FR3094987A1 - Device for determining bacteriological contamination in a fluid - Google Patents

Abstract

Device for determining contamination of microorganisms in a fluid, The invention relates to a device for determining contamination of microorganisms in a fluid, said device comprising a box comprising an internal volume, a cover closing the box, a fluid inlet port, at least one filtration member, at least one nutrient layer comprising a composition of a microbiological culture medium, characterized in that the device comprises a fluid outlet port, and in that the cover comprises an internal surface within the internal volume extending radially around the fluid inlet port to a peripheral edge of the cover, said inner surface being inclined and converging towards the fluid inlet port, and in that the bottom of the housing comprises a surface extending radially around the fluid outlet port to the side wall of the housing, said internal surface being inclined and converging towards the por t fluid outlet.

Description

Device for determining bacteriological contamination in a fluid

Technical field of the invention

The invention relates to the technical field of microbiological analysis. More particularly, the invention relates to a microbiological control device for controlling a liquid to be analyzed, this liquid being capable of containing at least one microorganism.

Background of the invention

The invention can be applied to the field of industrial, agrifood, pharmaceutical, cosmetic or veterinary microbiological control, whether in a terrestrial or space application.

The invention was developed following work that benefited from the participation of the Center National d'Etudes Spatiales (CNES) and the company INITIAL

Technological background of the invention

There are many situations in which it is sought to control the presence of at least one microorganism in a liquid, generally with a view to being able to ascertain the absence of this microorganism. Of course, the liquid to be analyzed may be a biological liquid (whole blood, serum, plasma, urine, cerebrospinal fluid, organic secretion, etc....). However, the liquid can also be an industrial liquid, in particular a food liquid (water, drink in general and in particular fruit juice, milk, soda, etc.) or a pharmaceutical or cosmetological or veterinary liquid (sick animal milk) .

Many laboratory techniques are known which make it possible to filter the liquid to be analyzed in order to collect any micro-organisms contained in the liquid, to culture these micro-organisms in order to then be able to detect them, count them, characterize and/or identify them. These techniques require a certain number of manipulations and infrastructures (filtration ramp, benches, ovens) well known to laboratory workers.

In these techniques, it is often necessary to use a filtration device which comprises a closed internal space delimited by an enclosure and which is intended to receive the liquid to be analyzed. Such a technique is in particular called “membrane filtration”. A microbiological filtration means, for example a filtering membrane, is arranged in the closed internal space and separates, in the closed internal space, a first compartment from a second compartment of the closed internal space. The device (= filtration cassette) comprises an inlet port for the liquid to be analyzed which opens into the first compartment of the closed internal space.

In certain known filtration devices, the device is opened to recover the filtration means, which is transferred into a culturing device to allow incubation of the microorganisms. Such a technique is easily achievable in the laboratory.

On the other hand, such a technique is difficult to implement in an operational environment, in the field, within the International Space Station and also in an industrial environment in which liquids are produced, packaged, distributed or used.

We know from document WO2018189478 A1, a device and a method for the microbiological control of a liquid to be analyzed which allow particularly simplified control operations, which it would even be possible to use or conduct outside the microbiological laboratory, including in an industrial environment. This document describes a microbiological control device for controlling a liquid to be analyzed which may contain at least one microorganism. The control device comprises a closed box intended to receive the liquid to be analyzed, a microbiological filtration means arranged in the closed internal space and separating, in the closed internal space, a first compartment from a second compartment of the space closed internal space, an inlet port for the liquid to be analyzed opening into the first compartment of the closed internal space, a nutrient layer comprising a composition of a microbiological culture medium. The main disadvantage of this device is the fact that the liquid after its filtration remains in the device and it is not possible to recycle it and that the liquid remaining in the device can wash out the PAD, dilute the nutrient medium and generate false negatives. In addition, the manufacture of the device imposes the vacuum of the case, which is a major constraint.

Object of the invention

The invention is an improvement of the aforementioned device, more compact and more practical.

To this end, the subject of the invention is a device for determining microorganism contamination of a fluid, said device comprising:

- a box comprising an internal volume delimited by at least one side wall and a bottom,

- a lid closing the case and positioned opposite the bottom,

- a fluid inlet port arranged on the lid and opening into the internal volume of said box, the fluid inlet port extending along a substantially secant axis and preferably perpendicular to the lid,

- at least one filtration member, arranged in the internal volume,

- at least one nutrient layer comprising at least one composition of a microbiological culture medium,

characterized in that the device comprises a fluid outlet port provided on the housing and opening into the internal volume of said housing, and in that the cover comprises an internal surface in the internal volume extending radially around the inlet port of fluid as far as a peripheral edge of the cover, the said internal surface being inclined or curved and converging towards the fluid inlet port, and in that the bottom of the housing comprises a surface extending radially around the fluid outlet port to the side wall of the housing, said internal surface being inclined and converging towards the fluid outlet port.

