CH648671A5 - Apparatus for measuring the blood clotting time - Google Patents

Description

The invention relates to a device for measuring blood, but the device is susceptible to faults, since sometimes the measuring tube clot time does not decrease at all, only partially or only very delayed because of its own weight. This primarily results

In such a known device it is found that the not particularly protected bore of the

the measuring tube, which is held in a steep inclined position and exposed to the risk of dust. The relocation of the steel

is driven in rotation, one in relation to the crumb is thus automatically registered. The registration with which the measuring tube wall merges into the measuring tube is, despite the very expensive construction of the device, a relatively small glass ball, which is insecure due to the inclined angle. Here too, the optical detection system

ge of the measuring tube in its bottom area due to the stem practically only the use of bright plasma samples,

Gravity is held at a predetermined location, but not dark plasma samples or whole blood samples.

in the normal case the glass ball by the rotation of the The present invention is therefore the task

Measuring tube is rotated. Now starts with creating a device of the generic type that prevents coagulation from forming fibrin or fibrin filaments safely and reliably with a simple design

automatic detection of the start of coagulation is guaranteed.

The solution according to the invention results from the characterizing part of claim 1.

The design there causes a fibrin thread structure to form between the ball in the area of its ball track at the start of coagulation, but also between the ball and the corresponding area of the measuring tube wall and, on the opposite side, also between the ball and the corresponding area of the limiting pin . The limiting pin also prevents the ball from moving under the weight of the rotating measuring tube towards the center of the tube base. It has been shown that with this configuration there is a safe and reliable ball entrainment when the coagulation begins and that the ball travels a precisely defined path in the entrainment phase, so that this change in position of the ball is automatically carried out accordingly by a sensor triggering a control pulse can be registered. The construction of such a device is also very simple. Only the rotary drive for the measuring tube is required. It is also preferred to hold the ball in a very simple manner in the first part of the measurement phase in a known manner at a predetermined location in the bottom region of the measuring tube by arranging the measuring tube in an inclined position, that is, the ball is held in place by gravity .

Particularly advantageous embodiments of the device according to the invention are characterized in the dependent claims.

Particularly noteworthy is the design according to claim 2. The use of such a channel ensures that the ball practically always has only point contact with the measuring tube in the first part of the measuring phase, in this phase there is therefore no tendency to take the ball around prematurely and in particular also there are no tendencies for the ball to wobble or swing.

It has also been shown that a particularly safe and, in particular, also very precisely defined driving of the ball can be achieved when the limiting pin and the measuring tube wall are corrugated in their regions close to the ball.

The use of the magnetic sensor and the formation of the ball from a ferromagnetic material are also of particular advantage. This makes it possible to examine not only bright plasma samples, but also dark plasma samples and whole blood samples, so that such a device is also particularly versatile.

An embodiment of a device according to the invention is described below with reference to the drawing.

Show it

1 is a plan view of a measuring tube of a device according to the invention,

2 shows a section along section line II - II of FIG. 1, showing the measuring tube in its oblique functional position,

Fig. 3 shows the circuit diagram of the magnetic sensor and the associated control circuit of a device according to the invention.

The measuring tube 1 of the present device shown in FIGS. 1 and 2 has an essentially cylindrical side wall 2 which tapers slightly upwards in terms of its material thickness and which merges at right angles into the bottom 3 of the measuring tube. Centrally to the central longitudinal axis of the tube stands from the base 3 a conically upward

3,648,671

recent limiting pin 4 before. Furthermore, the base 3 defines a ball track for a steel ball 5 to be arranged in the measuring tube (see FIG. 2). This ball raceway is defined by a groove 6 which is molded into the base 3 5 and which has a radius of curvature which is slightly larger than the radius of the ball 5. This configuration has the effect that the ball 5 lies practically only in the channel 6 with point contact.

As can be seen from FIGS. 1 and 2, the limiting pin 4 is corrugated on its outer jacket in that it is provided with a plurality of small webs 7 which are spaced apart and parallel to the longitudinal axis of the measuring tube. The side wall 2 of the measuring tube is also corrugated in its lower region, which cooperates with the ball 5, and i5 also in the form of a few small webs 8 which are spaced apart from one another and are parallel to the longitudinal axis of the tube. The webs 7 and 8 project only so far that they at least in the normal phase of operation, they cannot have any contact with the ball 5 located in the channel 6. The arrangement of the channel 6, 20, its dimensioning and the dimensioning of the ball and the dimensioning of the webs is dimensioned such that the ball 5 in this normal phase is only a short distance from the respective areas of the webs 7 and 8 concerned.

