FR2957536A1 - Test tubes for containing e.g. blood, to be analyzed in laboratory, has reading and/or writing unit that reads and/or writes identifier stored and/or to be stored in chip, where unit is located in circulation path of tube - Google Patents

Abstract

The test tubes (1) have a disk-shaped radio frequency identification (RFID) chip (3) incorporated in each tube and a tube holder (2). The chip stores an identifier of the tube, of a sample to be analyzed in the tube or an analysis process to be realized. A contactless radio frequency reading and/or writing unit reads and/or writes the identifier stored and/or to be stored in the chip, and is located in a circulation path of the tube. A joint made of flexible plastic material is inserted into inner circumference of an opening of a perforated upper plate (22) of the holder. The identifier of the tube corresponds to information representing defect of the tube, the material of the tube, and/or capacity and/or utilization period of the tube. The identifier of the sample in the tube corresponds to the information representing source, weight and/or volume of the sample. The identifier of the analysis process corresponds to the information representing the identification of chemical elements and/or specific instruments and/or obtained analysis results. An independent claim is also included for a method for utilizing test tubes in a tube holder.

Description

Test tubes and method of use

The present invention relates to the field of laboratory sample analysis. The present invention more particularly relates to test tubes, each containing a sample to be analyzed, and its method of use in a tube holder adapted to support a plurality of tubes. A problem in the field of laboratory sample analysis concerns the lack of productivity due in particular to the lack of automation and interoperability of the equipment of the laboratory analysis systems. Firstly, the demand for the analysis of samples of all kinds, whether liquid or solid, for example the analysis of blood or water samples, or of plants or soil, respectively, has greatly increased in recent years. years, for example because of the fight against sports doping 1s or influenza epidemics, or phytosanitary risks related to the cultivation of genetically modified organisms or the fight against impoverishment and soil pollution, respectively. Secondly, the laboratory analysis methods still require a large number of manual operations by the laboratory technicians. These manual operations, ranging from the preparation of the samples to be analyzed to the processing of the results of the analyzes, considerably slow down the rate of the analyzes and, because of the increase of the demand in analysis of samples, increase of the risks error. In order to increase the rate of analysis, while maintaining an irreproachable level of quality, the analysis laboratories, on the one hand, modernize their equipment and, on the other hand, optimize the analysis methods. They carry out a considerable work of automation and standardization of the different equipment of the analysis systems and call upon the industrial computing and the various techniques making it possible to increase the productivity by integrated processing of the data.

In this context, it is advantageous to propose a solution for the functional standardization of the test tubes containing the samples to be analyzed and a method of use in a tube holder supporting said test tubes which allows the automation of the analysis methods and interoperability of automated and standardized equipment analysis systems. The present invention aims to overcome one or more disadvantages of the prior art by providing test tubes and a method of using these tubes in a tube holder. This object is achieved by test tubes, characterized in that a radio frequency identification chip is incorporated in each of the tubes to store at least one identifier, the test tube, the sample to be analyzed and the method analysis to be performed, means for reading and / or writing without radiofrequency contact stored identifiers and / or to be stored in the identification chip of each tube being provided in the flow path of the tubes. According to one particularity, the identifier of each tube corresponds to information representative of the tare of the tube and / or of the material constituting the tube and / or of the capacity and / or duration of use of the tube. identifier of the sample contained by each tube corresponds to information representative of the source and / or weight and / or volume of the sample, and the identifier of the analysis method to be performed corresponds to information representative of the identification of one or more chemical elements and / or specific instruments and / or analysis results previously obtained, to be used for carrying out the analysis method. According to another feature, each tube has a cylindrical body portion closed by a bottom and has a ring fixed on the periphery of the tube approximately halfway up the cylindrical body portion.

According to another feature, the bottom of each tube has an inner profile whose radius of curvature is calculated to facilitate the stirring of a mixture, the sample and one or more chemical elements, placed in the tube.

