DE19505765A1 - Pressing force measurement appts. for medical compression cuffs and bands - Google Patents

Abstract

The appts. includes a pneumatic sensor system (S), a compression device and an inflator (I). The sensor system can be introduced between the body part under investigation and the compression device together with an electronic evaluation and display system. The inflator fills a closed vol. of the sensor system by linear air vol. injection. The sensor system detects the pressure increase within the closed vol. The resulting pressure signal is continuously applied to the electronic evaluation and display system so that the non-linear calibration curve of the sensor can be determined. The calibration curve depends on the external pressure of the compression device, and the external press. analytically derived from the shape of the curve.

Description

The invention relates to a device for direct Measurement of medical compression measures at the human body targeted pressure. The The main area of application for the device is over monitoring, quantification and control of compression therapy of venous leg disease.

For the function of the leg veins as working memory of the Blood is of great importance because of its elasticity,  however, their overexpansion from various medical Reasons undesirable. With a targeted external compress sion of the lower extremity, the elasticity of the limit superficial venous system. For the quantifi It adorns the mode of action of compression therapy therefore particularly important, the local contact pressure directly "on site" - d. H. under the stocking or bandage on the leg of the patient - to measure, both in the resting patient (static resting pressure) as well during patient movement (dynamic working pressure).

Several measuring methods are known from the literature, the different types of sensors for compression measurement use that between the leg and the stocking to the desired measuring point are introduced. The type of sensor, -form and dimensions are important requirements sets, because on the one hand the active sensor measuring surface must adjust the leg shape elastically and some squares may not fall below timeter (for local structural to be able to compensate for leg and stocking options), on the other hand, the sensor volume from nearby measuring technology no additional stocking expansion due to technical reasons may do things. In addition to various force transducers (e.g. Deh voltage measuring strip sensors), optoelectronic, capacitive ven and piezo sensors have emerged from the above. Reasons proven in all balloon or cushion-like hollow sensor bodies, which are filled with air or liquid and over a Hose are connected to the pressure gauge.

The biggest, so far unsolved problem of the latter However, the type of sensor is that the measurement results depend were from the pressure of the measuring medium (air or liquid) in the sensor system, which in turn is in the highly non-linear  and depend on various boundary conditions Volume / pressure ratio of the sensor is physically justified is. In the case of water-filled sensors, limit additionally the practicability and the measurement accuracy undesirable hydrostatic pressure components caused by an altitude difference between the sensor level and the pressure transducer arise.

In another known measurement method, the pneuma table sensor with an electrical contact on the inside inner wall of the sensor cavity, which is at rest condition (internal air pressure in the sensor corresponds to the atmosphere pressure) is closed. Now the air is inside pressure in the sensor increases until it detects the external connection pressure exceeds what is then through the contact break is displayed.

So you could according to the previous state of the art only approximately the static contact pressure agree, which is when the body is under the compressing Has stopped effect of the stocking.

The invention has for its object a Measuring device with a flat, air-filled sensor specify the disadvantages of previously known measurement methods eliminated and a direct measurement of both the static as well as the dynamic contact pressure of the medical compression measures allowed.

An inventive solution to this problem is in the pronounced 1. Advantageous further developments are Subject of claims 2 ff.

The invention is surprisingly simple  The basic idea behind every pressure measurement linear increase in air volume the current air volume-air pressure ratio of the sensor - the so-called Calibration curve - first to determine all Eliminate sources of measurement errors. This happens through a targeted (manual or automated) injection of for example 5 ml of air in 5 seconds in the pneumatic System, d. H. with a constant filling rate of preference way 1 ml / s. It can then be obtained from the calibration curve according to the static contact pressure of the compresses Determine measure by recognizing that this pressure Po the point of maximum curvature corresponds to the calibration curve. The maximum curvature will be online for filling the pneumatic sensor system electronically preferably by double differentiation the calibration signal and maximum value determination (d2P / dt2 = max) calculated.

At the same time, the air volume in Sen sorsystem to reach the static contact pressure of the Compression measure was required. Now will this Air volume in the sensor (again manually or automatically) then dynamic compression can also be set pressure measurements, e.g. B. during active footwork leads.

The invention is hereinafter without limitation general inventive concept based on exemplary embodiments play exemplary with reference to the drawings to the rest of the disclosure all of the invention not explained in detail in the text Details are expressly referred to.

Show it:  

Fig. 1 shows an embodiment of the sensor with its calibration curve (V / P function) and the inflator (ventilation system),

Fig. 2 shows the basic structure of a measuring and evaluating device according to the invention,

Fig. 3-5 different measurement results and typical measurement curves.

