WO2014102331A1

WO2014102331A1 - Impact of bacteria on interfaces between two immiscible fluids

Info

Publication number: WO2014102331A1
Application number: PCT/EP2013/078060
Authority: WO
Inventors: Michael Siegert; Patrick BOURIAT; Régis GRIMAUD; Laurent MARLIN; Danielle MOREL; Pierre SIVADON; Michel Magot
Original assignee: Total S.A.; Universite De Pau Et Des Pays De L'adour
Priority date: 2012-12-31
Filing date: 2013-12-27
Publication date: 2014-07-03
Also published as: FR3000411A1

Abstract

The invention proposes a containment chamber (10) for taking measurements relative to the impact of bacteria on interfaces between two immiscible fluids. The chamber comprises a receiving volume (12) suitable for containing a first fluid, a sealed needle insertion system (24) for sealingly inserting a needle into the chamber and forming a drop of a second fluid in the receiving volume, a transparent window (14) aligned with the receiving volume and suitable for observing an interface between the first fluid and the drop of the second fluid, and a system for controlling gas present in the chamber. The chamber can be used for improving the taking of measurements relative to the impact of bacteria on interfaces between two immiscible fluids.

Description

IMPACT OF BACTERIA ON INTERFACES BETWEEN TWO NON-MISCIBLE FLUIDS

The present invention relates to a confinement chamber for carrying out measurements relating to the impact of bacteria on interfaces between two immiscible fluids, a tensiometry device comprising the chamber, and a method for carrying out measurements relating to the impact of bacteria on interfaces between two fluids immiscible with the chamber.

Many bacteria are capable of interacting with interfaces between two immiscible liquids or adsorbing on such interfaces as, for example, water and hydrophobic organic compounds or HOCs (Hydrophobic Organic Compounds). ), for example hydrocarbons and lipids. In many cases, these bacteria use HOCs as a source of carbon and energy and develop a biofilm at the interface. This has been very often observed with hydrocarbon-degrading bacteria and it has been shown that HOC bio-films improve the accessibility of bacteria to these very poor substrates in water. Bio films or adsorption of cells have been observed on petroleum fuels, crude oil as well as on lipids such as triglycerides or cooking oil in a wide variety of environments such as seawater, fuel tanks, or oil pipelines. These biofilms are involved or suspected to be involved in natural processes such as the carbon cycle in ecosystems. They also play a beneficial or deleterious role in industrial activities such as agribusiness or oil production. Their study is therefore of great interest in terms of basic and applied research.

A critical step in the development of biofilms is the initial adsorption of cells at the interface. At this stage, the cells detect the interface, produce biosurfactants and / or polymers and begin the development of the biofilm. It is therefore useful to understand the events that occur at this stage. This can be achieved for example by using a dynamic drop tensiometer to monitor the alteration of the rheological properties of the interface during adsorption of the cells. To be relevant these measurements must be carried out under conditions compatible with the activity of the bacteria.

Tensiometry has been used only very rarely to study the impact of bacteria on oil-water interfaces. Two publications describe such experiences: • Kang ZW, Yeung A, Foght JM, Gray MR. Mechanical properties of hexadecane-water interfaces with adsorbed hydrophobic bacteria, Colloids and Surfaces B-Bio interfaces. 2008 Apr; 62 (2): 273-9; and

• Klein BBP. "Behavior of Marinobacter Hydrocarbonoclasticus SPI 7 Cells During Initiation of Biofilm Training at the Alkane-Water Interface",

Biotechnology & Bioengineering. 2010; 105 (3): 461-8.

However, these documents only concern aerobic bacteria. Moreover, existing commercial blood pressure monitors are not suitable for anaerobic bacteria.

The object of the present invention is to provide a means for performing measurements relating to the impact of bacteria on interfaces between two immiscible fluids, at least partially overcoming the aforementioned drawbacks.