According to another feature, the radio frequency identification chip is incorporated in a housing formed in the outer surface of the bottom of the tube and sealed after placement of the chip, each tube being reusable after washing for further analysis. Another object of the invention is to provide a method of using in a tube holder the test tubes described above. This object is achieved by a method of use in a tube holder of the test tubes described above, characterized in that a radio frequency identification chip is incorporated in the tube holder for storing at least one identifier, the tube holder, each tube supported by the tube holder and one or more analysis equipment involved in the analysis process to be performed. According to a feature, the identifier of the tube holder corresponds to information representative of the number of tube locations on the tube holder and / or the number of tubes actually supported by the tube holder and / or the duration of the tube holder. use of the tube holder, the identifier of each tube supported by the tube holder and information representative of the specific location of the tube on the tube holder and / or the method of analysis associated with the tube, and the identifier of the analysis equipment (s) involved in the analysis method to be performed corresponds to information representative of an access and / or routing code and / or a determined configuration of the analysis equipment. automatically adapted according to the number of tube locations on the tube holder. In another feature, the tube holder has a bottom plate forming a solid base and a perforated top plate at regular intervals, the two plates being rectangular in shape and of the same width, and the bottom plate being longer than the top plate. each corner of the upper plate being connected to the other plate by a rigid connecting element so that the plates are kept parallel to each other and at a certain distance determined according to the height of the test tubes, a first end the upper plate being aligned with a first end of the lower plate, so that the second end of the bottom plate remains unopposed at the height of the top plate to form a front end of the base of the carrier; tube. In another feature, each aperture of the perforated upper plate has an inside diameter slightly greater than the outside diameter of the director circle of the cylindrical body portion of the test tubes. According to another feature, in the inner periphery of each orifice of the perforated upper plate, is partially inserted a seal, in is flexible plastic material, so that the seal is clamped between the inner periphery of the orifice of the perforated upper plate and the outer surface of the test tube disposed in the corresponding location on the tube holder. According to another particularity, the radiofrequency identification chip of the tube holder is incorporated in the base of the tube holder and the length of the tube below the ring is such that the lower periphery of the ring abuts against the tube holder. perforated upper plate of the tube holder and that the bottom of each tube is held in a recess corresponding in size and shape made in the base of the tube holder, so that the identification chip of the tube holder and the chip 25 identification incorporated in the bottom of each tube disposed on the tube holder are approximately the same height. According to another particularity, the radiofrequency identification chip of the tube holder is incorporated in the front end of the base of the tube holder, so that the tube holder is oriented on its circulation path so that the front end of the base of the tube holder is located in front, the identification chip incorporated in the tube holder passes close to each reading means and / or writing without contact before the embedded identification chip in the test tube disposed at the first location that follows said front end of the base of the tube holder. According to another feature, the tube holder is adapted so as to be conveyed by one or more belt conveyors juxtaposed within the same analysis equipment and / or between several analysis equipment and so as to be able to be gripped and manipulated by a mechanical gripper within the same analysis equipment and / or between several Io analysis equipment and / or between several conveyor belts, without risk of overturning or falling, by adhesion and / or the interpenetration of sculptures between the lower surface of its base and the outer surface of the belts of the conveyors, by its dimensions and / or by its center of gravity. According to another feature, the tube holder comprises a single row of locations, each intended to have a test tube thereon, supports 5, 10 or 30 aligned test tubes and / or comprises, at each of the two ends of its base, one of two attachment means complementary to each other, so that several tube holders 20 can be attached to each other. According to another feature, the tube holder has on at least one side of its base an indentation for indexing the progress by automated drive means of the tube holder. Other features and advantages of the present invention will appear more clearly on reading the following description, made with reference to the appended drawings, in which: FIGS. 1, 2 and 3 represent the test tube according to FIG. FIGS. 4, 5 and 5 show an enlarged view on the bottom of the tube, in sectional view, respectively, of the indicated ribs corresponding to the dimensions of the test tubes for holding samples of soil to be analyzed; 6 represent the tube holder according to the invention in top view, in profile and in sectional view respectively, - Figures 7 and 8 show the tube holder on which are arranged the test tubes according to the invention. , in profile view and in sectional view respectively. The present invention firstly relates to a plurality of test tubes (1). These test tubes (1) are composed of a narrow cylindrical body part (11), open in its upper part with sometimes a slightly flared edge, closed by a bottom (12) rounded U or conical. The bottom of each test tube has a profile whose radius of curvature is calculated to facilitate agitation of the mixture of the sample to be analyzed and chemical elements added to the tube for analysis. These test tubes (1) are made of plastic or glass or any other suitable material chosen in particular according to the analysis method is to achieve. For example, in the case of analytical methods involving chemical reagents chemically attacking plastic materials, test tubes (1) made of glass will be preferred. The capacity of the test tubes (1) obviously depends on the inside diameter, or the area, of the circle of the cylindrical body part (11) and the height of the tubes (1) and is determined according to the processes of analysis implemented. For example, a standardized capacity of the test tubes (1) is determined by considering the analytical method requiring the largest volume of chemical species to be added to the volume of the largest sample to be analyzed. so that throughout said process 25 no material overflows the standardized capacity tube. The present invention also relates to a method of use in a tube holder (2) supporting and maintaining a plurality of said test tubes (1).

