BE1019588A5 - CONTAINER SYSTEM FOR DIP GROWTH REGIME. - Google Patents

Abstract

The present invention relates to an immersion growth system (28) as well as an incubator (28) containing such growth system (28) and a method for growing plant material in vitro. The immersion growth system (28) comprises two corresponding containers, namely a growth container (1) and a medium container (2), both containers being provided with connecting means (7,8,13) for mutually coupling the medium container (2) to the growth container (1), characterized in that the growth container (1) is suitable to be placed on top of the medium container (2) and the connecting means (7,8,13) are provided at a front side of the two containers.

Description

CONTAINER SYSTEM FOR DIP GROWTH REGIME Technical field

The present invention relates to an immersion growth system and method for the in vitro culture of biological material, more particularly plant cells, tissues, organs and embryos, seedlings or plants.

State of the art

Temporary immersion systems for in vitro vegetable culture have been described and classified into 4 categories according to their operation: by means of tilting and shaking machines; a complete immersion of the plant material and renewal of the nutrient medium; partial immersion with renewal of liquid nutrient medium; complete immersion by pneumatically driven transfer of liquid medium and without renewal of the nutrient medium. The positive effects of temporary immersion on plant in vitro culture have been demonstrated for proliferation of shoots and microcuttings, microtuberization and somatic embryogenesis. Immersion time, in particular the duration or frequency, is the most determining parameter for system efficiency. Optimizing the volume of the culture medium and the volume of the culture container also considerably improves the effectiveness, in particular for the proliferation of young shoots. Temporary immersion in general also improves the quality of plant material (Etienne and Berthouly, 2002).

FR 2 730 743 describes a container for in vitro culture using temporary immersion under sterile conditions in a housing closed with a lid and provided with a tray for plant tissue and a lower part provided for nutrient medium at the top. An inlet in the lid makes it possible to exert a positive pressure in a bell-shaped chamber in the lower part, whereby nutrient medium is pushed upwards from the lower part, via a tube connected thereto, to the upper part to the culture is submerged. The excess pressure is released by means of a valve to keep the pressure in balance during the rest periods.

MXPA04003837 discloses an invention relating to a system and method for the in vitro culture of biological material, more particularly plant cells, tissues, organs and embryos, seedlings or plants of vegetable crops. The system is integrated with a bioreactor suitable for the in vitro culture of biological material and a device for providing an up and down movement in the bioreactor. The bioreactor is formed by a chamber with at least two containers and a coupling element, the latter element being located on the platform of an apparatus suitable for providing a programmable up, down and cyclic movement of the bioreactor. The biological material and the liquid growth medium are stored in the containers, which are made of a light-transmitting material. The coupling element forms a part which is suitable for securing the containers between them, and which is placed axially on both sides of each container. The coupling part still contains a round flat piece, provided with grooves and openings suitable for improving the flow and without any limitation for liquids or gases, and furthermore contains a plurality of gas and liquid exits to which filters can be attached. The volume of the bioreactor can be increased by adding one or more of hollow profiles that are inserted between them or to the container through the coupling member. The bioreactor produces immersion and aeration cycles in the biological material due to the upward and downward movement caused by a device that generates a flow of fluid from a first container to a second container under the influence of gravity, while the plants remain present in a of the containers. In addition, the bioreactor allows temporary immersion to be grown during all phases of the in vitro culture: induction, multiplication, growth and adaptation.

The Twin Flask system (®BIT), contains two separate bottles arranged side by side, one for the growing medium and one for plant material, made of glass or plastic, connected to each other by silicone hoses, whereby by applying overpressure the growing medium alternates from one is brought to the other bottle (Escalona et al., 1998).

The existing systems have some disadvantages, for example, in most systems round-shaped containers (cups, bottles, ...) are used for the storage of the (plant) material. Due to rounding, present in such containers, the maximum volume to be used is not optimally used for the culture to be grown. In the systems where the containers for (plant) material and growing medium are located in one container, the pressure cannot be regulated separately in both containers. In the systems where two separate containers are provided for (plant) material and growing medium, many hoses are present, which limits the arrangement of such systems and furthermore this leads to an increased risk of contamination. In these systems, the ratio of the occupied area of the total setup to the usable area for the culture to be grown is suboptimal. Furthermore, the current systems are labor-intensive in their arrangement and use.

The present invention solves the above problems whereby on the one hand a maximum of culture is obtained per unit area and on the other hand the pressure-dependent parameters can nevertheless be optimized in each container separately, resulting in an improved culture quality. The lower labor required for the set-up and the ease of use of the immersion growth system are two more advantages in themselves and moreover result in a lower user cost.