Advantageously, in the device according to the invention, the fluid passes through the device and does not stagnate in the bottom of the box and on the filter, which allows rapid passage of the liquid in the device with reduction of the forces required for this passage and in in addition to avoiding leaching of the nutrient layer and ensuring that the microorganisms will be collected in the best conditions and incubated in the best conditions. In addition, the inclination of the inner surface of the lid allows to improve the distribution of the fluid in the device and to ensure that all the fluid is evenly distributed on the filter in order to allow an even distribution of the micro-organisms. on the filter, thus avoiding the formation of any microbial agglomerate on the filter which could generate false negatives.

Advantageously, the device is configured to quantify and detect two faecal contaminants, for example E. coli and Enteroccocus bacteria.

In the present invention, the term "port" means a fluid channel having a central orifice longitudinally passing through said channel.

Preferably, the device according to the invention is used vertically, that is to say that the fluid inlet port and the fluid outlet port are positioned vertically.

In the present application, an object positioned vertically is an object arranged in a direction parallel to the direction of gravity.

According to one characteristic of the invention, the fluid is a liquid, for example water, or the fluid is a gas, for example air.

According to another characteristic of the invention, the inclination of the internal surface of the cover is strictly greater than +4°. Preferably, the inclination of the internal surface of the lid is preferably between +5° and +15° and even more preferably equal to substantially 10°.

According to another characteristic of the invention, the inclination of the bottom surface is strictly less than 0°. Preferably, the inclination of the bottom surface is preferably between -5° and -10° and even more preferably between -6.5° and -7.5°.

According to another characteristic of the invention, the fluid inlet port protrudes into the internal volume of the case relative to the internal surface of the cover.

Preferably, the fluid inlet port is provided substantially at the center of the lid.

According to another characteristic of the invention, the inlet port comprises a first end extending out of the cover and configured to cooperate with a stopper.

According to another characteristic of the invention, the fluid inlet port comprises a second end extending into the internal volume, the second end being provided with at least one side orifice opening into the internal volume.

According to another feature of the invention, the at least one side orifice is oriented to at least partially project the fluid towards the internal surface of the cover.

According to another characteristic of the invention, the inlet port comprises at least two side orifices, preferably arranged opposite one another.

According to another characteristic of the invention, the fluid outlet port comprises a first end extending outside the housing and configured to cooperate with a plug.

According to another characteristic of the invention, the fluid inlet port comprises a second end flush with the bottom of the case.

According to one characteristic of the invention, the filtration unit is arranged in the box at a determined distance h from the inlet port. Advantageously, the determined distance h is strictly greater than 1 mm and is preferably between 1.5 and 5 mm and even more preferably between 2.5 and 3.5 mm. It is necessary for the filtration device to be at a determined distance h so that the microorganisms, when the device is incubated, can grow and form clearly visible colonies. This determined distance conditions a minimum volume of air necessary for the growth of said microorganisms.

According to another characteristic of the invention, when the inlet port and the fluid outlet port are closed off by plugs, the device according to the invention is fluid-tight.

According to one characteristic of the invention, the cover is transparent or translucent, which makes it possible to observe the microbial colonies after incubation.

According to a characteristic of the invention, the box of substantially cylindrical or polygonal shape.

According to one characteristic of the invention, the box comprises a first circumferential bearing surface shaped to cooperate in a complementary manner with a rim of the lid. Advantageously, the cover and the box are welded together by ultrasound.

According to one characteristic of the invention, the housing comprises at least a second bearing surface, extending into the internal volume and shaped to receive a peripheral portion of the filtration member, said second bearing surface being shaped to cooperate with a portion of the lid, so that the peripheral portion of the filtration member is clamped between the lid and the housing in a preferentially uniform manner so that the filtration member is stable and fixed during the passage of the fluid in the device and in such a way as to ensure that there are no leaks and that all the fluid passes through the filtration unit.

According to another characteristic of the invention, the bottom of the case comprises support blades arranged radially with respect to the fluid outlet port.

According to a characteristic of the invention, said blades are configured to support the support grid and guide the fluid towards the fluid outlet port.

According to a feature of the invention, the support blades project relative to the bottom surface and extend substantially perpendicular to said bottom surface.