To this end, the present invention provides a confinement chamber for carrying out measurements relating to the impact of bacteria on interfaces between two immiscible fluids. The confinement chamber comprises a receiving volume adapted to contain a first fluid, a hermetic needle introduction system for hermetically introducing a needle into the chamber and forming a drop of a second fluid in the receiving volume, a transparent window aligned with the receiving volume and adapted to observe an interface between the first fluid and the droplet of the second fluid, and a gas control system present in the chamber.

In preferred embodiments, the containment chamber comprises one or more of the following features:

The hermetic needle insertion system comprises a septum;

The chamber further comprises another septum for introducing another needle into the chamber and injecting the first fluid into the receiving volume;

The gas control system comprises a gas inlet and a gas outlet in fluid communication with the receiving volume;

The chamber further comprises another transparent window aligned with the reception volume and the transparent window adapted to observe an interface between the first fluid and the droplet of the second fluid, the other transparent window being adapted to the illumination of the taste of the second fluid during the observation;

The chamber further comprises a system for regulating the temperature within the reception volume; The chamber further comprises a box, a lid and a rubber seal between the lid and the box, the chamber further comprising locks adapted to keep the lid on the seal under pressure; and or

• the box is generally rectangular parallelepiped shape, side having a length less than 20 cm.

According to another aspect, the invention also proposes a tensiometry device comprising the confinement chamber described above and a needle inserted hermetically into the chamber and adapted to form the drop of second fluid in the receiving volume.

According to a preferred embodiment, the tensiometry device further comprises a system for observing the interface between the first fluid and the drop of the second fluid aligned with the transparent window and the reception volume.

According to another aspect, the invention also proposes a method for carrying out measurements relating to the impact of bacteria on interfaces between two immiscible fluids with the confinement chamber described above. The method comprises introducing a needle into the chamber by the hermetic needle insertion system; the evacuation of oxygen present in the chamber by the gas control system; injecting a solution of anaerobic bacteria into the receiving volume; forming a drop of oil in the receiving volume by the needle; and the observation of the interface between the solution of anaerobic bacteria and the drop of oil through the transparent window.

Other characteristics and advantages of the invention will appear on reading the following description of a preferred embodiment of the invention, given by way of example and with reference to the appended drawing.

Figures 1 and 2 show a diagram of an example of the confinement chamber.

FIG. 3 represents a diagram of an example of a tensiometer device.

Figure 4 shows an example of a method using the confinement chamber.

Figures 5-7 show examples of tensiometric measurements made with the confinement chamber.

According to the invention, there is provided a confinement chamber for carrying out measurements relating to the impact of bacteria on interfaces between two immiscible fluids. The chamber comprises a receiving volume adapted to contain a first fluid. The chamber also includes a hermetic needle insertion system for hermetically inserting a needle into the chamber and forming a drop of a second fluid in the receiving volume. The chamber also comprises a transparent window aligned with the receiving volume and adapted to observe an interface between the first fluid and the droplet of the second fluid. In addition, the room includes a gas control system present in the room. Such a chamber makes it possible to carry out measurements relating to the impact of bacteria on interfaces between two immiscible fluids improved.

The containment chamber is a chamber intended to confine (i.e. encapsulate) for example two immiscible fluids. Thus, the confinement chamber allows a certain control of the physico-chemical conditions to which the two fluids whose interface is being studied are subjected. The containment chamber is here provided / adapted for carrying out measurements, e.g. physico-chemical. The two immiscible fluids placed in the chamber will therefore be the subject of such measurements. In this case, these measures may include any measures relating to the impact of bacteria on interfaces between the two immiscible fluids. The two fluids being immiscible, interfaces are formed between the disjoint volumes of each of them. In the presence of bacteria, these interfaces may possibly exhibit a particular behavior, in any case that we may want to study through measurements. Thus, the confinement chamber is provided for a presence of bacteria within it.

The chamber includes a receiving volume adapted to contain a first fluid (e.g., an aqueous solution containing bacteria). The receiving volume can be defined by any container inside the chamber, such as a bowl, or possibly directly formed in one or more walls of the chamber itself.

