DK141079B - Apparatus for simultaneously performing a colorimetric measurement and a particle examination on a liquid suspension. - Google Patents

Description

(11) PRESENTATION 141079 ΠΛΜΜΛΟ / (51) Int.Cl.3 β 01 Η 15/00 DENMARK β 01 Ν 21/27 '(21) Application No 4570/71 (22) Submit' 'on 17.8βρ. 1971 (23) Race day 17 · δφΓ. 19® (44) The application presented and. in the letter of disclosure published on the 9th of the DIRECTORATE FOR.

PATENT AND TRADEMARKET (30) Woritet requested from it

Apr 17 1967, 6 ^ 1284, US

(71) COULTER ELECTRONICS LTD., High Street South, Dunstable, Beds, GB.

(72) Inventor: William Fletcher Rothermel, 1255 West 49th Place, Hialeah,

Florida, US: Robert Ivan Klein, 5595 West 15th Lane, Hialeah, Florida, US.

(74) Plenipotentiary in the proceedings:

The engineering company Budde, Schou & Co.

(54) Apparatus for simultaneously carrying out a colorimetric measurement and a pair * = cell count on a liquid suspension.

The present invention relates to an apparatus for carrying out a colorimetric measurement and a particle examination of the same liquid suspension of particles, comprising a vessel having transparent walls and adapted to contain an amount of the liquid suspension. Such an apparatus is used in medicine and biology. The device is primarily suitable for hematologists and diagnostics. In addition to studies of suspicious blood tests, the device is a valuable aid for routine routine examinations of a large number of samples.

As is known, blood is composed of small microscopic cells, namely of the predominant red blood cells and of the less dominant white blood cells. When examining the properties, both the cells themselves and the blood as a whole must be examined. It has been recognized that a group of measurements or characteristic sizes provides information that is characteristic of a given sample or can be widely considered to describe it.

One of these characteristic sizes is the hemoglobin (HGB) and is defined within the medicine as the number of grams of 3 hemoglobin in 100 cm of total blood. The fluid inside the red blood cells consists of an ferrous complex protein that gives the blood the characteristic red color. In accordance with the known method for determining the hemoglobin number, a suspension of the blood is dissolved by means of a suitable chemical which breaks down the walls of the blood cells and releases the hemoglobin. The free hemoglobin will then chemically react with a reaction agent contained in the diluent, thereby forming the color-producing compound enabling a determination. The color of the resulting solution is determined by a colorimetric method using various known apparatus, such as e.g. gennemstrømningskuvetter.

The known particle analyzers are only suitable for counting and determining the size of the particles. In this case, the results depend on the relative movement of the particles in the suspension with respect to a passage opening of very small dimensions in a vessel, where, every time a particle appears in the passage opening, a displacement of fluid corresponding to the volume of the particle occurs, the overall electrical impedance of the through orifice is subjected to a change.

In addition, a strong electrical current in the passage orifice proceeds, so that a change of impedance produces a short-term electrical signal as a particle migrates through the orifice. Furthermore, the amplitude of this signal is substantially proportional to the size or volume of the particle.

The object of the invention is to provide a novel apparatus for simultaneously measuring and examining the above-mentioned characteristic sizes for one or more samples in the form of a suspension.

The invention therefore solves the task of providing an apparatus for carrying out a continuous, automatic, colorimetric measurement and examination of particles in a suspension. This apparatus, as far as the colorimetric measurement is concerned, must act independently of the relative movement of the particles in the suspension relative to a passage opening. It should be possible to generate several electrical signals corresponding to the composition of the suspension, primarily for the purpose of determining the number of white blood cells and for the simultaneous determination of a hemoglobin number.

According to the invention, this task is solved by one or more aperture tubes of the kind known from electrical particle analyzers and adapted for particle indication on the basis of the change in the electrical impedance that occurs when particles pass through an opening in the wall of the tube. in the vessel such that the opening or openings of the tube or tubes are immersed in the suspension, that a portion of the vessel below the normal level of the suspension has a pair of opposed parallel parallel walls located at some distance from the aperture tube or tubes; and a means is provided for directing a beam of light through the parallel walls, but not through the aperture tube or tubes, for performing the colorimetric measurement simultaneously with the particle measurement, the aperture tube or tubes and tub being provided with electrodes for electrically scanning the suspension caused to pass through the opening into the tube and the electrodes arranged to a t is connected in a detector circuit.