Summary

In a first aspect, the present invention relates to an immersion growth system comprising two corresponding containers, in particular a growth container suitable for containing plant material, and a medium container suitable for containing growth medium, wherein both containers are provided with connecting means for mutually coupling the medium container to the growth container, characterized in that the growth container is suitable for being placed on top of the medium container and wherein the connecting means are provided on a front side of the two containers.

An advantage of placing the growth container on the medium container according to the present invention is an optimum ratio of the occupied soil surface of the total immersion growth system according to the present invention to the area available for the culture to be grown in the growth container.

Another advantage of the arrangement according to the present invention is the optimum incidence of light in the growth container because it is always at the top of the arrangement and is preferably made of light-transmitting material and thus captures all light from the light source that is arranged above the system. The incidence of light is also not impeded by the presence of connections or closable openings in the top of the growing container.

Furthermore, the present invention offers the advantage that each container is separately accessible and the pressure can be regulated separately for each container. For example, if the growth medium needs to be supplemented, this can be done without disturbing the culture from the growth container.

In a further aspect the invention relates to containers suitable for use in the immersion growth system described herein. These containers are characterized, inter alia, by the proportions of their dimensions in which the containers are wider than high and also deeper than high. The containers are beam-shaped.

In another aspect, the invention relates to an incubator, comprising a spatial repetition of immersion growth system according to the present invention.

An advantage of the incubator described herein is the optimized spatial efficiency in that on the one hand all connections to the containers are on the same front side and on the other hand because the containers are beam-shaped, which minimizes the loss of space between the different growth systems. The incubator, as described in the present invention, also leads to a reduced labor intensity due to the simplified arrangement and the increased ease of use.

The present invention also relates to a method for culturing cultures using the immersion growth system described herein or the incubator described herein.

Description of the figures

The following figures show preferred embodiments of the invention.

Figure 1 is a perspective view of a preferred form of the invention and contains the following elements: a growth container 1, placed on top of a medium container 2, both of which are connected to each other by means of a medium connecting element 13 connected to the medium connections 7 and 8 on the front of the respective containers 1 and 2. Furthermore, both containers on the front side containing the medium connections each have a closable supply opening, namely 3 and 4 respectively on the containers 1 and 2. The same front side of each container 1 and 2 on which the medium connector and the furthermore, there are furthermore a pressure connection, respectively 5 on the growth container and 6 on the medium container. These pressure connection means make it possible to transport air into or out of the container via the air hoses 12 and 12 'which furthermore comprise an air filter 11 and 11'. The medium container also has an injection point 9 on the same side as the medium connection 8. A handle 10 may also be attached to a bottom side of the medium container. The top side of the medium container has a slope 19.

Figure 2 illustrates the bottom view of a growth container according to the present invention in which the stability provisions 14 and 16 are present.

Figure 3 shows the side view of a growth container according to the present invention in which the stability provisions 14 and 16 are present in the bottom.

Figure 4 shows the side view of a medium container according to the present invention with the stability provision 15 visible on the top and the support system 10 in the lower part of the medium container.

Figure 5 illustrates the top view of a medium container according to the present invention with the stability provisions 15 and 17 visible on the top.

Figure 6 shows an oblique view of an incubator according to the present invention, in which elements 18 according to the present invention are placed in a rack 19, in which a light source is provided per shelf and in which further two pressure nets 22 and 23 are present, each containing all medium containers and connect growth containers to a pressure variation device, represented as the set of 24 (electronically controlled pressure valves) + 25 (vacuum pump) + 26 (compressor) that can be controlled with a computer-controlled system 27. An element 18 contains two immersion growth systems placed against each other with the rear sides together.

Detailed description

The present invention relates to an immersion growth system comprising two corresponding containers, in particular a growth container suitable for containing plant material, and a medium container suitable for containing growth medium, wherein both containers are provided with connecting means for mutually coupling the medium container on the growth container, characterized in that the growth container is suitable for being placed on top of the medium container and wherein the connecting means are provided on a front side of the two containers.

As described herein, "immersion growth system" refers to a system for culturing cultures by immersing the aforementioned cultures with a growth medium. The immersion is preferably temporary. In such systems, the advantages of a liquid growth medium are combined with the advantage of aeration of the culture.

As described herein, "connecting means" refers to the entirety of medium connections and medium connection elements that make it possible to transport a medium, for example a liquid, from one container to another container.