According to one characteristic of the invention, the internal pressure in the case is substantially equal to the pressure external to the case in terrestrial conditions, that is to say that no depression is produced before sealing the cover on the case.

According to one characteristic of the invention, the device comprises a support grid.

According to one characteristic of the invention, the support grid is configured to support the nutrient layer and the filtration member.

According to one characteristic of the invention, the support grid is arranged between the nutrient layer and the bottom of the box.

According to one characteristic of the invention, the support grid is generally cylindrical or polygonal in shape.

According to one characteristic of the invention, the support grid comprises a plurality of through openings distributed over the entire grid, which makes it possible to distribute the fluid having passed through the nutrient layer over the entire surface of the bottom in order to better evacuate it quickly. and thus avoid any liquid stagnation in the device.

According to one characteristic of the invention, the support grid preferably rests on support blades formed in the bottom of the case.

According to one characteristic of the invention, the support grid preferably has the same size and shape as the nutrient layer situated above, so as to avoid any formation of the latter during the passage of the liquid.

According to one characteristic of the invention, the support grid has a shaped perimeter to adapt to the shape of the case so that the grid is held in the case and in the internal volume by friction.

According to one characteristic of the invention, the box comprises a third support surface 25 intended to receive the support grid and more particularly to receive a peripheral edge of the support grid.

According to another characteristic of the invention, the third bearing surface extends in the internal volume of the case and corresponds to an external shoulder of the case.

According to one characteristic of the invention, the filtration member is permeable to fluids and in particular to a gas or to a liquid whose viscosity allows microbiological filtration and freed from all solid particles.

According to another characteristic of the invention, the filtration member is a filtration member impermeable to microorganisms and more preferably to bacteria, which makes it possible to retain them on the surface of said at least one filtration member.

According to one characteristic of the invention, the filtration member is separate from the nutrient layer.

According to one characteristic of the invention, the filtration member is permeable to the nutrients and to the possible additive elements included in the nutrient layer.

According to one characteristic of the invention, the filtration member is made in the form of a porous membrane and can for example be based on one or more materials, or derivatives of these materials, among latex, polytetrafluoroethylene, poly (vinylidene) fluoride, polycarbonate, polystyrene, polyamide, polysulphone, polyethersulfone, cellulose, a mixture of celluloses and nitrocellulose.

Advantageously, the filtration member has a surface greater than the surface of the nutrient layer so that the surface of said nutrient layer is entirely covered by the filtration member.

Preferably, the filtration member is white or the like, which makes it possible to optimize the differentiation of colored colonies on their surface. Alternatively, the organ of filtration can be dark to facilitate the visibility of white or cream colonies.

Advantageously, the filtration capacity and the hydrophilicity of the filtration member, for their part, are used to allow and optimize the passage of the nutrient elements and any additive elements present in the nutrient layer after its rehydration towards a surface. upper surface of the filtration member while preventing or limiting the reverse migration of bacteria, yeasts, etc. filtered at the upper surface of the filtration member.

Advantageously, the filtration member comprises pores whose diameter is between 0.01 and 0.8 microns, preferably between 0.2 microns and 0.6 microns, so as to retain bacteria, yeasts and molds on its surface. According to a particular embodiment, the filtration means comprises pores whose diameter is between 0.25 microns and 0.6 microns, for example between 0.3 microns and 0.6 microns, or even between 0.4 microns and 0.6 microns. Alternatively, it may be a layer having no measurable pores such as a dialysis membrane. For example, the filtration member may be a membrane of the “Fisherbrand™ General Filtration Membrane Filters” brand marketed by Fisher Scientific Company L.L.C, 300 Industry Drive, Pittsburgh, PA 15275, USA, or even a membrane of the “Nitocellulose Membrane Filters”, manufactured by Zefon International, Inc., 5350 SW lst Lane, Ocala, FL 34474, USA.

According to one characteristic of the invention, the nutrient layer is arranged under the filtration member and preferably in contact with said filtration member.

According to one characteristic of the invention, the nutrient layer comprises a support containing a microbiological culture medium.

According to one characteristic of the invention, the support can be based on various absorbent compounds, preferably with very high water retention power, such as rayon, cotton, natural or chemically modified cellulosic fibers such as carboxy- methyl cellulose, absorbent or superabsorbent chemical polymers such as polyacrylate salts, acrylate/acrylamide copolymer.

According to another characteristic of the invention, the support can be impregnated with a microbiological culture medium in liquid form.

Advantageously, the microbiological culture medium can advantageously be dehydrated, that is to say having an “Aw” (Activity of water) incompatible with microbial development. Alternatively, the support can be covered or impregnated in the dry state with a microbiological culture medium or its constituents in powder form. Alternatively, the liquid impregnation can, after dehydration, be completed by adding powder.