The tube holder (2) has a lower plate (21) forming a solid base (21) and an upper plate (22) perforated at regular intervals. The two plates (21, 22) are rectangular in shape and of the same width, and the lower plate (21) is longer than the upper plate (22).

Each corner of the upper plate (22) is connected to the other plate (21) by a rigid connecting element (23) so that the plates (21, 22) are kept parallel to each other and to a certain distance determined by according to the height of the test tubes (1). A first one of the ends of the upper plate (22) is aligned with a first one of the ends of the lower plate (21), so that the second end of the lower plate (21), which is longer than the top plate (21), 22), remains without vis-à-vis at the level of the upper plate (22). Subsequently, we call this second end without vis-à-vis the lower plate (21), the front end (24) of the base (21) of the tube holder. The difference in area between the two plates (21, 22), ie the area of the front end (24) of the tube holder (2), is approximately equal to the area corresponding to each location of a tube ( 1) on the tube holder (2). Each aperture (25) of the perforated top plate (22) has an inside diameter slightly greater than the outside diameter of the director circle of the cylindrical body portion (11) of the test tubes (1). In front of each orifice (25) of the perforated upper plate (22) and at the upper face of the solid base (21) of the tube holder (2) is formed a recess (27) of the shape and complementary dimensions of the bottom (12) of the test tube (1) for receiving the bottom (12) of the test tube (1) disposed in the corresponding location on the tube holder (2). In the inner periphery of each hole (25) of the perforated upper plate (22) is partially inserted a seal (26), made of flexible plastic material, so that the seal (26) is clamped between the inner periphery 30 orifice (25) of the perforated upper plate (22) and the outer surface of the test tube (1) disposed in the corresponding location on the tube holder (2). In addition, each test tube (1) comprises a ring (13) located around the cylindrical tube (11) approximately halfway up, and in a symmetry of revolution with respect to the axis of symmetry of the part of the tube. cylindrical body (11) of the tube (1), so that the lower periphery of the ring (13) abuts against the upper surface of the perforated upper plate (22) of the tube holder (2) at the periphery of the tube the orifice (25) through which the tube (1) is introduced, the bottom (12) of the tube being in contact with the corresponding recess (27) made in the base (21) of the tube holder (2). Each test tube (1) consists of a single piece or of several pieces fixed together and the tube holder (2) consists of one piece or several mechanically assembled parts. Thus, correctly placing a test tube (1) in a location of the tube holder (2) consists in introducing the test tube by its bottom (12) through an orifice (25) of the upper plate (22) of the tube holder until the bottom (12) of the tube rests in the recess (27) corresponding to the insertion orifice (25) and that the ring (13) of the tube comes into abutment against the upper surface of the perforated upper plate (22) of the tube holder at the periphery of the insertion orifice (25), the tube (1) being further maintained by the seal (26) inserted into the inner periphery of the tube the orifice (25) of introduction. Thus, any risk of imbalances and / or accidental falls from the tube holder (2) of the test tubes (1) 25 properly disposed are discarded. According to the invention, a radiofrequency identification chip (3) is incorporated in each of the test tubes (1) and in the tube holder (2). The identification chip (3) incorporated in each test tube (1) is incorporated in the bottom (12) of each tube (1). Each identification chip (3) is for example of the form of a disc, of a determined diameter smaller than the diameter of the directional circle of the cylindrical body part (11) of a test tube (1) according to the invention. The identification chip (3) incorporated in the tube holder (2) is incorporated in the front end (24) of the base (21) of the tube holder. Thus, the identification chips (3) of the test tubes (1) arranged in their respective locations of the tube holder (2) are approximately the same height as the identification chip (3) incorporated in the tube holder ( 2), and all the identification chips (3) are distributed over the entire length of the tube holder (2) at regular intervals, this interval being larger than the diameter of the identification chips (3). The insertion or incorporation of each identification chip (3) is performed by inserting the chip in a housing (32), of a size and shape adapted to the chip (3), provided in the bottom (12). of each tube and in the front end (24) of the tube holder, the chip (3) being fixed by a point of glue (31) applied in the bottom of the housing (32) and the housing being closed by a plug non-metallic material, or by incorporation of the chip (3) directly into the molding in the manufacture of the tubes (1) and the tube holder (2), respectively. Each tube holder (2) supporting test tubes (1), each containing a sample to be analyzed, is intended to be conveyed within an analysis equipment or between several analysis equipment so that each sample is analyzed, this conveying being for example provided by belt conveyors suitably arranged in an analysis equipment or between several analysis equipment. In the circulation path of the conveyor tube are located, for example slightly elevated relative to the conveyor belt level, non-contact reading and / or writing means 2957536 intended for reading and / or printing. write, respectively, information or identifiers in each identification chip (3). Because the identification chips (3) of the test tubes (1) disposed in their respective locations of the tube holder (2) are approximately the same height as the identification chip (3) incorporated in the holder. tube (2), each identification chip (3) that it is incorporated in one of the tubes (1) or in the tube holder (2) passes close to each reading and / or writing means. And since all the identification chips (3) are distributed over the entire length of the tube holder (2) at a regular interval, this interval being larger than the diameter of the identification chips (3), the reading and / or writing without contact in a determined identification chip (3) does not interfere with the reading and / or writing without contact in the identification chips (3) neighbors. All risks of interference are thus avoided. In addition, it is sufficient that the tube holder (2) is oriented during its conveying so that the front end (24) of the base (21) of the tube holder is located forward for the identification chip (3) incorporated in the tube holder (2) passes near each non-contact reading and / or writing means before the identification chip (3) incorporated in the test tube (1) disposed on the first location which follows said front end (24) of the base (21) of the tube holder. The tube holder has on at least one side of its base an indentation for indexing the progress by automated drive means of the tube holder. Thus, it is ensured a sufficient stopping time for reading and / or writing information or identifiers in each chip, whether it is incorporated in one of the tubes (1) or in the tube holder (2). ), precisely in front of or near each reading and / or non-contact writing means.

