NL8004548A - COAGULOMETER. - Google Patents

Description

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Coagulometer

The invention relates to a coagulometer as indicated in the heading of claim 1.

In such a known coagulometer, in the measuring tube, which is kept strongly inclined and rotatingly driven, there is a proportionately the arc with which the wall of the measuring tube merges into the bottom of the measuring tube, a small glass ball which, on account of the strongly inclined position of the measuring tube in the bottom part thereof is held in a certain place by gravity, whereby normally the glass-ball is rotated by the rotation of the measuring tube.

If the formation of fibrin or the fibrin wires starts at the beginning of the barrel, it is due to the adhesion of the fibrin wires to the glass ball and to the wall of the measuring tube that the glass ball passes through the measuring tube. its rotation is included. The position of the glass ball thus changes, which is registered by the operator with a view to which, for example, a time measuring device or a comparable recording device, which is switched on at the start of the measurement, is switched off.

An automatic registration of the start of the ronning and therefore an automatic measurement of the duration of the ronning for a particular sample present in the measuring tube is not sensible with such a coagulometer, because firstly the movement of the glass ball is relatively uncertain. and because, secondly, in this arrangement and design, the glass ball can again quickly divert towards the center of the bottom of the measuring tube under the influence of its own weight, so that often only a very slight displacement movement of the cone occurs, which can still be observed visually, but which cannot automatically be registered reliably enough. A further drawback of this arrangement is that, in view of the requirement of visual observation, only clear samples of plasma can be used. When dark samples of plasma are used and when whole blood is used, the displacement movement of the bullet cannot be visually observed sufficiently reliably.

Furthermore, a coagula meter has become known in which a steel ball is held in a stationary position relative to the moving tube by means of two opposing magnets in a measuring tube which can be moved up and down, wherein a scanning device consisting of a lamp is arranged in a perpendicular axis. and a photocell is arranged. Normally, the measuring tube moves relative to the ball held by the magnets. When the formation of fibrin wires starts at the beginning of the roning, the steel ball is again captured by the measuring tube moving up and down. As a result, the steel ball moves away from the position in front of the photocell 20, so that the light from the lamp reaches the photocell and a control pulse is generated which can be used to stop a previously started counting mechanism.

Such a coagula meter has a complicated construction and is expensive to manufacture. In any case, two detection systems for the ball must be present, firstly the magnetic retention system and, in addition, the optical impulse emitting control pulse. The steel ball and the walls of the measuring tube must be manufactured with great precision in order to ensure reliable transport.

3Q In addition, generating a forced up and down for the measuring tube is expensive. To be able to stay cheap here · a motor has therefore been installed under the measuring tube JL t.

which drives an eccentric. The eccentric periodically raises the measuring tube guided in a bore of a frame, which then drops back on the basis of its own weight. As a result, however, 800 4 5 48 * 3 makes the device susceptible to malfunctions, since the measuring tube often does not drop at all, or only partly or only very slowly, due to its own weight. This is primarily caused by the fact that the not particularly protected bore 5 is exposed to the risk of dust pick-up. The movement of the steel ball is thus automatically registered. Despite the very expensive construction of the device, the registration is relatively uncertain. Again, the optical sensing system practically allows the use of clear plasma samples, but not dark plasma samples or whole blood samples.

The object of the invention is a coagulometer of the above-described type, which, in the case of simple construction, ensures safe and reliable automatic detection of the start of the ronning.

This is possible according to the invention by the feature of claim 1.

This embodiment ensures that upon the initiation of the barrel, a system of fibrin threads between the ball in the region of its bullet loco, but additionally also between the ball and the corresponding region of the wall of the measuring tube and, opposite, also between the ball and the corresponding area of the limiting step are created. The limiting step moreover prevents the ball from diverting to the center of the bottom of the tube due to its own weight when it is carried along by the rotating measuring tube. It has been found that in this embodiment a safe and reliable transfer of the ball is achieved at the start of the rounding and that the ball passes through a precisely defined path during the transfer phase, so that the change of the position of the ball is also correspondingly reliable by a probe that delivers a control pulse can be automatically registered. Such a coagulometer is also very simple in its construction. Only the rotary drive for the measuring tube is necessary. It is further preferred to keep the measuring phase in the first part of 800 45 48 4 in a conceivably simple manner, thereby keeping the measuring tube in a tilted position in a known position in a known position in the bottom part of the measuring tube. and thus the bullet. by gravity in the determined position.

Particularly preferred embodiments of the invented coagulometer are indicated in the subclaims.

The embodiment according to claim 2 is particularly important. The use of such a channel ensures that the ball in the first part of the measuring phase practically always only has a point-like contact "with the measuring tube, so in this phase there is no tendency for a for example timely removal of the bullet and in particular no tendencies for tumbling or rocking movements of the bullet are available.