The chamber also includes a hermetic needle insertion system for hermetically inserting a needle into the chamber and forming a drop of a second fluid in the receiving volume. The hermetic introduction system is adapted so that a needle can be introduced into the chamber, eg by and / or via the introduction system. The needle thus introduced may be a needle designed to form a drop of a second fluid (eg an oil, eg a hydrocarbon such as an alkane or oil) and have the dimensions and characteristics appropriate to this function. The hermetic introduction system allows the introduction of the needle so that the drop is formed in the receiving volume, and thus in the first fluid when the receiving volume actually contains the first fluid. The hermetic introduction system thus allows the formation of an interfluid interface in the chamber, between the first fluid and the second fluid (immiscible in the case envisaged where the first fluid is an aqueous solution containing bacteria and the second fluid is an oil, eg a hydrocarbon).

The chamber also comprises a transparent window aligned with the receiving volume and adapted to observe an interface between the first fluid and the droplet of the second fluid. In other words, on a wall of the chamber, a transparent window, e.g. glass or plastic, is arranged such that it allows observation of the aforementioned interface. The chamber thus makes it possible to carry out measurements on the interface, eg relating to the impact on the interface of bacteria possibly contained in the first fluid, which may be an aqueous solution containing such bacteria, via observation of the interface. through the transparent window, eg to the eye, the microscope, or a camera.

In addition, the needle insertion system for forming the droplet of the second fluid is hermetic. Also, the chamber includes a gas control system present in the chamber. Thanks to these elements, the chamber makes it possible to subject the inside of the chamber to any desired atmosphere, possibly anoxic (i.e. without oxygen). Indeed, the introduction system allows a "hermetic" introduction of the needle, in that when the needle is introduced, the air surrounding the chamber does not penetrate (or penetrates only in a manner at least relatively limited ) in the bedroom. The gas control system makes it possible to evacuate the gas present in the chamber and to replace it with any desired gas. This allows for example to evacuate the oxygen inside the chamber.

Thus, the chamber makes it possible to carry out measurements relating to the impact of bacteria on interfaces between two immiscible fluids under a controlled atmosphere. Measurements can therefore be better adapted to real conditions, depending on the type of bacteria under study. The chamber may for example be used for any measurement of tensiometry requiring a controlled atmosphere, in particular anoxic atmosphere. Therefore, the confinement chamber makes it possible, for example, to measure the alteration of the interfacial properties (e.g. interfacial tension and / or interfacial viscoelasticity) between two immiscible fluids / liquids under conditions compatible with the activity and growth of the anaerobic bacteria. Also, the chamber is versatile in that it is usable for any type of bacteria.

Such measures may be particularly useful in a study of the operating conditions of a hydrocarbon reservoir. The chamber can therefore be used in a process comprising a study including such measurements. at least on interfaces between an oil taken from a hydrocarbon reservoir and an aqueous solution containing a bacterial strain, eg anaerobic, also taken from the reservoir. Such a process can be followed by an effective production of the hydrocarbons present in the reservoir.

An example of the confinement chamber will now be described with reference to FIGS. 1 and 2, which show a diagram of the same example of containment chamber 10, FIG. 2 having an open view allowing to see the inside of chamber 10 of The example. The containment chamber 10 is particularly simple to implement, and allows use to perform measurements with measuring devices, e.g. drop tensiometer, already existing.

The chamber 10 comprises a bowl 12 forming the receiving volume adapted to contain a first fluid. The bowl 12 is, in the example, transparent. The bowl 12 may be glass. This allows the observation of the bowl 12 by the transparent window 14 aligned with the bowl 12. The transparent window 14 is thus adapted to the observation of an interface between the first fluid and a drop of a second fluid. In effect, the chamber 10 also comprises, on its upper wall, a hermetic needle introduction system 24 for hermetically inserting a needle into the chamber and forming the droplet of the second fluid in the bowl 12. hermetic introduction 24 comprises a septum 27, which can be removable and / or, as in the example, occupy the location of an orifice 25 made on the upper wall of the chamber 10. The septum 27 comprises a wall of a material which tends to regain its shape when it is deformed, eg rubber. The septum 27, which is in the example offset on the diagonal above the bowl 12, thus allows, in a simple and inexpensive way, that a needle (eg curved) is introduced into the septum 27 and thus leads into the bowl 12, to form a drop (eg rising) of the second fluid (eg oily, so less dense), all so that the chamber remains (eg almost) hermetic thereafter.