The term "microbiological culture medium" means a medium comprising nutrients necessary for the survival and/or growth of microorganisms, in particular one or more of the carbohydrates, including sugars, peptones, growth factors, mineral salts and/or vitamins, etc. In practice, the person skilled in the art will choose the microbiological culture medium according to the target microorganisms, according to perfectly known criteria and within the reach of this person skilled in the art . The nutrient layer may contain any additive elements such as for example:

• one or more selective agents such as inhibitors or antibiotics to promote the growth and development of a particular species/strain of microorganism over another;
• stamps, dyes.

In general, the nutrient layer may additionally contain a substrate allowing the detection of an enzymatic or metabolic activity of the target microorganisms by means of a signal which can be detected directly or indirectly. For direct detection, this substrate can be linked to a part acting as a fluorescent or chromogenic marker. For indirect detection, the nutrient layer according to the invention may additionally comprise a pH indicator, sensitive to the variation in pH induced by the consumption of the substrate and revealing the growth of the target microorganisms. Said pH indicator can be a chromophore or a fluorophore. Mention may be made, as examples of chromophores, of neutral red, aniline blue, bromocresol blue. Fluorophores include, for example, 4-methylumbelliferone, hydroxycoumarin derivatives or resorufin derivatives. Thus, the preferential PC-PLC fluorescent substrate used for implementing the method according to the invention corresponds to 4-Methyl-Umbelliferyl-Choline Phosphate (4 MU-CP).

According to one characteristic of the invention, the microbiological culture medium of the nutrient layer is, in a configuration of provision of the device according to the invention before use, dehydrated. In this case, after dry impregnation of the support of the nutrient layer with the dehydrated microbiological culture medium, the nutrient layer can be the subject of a calendering operation. The calendering, by the pressure and the heating temperature generated, allows the retention and the stable maintenance over time of the dehydrated microbiological culture medium in the support of the nutrient layer, by ensuring the retention of the nutrient elements and any additive elements in the nutrient layer. The calendering of the nutrient layer also makes it possible to obtain a smooth and flat surface of the nutrient layer. Calendering also makes it possible to accelerate the rehydration of the nutrient layer compared with a non-calendered nutrient layer, due to the compression of the nutrient layer that it induces. In the case where the support is formed of fibers, this compression, associated with the presence of the dehydrated medium within the nutrient layer, generates a strong increase in the capillary power of the latter, causing its almost instantaneous rehydration. This can also contribute to a phenomenon of aspiration of the distinct microbiological filtration organ placed against its surface. The microbiological filtering member can thus find itself pressed against the nutrient layer, thus ensuring the absence of space or the reduction of space between the two, in favor of optimal microbial growth and/or survival on the entire surface of the microbiological filtration medium. It is thus possible to avoid the presence of a connecting means (for example avoiding the presence of a binding layer) between the microbiological filtration member and the nutrient layer when these are distinct. This represents a significant advantage, insofar as such a bonding means would slow down the passage of nutrients and possible additive elements from the rehydrated nutrient layer towards the microorganisms present on the microbiological filtration means, thus reducing the growth and/or or the chances of survival of these microorganisms.

Preferably, the nutrient layer may be of the type of microbiological culture device described in patent application FR19/03751 filed on April 8, 2019.

According to one characteristic of the invention, the nutrient layer is a microbiological culture device comprising all or part of a dehydrated microbiological culture medium in powder form, comprising at least two parts made of hydrophilic and absorbent material having an upper face at least substantially planar, and comprising between two contiguous parts said dehydrated microbiological culture medium in powder form, and said microbiological culture medium comprising at least one gelling agent in powder form.

Numerous absorbent, hydrophilic and water-insoluble materials can be used to produce the part made of absorbent material of a microbiological culture device according to the invention. These materials are mainly chosen for their absorbency, their ability to retain aqueous liquids and their ability to let aqueous liquids pass through them in all directions.

According to one characteristic of the invention, the part made of absorbent material is made from a substrate of non-woven short fibers, constituting an assembly having structural integrity and mechanical coherence. Particularly suitable substrates are natural (such as cotton) or synthetic (such as rayon) cellulosic fiber, modified cellulosic fiber (eg, carboxymethylcellulose, nitrocellulose), fiber of absorbent chemical polymers (such as polyacrylate salts , acrylate/acrylamide copolymers). Advantageously, the part made of absorbent material is made of non-woven fabric made of cellulose fibers.

