ITBO20090124A1 - DEVICE FOR THE EXECUTION OF ANALYSIS ON PREFERABLY FLUID SUBSTANCES. - Google Patents

Description

TITLE: DEVICE FOR PERFORMING ANALYSIS ON PREFERABLY FLUID SUBSTANCES

DESCRIPTION

The present invention relates to a device for carrying out analyzes on preferably fluid substances.

It is frequent to resort to optical absorbance measures to identify, according to the color of a substance, its transparency, and in general its optical properties, some characteristics that identify it.

It is possible, for example, to perform tests on human or animal sera (as in the case of the plasma fraction of blood obtained with fractionation operations, with centrifugation and the like or in the case of other body fluids), on food substances (food in general, water, beverages, wine, milk, etc.) or on chemical substances (such as medicines, pesticides and compositions of various kinds).

This type of analysis is generally performed through a sequence of operations.

It is necessary to first place the fluid to be examined in a test tube and add a specific reagent according to the type of parameter to be evaluated.

After a certain reaction time it is necessary to expose the test tube (and the solution in which the reaction contained in it took place) to a light radiation of a specific wavelength and measure the absorbance through a suitable sensor: the absorbance it is identified as a function of the absorption of light radiation by the fluid.

This analysis methodology can be performed through apparatuses called photometers and spectrophotometers.

In particular, these devices carry out the final part of the test, in practice they deal with the reading of the light absorption (absorbance) of the substance to be examined / reagent mixture in the test tube: the physical process through which the reading is performed is generally of the type of law by Lambert Beer which is an empirical relationship that correlates the quantity of light absorbed by a medium to the chemical nature, concentration and thickness of the medium passed through.

By interposing suitable filters between the light source and the test tube, it is possible to select the wavelengths that will hit the photometer sensor, thus making it selective and therefore associating the value detected by it only with the specific wavelength combined with the quantity we intend to measure.

To give an example, if it is necessary to identify the quantity of iron present in human serum obtained by centrifugation of the blood, it is necessary to mix a predefined quantity of reagent with a predefined quantity of serum, letting them react for a standard time. At the end of the time interval, the test tube containing the serum and the reagent must be measured with the photometer (previously prepared with an optical filter suitable for this analysis). The quantity of "absorbed light" by the liquid will identify a particular value which corresponds to a consequent entity of the physiological parameter (quantity of iron) that is to be determined.

It is evident that this type of measurement is affected by inaccuracies due to the need for the operator to perform perfect dosages and respect the timing imposed by the test being performed.

However precise the photometer used may be, preventive operations can determine very important deviations in the measurement following operator errors. Fully automatic apparatuses are also known which directly carry out the operations of mixing the fluid with the respective reagent (or the respective reagents).

These automatic devices are generally used in medium / large structures as they perform a variety of tests simultaneously.

The high level of automation imposes test execution times specifically designed for the device: although the standard methodology imposes longer reaction times, each device is designed in such a way that a relationship is identified between the result after the standard time and the result after the typical incubation time of the device.

This preventive calibration makes it possible to automatically perform any type of test always using the machine time as the reaction incubation time.

The precision of the measurements, therefore, is in this case affected by the failure to respect the ideal incubation time: the result obtained is a sort of transposition of a measured value after an intermediate time and therefore deviates from the final value, especially in those tests in which there is a strong non-linearity of the parameter to be investigated, over time, during the reaction.

The cost of running an automatic device also makes it prohibitively expensive to use it for a single test.

It is very important to point out that recent analysis methods provide for the addition of additional reagents at the end (or during) the first reaction: in practice it is necessary to add a first reagent to the serum, wait for the reaction to occur for a specific time, measure optionally, the absorbance value of the mixture, and add the mixture itself with a second reagent. After a second interval of time it will be necessary again to subject the final mixture to the optical survey.

In this case there is an overlap of the time constants of the first and second phase: an automatic device of a known type would determine an important deviation of the final measurement (with respect to the real value) since the starting point of the second reaction would not be the ideal one. (after the first time interval) but would be anticipated to the typical value of the time constant of the device itself. This means that the second reaction would start earlier than what is required by the methodology of use of the reagents and would last for a shorter time (always equal to the time constant of the apparatus) than the standard time of the second reaction.

In the hypothesis of using a simple spectrometer, however, it would be possible to respect the time constants, but the fluid is not accessible for the introduction of the second reagent as it is stored within a suitable cell of the spectrometer itself.

Apparatus of the known type are therefore not suitable for carrying out some types of tests, except with poor precision.

The main aim of the present invention is to solve the aforementioned problems by proposing a device for carrying out analyzes on preferably fluid substances suitable for the automatic execution of the entire analysis method, respecting precisely the dosages and incubation times.