In addition, the chamber 10 includes the gas control system present in the chamber. The gas control system of the example includes a gas inlet 30 on a side wall and a gas outlet (not shown because on the opposite wall in the example). The gas inlet 30 and the gas outlet are in fluid communication with the interior of the chamber 10, including the bowl 12. The gas inlet 30 may be connected to a gas cylinder (generally a CO mixture). ₂ / N ₂ for anaerobic bacteria) equipped with a pressure regulator. The gas outlet can be connected to a pipe allowing the evacuation of gas and preventing air from entering bedroom. The gas control system of the example is simple, but any other system for controlling gas in the chamber 10 can be implemented.

The chamber 10 further comprises another hermetic needle insertion system for injecting the first fluid into the receiving volume, here the cup 12. This other introduction system here comprises the septum 22. The septum 22 is provided to introduce another needle into the chamber 10 and inject the first fluid in the bowl 12. The septum 22, which is in the example aligned vertically above the bowl 12, allows an injection of the first fluid after having carried out the control of the atmosphere in the chamber 10. This makes it possible to adapt the atmosphere of the chamber 10 to the first fluid. For example, if the first fluid is an aqueous solution containing an anaerobic bacterial suspension, this makes it possible to return the atmosphere of the anoxic chamber before injection of the first fluid. Alternatively, the injection of the first fluid could be done by the septum 27, for example if it is wide enough. But having a separate septum 22 dissociates the needle for injecting the first fluid and the needle used to form the second fluid drop, which facilitates the preparation of the experimental conditions.

The chamber 10 further comprises another transparent window (not shown) aligned with the bowl 12 and the transparent window 14. The other window may be similar to the window 14 in terms of material and dimensions. In the example, the other window is on the side wall of the chamber 10 opposite the front wall (i.e. the wall carrying the window 14). The other transparent window is adapted to illuminate the taste of the second fluid during observation through the window 14. Thus, the interfluidic interface is more visible and observation is facilitated.

The chamber 10, in this example, further comprises a system for regulating the temperature within the reception volume. The temperature control system makes it possible to better adapt the conditions prevailing in the chamber to the actual conditions to which the bacteria used for a given study are subjected. The regulation of the temperature also makes it possible to carry out measurements of tensiometry more easily interpretable, because with controlled temperature. The temperature control system includes the base 32 of the chamber 10 which may be a brass temperature control block. A water inlet 34 and a water outlet 36 (which may optionally play the role of each other) ensure a circulation of water through the control unit 32 to control the temperature of the chamber 10. The inlet 34 and outlet 36 of water may for example be connected to a circulation circulating water bath. The temperature control system also includes the bowl support 38, eg metal to promote heat exchange. As can be seen in the figure, the chamber 10 comprises a box 40 covered with a lid 42. The box 40 comprises the brass base 32, the inlet 34 and the water outlet 36, the gas inlet and outlet 30, the window 14 and the other window (opposite the window 14). The cover 42 comprises the septa 22 and 24. The side walls of the box 40 and / or the cover 42 may be of polyvinyl chloride (PVC). The box 40 and its lid 42 can thus form an enclosure containing inside the bowl 12 (and its support 38). The box 40 (or the enclosure formed with the lid) is generally rectangular parallelepipedal shape, and may be of side (s) having a length of less than 20 cm, preferably less than 15 cm, and / or greater than 5 cm for example equal to about 10 cm. Thus, the chamber 10 may be used with conventional size tensiometers, as will be described later.