It has further been found that a very particularly safe and in particular also temporarily very precisely defined carrying of the ball can be achieved when the limiting step and the wall of the measuring tube are ribbed in their parts near the ball.

A further advantage is the use of the magnetic probe and the construction of the ball from a ferromagnetic material. This makes it possible to examine not only clear plasma samples, but also dark plasma samples and whole blood samples, so that such a coagulometer is also particularly versatile.

An exemplary embodiment of a coagulometer according to the invention is described in more detail below with reference to the drawing.

Fig. 1 is a top plan view of a measuring tube of a coagulometer according to the invention.

FIG. 2 is a sectional view taken on the line ΓΕ-ΓΕ in FIG. 1 showing the measuring tube in its oblique working position.

Fig. 3 shows the circuit diagram of the magnetic probe and the associated control circuit of a coagulometer 35 according to the invention.

800 45 48 φ * 5 The measuring tube 1 of the coagulimeter shown in Figs. 1 and 2 has a substantially cylindrical side wall 2 which narrows slightly upwards in its thickness and which extends rectangular into the bottom 3 of the measuring tube.

5 Centrally with respect to the center line of the tube, a limiting step 4 tapers upwards from the bottom 3 to the top. The bottom 3 further forms a ball race for a steel ball 5 to be arranged in the measuring tube (see Fig. 2).

This ball race is determined by a trough 6 which is formed in the bottom 103 and has a radius of curvature which is slightly greater than the radius of the ball 5. This embodiment ensures that the ball 5 practically only lies in the trough 6 with point contact.

As can be seen from Figs. 1 and 2, the limiting step 4 is ribbed on its outer jacket because the tap is provided with several small ribs 7, which are spaced apart from each other, which are parallel to the longitudinal axis of the measuring tube. is ribbed in its lower region co-operating with the ball 5 and is also in the form of some spaced apart small ribs 8, which are parallel to the longitudinal axis of the tube. The ribs 7 and 8 protrude only so far that they have no contact at least during the normal phase of operation, the ball 5 located in the gutter 6. The arrangement of the gutter 6, its dimensions as well as the dimensions of the ball and the dimensions of the ribs is such that the ball 5 in this normal phase is always only at a small distance from the respective parts of the ribs 7 and 8.

The design is thereby arranged such that, in contrast to the side wall 2, the ribs 8 of this side wall with a curvature radius correspond to the curvature radius of the trough itself into the trough 6. The ribs 7 and 8 are designed such that they narrow slightly upwards relative to their height as well as their width.

The coagulometer is equipped with a dry thermostat (not shown), the measuring tube being rotatably mounted in a slightly inclined position of approximately 10 ° (this inclined position is shown in Fig. 2 800 4 5 48 6). The measuring tube 1 is brought into its center line by a rotary drive (not shown) in slow rotation. To measure the ronning time, that is, the onset of the formation of fibrin threads at the onset of the nun, the nun material, either light or dark plasma or whole blood, is fed into the measuring tube. Due to the inclined position of the measuring tube, the steel ball 5 is held in a specific position relative to the measuring tube 1 and the ball is rotated by the point contact with the rotating measuring tube itself, but retains ------- --------- incidentally, based on its own weight, its certain position in space. At the start of the rounding, the free partial areas of the gutter 6 and in particular the side wall 2 and the boundary step 4, and here again in particular between the parts concerned, now form in the narrow spaces between the steel ball 5 on the one hand and on the other hand. of the ribs 7 and 8, a system of fibrin threads, which is particularly well anchored by the ribs 7 and 8, now leads to a reliable and temporarily very precisely defined transfer of the steel ball 5 through the measuring tube 1.

The steel ball 5 thus now follows the rotational movement of the measuring tube X and thereby leaves the first position given. This change of position, which is precisely defined in each view, is registered in the exemplary embodiment drawn by a magnetic sensor arranged in a continuous path adjacent to the outer jacket of the measuring tube 1, in the vicinity of the steel ball 5 in the drive-through phase, wherein the The sensor delivers a control pulse to stop a recording time recorder which has been triggered when the material to be regenerated is fed.

