IT202100011231A1 - Device for carrying out in vitro experiments on biological materials - Google Patents

Description

DESCRIPTION of the Industrial Invention entitled: ?Device for carrying out in vitro experiments on biological materials?

DESCRIPTION

The present invention relates to a device for carrying out in vitro experiments on biological/synthetic materials.

The device comprises at least one container which has an internal chamber.

? there is also a first hydraulic circuit connected to the internal chamber, so as to generate a flow of fluid forced inside the container.

The one just described? the common configuration of some fluidic devices known to the state of the art, used for the execution of fluid dynamic tests, ie tests to improve the vitality? of cultured tissue in vitro/ex vivo and/or to study the passage of substances/molecules/drugs/cells through tissue subjected to a flow of moving fluid, such as for example permeation and absorption tests and other types of applications.

Generally, but not necessarily, these devices have the internal chamber divided into a lower chamber and an upper chamber, divided by a retaining element.

In particular, the tissue or the biological material or the membrane is placed inside the container through this retention element.

An example of such devices ? described in the patent application WO2018130998, the content of which is? to be considered an integral part of this patent application.

The device object of the present invention can? be used for the execution of various experiments and on any biological/synthetic material.

Thus, for example, transdermal tests on tissue samples, absorption tests and/or vitality tests, such as for example vitality improvement tests, can be performed. of ex vivo tissue, skin culture tests, drug efficacy tests, toxicity tests, etc.

These devices, also known in the state of the art as bioreactors or lab-on-chip or micro-physiological systems, are used in combination with hydraulic circuits which provide fluid handling systems, generally pumps, generally peristaltic, which push the fluid inside the bioreactor through the inlet of the inner chamber and to draw the fluid out of the bioreactor through the outlet of the inner chamber.

Based on the configuration of the container and the hydraulic circuit? It is possible to foresee that the fluid is pushed into the bioreactor through the inlet in the lower and/or upper chamber and is pulled out of the bioreactor through the outlet in the lower and/or upper chamber.

It is evident how this configuration can work if the fluid does not encounter obstacles and is kept in balance, i.e. if the quantity? of fluid that enters inside the bioreactor? corresponding to the quantity of fluid that comes out of the bioreactor, cos? so as not to perturb the fluid levels around the hosted tissue.

In fact, in the event of a lack of balance, for example following a lower quantity? of outgoing fluid, the internal chamber of the bioreactor tends to fill up, with the risk that the fluid escapes from the opening of the upper chamber or overflows from the lower chamber to the upper one if inserts for cell cultures are used, making it impossible and unreproducible? test execution.

This effect is particularly frequent in the case of fluidic installations which envisage at least two bioreactors in series, i.e. connected to the fluidic circuit so that they are interconnected and connected to the peristaltic pump respectively, with the inlet of a bioreactor and with the outlet of the ?another bioreactor.

In this case, the fluid encounters a first bioreactor, enters the internal chamber of the bioreactor itself, but is unable to exit, as it encounters excessive resistance, due to the presence of the second bioreactor and the hydraulic resistance opposed by the connecting channel between the two devices. The result ? that the internal chamber of the first bioreactor fills up and the fluid overflows from the opening.

Currently some devices known in the state of the art, in order to solve the above problem, provide for the use of lids of the opening made with screw caps or with flexible/deformable/elastic caps capable of adapting to the container (eg silicone).

In order to work, these solutions are made with non-transparent materials given the required mechanical requirements (e.g. metal or polymer screw caps such as PP, PE, PET, deformable silicone caps), but the transparency requirement? essential for being able to observe cell cultures under a microscope and the techniques for making transparent covers require particularly high manufacturing costs and/or couplings with materials having glass-like transparency.

Furthermore, in addition to the aforementioned processes, it would be necessary to provide a thread also on the external walls of the bioreactor.

Other solutions known to the state of the art provide in any case for costly machining on the lids and on the structure of the devices, in order to allow closure and hermetic sealing.

A possible alternative, provides the possibility? to modify the hydraulic circuit, so as to interpose the pump between the bioreactors connected in series, so that the first line of the pump pushes the fluid to the inlet of the first bioreactor and the fluid leaving it connects to the second line of the pump (in suction) that will feed? (in thrust) the entrance of the second bioreactor, whose exit will be? connected to the first line (suction) and subsequently to the inlet of the first bioreactor (push).