In the context of the present invention, the parts made of hydrophilic and absorbent material of the same device can have the same density or have a different density. Similarly, the parts made of hydrophilic and absorbent material of the same microbiological culture device according to the invention may have an identical or different thickness.

According to one characteristic of the invention, the part made of hydrophilic and absorbent material has a density of between between 0.045 g.cm-3 and 0.10 g.cm-3, preferably between 0.05 g.cm-3 and 0.07 g.cm-3.

The parts made of hydrophilic and absorbent material of the same microbiological culture device according to the invention can have a thickness of between 0.5 mm and 2 mm. Preferably, the part made of hydrophilic and absorbent material has a thickness of 0.8 mm to 1.8 mm, more preferably 1 to 1.5 mm. The surface of the part made of hydrophilic and absorbent material is between 1 cm ² and 40 cm ² preferentially between 10 cm 2 and 30 cm 2 , more preferentially between 15 cm ² and 25 cm ² .

According to one characteristic of the invention, the part made of hydrophilic and absorbent material is capable of retaining a volume of water greater than 2 ml, preferably greater than 3 ml. Thus, a porous support with a surface area of 25 cm ² and a thickness of 1 mm after calendering will have the capacity to retain a volume of water of 3 ml.

According to one characteristic of the invention, the microbiological culture device has undergone a calendering operation. The calendering, by the pressure and the heating temperature generated, allows the retention and the stable maintenance over time of the dehydrated reaction medium comprising the gelling agent(s) in the microbiological culture device, by ensuring the retention of the various elements such as nutrients between the parts made of hydrophilic and absorbent material.

Preferably the calendering is done at a temperature above room temperature, preferably at a temperature between 30°C and 60°C. A temperature below 60° C. makes it possible not to denature the heat-labile compounds of the culture medium.

The calendering thus makes it possible to maintain the reaction medium inside the microbiological culture device and makes it easy to handle.

According to another characteristic of the invention, the culture medium further comprises at least one gelling agent also in powder form. Once activated, rehydrated, by a liquid to be analyzed, the gelling agent(s) will make it possible to create an assembly having a certain structural integrity and mechanical coherence. In addition, due to their presence in contact with the culture medium, the gelling agent(s) will give the microbiological culture device an agar consistency, thus promoting the establishment of microorganisms and will also allow the constituent elements of the culture medium, such as than the nutritive ingredients or the active agents, to be as close as possible to the microorganisms.

According to another characteristic of the invention, the gelling agent is chosen from: a xanthan gum, alginate, a gellan gum, a galactomannan gum, locust bean gum, starch, and a mixture of these.

Preferably, the culture medium of the device according to the invention comprises at least one gelling agent, the quantity of which is between 0.0030 g.cm-3 and 0.020 g.cm-3.

The invention also relates to an assembly comprising at least one at least one fluid supply, and at least one device according to the invention, said device being connected by its fluid inlet port to a fluid supply.

Advantageously, the assembly further comprises a second device according to the invention mounted in parallel with the first device according to the invention.

According to another characteristic of the invention, the assembly comprises a plurality of devices according to the invention mounted in parallel to each other.

Advantageously, the devices of the plurality can be identical or else be dedicated to a different type of microorganism.

According to another characteristic of the invention, the fluid outlet port can be connected to a container or not.

According to one characteristic of the invention, the device(s) according to the invention can be housed in compartments at the level of an industrial or other pipeline structure.

According to a characteristic of the invention, the device has a volume capacity allowing the analysis of 100ml of liquid.

Brief description of figures

The invention will be better understood, thanks to the description below, which relates to an embodiment according to the present invention, given by way of non-limiting example and explained with reference to the appended schematic figures. The attached schematic figures are listed below:

is a perspective view of the contamination determination device according to the invention,

is a median cross-sectional view of the device shown in Figure 1,

is a detail view of Figure 2,

is a partial perspective view of the device according to the invention illustrating the support grid housed in the case,

is a perspective view from below of the cover of the device according to the invention,

is a perspective view of the inside of the case of the device according to the invention,

is a cross-sectional view of the cover and of the filtration member of the device according to the invention, and,

is a cross-sectional view of the housing of the device according to the invention.

is a schematic view of a first step of a first mode of use of the device according to the invention,

is a schematic view of a second step of the first mode of use of the device according to the invention,

is a schematic view of a third step of the first mode of use of the device according to the invention,

is a schematic view of a first step of a second mode of use of the device according to the invention,

is a schematic view of a second step of the second mode of use of the device according to the invention,

is a schematic view of a third step of the second mode of use of the device according to the invention,

Detailed description of figures

The device 1 for determining microorganism contamination of a fluid according to the invention comprises a box 2, a cover 3, a filtration member 4, a nutrient layer 5 and a grid 6, as illustrated in particular in FIG. 2.