In one embodiment of the present invention, the fluid connections are preferably hollow tubular elements located on a front of the respective containers with the longitudinal direction of such tubular elements transverse to the aforementioned front of the containers. The medium connections have an opening in the front of the container and an opening at the opposite end of the medium connection. A medium connecting element can be connected to these medium connections. The medium connection is preferably integrated in the container housing. In a preferred form of the invention, these medium connecting elements are flexible tubes made of plastic and more preferably of silicone. The flexible tubes according to a preferred embodiment of the invention have an inner diameter between 3 mm and 10 mm, more preferably between 5 mm and 8 mm. In a preferred form according to the invention, the flexible tubes have an outer diameter between 6 mm and 12 mm, more preferably between 8 mm and 10 mm.

The medium connections make it possible to transport medium from one container to another container with both containers arranged one above the other. In such an arrangement, one container is preferably a growth container and the other container is a medium container. Most preferably in an arrangement the upper container is a growth container and the lower container is a medium container and both are connected by means of a medium connection element connected to the medium connection of both containers. The preferred embodiment according to the invention contains no hoses or tubes within the containers. This keeps the risk of contamination low.

"Lockable supply opening" is understood to mean an opening in the front of a container that is suitable for placing or removing material in / from the relevant containers, which can be closed by means of a multiple-use closure. In a preferred embodiment the seal is a cap, more preferably a screw cap, most preferably the seal is a screw cap with an inner ring made of silicone. The silicone inner ring ensures a good seal of the containers. A closable supply opening is suitable for transporting both solid and liquid matter. The closable supply opening according to the invention is preferably suitable for transporting plant material and growing medium through or into a container.

As described herein, the term "pressure connection means" refers to the entirety of pressure connections that make it possible to transport a gas mixture under a certain pressure into / from a container, which are further connected to a pressure variation means by means of pressure connection elements.

In an embodiment of the present invention, the pressure connections are preferably hollow tubular elements located on a front of the containers with the longitudinal direction of such tubular elements transverse to the aforementioned front of the containers. The pressure connections have an opening in the front of the container and an opening at the opposite end of the pressure connection. A pressure connection element can be connected to these pressure connections. The pressure connection is preferably integrated in the container housing. In a preferred form of the invention, these pressure connecting elements are hollow tubes, preferably flexible hollow tubes made of plastic and more preferably of silicone. The flexible hollow tubes according to a preferred embodiment of the invention have an inner diameter between 3 mm and 10 mm, more preferably between 5 mm and 8 mm. In a preferred form according to the invention, the flexible hollow tubes have an outer diameter between 6 mm and 12 mm, more preferably between 8 mm and 10 mm. A pressure connection element is further suitable for containing an air filter which is arranged such that the gas mixture that flows through the pressure connection elements is filtered by the air filter in question. The air filter according to the present invention is further characterized by the size of the pores that is between 0.1 µm and 0.45 µm, more preferably between 0.15 µm and 0.3 µm. The air filters are preferably hydrophobic. These filters offer the advantage that the gas mixture that is transferred into the containers is sterilized. The pressure connection means according to the invention are suitable for controlling the pressure of the container to which they are connected. Preferably, the pressure in each container can be controlled separately via the pressure connection means connected to the relevant container. Most preferably, the pressure in each container can be controlled separately via the pressure connection means which are connected to the relevant container and which are connected to a pressure variation device.

"Pressure variation device" means a means to generate a pressure, such as a pump. In an embodiment of the invention, the pressure variation means is an adjustable pressure pump. In another embodiment, this is a vacuum pump. The pressure generated in a pressure variation device can be transferred via a line to a sealed container, preferably to a container. In an embodiment according to the invention, the pressure variation device can generate a positive or a negative pressure (vacuum). Preferably, the pressure is transferred by means of the pressure connecting elements described herein. Most preferably, the pressure generated in the pressure variation device is transferred by means of pressure connecting elements so that this generated pressure is also present in the containers connected to these pressure connecting elements.

By "growth medium" is meant a medium that is preferably liquid and that contains nutrients suitable for absorption by the culture and which are essential for the growth of the culture. The advantage of liquid medium is that the composition in the liquid is much more uniform than in a solid medium. In addition, a liquid medium can also be moved more easily in the system than a solid medium. An additional advantage of liquid medium is that it ensures better nutrient uptake in the plant material and, moreover, is economically more advantageous than solid growth medium. Liquid growth medium suitable for use in the present invention includes Murashige and Skoog (MS) growth medium, without being limited thereto.

"Culture" means any material that is suitable to be grown by temporary immersion. Non-limiting examples are: potato, sugar cane, banana, orchid, eucalyptus, spatiphyllum sp., Pineapple, and paulownia sp.