The radiofrequency identification chip (3) incorporated in each test tube (1) stores at least one identifier, the test tube (1), the sample to be analyzed and the analysis method to be performed. More particularly, the identifier of the test tube (1) corresponds to information representative of the tare of the tube and / or of the material constituting the tube and / or of the capacity of the tube and / or of a duration of use of the tube . The identifier of the sample contained by each test tube (1) corresponds to information representative of the reference and / or the source and / or the weight and / or the volume of the sample. The identifier of the analysis method to be performed corresponds to information representative of the identification of one or more chemical elements and / or specific instruments and / or analysis results previously obtained, to be used to implement the method analysis. The radiofrequency identification chip (3) incorporated in the tube holder (2) stores at least one identifier, the tube holder (2), each test tube (1) supported by the tube holder and the tube holder (2). or analysis equipment involved in the analysis process to be performed. More particularly, the identifier of the tube holder (2) corresponds to information representative of the reference of the tube holder and / or the number of tubes (1) supported by the tube holder and / or of a duration of use of the tube holder, the identifier of each test tube (1) supported by the tube holder corresponds to information representative of the specific location and / or the analysis method associated with each tube (1), and the identifier of the analysis equipment (s) involved in the analysis method to be performed corresponds to information representative of an access and / or routing code and / or a determined configuration of the equipment. automatically adapted to the number of tubes (1) supported by the tube holder (2). Each analysis equipment is equipped with at least one means 3o reading and / or writing without contact information stored and / or store, respectively, in the identification chip (3) by radio frequency of each tube test tube (1) and tube holder (2). For example, an analysis equipment is equipped at its input with a reading means for reading and transmitting to software, stored and installed in a computer associated with said equipment and for controlling said equipment, at least the information necessary for the implementation of the analysis to be performed by said equipment. And an analysis equipment is equipped at its output with a writing means for writing in at least one identification chip (3) of a test tube (1) determined the results of Io the analysis carried out in said test tube (1) determined by said analysis equipment. Among the software dedicated to laboratory analysis, mention may be made of the "Starlims" software developed by the applicant and the "Empower 2" software developed by WATERS SAS. According to the invention, the tube holder (2) is adapted in size, shape and weight, so that it can be conveyed by one or more belt conveyors juxtaposed within the same analysis equipment and / or between several analysis equipment. And the tube holder (2) is adapted so that it can be grasped and handled by a mechanical gripper within the same analysis equipment and / or between several analysis equipment and / or between several conveyor belts. without risk of overturning or falling, by the adhesion and / or the interpenetration of sculptures between the lower surface of its base (21) and the outer surface of the belts of the conveyors and by its dimensions and / or its center of gravity. It should be noted that each test tube may be associated with a cap and each mechanical gripper may dispose and / or remove the cap to plug and / or unclog the associated test tube, respectively.

