EP2044210A2

EP2044210A2 - Method of detecting microorganisms within a specimen

Info

Publication number: EP2044210A2
Application number: EP07788921A
Authority: EP
Inventors: Luc Montagnier; Jamal Aissa
Original assignee: Nanectis Biotechnologies SA
Current assignee: Nanectis Biotechnologies SA
Priority date: 2006-06-22
Filing date: 2007-06-22
Publication date: 2009-04-08
Also published as: RU2449019C2; RU2009101670A; HK1133678A1; CN101506373A; US20100323391A1; WO2007147982A2; FR2902883A1; CN101506373B; WO2007147982A3; FR2902883B1; US20130224788A1

Abstract

The present invention relates to a method of preparing reactants intended for a test for detecting microorganisms and especially for detecting infections in humans or animals, characterized in that it comprises the following steps: a) centrifugation of a biological or artificial liquid medium containing a selected specific microorganism; b) filtration of the supernatant obtained in step a); c) preparation of a series of diluted specimens corresponding to increasing dilutions of the filtrate obtained in step b) until the filtrate has been diluted by a factor of at least 10<SUP>-15</SUP>; d) subjection of the diluted specimens obtained in step c) to an electric, magnetic and/or electromagnetic excitation field; e) analysis of the electrical signals detected by means of a solenoid and digital recording of said electrical signal after analogue/digital conversion of said signal; f) selection of the diluted specimens with which characteristic electrical signals are obtained in e), i.e. signals having an amplitude at least 1.5 times greater than the background noise signals emitted by the water and/or having a frequency shift towards higher values; g) introduction of the diluted specimens selected at step f) into protective enclosures, which protect said dilutions from the external electromagnetic fields; h) distribution of one of said diluted specimens of step g) volume to volume in two tubes, one, T1, remaining in the protective enclosure protecting said diluted specimens from interference by the external electromagnetic fields, which tube will serve as reference solution, and the other, T2, also being placed in a protective enclosure, which tube will be subsequently subjected to the presence of or be in contact with a specimen suspected to contain said selected specific microorganism.

Description

METHOD FOR DETECTING MICROORGANISM WITHIN A

SAMPLE

The present invention relates to the detection of latent infections in humans and animals, by demonstrating the inhibition, by the individual to be examined, electromagnetic signals generated by a microorganism.

It is known from the work of Dr. Jacques BENVENISTE and patent application WO 00/17637, to record and digitize, after analog-to-digital conversion using a computer sound card, a signal characteristic of a molecule with biological activity.

It is also known in the prior art (WO 09417406), a method and a device used to transmit the biological activity of a first so-called carrier material to a second so-called target material, free of any traces of said carrier material and physically separated from the latter, the target not initially having said biological activity. The method consists in (i) exposing the material carrying the biological activity of interest to an electric or electromagnetic signal sensor, (ii) amplifying the electromagnetic or electrical signals characteristic of the manifestation of the biological activity emitted then (iii) ) exposing the target material to an emitter of electrical or electromagnetic signals, said emitter being connected to said sensor via a transmission and amplification circuit, for transmitting the signal characteristic of the biological activity to said target. In a previous French patent application 05/12686 filed on

14/12/2005, unpublished to date, the inventor of the present invention described a method for characterizing biochemical elements exhibiting a biological activity, in this case microorganisms, by analysis of the low frequency electromagnetic signals, said process bringing improvements to the techniques of the prior art. The method also relates to the biological analysis of recording the electromagnetic or electrical "signatures" corresponding to known biochemical elements, and comparing said previously recorded "signatures" to that of a biochemical element to be characterized. The method involves filtration and dilution steps to eliminate microorganisms and cells. present in the initial sample, the highest dilutions generating the most electrical or electromagnetic signals while the least diluted samples do not present, most of the time, no electrical or electromagnetic signals. The inventor has also shown that microorganisms of different types, such as bacteria and viruses, produce "nanostructures" that persist in aqueous solutions, and that it is these "nanostructures" that emit electromagnetic signals. Said "nanostructures" behave as polymers having a size less than 0.02 μm for viruses, and less than 0.1 μm for bacteria of conventional size and have a density of between 1.12 and 1.30 g / ml. .