As described herein, "container" refers to a container that is preferably made from a transparent plastic polymer that is capable of withstanding autoclave sterilization conditions. More preferably, the container is made from polycarbonate (PC). In an embodiment according to the present invention, the container has a rectangular shape, preferably beam-shaped, the container comprising six sides namely, a front side, a rear side, a left side, a right side, a top side and a bottom side. Furthermore, the dimensions of a container in an embodiment according to the present invention have the following properties: the height of the container is smaller than the depth of the container, preferably in a ratio of height of the container to the depth of the container included between 1 : 2.30 and 1: 1.65; the height of the container is smaller than the width of the container, preferably in a ratio of the height of the container to the width of the container comprised between 1: 1.75 and 1: 1.25; and - the width of the container is smaller than the depth of the container, preferably in a ratio of the width of the container to the depth of the container included between 1: 1.36 and 1: 1.30.

An embodiment of a growth container according to the present invention is a container that is preferably made of a transparent plastic polymer that is capable of withstanding the conditions of autoclave sterilization. More preferably, a growth container is made from polycarbonate (PC). In another preferred embodiment, the growth container is made from a material on which can be written or printed. The preferred embodiment of a growing container according to the present invention has a rounded upper side, most preferably the upper side of the growing container is made of a light-transmitting material and viewed convex from outside the container. This means that the top side protrudes outwards, seen from inside the container. This has the advantages that on the one hand the incidence of light is optimized in the growth container and on the other hand that the accumulation of water vapor on the upper side is prevented. In an embodiment according to the invention, the top side is free of connectors and / or openings. Another embodiment of a growth container comprises a flat top. The preferred embodiment of a growth container according to the invention comprises a closable supply opening with a sufficiently large diameter for a hand to pass through. This makes the cultural material more accessible, which results in increased ease of use. Preferably, the closable supply opening is provided with a protruding neck on a front side of the growth container, whereby the closable supply opening protrudes more forward than the container, which makes the contents of the growth container arranged in an incubator more accessible. Furthermore, the preferred embodiment of a growth container comprises a medium connection means for growth medium and a pressure connection means, which are located on the same front side as the closable supply opening. In one embodiment of a growth container, the surface of the underside of the growth container is similar to the surface of the top of a medium container. This means that both surfaces have the same dimensions and the same shape so that both containers are suitable to be placed on top of each other. In a preferred embodiment, the growth container has a bottom side whose surface is similar to the surface of the top of the medium container on which the growth container is positioned. Furthermore, this embodiment of a growth container is characterized by the presence of stability provisions in the bottom. These stability provisions are a combination of indentations and protrusions from the bottom or top of a container. Furthermore, these stability provisions are suitable for hooking in to corresponding stability provisions on the top or bottom of another container. Preferably, one container is a growth container and the other container is a medium container. Most preferably, the container that contains the stability features on the bottom is a growth container and the container that contains the stability features on the top is a medium container. In an embodiment of the invention, a growth container comprises four stability provisions on the underside. Two stability provisions are protrusions of the surface from the bottom and two stability provisions are protrusions from the surface of the bottom. In other embodiments, a container contains 5, 6, 7, 8, 9, 10 or more stability provisions. Preferably, the indentations in the underside lie on one line parallel to the front or rear side of the growing container and the protrusions lie on another line parallel to the front or rear side of the growing container. Most preferably, a line with protrusions is closest to the front (16) of the growing container and a line with protrusions (14) is closest to the rear of the growing container. The position of the recesses on the underside of the growth container prevents growth medium from being stacked in the container during removal of growth medium from the growth container.

The growth container according to a preferred embodiment of the invention is further characterized in that the longitudinal direction of the medium connection present on the front forms an angle with the underside of the growth container in the sense that the connection of the medium connection to the growth container is higher than the end of the medium connection to which the medium connection element can be connected.

The growing container according to a preferred embodiment of the invention is further characterized in that the ratio of the area of the underside of the growing container to the height of the growing container is comprised between 20 cm2 / cm height and 40 cm2 / cm height.

An embodiment of a medium container according to the present invention is a container that is preferably made from a transparent plastic polymer that is capable of withstanding the conditions of autoclave sterilization. More preferably, the container is made from polycarbonate (PC). Preferably, the top and bottom of the medium container are not parallel. More preferably, the top of the medium container is inclined towards the front of the medium container with an inclination between 2.5 ° and 5.0 °. Most preferably the slope of the top side is 3.1 °. This has the advantage that the underside of a growth container, placed on top of such a medium container, has the same inclination. This ensures that the front side of such a growth container is lower in light than the rear side of the same growth container. In the preferred embodiment of the growth container, characterized in that the medium connection present on the front forms an angle with the underside of the growth container as described herein, this slope offers the advantage that the growth medium contained in the growth container only acts as a result of gravity can be removed from the growing container and flows back to the medium container. The preferred embodiment of a medium container contains stability provisions in the upper side which are suitable to be connected to the corresponding stability provisions of a growth container. These stability provisions are a combination of indentations and protrusions from the bottom or top of a container. Furthermore, these stability provisions are suitable for hooking in to corresponding stability provisions on the top or bottom of another container. Preferably, one container is a growth container and the other container is a medium container. Most preferably, the container that contains the stability features on the bottom is a growth container and the container that contains the stability features on the top is a medium container.