The tube holder (2) comprises a single row of locations, each provided for disposing a test tube (1) therein. The pipe holder (2) supports 5, 10 or 30 aligned test tubes, the number of test tubes (1) supported by the tube holder (2) being chosen for example according to the number of samples of a same batch to analyze. The tube carrier (2) has at each of the two ends of its base (21) one of two attachment means (not shown), for example complementary to one another, so that several carriers tubes (2) can be attached to each other. The tube holder (2) according to the invention thus offers a great modularity. The identification chip (3) of the tube holder (2) contains information relating to the number of test tubes (1) potentially and / or actually supported by the tube holder, the specific location of each tube (1) supported, and / or the number of tube holders (2) and the location of each of them when several tube holders (2) are attached to each other. The test tubes (1) and tube holder (2) associated according to the invention are advantageously reusable after washing. The information stored in each identification chip (3) relating to the duration of use of the tube (1) or the tube holder (2) in which it is inserted makes it possible to identify and discard the tubes (1). ) and tubing (2) too worn or old, as well as managing the supply of the laboratory in new test tubes and tube holders. Analysis equipment is standardized and automated. Analytical equipment and conveyor belts are controlled by at least one common software or software dedicated to each, the software (s) being stored and installed (s) at least in a common computer or a computer dedicated to each device to enable the processor (s) to implement the analysis (s) to be performed. These software and hardware media are capable of communicating with each other the information necessary for the analysis method (s) to be implemented and / or for the conveying (s) of the tube holder (s). (2). In addition, it is conceivable that each equipment has several operating arrangements, a provision for each envisaged length of the tube holders; the equipment reads, thanks to its contactless reader located at the entrance, the number of locations of the tube holder which is presented there and automatically takes the corresponding disposition. Analysis equipment includes a sample collection machine, a sample preparation and dose reduction machine, a chemical injection machine in a test tube containing a sample, a machine for measuring the pH and / or lo the calcium level of a sample, a machine for grinding a sample to a given particle size, etc. Of course, the particular information listed above stored in each identification chip (3) of the test tubes (1) and the tube holder (2) are not limited. Any other information necessary for carrying out analysis methods known from the prior art is to be envisaged. It should however be noted that the storage capacity of identification chips (3) by radio frequency is limited. If necessary, the information necessary for the implementation of the analysis methods will be deported to storage media of the analysis equipment, and only codes or identifiers, making it possible to match such a tube or tube holder to such or such information stored on the storage media of the analysis equipment, will be stored in the identification chips. By way of example, the sample taking machine comprises an input contactless reading means which reads and uses the information stored in the tube (1) passing in its vicinity to communicate to the control software the tare of the previously measured tube and to indicate to the laboratory, for example on a display medium connected to the equipment computer, which instrument, or more particularly which picking spoon, it must use to collect the determined sample volume necessary for the analyzes to be carried out. The sample and the tube (1) are then manipulated, for example by a mechanical gripper, to be deposited on a scale. And, knowing the tare of the tube, the weight of the sample is then automatically measured. The test tube (1) containing the sample is then disposed, for example by a mechanical gripper, in an unoccupied location of a tube holder (2), and a contactless writing means, located at the outlet of the sample taking machine, writes the volume and / or the weight of the sample into the identification chip (3) of the test tube (1) containing the sampled sample.

