NL8400598A - ELECTRICAL MEASUREMENT SYSTEM FOR THE SELECTIVE MEASUREMENT OF THE CONCENTRATION OF AN ION I IN A LIQUID BY INTERVENTION OF AN ION I SELECTIVE FET COMPONENT. - Google Patents

Description

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Title: Electric measuring system for the selective measurement of the concentration of an ion Γ in a liquid by means of an ion-selective FET comonent.

The invention relates to an electrical measuring system for • selective measurement of the concentration of an ion uitgedrukt, expressed as pi, in a liquid »via an FET component selective for the ion I, which measuring system further contains as components 5 a reference electrode, an electrical voltage source for applying the drain-source voltage within the FET component and a voltage source for applying the gate voltage VqS between the gate and the source, an amplifier system and current-conducting wiring, with which the components are electrically connected rhine ·; Such a measuring system is known. Here, as the reference electrode, an ion-selective electrode is used, for example an Ag / AgCl electrode, which is in contact with a liquid with a constant Cl concentration. A practical drawback of the use of such an ion-selective electrode fs that drifts of this electrode leads to drifts of the entire measuring system *

The object of the invention is an electrical measuring system in which the above-mentioned drawback is eliminated.

According to the invention, a measuring system of the type stated in the opening paragraph is provided for this purpose, characterized in that the reference electrode is also a FET component selective for the ion I and this ISFET reference electrode can be brought into contact with a flush liquid of constant composition and constant pf, respectively, while both FET components are connected in a differential circuit.

It is true that an electrical blood measurement measuring system containing a pH-FET and a reference FET component is known. However, both FET components are contacted with the measuring liquid, i.e. with the blood, whereby one FET component is coated with a pH-sensitive layer while the other FET-30 component is coated with a membrane that would be insensitive. should be 8 * «0 5 9 8 .............. ........................... ......- 5 '. *. For each ion. The problem here, however, is that it is difficult to manufacture a truly ion-insensitive membrane. According to the out- * '. * invention · this problem is solved by using a FET component sensitive to the same ion type I in the measuring system as the reference electrode.

5 to record; and further providing means by which the FET reference electrode is exposed to a rinsing liquid with a known and constant pi value.

According to a . In a preferred embodiment, within the electrical measuring system according to the invention, the SFET reference electrode 10 is also electrically combined with an ion-selective electrode, which advantageously has an Ag / AgCl electrode fs. possible to calibrate the FET component in vivo during fn-vivo measurements as Tater will explain “

The invention will be explained in more detail with reference to the drawing, which shows an embodiment of the electrical measuring system. In the drawing, figure 1 schematically shows a longitudinal section of a catheter to be introduced into a bloodstream of the human for the in vivo measuring the blood plt; Figure Z schematically shows the differential circuit of the two FET components. and figure 3 shows an overview of the potential jumps at issue within the measuring system.

In Figure 1, a catheter is indicated by 5 which can be introduced into a human bloodstream. The catheter comprises the catheter tip 7 where a pH-FET 1 is arranged. The pH-FET may come into contact with the blood via the opening 11 in the wall of the catheter tip .7. electric line pair 12 are the drain resp. the source included in the total electrical measurement system.

The catheter is of two lumens 8 resp. 9, wherein the pair of lines 12 is led further through the lumen 9 (arrow Q). ·

The catheter tip is via the annular metal electrode. 5 connected to the rest of the catheter, this metal electrode within the electrical measuring system being connected in such a way that it is ground -. 8-4-0 0 § - # - 8 ------------- -----— • V # <· -3- functions.

In the lumen 8 of the catheter 6, a reference electrode Z is arranged, which is a. pH-FEX and "on-chip" also includes an Ag / AgCl ion-selective electrode ^ An opening 13 has been made to -S in the wall of the lumen 8- The lumerr 8. is connected upstream past the bifurcation 3 via the tube% to a source of rinsing fluid of constant pH and pCl passed through Gymnastics 8 according to arrows' B.