The connection between corresponding stability provisions occurs because a protrusion from one container intervenes in the corresponding protrusion from another container. In one embodiment, a protrusion is a block of material made from an anti-slip material such as rubber or soft plastic that is attached to an upper or lower side of a container. In a preferred embodiment of the invention, a protrusion is a local elevation to the outside of the container of the material from which the bottom or top of a container is made. This local elevation can be shaped differently and includes, without being limiting, a circular shape, a drop shape, an ellipse shape, a square, a rectangle, or a polygon. By "indentation" is meant a local elevation of the material from the top or bottom of a container, provided that the material is elevated to the inside of the container. In an embodiment according to the invention, an indentation can be given a different shape and comprises the following shapes without being limiting: a circular shape, a drop shape, an ellipse shape, a square, a rectangle or a polygon.

In a preferred embodiment of an immersion growth system, the indentations and protrusions of the underside of the growth container and the top of the medium container correspond. This means that the protrusions from the underside of the growth container have the same shape as the protrusions from the top of the medium container on which the growth container is located. Furthermore, the indentations and protrusions are dimensioned so that they fit together. The indentations and protrusions are positioned such that an indentation is always placed above or below a protrusion in the corresponding side of the other container and vice versa. This preferred embodiment has the advantage that the containers that are placed on top of each other are stable and that the upper container does not slip off the lower one. Preferably, the underside of the growing container has bulges close to the rear and bulges closest to the front. This has the advantage that, if such a growth container is arranged in an immersion growth regime according to the present invention, the growth medium can optimally flow back to the medium container under the influence of gravity during the drainage phase (see further).

An embodiment of a medium container according to the present invention further comprises an injection point, which is provided on a front side, suitable for transporting growth medium and / or chemicals from and to the medium container without thereby inducing an increased risk of contamination in the system. "Injection point" is understood to mean an opening that can be closed and that is suitable for exchanging growth medium and / or chemicals in the medium container while the immersion growth system is in operation.

An embodiment of a medium container according to the present invention further comprises a carrying system. By "carrier system" is meant a system that makes it possible to easily receive a medium container disposed in an immersion growth system and to move the entire immersion growth system. A possible embodiment according to the invention is a handle placed on the left and right side of the medium container. In the preferred embodiment according to the present invention, the support system consists of 2 notches. A notch is located on the rib located in the bottom, which connects the left side with the bottom of the medium container. The second notch is located on the rib located in the bottom, which connects the right side with the bottom of the medium container. Both notches allow fingers to interfere with the notches and thus lift the medium container and thus the entire immersion growth system. The notches are preferably centered around the center of the rib connecting a left or right side to the bottom. This embodiment has the advantage that the left and right sides are free and that 2 medium containers can be placed laterally against each other with a left side against a right side without loss of space.

In the present invention, temporary immersion is achieved by moving the growth medium from the medium container to the growth container via the connecting means. As a result, the culture in the growth container is immersed by the supplied growth medium. The displacement of the growth medium from the medium container to the growth container preferably takes place under the influence of an external force. More preferably, the displacement of growth medium is driven by pressure. Most preferably, the displacement of growth medium is driven by an external pressure that is generated in a pressure variation device connected to the medium container by the pressure connection means. Once the immersion phase has ended, the growth medium can be removed from the growth container. For this purpose, the pressure generated in the medium container is released, so that the ambient air pressure prevails in the growth container and the growth medium flows out of the growth container under the influence of gravity and ends up in the medium container via the connecting means. This is possible due to the sloping top surface of the preferred embodiment of a medium container in combination with the medium connection present on the front side of the growing container that forms an angle with the underside of that growing container. This means that no extra energy is required during the rest period, which saves costs.

In a preferred embodiment according to the invention, the front of a container contains the medium connections and pressure connections, respectively at opposite corner points. These angular points are formed by the intersection of three faces, namely the face of the front with the face of the top or bottom and with the left or right side respectively.

The present invention further relates to an incubator consisting of the spatial repetition of an immersion growth system as described herein, wherein - the immersion growth systems are preferably grouped in an element consisting of 2 immersion growth systems which are positioned against each other with a rear side and - such element can be repeated in the horizontal plane to form a row of elements and - the incubator can consist of several rows that repeat in the vertical plane.