In the figures, it can be seen that the chamber 10 also comprises a seal 44 between the cover 42 and (the upper edge of) the box 40. The chamber 10 also comprises a seal of the same type between the block 32 and (the lower edge of ) The box 40. The seal 44 is (at least relatively) hermetic, so as to allow the envisaged gas control. The seal 44 may for example be silicone, or rubber. The chamber 10 may then comprise locks 46 adapted to keep the lid 42 under pressure on the seal 44, and thereby to achieve a hermetic and pressurized closure between the lid 42 and the box 40. For a simple implementation, it is possible to use locks in two parts with a hook eg on the cover 42 and a ring eg on the box 40 cooperating with the hook in the closed position, eg latches type "latches". The chamber 10 of the example comprises four locks 46 of this kind, on each side of the box 40, two of them being represented in the figures.

The confinement chamber, for example the chamber 10 of FIGS. 1 and 2, may advantageously be integrated with an otherwise conventional tensiometric device (or tensiometer). A tensiometer device is a device for performing interfacial tension measurements between two immiscible fluids, as described in the Kang et al. and Klein previously mentioned.

An example of such a tensiometer device will now be described with reference to FIG.

The tensiometer device 50 of FIG. 3 comprises the chamber 10 of FIGS. 1 and 2 and a curved needle 52 inserted hermetically (when the tensiometer device is in use) into the chamber 10 and adapted to form the second droplet. fluid in the receiving volume. In the case of 10, the needle is introduced into the septum 27 and opens into the bowl 12.

Such a tensiometer device is typically used by placing an aqueous solution containing bacteria in the receiving volume, the bowl 12 when it is about the chamber 10, the injection being made through the septum 22. a drop of hydrocarbon at the end of the bent needle, connected to a syringe and opening into the bowl 12 to form a water / oil interface. The observation of the deformation of the drop of hydrocarbons by the window (e.g. the window 14) makes it possible to obtain values of interfacial tensions.

The oil being less dense than water, and in the example of Figures 1 and 2 where the box 40 is provided to be arranged vertically on its base 32, and where the cover 42 and the septum 22 are above of the bowl 12, the needle can be bent upwards at its end, so as to form a U (or a hook). This makes the device more suitable for the intended use.

It is also possible to oscillate the drop by operating the syringe and measure the interfacial voltage variation that results from these oscillations to determine the interfacial elastic modulus and its phase angle.

Such a tensiometer device also makes it possible to perform contact angle measurements. For example, the device may include a flat blade within the chamber 10 disposed (potentially) just above the end of the needle curving upwardly. The device may then comprise a vertical displacement system of the needle, so as to approach as much as necessary the drop in contact with the blade. This then makes it possible to observe the angle of contact between the drop and the blade, and to measure it.

The observation can be done automatically through an observation system of the interface between the first fluid and the drop of the second fluid which is aligned with the transparent window and the reception volume. The observation system can be a camera recording the images of the oil drop that is deformed. Further, in the example of the chamber 10, the tensiometer device may include (or be used with) a lighting system aligned with the transparent window 14, the area of the bowl 12 where the drop is formed, and the other window. The lighting system is "behind" the chamber 10 with reference to Figures 1 and 2.

A method for performing measurements relating to the impact of bacteria on interfaces between two immiscible fluids with the confinement chamber, for example the chamber 10 of FIGS. 1 and 2, will now be described with reference to FIG. 4. The method includes a first phase of installation of the experimental equipment.

The first phase involves the introduction of a needle into the chamber by the hermetic needle insertion system. In the case of the aforementioned examples, when the needle is bent at its end, the needle can be introduced by hooking it by its curved end into the removable septum 27 which is subsequently housed in the hole 25 of the lid . The method may then include connecting the needle to a syringe containing the second fluid, e.g., an oil. The method may then comprise sealing the lid 42 on the box 40 with the locks 46.

The first phase of the process then comprises the evacuation S20 of oxygen present in the chamber by the gas control system, thus rendering the atmosphere of the chamber anoxic. This allows then to inject S30 a solution of anaerobic bacteria into the receiving volume, without risk for bacteria. It is also possible to control the temperature of the chamber, for example with a control system as described above, for example in the case of the chamber 10 by circulating water at an appropriate temperature between the inlet 34 and the exit 36.

The method then comprises a second phase of experimentation itself.