The method described in the present application is based on the astonishing observation that in the absence of physical contact, the simple vicinity of a closed tube containing a sample of a bacterial or viral filtrate slightly diluted and negative with respect to the emission of electrical or electromagnetic signals inhibits the signals produced by a more highly diluted sample of the same initially positive filtrate with respect to the emission of electrical or electromagnetic signals. In the present application, this inhibition will be called indistinctly "inhibitory effect" or "negative effect". Similarly, in the present application, "inhibit" and "negativer" will be used indiscriminately and have a similar meaning. This observation led the inventor to search for the same inhibitory phenomenon from the infected human being. It has been observed in a patient with autoimmune microvascularitis of infectious origin that the diluted samples of his plasma have an inhibitory effect on diluted E. electromagnetic signal emitters (hereinafter SEM), suggesting that the patient was chronically infected by this germ or a related organism. It has also been found that the patient suffering from microvascularitis, cited in the previous example, itself inhibits the SEM emitted in its filtered and diluted plasma, and also inhibits SEM emitted by a culture sample of E. coli. filtered and diluted E. coli present in a closed tube. In this case, a 5-minute contact of positive dilution in the patient's hand, or 10 minutes to a distance of 50 cm is sufficient to observe the inhibitory effect.

This inhibitory power thus relates both to the emitting structures of its own plasma, but also to those of a specific bacterial germ, which would make it possible to use the latter as a universal identification system. The invention can therefore identify a bacterial or viral origin in diseases where these germs have not been identified.

A first object of the invention relates to a process for the preparation of reagents intended for a test for the detection of microorganisms and in particular for infection in humans or animals. In its most general sense, the method comprises the following steps: a) centrifugation of a biological or artificial liquid medium containing a selected specific microorganism; b) filtration of the supernatant obtained in step (a); c) preparing a series of diluted samples corresponding to increasing dilutions of the filtrate obtained in step (b), up to a dilution of the filtrate by a factor of 10 ^"at least ^15, d) subjecting the diluted samples obtained in step (c) at an excitation field of electrical, magnetic and / or electromagnetic nature; e) the analysis of the electrical signals detected by means of a solenoid and the digital recording of said electrical signal after analogue / digital conversion of said signal, f) the selection of the diluted samples with which characteristic electrical signals are obtained in (e), by characteristic signals means signals whose amplitude is at least 1.5 times greater than the noise signals from the bottom emitted by the water and / or which have a frequency shift towards higher values g) the introduction of the diluted samples selected in step (f) into protective enclosures, which protect said dilutions of the external electromagnetic fields of very low frequencies; h) the distribution of one of said diluted samples from step (g) volume to volume in two tubes, one, T1, remaining in a protective enclosure protecting said diluted samples from interferences of external electromagnetic fields, which tube will be used of reference solution, the other, T2, also placed in a protective enclosure, tube which will subsequently be subjected to the presence or in contact with a sample suspected of containing said selected specific microorganism.

By "a test sample, for the presence or absence of said selected specific microorganism" is meant (i) a human or animal individual suspected of being infected by said selected specific microorganism, or (ii) a biological sample or a biological or artificial liquid suspected of containing said selected specific microorganism, or (iii) a food, cosmetic or pharmaceutical composition capable of containing said selected specific microorganism. By biological fluids is meant any liquid coming from the human or the animal, for example the blood, the urine, the various secretions. By artificial liquid is meant any reconstituted liquid for the culture of microorganisms, for example the various culture broths for bacteria, yeasts and molds, and culture media of cells infected with a virus.

Another subject of the invention concerns a microorganism detection system within a sample. This system comprises: a) a tube T1, which contains a reference sample transmitting characteristic electromagnetic signals, by characteristic signals is meant signals whose amplitude is at least 1.5 times greater than the signals of the background noise emitted by the water and / or have a frequency shift to higher values; b) a T2 tube which contains a sample emitting characteristic electromagnetic signals, said sample being identical to that contained in the tube T1; c) a protective enclosure protecting the T1 and T2 tubes from external electromagnetic fields of very low frequencies; d) a T3 tube that contains a control solution that does not emit electromagnetic signals; e) equipment for receiving electromagnetic signals.

Upon detection, the tube will be T2 placed in contact with or in contact with the sample X to be tested for the presence or absence of a selected specific microorganism.