By way of example, the chemical element injecting machine comprises a contactless reading means which reads and uses the information, stored in the tube (1) passing close to it, to communicate to the control software, which is the the weight of the sample to be analyzed and the method of analysis to be performed, according to which the chemical species to be injected, and their amounts and proportions, are determined. By way of example, the identification chip (3) of the tube holder (2) contains a routing code read at the input of an analysis equipment for accepting or refusing and directing to another analysis equipment the tube holder (2) according to the analyzes to be carried out.

By way of example, the identification chip (3) of the tube carrier (2) contains the information representative of each tube (1) supported and this information is read by a contactless reading means of a device. before the information contained in the identification chips (3) of each tube (1). Thus, the equipment control software knows the identification information of the test tubes (1) supported before their actual and consecutive reading by the same non-contact reading means and is able, by comparison, to identify by example any accidental or intentional substitution of the test tubes (1) to stop the analyzes in progress and send a warning signal. More generically, the tube and associated tube holder according to the invention make it possible to ensure the traceability of the samples and analyzes. Thanks to the test tubes (1) and to the tube holder (2) associated with the invention, it is advantageously possible to carry out various and varied analyzes requiring one or more standardized analysis equipment by limiting or even canceling, the number of manipulations performed by the laboratory technician. A significant increase in the rate of analysis is thus achieved. It should be obvious to those skilled in the art that the present invention permits embodiments in many other specific forms without departing from the scope of the invention as claimed. Therefore, the present embodiments should be considered by way of illustration, but may be modified within the scope defined by the scope of the appended claims, and the invention should not be limited to the details given above.

Claims (9)