Within this aim, an object of the invention is to propose a device for carrying out analyzes on preferably fluid substances suitable for the automatic execution of tests which provide for the deferred supply of a plurality of reagents, with time intervals between one predetermined adduction and the next.

Another object of the invention is to propose an automatic device for carrying out analyzes on preferably fluid substances, with reduced operating costs and therefore suitable for carrying out tests also on single samples of fluid.

A further object of the present invention is to provide a device for carrying out analyzes on preferably fluid substances with low costs, relatively simple to make in practice and safe to apply.

This task and these purposes are achieved by a device for carrying out analyzes on preferably fluid substances of the type comprising a light source substantially facing an optical sensor of the type of a photometer, a suitable seat being identified between said source and said sensor 'reception of a test tube containing, during the measurement phase, the substance to be analyzed, between said source and said seat a respective optical filter being interposed, characterized in that it comprises at least one recess for a test tube containing the said substance to be examined, at least one housing for suitable reagents to be combined with said substance, and at least one precision dispenser, responsible for withdrawing said substance and at least one said reagent in separate times, and for introducing what has been withdrawn into the test tube aligned with the light source and the photometric sensor.

Further characteristics and advantages of the invention will become clearer from the description of a preferred but not exclusive embodiment of the device for carrying out analyzes on preferably fluid substances according to the invention, illustrated by way of non-limiting example, in the accompanying drawings, in which:

Fig. 1 is a schematic front view of a device for carrying out analyzes on preferably fluid substances according to the invention;

Fig. 2 represents, in a schematic view in which the seats and housings are seen from above, a device for carrying out analyzes on preferably fluid substances according to the invention.

With particular reference to these figures, the reference numeral 1 generally designates a device for carrying out analyzes on preferably fluid substances A.

The methods of analysis on fluid substances A (generally liquid or more or less dense and viscous liquid solutions of the substance itself) generally involve the initiation of a chemical reaction by mixing substance A with an appropriate reagent B: the mixture C thus obtained it must be examined with optical type detectors to verify the light absorption by the same. The response to the chemical reaction and therefore the quantity of components (within substance A) capable of reacting with reagent B can be identified from the absorption value.

The device 1 comprises a light source 2 substantially facing an optical sensor 3 of the type of a photometer.

In particular, between the source 2 and the sensor 3 there is identified a seat 4 suitable for receiving a test tube 5 containing, during the measurement phase, the mixture C between the substance A to be analyzed and the relative reagent B.

For the purposes of the correct execution of the optical reading by the sensor 3, a respective optical filter 6 is interposed between the source 2 and the seat 4.

The device 1 according to the invention comprises at least one recess 7 for a test tube 8 containing the substance A to be examined, at least one housing 9 for a respective test tube 10 containing suitable reagents C to be combined with the substance A itself in order to obtain the mixture C in where the chemical reaction will occur.

The device 1 also comprises at least one precision dispenser 11, designed to withdraw the substance A and at least one reagent B in separate times, and to introduce what has been withdrawn into the test tube 5 aligned with the light source 2 and with the photometric sensor 3. The seat 4 comprises suitable means 12 for adjusting the temperature for maintaining the test tube 5 and its contents (the mixture C) at a predetermined temperature.

In particular, according to an embodiment of undoubted practical and applicative interest, these adjustment means 12 comprise at least one component of the type of a Peltier cell.

The use of other components for regulating the seat temperature 4 is not excluded.

The metering device 11 comprises at least one terminal portion 13 constrained to a shoe 14 sliding along a track 15.

The track 15 is aligned with the at least one seat 4, the at least one recess 7 and the at least one housing 9, for the selective juxtaposition of a dispenser 16 arranged in an end position with respect to the portion 13 of the metering device 11 at the mouth of at least test tube 5 contained within one of the seats 4, the recesses 7 and the seats 9.

An actuator 17 is interposed between the metering device 11 and the shoe 14, which is designed to translate the portion 13 of the metering device 11 with respect to the shoe 14 in a substantially vertical direction.

It is important to highlight that, according to a particularly efficient embodiment solution, the light source 2 is a light emitting diode, normally called LED, having a spectrum of wavelengths emitted substantially comprised between 340 nm, nanometers, and 700 nm, nanometers. . This type of light source 2 guarantees a high stability of the spectrum emitted over time (it is almost impossible to detect a performance decay over time) and moreover, since it does not emit heat, it does not cause any disturbance to the measurement (as already mentioned, the seat 4 must be kept at a constant temperature). The small size of a diode also allows it to be placed near the seat 4 (in particular a diode for each seat 4 with the sole interposition of the optical filter 6): this type of positioning guarantees an optimal reading of the beam emitted by the corresponding sensor photometric 3.