As can be seen in Figure 1, only cover 3 and box 2 are visible from the outside. Advantageously, the cover 3 and the box 2 are sealed together by ultrasound. According to the cross section shown in Figure 2, it can be seen that the filtration member 4 is arranged in the internal volume of the housing 2, the nutrient layer 5 is arranged under the filtration member 3, preferably in contact with the latter and a support grid 6 is arranged between the nutrient layer 5 and the bottom 22 of the box 2.

According to the invention, the filtration member 4 is permeable to fluids and in particular to a gas or to a liquid whose viscosity allows microbiological filtration and freed from all solid particles.

The device 1 further comprises a fluid inlet port 11 and a fluid outlet port 12 as shown in Figure 1. The fluid inlet port 11 is positioned on the cover 3 and the fluid outlet port 12 is positioned on the housing 2 and preferably on the bottom of the housing 2. The fluid inlet port 11 and the fluid outlet port 12 open into the internal volume of the housing 2, as shown in Figure 2. When the port of the inlet and the fluid outlet port are closed off by plugs, the device according to the invention is fluid-tight.

As can be seen in Figure 2 for example, the fluid inlet port 11 protrudes into the internal volume of the housing 2 with respect to the internal surface 31 of the cover 3. Preferably, the fluid inlet port 11 is formed substantially at the center of the cover 3. The fluid inlet port comprises a first end 11a extending outside the cover 3 and configured to cooperate with a stopper (not shown) and a second end 11b extending into the internal volume , the second end being provided with at least one lateral orifice 11c opening into the internal volume and oriented to at least partially project the fluid towards the internal surface 31 of the lid 3.

As can be seen in Figure 2 for example, the fluid outlet port 12 comprises a first end 12a extending out of the box 2 and configured to cooperate with a plug and a second end 12b flush with the bottom 22 of the box 2.

The fluid inlet port 11 and the fluid outlet port 12 respectively extend along a substantially secant axis and preferably perpendicular to the cover 3 or to the bottom of the case 2. In the example illustrated in FIG. 2, the port of fluid inlet 11 and fluid outlet port 12 are aligned and facing each other.

The housing 2 of the device 1 will now be described in detail with reference to Figures 1, 2, 6 and 8. As can be seen in Figure 1, the housing 2 of substantially cylindrical shape.

As illustrated in Figure 2, the box 2 comprises an internal volume delimited by at least one side wall 21 and a bottom 22.

In FIGS. 2 and 8, the casing 2 is illustrated in cross section, which shows a first circumferential bearing surface 23 shaped to cooperate in a complementary manner with a rim 33 of the cover 3. Furthermore, according to the invention, the housing 2 comprises at least one second bearing surface 24, extending into the internal volume and shaped to receive a peripheral portion 41 of the filtration member 4, said second bearing surface 24 being shaped to cooperate with a portion 34 of the cover 3, so that the peripheral portion 41 of the filtration member 4 is pinched between the cover 3 and the box 2 as can be seen in detail in FIG. 3. In addition, the box 2 comprises a third support surface 25 intended to receive the support grid 6 and more particularly to receive a peripheral edge 65 of the support grid 6. The third support surface 25 extends in the internal volume of the box 2 and corresponds to a external shoulder 26 of case 2, as shown in figure 8.

As can be seen in Figure 8, each bearing surface 23, 24, 25, has a different diameter and advantageously, the first bearing portion 23 has a diameter greater than the second bearing portion 24 which itself has a diameter greater than the third support portion 25.

As can be seen clearly in Figure 6, the bottom 22 of the housing 2 comprises a plurality of support blades 27 configured to support the support grid 6 and guide the fluid to the fluid outlet port 12. The support blades 27 are arranged radially with respect to the fluid outlet port 12. The support blades 27 project with respect to the surface of the bottom 22 and extend substantially perpendicular to said surface of the bottom 22, as visible in cross section illustrated in FIG. .

As can be seen in particular in Figure 8, the bottom 22 of the housing 2 comprises a surface 28 extending radially around the fluid outlet port 12 to the side wall 21 of the housing 2, said internal surface 28 being inclined and converging towards the fluid outlet port 12, in order to facilitate the evacuation of the fluid. In the example illustrated in Figures 2 and 8, the inclination β of the surface 28 of the bottom 22 is strictly less than 0° and is between -5° and -10°. Tests were carried out by the Applicant who found that if the bottom was flat, the fluid did not drain or only partially.