Another subject of the invention relates to a method for detecting a microorganism within a sample, characterized in that said method comprises the following steps: a) a sample X for which the presence of a suspected microorganism, for example E coli, must be established, is placed in the presence of a sample as obtained after step (f) of the method according to any one of claims 1 to 3, said sample as obtained after step (f) being a dilution from the filtrate of a culture or a biological medium which contained said microorganism suspected of being present in sample X; b) the comparison of the electromagnetic signal emitted by sample X, in the presence of the sample as obtained after step (f), obtained in step (a), with the electromagnetic signal emitted by an aliquot of same sample as obtained after step (f) not subject to sample X.

"Sample X" means (i) a human or animal individual suspected of being infected with the selected specific microorganism, or (ii) a biological sample or a biological or artificial fluid suspected of containing the selected specific microorganism, or (iii) a food, cosmetic or pharmaceutical composition capable of containing said selected specific microorganism.

The methods according to the invention allow (i) the preparation of reagents for a test for the detection of microorganisms involved in chronic diseases and / or intended to detect systemic latent infections under circumstances in which a rapid and non-invasive response is required, as is the case, for example, with regard to the detection of avian influenza viruses, (ii) the identification of an infection in humans or animals.

Once the microorganism responsible identified, it is then possible to confirm the presence of this seed by performing ultrasensitive PCR using oligonucleotide primers specific for this microorganism.

The invention will be better understood on reading the description which follows, explaining nonlimiting examples of implementation of methods according to the invention.

The appended figures correspond to nonlimiting examples of embodiment.

EXAMPLE 1: A BACTERIAL CULTURE LOW DILUTED AND NON-TRANSMITTING "NEGATIVE" ELECTROMAGNETIC SIGNALS ELECTROMAGNETIC SIGNA UX EMITTED BY A HIGH DILUTION FROM THE SAME CULTURE

1) Sample preparation

A culture of Escherichia coli bacteria (E. coli) in LB medium (Luria broth) is centrifuged at 8000 rpm for 15 minutes to remove the cells. The bacterial supernatant is then filtered through a Millipore PEVD filter with a porosity of 0.45 μm and the filtrate is filtered again on a Millipore filter with a porosity of 0.1 μm. From the filtrate of the culture of E. resulting coli, which is completely sterile, a series of diluted samples are prepared by diluting the filtrate from 10 to 10 in water for injection to ^10-15 . The successive dilutions are shaken vigorously with a vortex, while 15 seconds, between each dilution.

The diluted samples are dispensed into 1.5 milliliter Eppendorf conical plastic tubes. The volume of liquid is usually 1 milliliter.

2) Selection of diluted samples generating electromagnetic signals.

Each diluted sample is tested for the emission of basic frequency electromagnetic signals.

The method for detecting SEM includes a step for transforming the electromagnetic field from different diluted samples into a signal, including an electrical signal, by means of a solenoid sensing said electromagnetic field. The transformation of the electromagnetic field from the analyzed diluted sample into an electrical signal is performed as follows:

(i) Submission of the diluted sample under verification to an excitation field of electrical, magnetic and / or electromagnetic nature;

(ii) analyzing the electrical signals detected by means of a solenoid and digital recording of said electrical signal after analog / digital conversion of said signal;

(iii) Selection of Diluted Samples Generating Characteristic Electrical Signals means characteristics of signals whose amplitude is at least 1.5 times greater than background noise signals emitted by water and / or have a frequency shift to higher values, are placed in mumetal protective enclosures protecting said diluted samples from interference from external electromagnetic fields.

The detection of the signals is carried out with equipment shown diagrammatically in FIG. 1. The equipment comprises a solenoid reading cell (1) sensitive from 0 to 20000 hertz, placed on a table made of insulating material. Said solenoid used in step (ii) comprises a coil having a soft iron core. This coil has an impedance of 300 ohms, an inside diameter of 6 mm, an outside diameter of 16 mm, a length of 6 mm. The soft iron magnetic core is placed in contact with the outer walls of the tube comprising the dilution to be analyzed.

The diluted samples to be read are distributed in 1.5 milliliter Eppendorf (commercial name) conical plastic tubes (2). The volume of liquid is usually 1 milliliter. The characteristic electrical signal acquisition is performed for a predetermined period, for example between 1 and 60 s. In this example, each sample is read for 6 seconds, twice in succession.