The metering device 1 comprises a plurality of elements which guarantee its correct functioning: through a motorized pump 18 (connected through a suitable duct 19 to the portion 13) it is possible to start the suction and / or expulsion of fluid.

In particular, the pump 18 can be arranged downstream of a diverter 20 connected with a first branch 21 to a tank of distilled water 22 necessary for washing the portion 13, and with a second branch 23 to a container 24 in which to discharge contaminated fluids or however already used.

By aligning the portion 13 to a suitable washing tank 25 it is possible to send to the portion 13 the same distilled water taken from the tank 22 until the tank 25 is filled (at least partially) ensuring a washing of the portion 13 immersed therein.

At the end of the washing, the water present in the tank 25 can be withdrawn and discharged into the container 24.

According to an embodiment of certain practical and applicative interest, the pump 18 can be constituted by a piston that can be moved within a cylinder, by the action of a suitable mechanical actuator, suitable for dosing with a precision of the order of μl, microlitre.

In order to guarantee the execution of tests and analyzes of any type, the seats 4 can be a plurality, each provided with its own light source 2, with its own optical filter 6 constrained in proximity to a wall of the respective seat 4, and of its own optical sensor 3 of the type of a photometer.

In this case each seat 4 will comprise an optical filter 6 and a sensor 3 having specific wavelengths of filtration and detection: it is not excluded that the sensor 3 may have the same characteristics in all the seats 4, while the filters 6 are different, guaranteeing the necessary optical selectivity required by the type of analysis and test to be carried out.

The method of analyzing preferably fluid substances according to the present invention consists of a sequence of operations according to which it is necessary to introduce into a first test tube 8 at least a predefined quantity of a substance A to be examined and to arrange the first test tube within a recess 7 of a device analysis 1.

Subsequently it is necessary to introduce into at least a second test tube 10 at least one reagent B according to a known dosage (normally defined by the manufacturer of the reagent B itself) and to arrange the second test tube 10 inside a housing 9 of the analysis device 1.

At this point it is necessary to start the device 1 for the automatic withdrawal, through a suitable dispenser 11, of a specific ration of substance A from the first test tube 8 and of at least one suitable dose of reagent B from the second tube 9 and the subsequent release of the substance A and reagent B (the mixture C), mixed together, within at least a third test tube 5 arranged within a respective seat 4 aligned with a light source 2, an optical filter 6 and an optical sensor 3 of the type of a photometer.

Sensor 3 will read the amount of light radiation absorbed by the mixture C of substance A and reagent B after a predetermined time (also normally defined by the standards of the type of test and / or analysis in progress or defined by the manufacturer of reagent B used).

To carry out some particular type of particularly complex analyzes, at least a second reagent can be introduced into the mixture C to carry out at least a second reading of the amount of light radiation absorbed by the new mixture obtained each time by adding new reagents.

Advantageously, the device 1 according to the invention allows very precise readings of the absorbance values since its structure ensures perfect alignment (without dispersion) of the light source 2 with the respective photometric sensor 3.

Usefully the choice of adopting LEDs as light sources allows to have the maximum stability of the time of the measurements that are going to be carried out (there is no decay of the light emission with the use of the LED) and not to subject the sample under examination. to thermal contamination (the LED does not emit heat). Positively, the adoption of Peltier cells to thermostat each seat 4 guarantees immediate and stable temperature control.

It is important to underline that by adopting fixed sources 2, respective fixed filters 6 and respective fixed photometric sensors 3, the reciprocal positioning of each component with the adjacent ones is constant and cannot compromise the correctness of the measurement. Each seat 4 (having a different filter 6) will be responsible for reading a specific wavelength: even the use of the device 1 will therefore be simplified as it will not require the calibration of any component.

The presence of a plurality of housings 9 for different reagents B makes it possible to carry out analyzes in which several reactions must be carried out in sequence, respecting, for each of them, the foreseen incubation time.

For the purposes of the integrity of the measurements and the impossibility of contamination of a mixture C by previous test residues, portion 13 is subjected to continuous washing in distilled water. The waste from previous washing is eliminated through an appropriate drain.

According to a particular embodiment solution, the actuator 17 is enslaved to a level sensor so that the portion 13, in particular the dispenser 16, are not totally immersed: the level sensor will ensure that they lick the liquid (or fluid) only for the minimum quantity that allows it to be removed, this to prevent the surface of these components from becoming “dirty” with these liquids (fluids) and subsequently deposits of debris may occur (which could contaminate subsequent measurements and analyzes).