In an embodiment according to the invention, an incubator comprises at least four elements, one element consisting of two immersion growth systems according to the invention which are placed with their rear sides against each other. This has the advantage that both systems are free at the front. Because all elements for operation and operation are located at the front, the systems can be controlled and maintained separately. The absence of internal tubes / hoses in the containers prevents an increased risk of contamination. In an incubator according to another embodiment, two elements stand side by side on a horizontal surface. A light source is arranged above the two elements in such a way that the light from the light source illuminates the growth containers from the systems. A light source can be selected from the collection of fluorescent lamps, incandescent lamps, halogen lamps and LEDs.

Another embodiment comprises two elements side by side on a horizontal surface with a light source arranged above it and below that a second horizontal surface on which two other elements are arranged side by side above which a light source is also arranged.

In a preferred embodiment, an incubator according to the invention is a rack system consisting of several rows on which several elements can be placed and wherein each row is exposed over the full length of the row and wherein several rows are arranged below each other. In an embodiment according to the invention, an incubator contains at least 2 elements in a row and at least 2 rows. Other embodiments of the invention include 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20 or more elements per row and 3, 4 , 5, 6, 7, 8, 9, 10 or more rows.

In a preferred embodiment according to the invention, all growth containers are connected in one incubator to one pressure network via the pressure connection means present on the fronts of the growth containers. All medium containers are connected to one pressure network, different from the pressure network to which the growth containers are connected.

"Pressure net" is understood to mean a pressure line comprising a plurality of lateral connections and this pressure net is connected at one of its ends to a pressure variation means. The connections of a pressure network are suitable for connection to the pressure connections of the containers according to the invention. As a result, the pressure in the growth containers on the one hand and in the medium containers on the other can be regulated, whereby the pressure in all growth containers is the same but can be different from the pressure in the medium containers. The pressure in all medium containers is the same and can be different from the pressure in the growth containers.

Another aspect of the present invention relates to a method for growing plant material in vitro by using an immersion growth system as described herein or by using an incubator as described, wherein - the growth medium can be brought from the medium container to the growth container via the connected connection means and by exerting a pressure variation in the medium container and - the growth medium can flow from the growth container to the medium container via the connected connection means by means of the action of gravity and - the stability provisions of the growth container are connected with the corresponding stability provisions of the medium container.

By this method, four phases can be defined: - A first phase is the resting phase, in which the growth medium is in the medium container and the culture in the growth container and in which no growth medium is displaced.

- A second phase is the immersion phase, whereby an generated pressure in the pressure variation provision will also prevail in the medium container via the pressure connection means on the medium container. This pressure causes a gas mixture under a pressure comprised between 0.05 bar and 1.5 bar, more preferably between 0.2 bar and 0.8 bar. This pressure ensures that the growth medium is pushed out of the medium container via the connecting means and enters the growth container via the medium connecting element. The growth medium will submerge the culture in this phase. When all of the growth medium has been moved from the medium container, air is displaced by the connecting means, which prevents the growth medium from flowing back out of the growth container. The frequency of immersion preferably varies between 1-10 times per day, for example 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 or more times per day, depending on the culture to be grown and the chosen culture. growth regime. The immersion time varies between 1-20 minutes, preferably between 3-10 minutes.

- A third phase is the drainage phase which preferably starts after the immersion phase. At the start of this phase, the pressure generated in the pressure variation facility is stopped. As a result, the growth medium flows back under the influence of gravity via the connecting means to the medium container. The preferred embodiment of a medium container with a slope from the top allows the growth medium to flow back to the medium container without external force from the growth container arranged above the medium container.

- A fourth phase that preferably starts after the drainage phase is the ventilation phase. During this phase, a pressure is generated in the pressure variation device and this pressure is transferred to the growth container via the pressure connection means. The pressure generated is between 0.05 bar and 1.5 bar, more preferably between 0.2 bar and 0.8 bar. As a result of this pressure, the gas mixture present in the growth container is replaced by a gas mixture supplied from the pressure variation facility. A similar effect can be achieved by applying a negative pressure (vacuum) to the pressure connecting means of the medium container.

The invention is further illustrated below with reference to the following non-limiting examples.

Examples

The following examples are for illustrative purposes only and are preferred embodiments of the invention.