The electrical signals delivered by the solenoid are amplified and converted into analog-digital signals by means of a signal acquisition card (sound card) (4) comprising a computer-integrated analog-digital converter (3). Said analog-to-digital converter has a sampling frequency that is twice the maximum frequency that it is desired to be able to digitize, for example 44 kHz.

The digital file corresponding to said converted electrical signal is recorded in a mass memory, in the form of a sound file in WAV format, for example.

For the processing of the characteristic electrical signal, two software Matlab and SigView (trade names) are used as examples. The recorded digital file can optionally be digitally processed, such as digital amplification for signal level calibration, filtering for the elimination of unwanted frequencies, calculation of the spectral power distribution (PSD), and then Spectral power is truncated by keeping only the frequency band ranging for example from 140 Hz to 20 kHz (Matlab), or is transformed into frequency components by Fourier transform (SigView). δ

3) Evaluation of the inhibitory activity of a low non-emitting dilution on the emission of electromagnetic signals generated by active dilution.

Diluted samples with characteristic electrical signals are samples diluted at 10 ^"8 , 10 ^{" 9} , 10 " ¹⁰ . The 10 ^"2 to 10 ^{" 6} dilutions are negative (Fig.2).

A closed tube is placed side by side containing an aliquot of the 10 ^"3 dilution of

E. coli and a closed tube containing an aliquot of the sample diluted to 10 ^"8 E. coli into an enclosure surrounded by a magnetic shield mumétal® and left 24 hours at room temperature. In parallel, a control series is performed. This control series consists of a tube containing an aliquot of the sample diluted to 10 ^"3 E. coli and another containing an aliquot of the sample diluted to ^{10" 8} E. coli are treated in the same way, but in separate mumetal® enclosures that are distant from each other.The placement in a mumetal® enclosure eliminates the very low frequencies (5 to 100 Hertz) of excitation but not the higher frequencies that could come from ambient electromagnetic noise.

After 24 hours, the tubes containing the diluted samples are again analyzed as described above, revealing that the tube containing an aliquot of T sample diluted to 10 ^"8 attached to the tube containing an aliquot of the sample diluted to ^{10" 3} no longer emits electromagnetic signals, or much weaker. On the other hand, the tubes of the control series remained identical; the tube containing an aliquot of the diluted sample to 10 ^"8" protected "from contact with the tube containing an aliquot of the sample diluted to ^{10" 3} remained positive for the emission of electromagnetic signals.

An important feature of the invention is that the negativising effect observed is specific, that is to say that the non-emitting lightly diluted sample and the highly diluted electromagnetic signal emitter must come from the same species of microorganism.

Thus, diluted E. coli emitting samples are "negative" only by a non-emitting diluted E. coli sample and not by a non-emitting low-dilution Streptococcus or Staphylococcal sample. Likewise, a diluted sample of Staphylococcus emitter is "negative" only by a non-emitting diluted Staphylococcal sample, and not by a non-emitting diluted non-emissive Streptococcus or E. coli sample. EXAMPLE 2: RAPID AND NON-INVASIVE METHOD OF DETECTING INFECTIONS IN HUMANS AND ANIMALS

1) Preparations of biological and artificial fluid samples containing microorganisms.

A blood sample, taken by anticoagulant, preferably heparin, from a patient suffering from neurological damage following a bacterial infection and suspension culture in LB (Luria broth) of Escherichia coli Kl (E. coli) are centrifuged to remove the cells. The bacterial supernatant and / or the plasma harvested are then diluted with ICT ² in RPMI medium. The solutions are filtered through a 0.45 μ Millipore PEVD filter and the filtrate is then filtered again on Whatman 0.02 μm filter or Millipore 0.1 μm filter. From the filtrates of the plasma of the infected individual and the culture of E. coli. coli Kl, a series of diluted samples corresponding to increasing dilution levels, up to 10 ¹⁵ , are prepared by carrying out dilutions of 10 to 10 in water for injection in a laminar flow hood. Successive dilutions are shaken vigorously with a vortex for 15 seconds between each dilution. The diluted samples are then dispensed into 1.5 milliliter Eppendorf conical plastic tubes. The volume of liquid is usually 1 milliliter.

2) Selection of diluted samples generating electromagnetic signals.

The selection of diluted samples emitting characteristic signals, signals whose amplitude is at least 1.5 times greater than the signals of the background noise and / or have a higher frequency than the background noise, is carried out identically to what is described above in Example 1, Chapter 2. The method described and the material is identical to that described above. Thus, the method comprises a step that is intended to transform the electromagnetic field from different dilutions into a signal, including an electrical signal, by means of a solenoid sensing said electromagnetic field.