Fig. 1 shows schematically a possible configuration of the pneumatic sensor system. The sensor (S) is preferably designed as an airtight capsule-like and very flat hollow body with elastic, but not stretchable film walls. It is connected to a pressure transducer ( 1 ) via a pneumatic hose system (P) consisting, for example, of two hose lines (P1, P2) and a 3-way valve (P3). An inflator (I) is connected to the 3-way valve, which is used for targeted ventilation and also ventilation of the pneumatic sensor system. Depending on the required precision of measurement, either an electronically controlled pump and valve system or a manually operated air pump serves as the inflator. Not shown in the figure is a temperature sensor which comes to rest with the sensor (S) between the body part to be measured and the compression measure, for example a rubber stocking.

When preparing for the measurement, the first is empty Sensor in the desired position between the body and Compression stocking put on. Because of the adaptation to the Leg shape and temperature is recommended to use the sensor for a few seconds with the full inflator content to fill. After emptying and calibration the measuring electronics to 0 mmHg can do the actual measurement be started. Helpful for a favorable measurement situation  is a constant temperature that is currently from the Temperature sensor that is in the same place as the sensor is displayed.

In an inexpensive embodiment, this is Sensor system made from a modified Leitz plastic doo document cover (60 × 70 × 0.5 mm) designed as a sensor, two 1 m long infusion lines, an infusion tap and a modified 5 ml plastic syringe. Under have searches with different sensor sizes result in sensors with surfaces between 30 to 40 cm² are cheap.

According to the invention, the plastic syringe has a ventilation opening (E) in the upper part, so that when the syringe plunger is pulled out, the outside air pressure in the system is automatically established. When carrying out the measurement, for example on the lower extremity, the sensor is placed in the desired position between the leg and the compression stocking. When the syringe plunger moves slowly, the vent hole (E) is first closed and then the air content of the syringe is injected into the pneumatic sensor system at a linear filling rate of preferably 1 ml / s (V (t) is a straight line). The linear increase in air volume is converted as a non-linear pressure function P (t) by the pressure transducer ( 1 ) into an electrical measurement signal due to the sensor-specific, strongly non-linear V / P function (air volume / air pressure function).

An embodiment of the further signal evaluation according to the invention is shown in FIG. 2, specifically for a single-channel measuring device.

The electrical measurement signal at the output of the pressure transducer ( 1 ), which is proportional to the air pressure in the sensor system, is first preferably processed in the amplifier ( 2 ), freed of any interference signals with a filter ( 4 ), via a switching circuit ( 9 ) to the analog / digital converter ( 10 ) guided and finally shown on a LC display ( 11 ) as the current air pressure in the sensor system. A calibration circuit ( 3 ) ensures that the start air pressure 0 mmHg is shown on the display when the atmospheric air pressure in the sensor system (ventilation hole in the inflator is open). During the recording of the calibration curve, the P (t) signal is additionally fed via filter ( 5 ) to a differentiator ( 6 ). After a double signal derivation, the circuit ( 7 ) ensures maximum value detection within a specially defined time window. This pressure value corresponds to the resting pressure Po of the external compression measure; it is stored electronically in ( 8 ) and can be read visually via ( 11 ) or registered on an xt recorder via the analog interface ( 12 ). The determination of the resting pressure of the external compression is now complete.

If the dynamic compression pressure behavior is also to be measured and registered, proceed as follows:
With the help of the inflator, the air volume in the sensor system which corresponds to the determined resting pressure Po is now set manually or automatically. If now, for example, a standardized leg exercise is performed for the patient (walking, squatting, etc.), the measuring device registers the time-dependent change in the contact pressure of the compression measure, which is often referred to as the so-called working pressure of the stocking.

If a commercially available microcontroller system ( 13 ) is optionally integrated into the measuring device according to the invention, the entire measuring sequence can be automated by controlling the inflator and the individual circuit groups ( 1 to 12 ), which at the same time leads to an increase in measuring accuracy by means of appropriate pattern recognition algorithms. One of these additional calculation algorithms, for example, determines the tangent at the point (dP / dt = max), which corresponds to the maximum slope of the calibration curve. It was shown empirically that the point of intersection of the tangent with the pressure axis generally does not deviate significantly from the Po value. So z. B. Detect operating errors or invalid measurement results with microprocessor support. Via the digital interface ( 14 ), the entire data and protocols z. B. for archiving or further processing to external computer systems.

Multi-channel sensor measurement systems for simultaneous Compression pressure measurement on different parts of the body or in different leg floors are corresponding train several times. So is to operate several pneumatic sensor elements for pressure measurement on under different parts of the body just a single inflator necessary. The inflator pump is used in an advantageous manner connected to a pneumatic distributor, the one Splits the line into, for example, three further lines.