In the following, a preferred embodiment of an apparatus according to the invention will be described in more detail with reference to the drawing, in which Figure 1 is a perspective view of the aperture tubes for white blood cell samples and a immersion vessel with a schematic hemoglobin measurement apparatus; 2 is a sectional view taken substantially along line 2-2 of FIG. 1 and seen in the direction indicated, and FIG. 3 shows in detail a portion of a horizontal section substantially along line 3-3 of FIG. First

First, it will be appropriate to explain the apparatus generally by describing the functions performed.

The blood sample is randomly sampled and identified in its entirety by means of a suitable marker, usually in the form of a card having fields in which the desired information is printed by the apparatus's printer. The apparatus has a tube or snorkel which is immersed in the sample and which sucks part of the sample into the flow circuit. A small metered portion of this blood is transferred to a mixing chamber together with a predetermined amount of diluent, a first dilution being carried out in this mixing chamber. From this chamber, a portion of the resulting suspension is passed to another mixing chamber together with an introduced cell degradation agent, the suspension remaining in this second mixing chamber for a period sufficient to allow red blood cell degradation to dissolve their hemoglobin.

The blood sample containing white blood cells and the hemoglobin is inserted into a bath containing three aperture tubes and is sucked into all three tubes simultaneously by a constant fluid pressure for a predetermined period of time. The aperture tubes are provided with associated electrodes, and a common electrode is provided in the bath so that three sets of signals are obtained upon passage of the white blood cells into the aperture tubes. Electronic circuits provide an output signal from a detector which directly represents a white blood cell count.

For the determination of HGB on the basis of the sample in the aperture tube, there is a special extension of the bath to provide parallel observation surfaces through which a beam of appropriate light is passed through the suspension and into a photosensitive means to provide information regarding the hemoglobin parameter of the original sample. Appropriate electrical circuits are connected to the output of the photosensitive means to provide information regarding the hemoglobin parameter of the original sample. Appropriate electrical circuits connected to the output of the photosensitive device emit a size representing HGB.

Reference is now made to the drawing showing the aperture tubes for white blood cells and their immersion vessels as well as certain details of the apparatus.

Since the white blood cell sample has been subjected to cell degradation, no red blood cells are found therein. Incidentally, the hemoglobin from the red blood cells has been released and the same sample is suitable for a hemoglobin assay. This is done using the new construction illustrated. A chemical in the diluent causes a treatment of the hemoglobin to be oxidized to produce the desired color.

The vessel 90 is preferably formed of glass vessels and is preferably in the form of a pocket which is open at the top, as shown at 210, and is narrowed at its lower end, as shown at 212.

The chamber 214 formed in the interior thereof is relatively narrow, and the aperture tubes 144 disposed in the chamber are flattened so that a minimum of sample will rise relatively high in the chamber 214. For example, the level is shown at 216. in FIG.

2 above the openings 146. These aperture tubes are inserted into a plate 218 by means of which all three aperture tubes can be lifted or lowered simultaneously. This plate interacts with a large, not shown, carrier located over the upper end of the vessel 90.

At its lower end, the vessel has a measuring chamber 200 formed integrally with it, which has a rectangular, almost square cross-sectional shape, and which constitutes a hemoglobin measuring chamber. The plates 220 and 222 are completely parallel and planar, and the insides of the spot where the light beam 224 passes through them are also parallel and planar. A light source, projector, filter, etc. 202, 204 of standard specifications direct a beam 224 through the same suspension used to determine the white blood cell count, and further to a photosensitive organ 225 in a hemoglobin assay apparatus not shown. The sample is inserted from conduit 120 into a pin or nipple 226, the bore 228 of which is tangentially to the inner wall of the chamber so that fluid entering and following the arrows of FIG. 3, will flow in a sliding motion into the chamber without turbulence or bubble formation.

When the new sample is in chamber 214 while the aperture tubes 144 are full of a previous sample, a supply of vacuum over conduit 198 will cause the new sample to be drawn through the apertures 146 into the interior of the aperture tubes 144. Each tube has its own own internal electrode 230 with a line 231 leading to a detector shown in FIG. 2 and in the main are of the type disclosed in the specification of British Patent No. 722,418. A common grounded electrode 232 provided with a conduit 233 is disposed in the chamber 214 so that the particles as they pass through the openings will produce signals over the electrodes and over the electrical conduits 231 and 233 associated with them. electrodes for counting, sizing, etc. Each of the three apertures is illuminated by a light source 234, and some form of collimator or lens 236 is used to assemble beam 238. This beam passes through the aperture which is usually quite close to one of the side walls, and then directed to a mirror 239 from which the appearance of the aperture can be projected onto a ground glass screen. In this way, all three openings can be observed optically at the same time for the purpose of controlling clogging, etc.

The drain for the bath 90 starts from a fitting 240, the bore of which is an inclined conduit 140.