elastic band section (16au includes a registration mark (23> for determining said initial elongation  13- Monitoring device according to one of the preceding claims, characterized in that the electronic monitoring means comprise means for shaping (40, 41, 42) of the signals delivered by said sensor and time measurement means ( 44, 45), controlled by said shaping means.  14- Monitoring device according to claim 13, characterized in that the time measuring means comprise a monostable for apnea control (45), connected to return to a predetermined state if no signal is delivered by the means shaping for a predetermined period of time, the return to said state controlling said alarm means (50, L1).  15- Monitoring device according to claim 14, characterized in that the time measuring means further comprise a monostable for the control of polypnea (44), connected to the shaping means.  16- Monitoring device according to claim 14, characterized in that said monostable for the control of polypnea is inserted between said shaping means and said monostable for the control of apnea.