There is one electronic in each line controllable pneumatic valve provided through which the inflation process for each subsequent pneumatic Sensor element can be made separately. With this structure, the calibration process can be computer controlled be carried out one after the other for each sensor element.

The pneumatic sensor elements each have  a separate pressure transducer so that the respective idle Contact pressures can be determined independently of each other can. To perform dynamic compression pressure measurement, it is advantageous that with the help of pneumatic valves in the individual pressure lines Air volumes in the sensors are set fully automatically can be to the respective resting pressures P₀ ge Listen.

Fig. 3 shows the results of a series of tests with which the measurement accuracy of the device according to the invention was experimentally checked. The sensor was placed on an artificial leg. A wide blood pressure cuff served as a compression measure with an exactly definable contact pressure. In a total of 33 measurements, the contact pressure was set to predetermined pext values between 10 and 50 mmHg using a calibrated electronic pressure gauge system and compared with the Po pressure values measured by the invention. The statistical evaluation showed good measuring accuracy of the device. With a correlation factor of 0.98, the mean value difference was only 2% with comparable standard deviations.

Fig. 4 shows the results of a further test series, in which (14 healthy veins and 7 venous patient) the resting pressures Po of compression stockings of Class 2, AD, in the B level were measured (shortly above the ankle) in 21 subjects. In the standing position, the mean resting pressure was 23.7 +/- 3.1 mmHg. With the legs elevated, the mean resting pressure value decreased to 18.4 +/- 3.1 mmHg, in accordance with the physiological idea.

Finally, FIG. 5 shows the registration of the working pressure of a class 2 compression knee weep measured in the middle of the lower leg of a 48-year-old patient with varicose veins during standardized walking (13 steps after metronome dictation in 26 seconds). The resting pressure before the start of the exercise was 24.8 mmHg. The maximum registered pressure fluctuation was 4.9 mmHg. In the resting phase after the end of the exercise you can see from the increase in the registered contact pressure the increase in blood volume in the extremity. With the invention, the kinetics of the change in blood volume in the extremity or the decongestive kinetics (reduction of the tissue water volume) in lymphatic diseases can thus be demonstrated.

Claims (13)

1. Device for measuring the contact pressure of medical compression measures with a pneumatic sensor system which can be attached between the body part to be examined and the compression measure, and an electronic evaluation and display system, characterized in that
that an inflator is provided which fills a closed volume of the sensor system by linear air volume injection,
that the pneumatic sensor system detects the air pressure rise occurring within the closed volume, and
that the pressure measurement signals of the sensor system are continuously applied to the electronic evaluation and display system, so that a non-linear calibration curve of the sensor which is dependent on the external pressure of the compression measure can be determined and the external pressure of the compression measure acting on the sensor can be determined analytically from the shape of the calibration curve . 2. Device according to claim 1, characterized in that the compression measure over the human extremities rubbery coating is. 3. Device according to claim 1 or 2, characterized in that the pneumatic sensor system has a pressure transducer and a closed volume, that as an extremely flat, capsule-like, airtight  Hollow body with soft elastic, but not stretchable Walls is formed. 4. Device according to one of claims 1 to 3, characterized in that a targeted loading and Ent ventilation of the pneumatic sensor system by a manually operated inflator (I) is made, the consists of an injection syringe with an opening (E) which, when the syringe plunger is pulled out to automatic pressure equalization. 5. Device according to one of claims 1 to 4, characterized, that the inflator (I) is an electronically controlled one Has a pump-valve combination. 6. Device according to one of claims 1 to 5, characterized in that a microprocessor ( 13 ) controls the entire measurement procedure including the targeted ventilation of one or more pneumatic sensor systems. 7. Device according to one of claims 1 to 6, characterized in that the inflator during the up Take the calibration curve 5 ml within 5 seconds Air with a constant filling rate of 1 ml / s into the sensor system injected. 8. Device according to one of claims 1 to 7, characterized in that the pneumatic sensor system is combined with a temperature sensor. 9. Device according to one of claims 1 to 8, characterized in that a single inflator over  a pneumatic distributor unit for ventilation of several pneumatic sensor systems. 10. The device according to claim 9, characterized in that between the pneumatic Distribution unit and the pneumatic sensor systems one electronically controlled pneumatic valve each is provided. 11. The device according to one of claims 1 to 10, characterized, that with the help of the evaluation electronics the maximum Curvature point of the calibration curve can be determined, which is the sought static contact pressure of the compression measure corresponds directly. 12. The device according to one of claims 1 to 11, characterized, that with the help of the evaluation electronics additional charak Teristic shape features of the calibration curve can be calculated are used to determine the contact pressure become. 13. The device according to one of claims 1 to 12, characterized, that with the help of the evaluation electronics tical shape features of the calibration curve only in certain Time windows are predictable.