Example 1: An immersion growth system 28 as represented in figure 1. The growth container 1 has the following dimensions: 14 cm height, 18 cm width and 24 cm depth. This means that 30 cm 2 of ground surface area is available per cm of height. This growth container connected via a silicone medium connection element 13 in the lower left corner of the front side with the medium connection 8 of the medium container 2. The medium connection element 13 has an inner diameter of 6 mm and an outer diameter of 9 mm. The growing container further comprises a closable supply opening 3 with an inner diameter of 8 cm, a medium connection 7, which has an angle of inclination of -5 °, measured as the angle between the longitudinal direction of this connection and the underside of the growth container on which the fluid connection element 13 is connected. The pressure connection 5 is present in the upper right-hand corner of the front side, to which the pressure connection element 12 'is connected with a hydrophobic air filter 11', which connects the growth container to the pressure variation facility. The growth container contains a potato culture.

The connected medium container 2 has the following dimensions 11 cm height, 18 cm width and 24 cm depth. The growing container is arranged on top of the medium container and stability is ensured by the stability provisions 14 and 16, 15 and 17. The medium container contains a closable supply opening 4 centrally in the front through which growth medium can be moved. The medium container contains Murashige and Skoog (MS) medium. The inside diameter of the inlet opening is 5 cm. In the upper right corner of the front side of the medium container is the pressure connection means 6 on which the pressure connection element 12 is located. The pressure connection element further comprises a hydrophobic air filter 11. This filter has a pore size of 0.2 µm. The support system 10 consists of a notch with a width of 9 cm, measured according to the rib located in the bottom, which connects a left or right side with the bottom. The depth of the notch is 3 cm. The notches are located centrally on the ribs that connect the left and right sides with the bottom. This medium container also contains an injection point 9. This injection point has a diameter of 1.3 cm. The top side of the medium container has a slope 19 with a slope of 3.1 °.

Example 2: An incubator as shown in Figure 6. The incubator is a rack system 19 arranged in a growth chamber. The incubator contains four shelves on which seven elements 18 are arranged. An element contains two immersion growth systems as in Example 1 which are placed with the rear sides against each other. The left and right sides of the adjacent elements are also in contact with each other. A light source 20 is arranged above each shelf, in this example a fluorescent lamp. All growth containers of the immersion growth systems are connected via their pressure connection means in a pressure network 23 which is finally also connected to a pressure variation system, consisting of electronically controlled pressure valves 24, which control the pressure supply of the vacuum pump 25 and the compressor 26. The electronically controlled pressure valves 24 are controlled by the computer software installed on a system 27. All medium containers of the immersion growth systems are connected via their pressure connection means in a pressure network 22 which is finally also connected to a pressure variation system, consisting of electronically controlled pressure valves 24, which control the pressure supply of the vacuum pump 25 and the compressor 26.

All immersion growth systems are at the same time in the same phases of the process: resting phase, immersion phase, drainage phase and ventilation phase.

During the rest phase no pressure or vacuum is generated in the compressor 26 or the vacuum pump 25. At the start of the immersion phase a pressure of 0.5 bar is generated in the compressor 26. The software of the system 27 controls the pressure valves 24 so that this pressure is simultaneously transmitted via the pressure network 22 to all medium containers in the incubator. This phase lasts five minutes. During this phase, the growth medium is brought from the medium containers to the growth containers via the connecting means, whereby the culture to be grown is immersed. The immersion phase is repeated six times during the entire process. After all of the growth medium has flowed from the medium containers to the growth containers, air is pressed through the medium connections so that the growth medium does not flow back to the medium container. At the same time, the pressure valves 24 are adjusted so that there is no excessive overpressure in the growth containers. Air can be discharged via the pressure connections of the growth containers. After the set immersion time, the pressure generated is released from the containers via the pressure nets 22 and 23 by means of the pressure valves 24. Here the air pressure prevails in both containers and the growing medium that was not used flows back to the medium containers. This phase is followed by the programmed (by system 27) generation of a vacuum pressure in the vacuum pump 25 which is transferred to the medium containers via the pressure valves 24 and the pressure network 22. At the same time, the pressure connections of the growth containers are opened by means of the pressure valves 24. Because medium and growth containers are connected to each other via the connecting means, the vacuum in the medium containers ensures the supply of fresh air into the growth containers. This fresh air is also supplied to the medium connectors. After this phase a rest phase can follow.

References ETIENNE H. & BERTHOULY M. (2002). Temporary immersion Systems in plant micropropagation. Plant Cell, Tissue and Organ Culture 69: 215-231.

ESCALONA M, LORENZO JC, GONZALEZ B, DAQUINTA M, FUNDORA Z, BORROTO CG, ESPINOSA D, ARIAS E & ASPIOLEA ME (1998) New System for in vitro propagation or pineapple (Ananas comosus L. Merr). Pineapple News 5: 5-7

Murashige T. and Skoog F. (1962). Physiol. Plant 15: 473.