Cover 3 of device 1 will now be described in detail with reference to Figures 1, 2, 5 and 7.

As can be seen in Figure 1, the cover 3 comprises a base of substantially cylindrical shape, surmounted by the fluid inlet port 11. The cover 3 comprises an internal surface 31 closing the internal volume of the box 2. The internal surface of the cover 3 extends radially around the fluid inlet port 11 as far as a peripheral edge 32 of the cover 3, said internal surface 31 being inclined and converging towards the fluid inlet port 11. The internal surface 31 therefore has a frustoconical overall shape extending from the fluid inlet port 11 and widening as far as the peripheral edge 32 of the lid 3. In a variant not shown, the internal surface may be curved.

In the example illustrated in FIGS. 2 and 7, the inclination α of the internal surface 31 of the cover 3 is strictly greater than +4° and is between +5° and +15°. Tests were carried out by the Applicant, who found that if the internal surface of the cover had an inclination of less than or equal to 4°, the fluid was not distributed uniformly over the filtration unit 4.

As can be seen in Figure 7, the filtration member 4 is arranged in the housing 2 at a determined distance h from the fluid inlet port 11. Advantageously, the determined distance h is strictly greater than 1 mm and is preferably included between 1.5 and 5mm. Indeed, tests conducted by the applicant have demonstrated that it was necessary for the filtration member 4 to be at a determined distance h so that the microorganisms can grow when device 1 according to the invention was incubated can . This determined distance h conditions a minimum volume of air necessary for the growth of said microorganisms. In the example illustrated in Figures 1, 2, 5, and 7, the cover 3 is transparent or translucent, which makes it possible to observe the growth of microorganisms.

According to one characteristic of the invention, the support grid is configured to support the nutrient layer and the filtration member.

The support grid 6 of the device 1 will now be described in detail with reference to Figures 2 and 4.

As can be seen in Figure 2, the support grid 6 is arranged between the nutrient layer 5 and the bottom 22 of the box 2. The support grid 6 is generally cylindrical in shape and of the same size as the nutrient layer 5.

As can be seen in Figure 4, the support grid 6 comprises a plurality of through openings 61 distributed over the entire grid 6, which makes it possible to distribute the fluid having passed through the nutrient layer 5 over the entire surface 28 of the bottom 22 in order to better evacuate it quickly.

As illustrated in figure 2, the support grid 6 rests on the support blades 27 of the box 2. The support grid 6 comprises a peripheral edge 65 resting on the third support surface 25 of the box 2 as shown in figure 2, and 3.

In a variant not shown, the grid rests only on the third support surface 25 of the box, the support blades being optional.

Two possible uses of the device according to the invention will now be described with reference to Figures 9 to 14.

According to a first use illustrated in FIGS. 9 to 11, a syringe 100 or any other element comprising a piston containing the fluid to be analyzed is connected to the fluid inlet port 11 of the device 1, and connected to the fluid outlet port 12 of the device 1, a manifold 101 or another syringe, as illustrated in FIG. 9. A three-way valve 102 is positioned between the device 1 and the syringe 100, the syringe 100 being connected indirectly to the fluid inlet port 11 of the device 1. Initially and as illustrated in Figure 9, the first inlet 102a of the valve 102, connected to the syringe 100 is closed, the second inlet 102b is open and connected to an air inlet, and the outlet 102c is also open and connected to the fluid inlet port 11 of the device. By this means, it is possible to create a vacuum before using the device and before introducing the fluid to be analysed/filtered.

Then, as shown in Figure 10, the first inlet 102a of the valve 102 is opened and the fluid is introduced by injection into the device 1, the piston of the syringe 100 allowing the fluid to be pushed into the device 1, the second inlet 102b of the valve is then closed and the outlet 102c is opened in order to let the fluid flow through the device 1.

Once all of the fluid to be analyzed has been injected through device 1, it is recovered in manifold 101, as shown in FIG. 11.

According to a second use illustrated in FIGS. 12 to 14, a reservoir 103 containing the fluid to be analyzed is connected to the fluid inlet port 11 of the device 1, and a syringe is connected to the fluid outlet port 12 of the device 1. 104 or any other piston element allowing the aspiration of the fluid, as illustrated in FIG. 12. A three-way valve 105 is positioned between the device 1 and the syringe 100, the syringe 100 being connected indirectly to the fluid inlet port 11 of the device 1. Initially and as illustrated in FIG. 12, the first inlet 105a of the valve 102, connected to the manifold 103 is closed, the second inlet 105b is open and connected to an air inlet, and the outlet 105c is also open and connected to fluid inlet port 11 of device 1.