2s The configuration is such that, in contrast to the side wall 2, the webs 8 of this side wall enter the channel 6 themselves with a radius of curvature corresponding to the radius of curvature of the channel. The webs 7 and 8 are designed in such a way that they taper slightly upwards both in terms of their height and their width.

The device contains a dry thermostat (not shown), in which the measuring tube is rotatably mounted in a slight inclined position of approximately 10 ° - this inclined position is shown in FIG. 2. The measuring tube 1 is set in slow rotation about its longitudinal axis by a rotary drive (not shown). To measure the clotting time, i.e. of the onset of fibrin filament formation in the coagulation batch, the coagulation batch, either light or dark plasma or whole blood, is introduced into the measuring tube tube. Due to the inclined position of the measuring tube, the steel ball 5 is held at a predetermined position relative to the measuring tube 1 and it is set in rotation by the point contact with the rotating measuring tube itself, but otherwise maintains its predetermined spatial position due to its own weight. When the coagulation occurs, the narrow spaces between the steel ball 5 on the one hand and on the other hand the free partial area of the channel 6 and in particular the side wall 2 and the limiting pin 4, and here again in particular between the affected web areas 7 and 8, are immediately formed by the webs 7 and 8 is a particularly well anchoring fibrin thread framework, which leads to a safe and very precisely defined time of the entrainment of the steel ball 5 through the measuring tube 1. The steel ball 5 now follows the rotational movement of the measuring tube 1 and thereby leaves the initially predetermined position. This change of position, which is precisely defined in every way, is registered in the exemplary embodiment shown by a magnetic sensor arranged adjacent to the outer jacket of the measuring tube 1, specifically in the area of the path traversed by the steel ball 60 5 in the entrainment phase, which triggers a control pulse in order to prevent a Enter the coagulation approach to start the registering device for the coagulation time.

65 The magnetic sensor 9 used in the illustrated embodiment is shown together with its control circuit in FIG. 3. The magnetic sensor used has an integrated Hall system 10 and is designed to use an induction

648 671

to convert the change into a proportional voltage change, the output voltage rising with increasing induction. A magnetic sensor of this type with a Hall system has no hysteresis behavior and should therefore be regarded as a linear converter. A permanent magnet (not shown) is provided on the back of the sensor chip, which generates an inductive bias which ensures that the change in induction can be achieved solely by the approach of a magnetic material. Such a change in induction is made even more longitudinally by the sensor chip, since the permanent magnet on the back and the magnetic material passing by on the front are the causes of the magnetic flux. Via a passive RC low-pass filter 11, which serves to suppress interference, the signal emitted by the sensor 9 is capacitively passed to a first operational amplifier 12, namely to its non-inverting input. As a special feature, this first operational amplifier is wired in such a way that its inverting input receives a part of the output voltage of the operational amplifier via a resistor-resistor combination, one resistor being controllable and at the same time bridged by a capacitance. The gain ratio of the operational amplifier 12 results from the set ratio of the two resistors. The bridging capacitance C automatically reduces the set ratio and thus the gain with increasing frequency. As a result, signals with a high voltage change rate, which are a common cause of interference, are completely negative feedback and have no influence on the measurement.

The highly amplified signal obtained in this way at the output of the operational amplifier 12 is fed to a second operational amplifier 13, which acts as a voltage compensator.

rator with hysteresis. The hysteresis behavior ensures that the system is not switched continuously. The shading is designed such that, for example, half the voltage is given to the inverting input of the operational amplifier 13 in type 5 of a voltage divider via two resistors such that the operational amplifier when the half supply voltage is exceeded, as it is from the first operational amplifier 12 to the non-inverting one Given the input of the operational amplifier 13, emits an OK pulse, which is taken as a stop signal for the coagulation time measuring device, for example an electronic stopwatch (not shown). The course of the triggering is such that the ball 5 first approaches the sensor 9 in the entrainment phase and then runs ahead of it, so that a half-wave-shaped course of the signal results. The described arrangement and configuration of the second operational amplifier 13 exactly defines the point, on the rising edge of such a half-wave, at which the stop signal for the electronic stopwatch is emitted.

In order to further switch off influences of the mains supply and to keep the operating points that have been set stable, the described control circuit including the sensor is expediently fed via a voltage regulator. 25 At the same time, a temperature-stabilized differential voltage source uses the reference voltage required to set the sensor's offset voltage.

In the exemplary embodiment described above, the steel ball 30 5 is held in a structurally particularly simple manner in the first phase of the measurement by gravity in connection with the inclined position of the measuring tube at the predetermined point. In a modification of this, in special cases with a vertical measuring tube, the ball could also be held at the predetermined point by a small holding magnet of predetermined force.