The automatic dosage of substance A and the respective reagents B guarantees to perfectly comply with the standards set for a specific test or a specific analysis, eliminating the human errors typical of assays with pipettes, droppers and the like.

In order to provide an indicative and non-limiting example of the field of application of the device 1 according to the invention, it should be noted that it can be used to perform analyzes of any type on serums (humans and animals), foods (drinks, suspensions of solid foods and the like. ), water, chemicals in general, medicines, pesticides and more.

The invention, thus conceived, is susceptible of numerous modifications and variations, all of which are within the scope of the inventive concept; moreover, all the details can be replaced by other technically equivalent elements.

In the illustrated embodiments, individual characteristics, reported in relation to specific examples, may actually be interchanged with other different characteristics, existing in other embodiments.

Furthermore, it should be noted that everything that in the course of the procedure for obtaining the patent turns out to be already known, is intended not to be claimed and the subject of an excerpt (disclaimer) from the claims.

In practice, the materials used, as well as the dimensions, may be any according to the requirements and the state of the art.

Claims (1)

R I V E N D I C A Z I O N I 1.Device for carrying out analyzes on preferably fluid substances (A) of the type comprising a light source (2) substantially facing an optical sensor (3) of the type of a photometer, between said source (2) and said sensor ( 3) being identified a seat (4) suitable for receiving a test tube (5) containing, during the measurement phase, the substance (A) to be analyzed, between said source (2) and said seat (4) a respective optical filter (6), characterized in that it comprises at least one recess (7) for a test tube (8) containing said substance (A) to be examined, at least one housing (9) for suitable reagents (B) to be combined with said substance (A), and at least one precision dispenser (11), responsible for withdrawing said substance (A) and at least one said reagent (B) in separate times, and for introducing what was taken into the test tube (5) aligned with the light source (2) and the photometric sensor (3). 2.Device according to claim 1, characterized in that said seat (4) comprises suitable means for adjusting the temperature (12) for maintaining the test tube (5) and its contents at a predetermined temperature. 3. Device according to claim 2, characterized in that said adjustment means (12) comprise at least one component of the type of a Peltier cell. 4. Device, according to claim 1, characterized in that said metering device (11) is attached to a sliding shoe (14) along a track (15), aligned with the at least one seat (4) at the at least one recess (7 ) and to the at least one housing (9), for the selective juxtaposition of a dispenser (14) of the dispenser (11) to the mouth of at least test tube (5), (8), (10) contained within one of said seats 4 , said recesses (7) and said housings (9). 5.Device, according to claims 1 and 4, characterized in that an actuator (17) is interposed between said metering device (11, 13) and said shoe (14), designed to move the said metering device (11, in a substantially vertical direction) 13) with respect to said shoe (14). 6. Device, according to claim 1, characterized in that said light source (2) is a light emitting diode, normally called LED, having a spectrum of emitted wavelengths substantially comprised between 340 nm, nanometers, and 700 nm , nanometers. 7. Device according to claim 1, characterized in that said metering device (11) comprises a piston that can be moved within a cylinder, by the action of a suitable mechanical actuator, suitable for dosing with precision of the order of μl, microlitre. 8. Device, according to one or more of the preceding claims, characterized in that said seats (4) are a plurality, each provided with its own light source (2), with its own optical filter (6) constrained in proximity to a wall of said seat (4), and of its own optical sensor (3) of the type of a photometer, each seat (4) comprising an optical filter (6) and a sensor (3) having specific filtration and detection wavelengths . 9. Analysis procedure on preferably fluid substances which consists in introducing into a first test tube (8) at least a predefined quantity of a substance (A) to be examined; arranging said first test tube (8) within a recess (7) of an analysis device (1); introducing into at least a second test tube (10) at least one reagent (B) according to a known dosage; arranging said second test tube (10) within a housing (9) of an analysis device (1); start said device (1) for the automatic withdrawal, through a suitable dispenser (11), of a specific ration of substance (A) from said first test tube (8) and of at least one suitable dose of reagent (B) from said second test tube (10) and the subsequent release of substance (A) and reagent (B), mixed together, within at least a third test tube (5) arranged within a respective seat (4) aligned with a light source (2), an optical filter (6) and an optical sensor (3) of the type of a photometer, for reading the amount of light radiation absorbed by the mixture of substance (A) and reagent (B) after a predetermined time. 10. Analysis procedure, according to claim 9, characterized in that at least a second reagent (B) is introduced into the mixture (C), of the substance (A) with at least one first reagent (B), for carrying out at least a second reading of the amount of light radiation absorbed by the new mixture obtained from time to time by adding new reagents, for carrying out complex analyzes and tests that require the subjecting of the substance (A) to a multiplicity of subsequent reactions.