Then, as visible in FIG. 13, the first inlet 105a of the valve 105 is opened and the fluid contained in the collector 103 is sucked up by the syringe 104 positioned downstream of the device 1, the second inlet 105b of the valve is then closed and outlet 105c is open to allow fluid to flow through device 1.

Once all of the fluid to be analyzed has been sucked up through the device 1, it is recovered in the syringe 104, as shown in FIG. 14. Of course, the syringes and reservoirs or collectors have a capacity adapted to the volume of fluid to be analyzed.

Whatever the use of the device described above, once the injection of the fluid is complete (FIGS. 11 and 14), it is advantageous to inject sterile air via the air inlet 110 to eliminate any stagnant water from the surface of the filtration unit 4 of the device 1.

Indeed, the presence of fluid, even in small quantities, on the surface of the filtration device could indeed lead to the diffusion of bacterial colonies, to false negative results or to certain difficulties in counting the colonies after the step of incubation. To this end, sterile air was drawn in by the syringe 100 or the reservoir 103 through the valve 102, 105, then injected inside the device 1, in order to dry the surface of the filtration member 4 .

The advantages of these uses are the fact that these techniques of use are simple, achievable without effort, in particular the first use, the workflow is of a total duration of less than 1 minute, no need for a laboratory infrastructure to carry out these manipulations, no need for skilled labor in microbiology, very good reproducibility of the operation.

Of course, the invention is not limited to the embodiments described and/or shown in the appended figures. Modifications remain possible, in particular from the point of view of the constitution of the various elements or by substitution of technical equivalents, without thereby departing from the scope of protection of the invention.

Claims (9)

Device for determining microorganism contamination of a fluid (1), said device (1) comprising:

• a box (2) comprising an internal volume delimited by at least one side wall (21) and a bottom (22),
• a lid (3) closing the box (2) and positioned facing the bottom (22),
• a fluid inlet port (11) arranged on the cover (3) and opening into the internal volume of said box (2), the fluid inlet port (11) extending along a substantially secant and preferably perpendicular axis to the lid (3),
• at least one filtration member (4), arranged in the internal volume,
• at least one nutrient layer (5) comprising a composition of a microbiological culture medium,

characterized in that the device (1) comprises a fluid outlet port (12) arranged on the box (2) and opening into the internal volume of the said box (2), and in that the cover (3) comprises a surface internal volume (31) in the internal volume extending radially around the fluid inlet port (11) as far as a peripheral edge of the cover (3), said internal surface (31) being inclined or curved and converging towards the fluid inlet (11), and in that the bottom (22) of the housing (2) comprises a surface (28) extending radially around the fluid outlet port (12) up to the side wall (21 ) of the housing (2), said surface (28) being inclined and converging towards the fluid outlet port (12). Device according to Claim 1, in which the inclination of the internal surface (31) of the cover (3) is strictly greater than +4°, the inclination of the internal surface (31) of the cover (3) is preferably between +5° and +15° and even more preferably equal to substantially 10°. Device according to any one of claims 1 or 2, in which the inclination of the surface (28) of the bottom (22) is strictly less than 0°, the inclination of the surface of the bottom is preferably between -5° and -10° and even more preferably between -6.5° and -7.5°. Device according to any one of Claims 1 to 3, in which the fluid inlet port (11) protrudes into the internal volume of the casing (2) with respect to the internal surface (31) of the cover (3). Device according to any one of Claims 1 to 4, in which the filtration member (4) is arranged in the box (2) at a determined distance h from the inlet port (11), the determined distance h being strictly greater than 1mm. Device according to any one of Claims 1 to 5, in which the casing (2) comprises a first circumferential bearing surface (23) shaped to cooperate in a complementary manner with a rim (33) of the cover (3). Device according to any one of Claims 1 to 6, in which the casing (2) comprises at least one second bearing surface (24), extending into the internal volume and shaped to receive a peripheral portion (41) of the filtration member (4), said second support surface (24) being shaped to cooperate with a portion (34) of the lid (3), so that the peripheral portion (41) of the filtration member ( 4) is pinched between the cover (3) and the box (2). Device according to any one of Claims 1 to 7, comprising a support grid (6), the bottom (22) of the box (2) comprises support blades (27) arranged radially with respect to the fluid outlet port ( 12), said blades (27) being configured to support the support grid (6) and guide fluid to the fluid outlet port (12). Assembly comprising at least one fluid supply, and at least one device (1) according to any one of the preceding claims, said device (1) being connected by its fluid inlet port (11) to a fluid supply.