The magnetic scanning device 9 used in the illustrated exemplary embodiment is shown in FIG. 3 together with its control circuit. The deployed magnetic scanner has an integrated Hall system 10 and is adapted to convert an inductance change into a proportional voltage change with a positive increase of 800 45 48 7 in output voltage with increasing inductance. Such a Hall system magnetic scanning device has no hysteresis behavior and can thus be regarded as a linear converter. A permanent magnet (not shown) is mounted on the back of the scanning chip, which generates an inductive bias voltage which ensures that the change of the induction can only be achieved by approximating a magnetic material. Such a change in the inductance extends through the sensing chip since the permanent magnet located on the back and the passing magnetic material on the front are the causes of the magnetic current. Via a passive EC low-pass fliter 11, which serves by suppressing interfering influences, the signal delivered by the scanning device 9 is capacitive on a first operational amplifier 12, namely on the non-inverting input thereof. As a special feature, this first operational amplifier is switched in such a way that its inverting input is supplied via a resistor-resistance combination with a part of the output voltage of the operational amplifier, one resistor being adjustable and simultaneously bridging it with a capacitance. . The amplification ratio of the operational amplifier 12 follows from the adjusted ratio of the two resistors. The bridging capacitance C automatically decreases this set ratio with increasing frequency and thereby the gain. As a result, signals with a high voltage change rate, which are a frequent cause of disturbances, are completely counter-coupled and have no influence on the measurement.

The very amplified signal obtained in this way at the output of the operational amplifier 12 is supplied to a second operational amplifier 13, which acts as a voltage comparator with hysteresis. The hysteresis behavior ensures that there is no constant switching, for example. The circuit is designed such that over two resistors at the inverting input of the operational amplifier 13 35 in the manner of a voltage divider, for example, the half voltage 800 4 5 48 δ is given such that the operational amplifier exceeds the half supply voltage, such as when it is given from the first operational amplifier 12 to the non-inverting input of the operational amplifier 13, it produces a pulse which is taken as a stop signal for the recording mechanism measuring the ringing time, for example an electronic stop clock (not shown). The course of the actuation is after all such that the ball 5 in the take-over phase first approaches the scanning device 9 and then passes it, so that a semi-wave-like course of the signal is created.

By the indicated arrangement and circuit of the second operational amplifier 13, exactly the point, namely on the rising edge of such a half wave, is fixed, to which the stop signal for the electronic stop clock is delivered.

To further eliminate influences from the mains supply and to keep the operating points set once stable, the described control circuit, including the scanning device, is preferably supplied via a voltage regulator. At the same time, a temperature-stabilized differential voltage source supplies the reference voltage necessary for setting the shifting voltage of the scanning device.

In the above-described embodiment, the steel ball 5 is held in a particularly simple manner in the construction phase by gravity 25 in connection with the inclined position of the rowing tube in the determined position in the first phase of the measurement. In an embodiment of this, in special cases with perpendicular measuring tubes, the ball can also be held in position by a small holding magnet with a certain force.

800 4 5 48

Claims (10)

1. Coagulometer with a rotatingly driven measuring tube and a ball held on the bottom of the tube and movable ball rotating through the wall of the tube, which is movable through the wall of the measuring tube at the time of the formation of flbrine fibers. characterized in that the ball race is located in the region of the bottom (3) of the measuring tube and a limiting step (4) projecting centrally with respect to the bottom (3) is such that the ball (5) is located at a small distance from the affected area 10 of the limiting step (4) as well as at a small distance from the affected area from the wall (2) of the measuring tube and that on the path described by the ball (5) in the entrainment phase the ball-sensing control pulse-emitting sensor (91) is disposed. Coagulimeter according to claim 1, characterized in that the ball trajectory is defined by a trough (6) formed in the bottom (3) of the measuring tube, the radius of curvature of the trough being slightly greater than the radius of curvature of the bullet 5. Coagulimeter according to claim 1, characterized in that the limiting step (4) and the wall (2) of the measuring tube are ribbed in their sections near the ball. Coagulometer according to claim 3, characterized in that the corrugation is formed by small ribs (7, 9) which are spaced apart from one another and parallel to the axis of the measuring tube. Coagulometer according to claim 4, characterized in that the ribs (8) present on the wall 0 of the measuring tube with a radius corresponding to the radius of the channel (6) run into the channel (6). Coagulometer according to claim 1, characterized in that the scanning device is a magnetic scanning device (9) and the ball (5). consists of ferromagnetic material. Coagulometer according to claim 6, characterized in that the magnetic scanning device (9) is provided with an integrated Hall system (10). Coagulaneter according to claim 6 or 7, characterized in that the magnetic scanning device (9) is coupled to an operational amplifier (12) in control mode, the scanning device loading the non-inverting input of the amplifier, the inverting input of the operational amplifier (12) is connected to part of its output voltage across two resistors, one of the resistors being adjustable and bridged by one capacitance. Coagulaneter according to claim 8, characterized in that a passive RC low-pass filter (11) is switched on between the output of the magnetic scanning device (9) and the non-inverting input of the operational amplifier (12). Coagulonter according to claim 7, characterized in that a second operational amplifier (13) is arranged behind the first operational amplifier (12), which is connected as a voltage comparator with hysteresis. 800 4 5 48