C.

3 sheets of drawings

Claims (10)

648 671 2 PATENT CLAIMS arrive because of the adherence of the fibrin threads 1. Device for measuring the blood coagulation time with one of the glass ball and on the wall of the measuring tube, rotatingly driven measuring tube and one in which the glass ball is held by the measuring tube at its three-bottom region at a predetermined point and is carried away by the hung. So there is a change in the position of the wall of the tube, which can be rotated and rotated in the time 5 of the glass ball, which is registered by the operator with the point of fibrin fiber formation from the wall of the measuring eye, whereupon, for example, a time tube can then be taken along. characterized in that the factory or a comparable recording device, which was switched on at the beginning of the ball track in the area of the measuring tube bottom (3) so the measurement is switched off, is arranged and an automatic registration of the beginning of the low Limiting pin (4) is assigned in such a way that the ball is opened and thus an automatic measurement of the coagulation (5) at a short distance from the corresponding area of time for a specific limiting pin (4) entered in the measuring tube and also at a short distance from the sample is not sensibly possible with such a device, the corresponding area of the measuring tube wall (2) is because first, the movement of the glass ball is relatively un- and that the ball (5) is safe in the driving phase, and because, secondly, with this arrangement and the specified path, a response to the ball, the glass ball moves very quickly towards the center of the Measuring tube control pulse triggering sensor (9) is arranged. can move under their own weight, 2. Apparatus according to claim 1, characterized in that so that only a very slight displacement movement-the ball raceway is set by a movement of the ball in the tube bottom (3), which is defined by the visually still perceived groove (6) , whose radius of curvature can be made, but which is automatically not sufficiently sufficiently ring-greater than the radius of curvature of the ball (5). 20 can be registered. This configuration is disadvantageous 3. Apparatus according to claim 1, characterized in that in addition that in view of the need for the visual earth limiting pin (4) and the measuring tube wall (2) can only be worked with bright plasma samples, their spherical areas are corrugated. When using dark plasma samples and when using 4. Apparatus according to claim 3, characterized in that the whole movement of the ball would visually detect the corrugation by small, spaced apart and partly not sufficiently reliable record. Gauges parallel longitudinal webs (7,8) is formed. 5. Apparatus according to claim 4, characterized in that a device has also become known in which a steel ball having a radius corresponding to the channel radius is provided in the webs (8) provided on the measuring tube wall (2) with a measuring tube that can be moved up and down the gutter opposite by two opposing magnets (6) break in. 30 the moving tube in a standstill position 6. Apparatus according to claim 1, characterized in that ten is, wherein in a perpendicular axis to a sensor and the sensor is a magnetic sensor (9) and the ball (5) direction, consisting of lamp and photocell, is arranged. consists of ferromagnetic material. Normally, the measuring tube moves relative to that 7. Apparatus according to claim 6, characterized in that the ball held by the magnet. If fibrin thread formation begins with the coagulation magnetic sensor (9) with an integrated Hall system, the egg stem (10) is again provided. taking the steel ball through the up and down movement 8. Apparatus according to claim 6 or 7, characterized gekennzeich- measuring tube. As a result, the steel ball travels so that the magnetic sensor (9) continues to control in front of the photocell, so that the light from the lamp is linked to the operational amplifier (12) whose non-in photocell is reached and a control pulse is generated , the da-vertierend input it acts, whereby the inverting to can be used to stop a previously started count input of the operational amplifier (12) with part of its mechanism. Output voltage is connected via two resistors, Such a device has a complicated structure and one of which is adjustable, the latter of which is expensive to manufacture. In any case, two capacity is bridged. frame systems for the ball 9. Apparatus according to claim 8, characterized in that «times the magnetic holding system and on the other hand the optical detection system which triggers between the output of the magnetic sensor (9) and control pulse. A passive RC low-pass filter (11) must be switched on at the non-inverting input of the steel ball operational amplifier and the walls of the measuring tube (12). be manufactured with high accuracy in order to ensure 10. Apparatus according to claim 8, characterized in that take would ensure. In addition, the generation behind the first operational amplifier (12) would be a second operation of a forced up and down movement for the measuring tube ration amplifier (13), which is expensive as voltage cooking. In order to remain inexpensive here, da-parator is connected to hysteresis. a motor is provided under the measuring tube, which one Eccentric drives. The eccentric periodically lifts that in a adjusting bore guided measuring tube, which is then due 55 of its own weight drops again. This will