When performing a measurement in which the catheter 6 - fnreen bloodstream 'has been introduced, the pH-FEX 1 is in contact with the blood Ar 10 and adjusts to the pH of the blood. The pH-FET- reference electrode Z frr contact with the coil liquid. Bienifegate potential Vg ^ thereof is constant if care is taken that the pH of the liquid and the liquid junction potential are constant. Incorporating the pH-FET 1 and the pH-FET reference electrode Z within the measuring system shown in Figure Z 15 according to the specification will, due to the nature of the circuit as differential circuit, have corresponding changes in the behavior of the two pH * FETs. compensate each other. These behavioral changes may be or may result from, for example, drift, temperature effects, aging, etc., 20 The stability of the metal electrode 5 as ground is not essential for the operation of the measuring circuit,

The relationship can be given for the voltage Vo to be measured (Figure 3]: ..j:.

Vo = (Φι-φ2-φω) x x R.

.25 .L w, .a = transconductance "of the FE7 * liquid junction epo tential * constant h" φ2 * pH blood "pH flushing liquid So Vo * adH- 30 With the measuring device, as shown in figure 1, it is easy to if desired or necessary, an in vivo calibration measurement is carried out, for this purpose, in a first step, the pH-FET reference electrode Z and the Ag / AgCl electrode are exposed to the flushing liquid and the instrument adjusted to the pH value 8.4 0-0 -5 9 £ --------------------------

Cl * -4- / of the rinsing liquid. Then, in a second stage, blood in lumen 8 is admitted to this: contacts pH-FET reference electrode 2. The output signal Vo of the differential circuit should be .o mV.

If not, the setting: of the. pH-FET 1 to be corrected so that the value of the output signal weT is zero.

The Fury; can be expelled again from the gymnastics 8 by means of the flushing liquid for measurement 1. The instrument designation has now been corrected and the instrument is ready for use again. 10 'Recapitulating: With the first calibration stage, exposing the pH-FET reference electrode to the rinsing liquid, any misalignment of the reference electrode is corrected, while the second calibration stage corrects the misalignment of the pH-FET.

If the pH-FET chip is equipped with a 'bn-chip' temperature sensor and Ag / AgCT electrode, as explained above, in vivo calibration is possible without a special construction for the catheter - or also without taking blood samples in which the calibration is to be performed.

20 Addition of the pH of the flushing liquid to the & pH measured with the differential circuit yields the current value of * the blood pH.

Naturally, changes can be made to the measuring system as discussed above and shown in the drawing without leaving the scope of the invention. Thus, for example, in the example shown in Figure 1, the pH-FET reference electrode may also be arranged in the liquid connector or even in the external flushing fluid system.

Claims (6)

1. Electric measuring system for selective measurement of the concentration ion I, expressed as pi, expands in a liquid, through an ion I-selective FET component, which measuring system further contains as components a reference electrode, a electrical voltage source for applying the drain-source voltage within the FET component and a voltage source for applying the gate voltage Vg Between the gate and the source an amplifier system as well as current-conducting wiring to which the components are electrically connected to each other, characterized in that the reference electrode is also an ion selective FET component and this SFET reference electrode can be contacted with a constant composition or constant pi fuel, while the two FET components are connected in a differential circuit. 15 2. Measuring system according to claim 1, characterized in that the ISFET reference electrode is further electrically combined with an ion-selective electrode. 3. Measuring system according to claim 2, characterized in that the ion-selective electrode is an Ag / AgCl electrode. Electric measuring system according to claim 1, wherein the FET component selective for Ret ion is a pH-FET, characterized in that the pH-FET is applied in the. tip of a metal electrode containing catheter "as known per se" while the metal electrode within the differential amplifier is connected as 25 ground, Electric measuring system according to claim 4, characterized in that the pH-FET reference electrode is arranged in a lumen of a buttock urn catheter that flows through the flushing liquid 84 0 0 5JJ 8_____ * I '-6- 3 * V * upstream or downstream of its bifurcation, the other lumen being utilized for the drain leads and the source of the pH-sensitive pH-FET disposed in the catheter tip. 5 6 »Electrical measuring system according to claim 4 ·, m u a r k e r k ,. that the pH-FET reference electrode is installed in the external flushing fluid system. 8400598