The second phase comprises the formation S40 of a drop of oil in the receiving volume by the needle. It is thus possible to "oscillate" a drop of oil as described above. Finally, the interface between the solution of anaerobic bacteria and the drop of oil by the transparent window is observed. This observation can be done by a camera as mentioned above and can lead to measurements of interfacial tension and elasticity or to measurements of angles of contact with a blade. The chamber may further be placed on an adjustable tilt and / or height support so that the windows are aligned with a camera-lamp axis of the monitor. Example:

The chamber 10 of FIGS. 1 and 2 has been used successfully in the process of FIG. 3 to make measurements relating to the impact of different anaerobic bacteria on hexadecane-water interfaces. A water containing a strain of different anaerobic bacteria was injected S30 in the bowl 12, then a drop of hexadecane was formed S40 in the injected water and observed S50 by a camera which filmed the behavior of gout. Conventional interfacial tension (IFT) and elasticity measurements were then conventionally derived.

Figures 5-7 show results obtained. These figures represent the interfacial tension as a function of time respectively for the strain 6273 taken from a reservoir in the Congo and at 52 ° C., the Termotaga strain elfïi at 60 ° C., and the strain Clostridum acetobutylicum at 37 ° C.

Overall, it was thus possible to demonstrate a decrease in interfacial tension at the water-hexadecane interface in the presence of the strains tested. The rate of modification of the interfacial properties is the main difference between the bacterial strains tested during this experiment. It therefore seems that the ability to lower the interfacial tension (IFT) would be shared by many strains. It is important to note that the FTI reductions measured here were not large enough to have an impact on oil mobilization without the intervention of other factors. However, they do highlight an interaction of bacteria with the interface.

Claims

A containment chamber (10) for performing measurements relating to the impact of bacteria on interfaces between two immiscible fluids, comprising:

A reception volume (12) adapted to contain a first fluid,

A needle insertion system (24) for hermetically inserting a needle into the chamber and forming a drop of a second fluid in the receiving volume;

A transparent window (14) aligned with the reception volume and adapted to observe an interface between the first fluid and the droplet of the second fluid, and

• a gas control system in the room.

The chamber of claim 1, wherein the hermetic needle insertion system comprises a septum (22).

The chamber of claim 2, further comprising another septum (20) for introducing another needle into the chamber and injecting the first fluid into the receiving volume.

4. Chamber according to one of claims 1 to 3, wherein the gas control system comprises a gas inlet (30) and a gas outlet in fluid communication with the receiving volume.

5. Chamber according to one of claims 1 to 4, further comprising another transparent window aligned with the receiving volume and the transparent window adapted to the observation of an interface between the first fluid and the drop of the second fluid, the other transparent window being adapted to illuminate the taste of the second fluid during the observation.

6. Chamber according to one of claims 1 to 5, further comprising a temperature control system (34,36, 32, 38) within the receiving volume.

7. Chamber according to one of claims 1 to 6, comprising a box (40), a cover (42) and a rubber seal (44) between the lid and the box, the chamber further comprising locks adapted to pressurize the lid on the seal.

8. Chamber according to claim 7, wherein the box is of rectangular parallelepiped general shape, side having a length less than 20 cm.

9. Tensiometry device comprising:

The chamber according to one of claims 1 to 8; and

A needle inserted hermetically into the chamber and adapted to form the drop of second fluid in the receiving volume.

The tensiometric device of claim 9, further comprising a system for observing the interface between the first fluid and the drop of the second fluid aligned with the transparent window and the receiving volume.

A method of performing measurements relating to the impact of bacteria on interfaces between two immiscible fluids with a chamber according to any one of claims 1 to 8, comprising:

• introducing (S 10) a needle into the chamber by the hermetic needle insertion system;

• the evacuation (S20) of oxygen present in the chamber by the gas control system;

• the injection (S30) of a solution of anaerobic bacteria into the receiving volume;

• the formation (S40) of a drop of oil in the reception volume by the needle; and

• observation (S50) of the interface between the solution of anaerobic bacteria and the drop of oil through the transparent window.