However, this solution is also inefficient from the point of view of carrying out the test, since, as the bioreactors are connected to different channels of the pump, a flow rate difference could occur between the inlet of the first bioreactor and the outlet of the second bioreactor.

So is there a need? not satisfied by devices known in the state of the art, to solve the disadvantages set out above.

The present invention achieves the above aims, realizing a device as previously described, in which the internal chamber has an upper opening, which is closed by a cover configured to be removably fixable at the opening itself.

? also provided is an elastic sealing element interposed between the lid and the edge of the opening, in such a way that the elastic element passes from an uncompressed condition, corresponding to the unfixed condition of the lid, to a compressed condition, corresponding to the condition attached to the lid.

A sealed device is therefore obtained, in a simple and effective manner, with contained costs.

In fact, thanks to the mechanical yielding of the elastic element, when the lid is fixed to the container, the elastic element remains compressed between the upper edge of the container and the lid; does the elastic element ?spread? on the walls of the lid and of the container ensuring tightness of the container.

In this way, regardless of the conditions at the exit from the internal chamber, the fluid will be able to flow in the hydraulic circuit in a balanced way, ie so that the quantity? of fluid that enters is equivalent to the quantity? of fluid flowing out. This effect? guaranteed by the presence of air inside the container, in pressure equilibrium with the liquid present in the internal chamber at the time of closure. If there were an imbalance in the inlet/outlet flow of the liquid, the air would exert a counter pressure which tends to re-establish the previous levels, thus guaranteeing continuity? of flow and levels.

The pressure of the lid causes a deformation of the elastic element, which turns into a gasket and spreads on the lid itself, generating a seal.

Obviously, to guarantee correct compression/decompression of the elastic element, the material which constitutes the elastic element must have a certain softness and compliance when subjected to external pressure forces.

In this case the material has a shore A value preferably lower than 40.

The chosen shore A value can? also depend on the size of the container used.

Regardless of the degree of compliance of the elastic element, its elastic nature allows the elastic element to be used even in the case in which the container retention element consists of cup-shaped elements of the transwell type.

In fact, these cup-shaped elements have arms for locking to the container which engage at the edge of the opening: the presence of these arms further deforms the elastic element, which follows the profile of these arms, which do not compromise the seal.

These and further objects of the present invention are achieved by means of a device for carrying out in vitro experiments on biological materials according to the attached independent claim and the subclaims.

Optional characteristics of the device of the invention are contained in the attached dependent claims, which form an integral part of the present description.

These and other features and advantages of the present invention will be more clearly from the following description of some executive examples illustrated in the attached drawings in which:

Figure 1a shows a section through a possible embodiment of a bioreactor known in the state of the art;

figure 1b illustrates a possible configuration of a bioreactor known in the state of the art in combination with a hydraulic circuit;

figures 2a and 2b show two sections of a possible embodiment of the device object of the present invention, respectively with the elastic element in the non-compressed condition and in the compressed condition;

figures 2c and 2d show two views of a possible embodiment of the device object of the present invention;

figures 3a and 3b show two views of a possible embodiment of the lid belonging to the device object of the present invention;

figures 4a and 4b illustrate two exemplary diagrams of two possible configurations of the device object of the present invention;

figures 5a and 5b illustrate two details relating to the lid belonging to the device object of the present invention.

It is specified that the figures attached to the present patent application show some embodiments of the device for carrying out in vitro experiments object of the present invention in order to better understand its advantages and specific characteristics.

These embodiments are therefore to be understood for an explanatory and non-limiting purpose of the inventive concept of the present invention, i.e. that of realizing a device for carrying out in vitro experiments which has an internal sealed chamber, regardless of the upstream and downstream fluid configuration of the container.

With particular reference to figures 1a and 1b, the device comprises a container 1 inside which insertable element for holding a tissue sample.

The insertion of the retention element does s? that inside the container 1 an upper chamber 12 and a lower chamber 11 can be identified.

As anticipated, some embodiments relating to a connection to the lower chamber of the container 1 are illustrated.

However, it is evident, from what has been previously described, that ? it is possible to provide the hydraulic connection also, alternatively or in combination with the lower chamber, with the upper chamber, without requiring substantial modifications to the device object of the present invention.