REVENDICATIONS1. Test tubes (1), characterized in that a radiofrequency identification chip (3) is incorporated in each of the tubes for storing at least one identifier, of the test tube (1), of the sample to be analyzed and of the analysis method to be carried out, means for reading and / or writing without radiofrequency contact of the identifiers stored and / or stored in the identification chip (3) by radio frequency of each tube being provided on the path of circulation of the tubes. l0 2. test tubes (1) according to claim 1, characterized in that the identifier of each tube corresponds to information representative of the tare of the tube and / or the material constituting the tube and / or the capacity and / or a duration of use of the tube, the identifier of the sample contained by each tube corresponds to information representative of the origin 1s and / or the weight and / or the volume of the sample, and the identifier of the method of analysis to be performed corresponds to information representative of the identification of one or more chemical elements and / or specific instruments and / or analysis results previously obtained, to be used to implement the analysis method. 20 3. test tubes (1) according to claim 1, characterized in that each tube has a cylindrical body portion (11) closed by a bottom (12) and comprises a ring (13) fixed on the periphery of the tube approximately to half height of the cylindrical body part (11). 4. test tubes (1) according to claim 1, characterized in that the bottom (12) of each tube has an inner profile whose radius of curvature is calculated to facilitate the stirring of a mixture, the sample and one or more chemical elements, placed in the tube. 5. test tubes (1) according to claim 1, characterized in that each radio frequency identification chip is incorporated in a housing formed in the outer surface of the bottom (12) of the tube and sealed after installation of the puce, each tube being reusable after washing for new analyzes. 6. A method of use in a tube holder (2) test tubes (1) according to claims 1 to 5, characterized in that a radiofrequency identification chip s (3) is incorporated in the carrier tube for storing at least one identifier, the tube holder, each tube supported by the tube holder and one or more analysis equipment involved in the analysis process to be performed. 7. The method of use as claimed in claim 6, characterized in that the identifier of the tube holder (2) corresponds to information representative of the number of tube locations on the tube holder and / or the number of tubes. effectively supported by the tube holder and / or the duration of use of the tube holder, the identifier of each tube supported by the tube holder and information representative of the specific location of the tube on the is tube holder and / or the analysis method associated with the tube, and the identifier of the analysis equipment or devices involved in the analysis method to be performed corresponds to information representative of an access and / or routing code and / or a determined configuration of the analysis equipment adapted automatically according to the number of locations for tube 20 on the tube holder. 8. Method of use according to claim 6, characterized in that the tube holder comprises a lower plate (21) forming a base (21) and a solid plate (22) perforated at regular intervals, the two plates (21). 22) being of rectangular shape and of the same width, and the lower plate (21) being longer than the upper plate (22), each corner of the upper plate (22) being connected to the other plate (21). by a connecting element (23) rigid so that the plates (21, 22) are kept parallel to each other and at a certain distance determined as a function of the height of the test tubes (1), a first of the ends of the upper plate (22) being aligned with a first end of the bottom plate (21), so that the second end of the bottom plate (21) remains unopposed at the height of the top plate (22) to form a front end (24) of the base (21) of the tube holder. 9. Method of use according to claim 8, characterized in that each orifice (25) of the perforated upper plate (22) has an inside diameter slightly greater than the outside diameter of the circle of the cylindrical body portion (11) of the test tubes (1). 11. A method of use according to claim 8, characterized in that, in the inner periphery of each orifice (25) of the upper perforated plate Io (22), is partially inserted a seal (26), of flexible plastic material, so that the seal (26) is clamped between the inner periphery of the orifice (25) of the perforated upper plate (22) and the outer surface of the test tube (1) disposed in the corresponding location on the holder (25). tube (2). 12. The method of use as claimed in claim 8, characterized in that the identification chip (3) by radiofrequency of the tube carrier (2) is incorporated in the base (21) of the tube holder and the length of the tube. below the ring is such that the lower periphery of the ring abuts against the perforated upper plate of the tube holder and that the bottom of each tube is held in a recess corresponding in size and shape made in the base ( 21) of the tube holder, so that the identification chip of the tube holder and the identification chip incorporated in the bottom (12) of each tube disposed on the tube holder are approximately the same height. 13. The method of use as claimed in claim 8, characterized in that the radiofrequency identification chip (3) of the tube holder (2) is incorporated in the front end (24) of the base (21) of the tube holder, so that, the tube holder (2) being oriented on its circulation path so that the front end (24) of the base (21) of the tube holder is located in front, the chip identification device (3) incorporated in the tube holder (2) passes near each radiofrequency contactless reading and / or writing means before the identification chip (3) incorporated in the test tube (1) disposed on the first location that follows said front end (24) of the base (21) of the tube holder. 14. Method of use according to claim 6, characterized in that the tube carrier (2) is adapted so that it can be conveyed by one or more belt conveyors juxtaposed within the same analysis equipment and / or between several analysis equipment and so that it can be grasped and manipulated by a mechanical gripper within the same Io analysis equipment and / or between several analysis equipment and / or between several conveyor belts, without risk of overturning or falling, by the adhesion and / or interpenetration of sculptures between the lower surface of its base and the outer surface of the conveyor belts, by its dimensions and / or by its center of gravity . 15. The method of use as claimed in claim 6, characterized in that the tube holder (2) comprises a single row of locations, each provided for disposing a test tube, supporting 5, 10 or 30 test tubes. (1) aligned and / or comprises, at each of the two ends of its base (21), one of two attachment means complementary to each other, so that several tube holders (2) can be tied together. 16. A method of use according to claim 8, characterized in that the tube holder (2) has on at least one side of its base an indentation for indexing the progress by automated drive means of the door -tube.