The transformation of the electromagnetic field from the analyzed dilution into an electrical signal is carried out as follows: (i) Submission of the diluted sample under verification to an excitation field of electrical, magnetic and / or electromagnetic nature;

(iii) Selection of Diluted Samples with Characteristic Electrical Signals: Characteristics of signals whose amplitude is at least 1.5 times greater than background noise signals emitted by water and / or which exhibit frequency to higher values, are placed in protective enclosures protecting said diluted samples from interference from external electromagnetic fields.

3) Evaluation of the inhibitory activity of an infected individual on the emission of electromagnetic signals generated by a microorganism. The diluted samples selected in the previous step (item (iii), from the plasma filtrate of the infected individual, the E. coli culture filtrate, i.e. the filtered sample dilutions exhibiting a characteristic electrical signal, are distributed in plastic tubes Eppendorf, at a rate of 1 ml per tube and stored at + 4 ° C. The diluted emitting samples of SEM thus distributed in aliquots are protected from external influences by being placed in an enclosure to away from electromagnetic fields Preferably, the enclosure is surrounded by a magnetic shield made of mumetal isolating the enclosure parasitic fields of very low frequencies from the environment.

One of the diluted SEM emitting samples, from the plasma filtrate of the infected individual, the E. coli culture filtrate, coli, is distributed volume by volume in two tubes, one, Tl, remaining in a protective enclosure protecting said diluted samples from interference from external electromagnetic fields, which tube will serve as a reference solution, the other, the T2 tube which will be subsequently submitted to the patient is also placed in a protective enclosure. Said protective enclosure preferably being surrounded by a shield made of mumetal ^®

FIG. 2 diagrammatically represents the steps to be performed during the search for the inhibitory effect. The search for the inhibitory effect is carried out as follows: a) the Tl tube containing the reference solution remains stored in a chamber (3) surrounded by a magnetic shield made of mumetal ^® , the Tl tube is thus located free from the potential alterations of the individual to be examined ( 4) while the T2 tube is subjected to the influence of the infected individual to be examined (4) whose plasma present in the tubes T1 and T2 is derived, said individual holds T2 in his hand (5) for a determined period for example 5 minutes;

b) the tube T2 is placed in an equipment for receiving electromagnetic signals, preferably a solenoid reading cell as previously described in chapter 2 of this example; c) the electrical signals are then amplified, processed, converted to analog-digital signals as previously described in Chapter 2; d) said analog-digital signals are optionally decomposed into harmonics by Fourier transform. The signals corresponding to the tube T1 and those corresponding to the tube T2, as well as the signals corresponding to the tube T3 containing water (background noise) are compared.

The figures which follow represent the results obtained in the case where the active dilution comes from the plasma of the infected individual examined: FIG. 3 represents a three-dimensional histogram (Matlab) of the electrical signals detected by the solenoid in the presence of the T3 tube; (background noise);

FIG. 4 represents a three-dimensional histogram of the frequency spectrum detected by the solenoid in the presence of the tube 1;

FIG. 5 represents a three-dimensional histogram of the frequency spectrum detected by the solenoid in the presence of the tube 2;

FIG. 6 represents a Fourier analysis (SigView) of the same background noise (unfiltered electric power supply harmonics);

FIG. 7 represents a Fourier analysis of the signal detected by the solenoid in the presence of the tube 1; FIG. 8 represents a Fourier analysis of the frequency spectrum detected by the solenoid in the presence of the tube 2 manipulated by the individual to be examined.

3-dimensional histogram analysis, respectively of the background noise (FIG. 3) and of the signal obtained in the presence of the Tl tube containing the reference solution SEM transmitter (Fig.4), shows a shift towards higher frequencies. On the other hand, when one analyzes the tube T2 containing the solution subjected to the influence of the individual to be examined (Fig.5), one does not note displacement towards the higher frequencies; the 3D histogram representing the signals of the tube T2 is similar to that obtained for the background noise.

Fourier analysis of the positive frequencies generated by the tube 1 (FIG. 7) revealed peaks at different frequencies. In order of decreasing intensity of the signal, the following frequencies present signals: 1000, 2000, 3000, 4100, 5100 and 5500. On the other hand, the Fourier analysis of the T2 tube reveals results similar to those obtained by the analysis. background noise: no significant peak was observed, neither for the background noise nor for the T2 tube.