Claims (17)

An immersion growth system (28) comprising two corresponding containers, in particular a growth container (1) suitable for containing plant material, and a medium container (2) suitable for containing growth medium, wherein both containers are provided with connecting means (7 , 8, 13) for mutually coupling the medium container (2) to the growth container (1), characterized in that the growth container (1) is suitable for being placed on top of the medium container (2) and wherein the connecting means (7, 8, 13) are provided on a front side of the two containers. An immersion growth system (28) as in claim 1 wherein said fronts of both containers are also provided with a closable supply opening (3, 4) suitable for the supply of material and / or medium in and discharge of material and / or medium from the containers. An immersion growth system (28) as in any of the preceding claims wherein said facades of both containers are also provided with pressure connection means (5, 6, 11, 11 ', 12, 12') suitable for connection to a pressure variation facility ( 24, 25, 26) to control the pressure in both containers separately. An immersion growth system (28) as in any preceding claim wherein the surface of the underside of the growth container (1) is similar to the surface of the upper side of the medium container (2). An immersion growth system (28) as in any preceding claim wherein the underside of a medium container (2) is not parallel to the top of that same medium container (2). A container suitable for use in an immersion growth system (28) as in any preceding claim, wherein the container comprises six sides, namely an upper side, a lower side, a left side, a right side, a front side and a rear side, the six sides enclosing a beam-shaped volume. A container as in claim 6 wherein - the height of the container is smaller than the depth of the container, preferably in a ratio of height of the container to the depth of the container comprised between 1: 2.30 and 1: 1.65; and - the height of the container is smaller than the width of the container, preferably in a ratio of height of the container to the width of the container included between 1: 1.75 and 1: 1.25; and - the width of the container is smaller than the depth of the container, preferably in a ratio of width of the container to the depth of the container comprised between 1: 1.36 and 1: 1.30. A growth container (1) according to claim 7, suitable for use in an immersion growth system (28) as in claims 1-5, wherein the closable supply opening (3) is suitable for allowing a hand through. A growing container (1) as in claim 8, wherein the ratio of the area of the underside of the growing container (1) to the height of the growing container (1) is comprised between 20 cm 2 / cm height and 40 cm 2 / cm height . A growing container (1) as in claims 8 and 9, wherein the longitudinal direction of the medium connection (7) present on a front side of the growing container (1) forms an angle with the underside of the growing container (1) in the meaning that the connection of the medium connection (7) to the growth container (1) is higher than the end of the medium connection (7) to which a medium connection element (13) can be connected. A growing container (1) as in claims 8-10 wherein the upper side of the growing container (1) is made of light-transmitting material and is preferably convex and free of connectors and / or openings. A growth container (1) as in claims 8-11 wherein stability provisions (14, 16) are present in the bottom surface, suitable for connection to the corresponding stability provisions (15, 17) of a medium container (2). A medium container (2) according to claim 7 and suitable for use in an immersion growth system (28) as in claims 1-5, wherein the medium container (2) is provided with stability provisions (15, 17) in the plane of the top, suitable to be connected to the corresponding stability provisions (14, 16) of a growth container (1). A medium container (2) according to claim 13, suitable for use in an immersion growth system (28) as in claims 1-5 wherein an injection point (9) is provided on a front suitable for transporting growth medium and / or or chemicals from and to the medium container (2). A medium container (2) as in claims 13 and 14 wherein a carrying system (10) is present. An incubator (29) consisting of the spatial repetition of an immersion growth system (28) as in any one of claims 1 to 5, wherein - the immersion growth systems are preferably grouped in an element consisting of 2 immersion growth systems that are positioned with their backs against each other and - such element can be repeated in the horizontal plane to form a row of elements and - the incubator (29) can consist of several rows that repeat in the vertical plane; wherein the incubator is further characterized by a pressure variation facility (24, 25, 26) to which all pressure connection means (5, 6, 11, 11 ', 12, 12') of the immersion growth systems are connected by means of a pressure network (22, 23 ); and preferably the incubator is provided with light sources (20) positioned so that all growth containers (1) in all rows are illuminated thereby. A method for growing plant material in vitro by using an immersion growth system (28) as claimed in claims 1-5 or by using an incubator (29) as claimed in claim 16, wherein - the growth medium from the medium container (2) can be brought to the growth container (1) via the connected connecting means (7, 8, 13) and by exerting a pressure variation in the medium container (2) and - the growth medium from the growth container (1) to the medium container (2) can flow via the connected connecting means (7, 8, 13) through the action of gravity and the stability provisions (14, 16) of the growth container are connected to the corresponding stability provisions (15, 17) of the medium container (2).