In conclusion, these analyzes make it possible to deduce that the examined individual has a capacity of inhibition of the electromagnetic signals emitted by a dilution of his own plasma. Similar results were obtained with the reference solution, derived from

E. coli Kl.

Therefore, this inhibitory power relates both to the emitting structures of its own plasma, but also to those of E. CoIi, which suggests that the individual is infected with a nanostructure producing agent close to those of E. coli. .

Claims

1) Process for the preparation of reagents intended for a test for the detection of microorganisms and in particular for infection in humans or animals, characterized in that it comprises the following steps: a) the centrifugation of a biological or artificial liquid medium containing a selected specific microorganism; b) filtering the supernatant obtained in step (a); c) preparing a series of diluted samples corresponding to increasing dilutions of the filtrate obtained in step (b), until dilution of the filtrate by a factor of 10 ^"

At least ¹⁵ ; d) subjecting the diluted samples obtained in step (c) to an excitation field of electrical, magnetic and / or electromagnetic nature; e) analyzing the electrical signals detected by means of a solenoid and digitally recording said electrical signal after analog / digital conversion of said signal; f) the selection of the diluted samples with which characteristic electrical signals are obtained in (e), i.e. signals whose amplitude is at least 1.5 times greater than the signals of the background noise emitted by the water and / or have a frequency shift to higher values; g) introducing the diluted samples selected in step (f) into protective enclosures, which protect said dilutions of the external electromagnetic fields; h) the distribution of one of said diluted samples from step (g) volume to volume in two tubes, one, T1, remaining in a protective enclosure protecting said diluted samples from interferences of external electromagnetic fields, which tube will be used of reference solution, the other, T2, also placed in a protective enclosure, tube which will subsequently be subjected to the presence or in contact with a sample suspected of containing said selected specific microorganism.

2) Method according to claim 1, characterized in that the biological fluid is a liquid from the man or the animal. 3) Process according to claim 1, characterized in that the artificial liquid is a culture medium of microorganisms.

4) A method for detecting microorganism in a sample, characterized in that said method comprises the following steps: a) a sample X for which the presence of a microorganism is suspected, for example E. coli, is put into the presence of a sample as obtained after step (f) of the process according to any one of claims 1 to 3, said sample as obtained after step (f) being a dilution from the filtrate of a culture or biological medium that contained said microorganism suspected of being present in sample X; b) the comparison of the electromagnetic signal emitted by the sample X in the presence of the sample as defined in step (f), obtained in step (a), with the electromagnetic signal emitted by an aliquot of the same sample as obtained after step (f) not subject to sample X.

5) Method according to claim 4, characterized in that said sample X is a human or animal individual.

6) Process according to claim 4, characterized in that said sample X is a biological sample.

7) Method according to claim 4, characterized in that said sample X is a food composition, cosmetic or pharmaceutical.

8) Microorganism detection system within a sample: a) a Tl tube prepared according to the method of one of claims 1 to 3 which contains a reference sample emitting characteristic electromagnetic signals, signals whose amplitude is at least 1.5 times higher than the background noise signals emitted by water and / or which exhibit frequency shifts to higher values; b) a T2 tube prepared according to the method of one of claims 1 to 3 which contains a sample emitting characteristic electromagnetic signals, said sample being identical to that contained in the tube T1; c) a protective enclosure protecting the T1 and T2 tubes from external electromagnetic fields; d) a T3 tube that contains a control solution that does not emit electromagnetic signals; e) equipment for receiving electromagnetic signals.

9) System according to claim 8, characterized in that the equipment for receiving the electromagnetic signals (e) comprises:

• a solenoid reading cell; "A computer equipped with a signal acquisition card (sound card), said computer comprising at least one signal processing software.

10) System according to claim 9, characterized in that the solenoid reading cell is sensitive from 0 to 20000 hertz, it comprises a coil having a soft iron core, said coil has an impedance of 300 ohms, an inside diameter of 6 mm, an outside diameter of 16 mm, a length of 6 mm.

11) System according to one of claims 8 to 10, characterized in that the negative control solution T3 is the solution that was used to perform the dilutions of the samples leading to the reagents T1 and T2.