With particular reference to the figures, the upper chamber 12 comprises an upper opening 13, configured to allow the insertion of any retention element and/or of the biological tissue to be examined.

The opening 13 is closed by a lid 14, which can be fixed to the upper chamber, in correspondence with the opening 13.

The cover 14 ? illustrated in figure 1b in a condition not coupled to the container 1, but it is evident how the lid 14 can be fixed to the upper edge of the upper chamber 12.

This configuration? illustrated in Figure 2b. Furthermore, ? there is a hydraulic circuit connected to the lower chamber 11, so as to generate a flow of forced fluid inside the lower chamber 11.

This hydraulic circuit? illustrated, through an exemplifying scheme, in figure 1b, in which ? there is a peristaltic pump 3 which pushes the fluid inside the lower chamber 11, through the delivery duct 31 and sucks the fluid from the lower chamber 11 through the suction duct 32.

Obviously, based on the operation of pump 3, the fluid can? change its path and the delivery pu? become suction and suction becomes delivery.

For simplicity? exposition, in the figures attached to the present patent application, it is assumed that the fluid enters the lower chamber 11 from the right and exits from the left, however the direction of the fluid does not influence the present invention, nor? requires changes to it.

As illustrated in figure 1b, the lid 14 has a lower ring element which has an internal side surface 141.

The lid 14 also has an abutment wall 142, which in the specific case of the figures, coincides with the top wall of the cap.

The fastening between the lid 14 and the container 1 takes place through a shape coupling between the ring nut of the lid 14 and the upper edge of the upper chamber 12, realized as a radial enlargement of the opening 13.

The upper edge therefore has an external lateral surface 121 and an abutment wall 122.

Also, the top edge? shaped so as to create a housing seat 123, which will later described.

In the fixed condition of the lid 14, the internal surface 141 cooperates with the lateral external surface 121, while the abutment wall 142 cooperates with the abutment surface 122 of the upper edge.

In order to guarantee correct locking of the lid 14, the lid 14 has a plurality of of ribs 143 on the inner surface 141 of the ferrule element, as illustrated in figures 3a and 3b.

During the coupling between the lid 14 and the upper edge of the upper chamber 12, the ribs 143 deform elastically against the lateral outer surface 121 and lock the lid 14 in position.

The device object of the present invention provides an elastic sealing element 2 interposed between the lid 14 and the edge of the opening 13, in such a way that the elastic element 2 passes from an uncompressed condition, corresponding to the unsecured condition of the lid 14, to a compressed condition, corresponding to the fixed condition of the lid.

The elastic element 2 ? preferably made from an annular element and figures 2a and 2b show two sections of the container 1 in combination with the elastic element 2.

The elastic element 2 ? interposed between the lid 14 and the upper edge of the container 1, in such a way that the elastic element 2 is not compressed, figure 2a, in the non-fixed condition of the lid 14 to the container 1, while the elastic element 2 is compressed, figure 2b, in the fixed condition of the lid 14 to the container 1.

The yieldability of the material constituting the elastic element allows the compression of the elastic element itself subjected to the pressure exerted by the fixed condition of the lid 14, in such a way that the elastic element 2 realizes a sealing lip of the internal chamber of the container 1 .

Figure 2c illustrates in particular a container 1 without the elastic element 2, while figure 2d illustrates a container 1, with the elastic element 2.

As anticipated, the elastic element 2 ? consisting of an annular element, i.e. an element which has the same shape as the opening 13 and which is housed inside the housing seat 123.

The housing seat 123 has a stepped profile, so as to partially house the elastic element 2.

In the fixed condition of the lid 14, therefore, the abutment walls 142 compress the annular element 2, in particular the part of the annular element 2 interposed between the two walls 123 and 142.

The compression of the elastic element 2, in the locked condition of the lid 14, allows to create a "tight" internal chamber of the container 1.

As previously described, the creation of an internal sealed chamber of the container 1 is particularly advantageous in the case of connection of two containers 1 in series, as illustrated in figures 4a and 4b.

In this configuration, the flow between the two chambers remains constant over time even in the presence of significant hydrodynamic resistance in the connection between the two chambers (e.g. connecting pipes with very small internal diameters) since the pressure difference necessary to push the liquid from the first room to the second ? guaranteed by the pumping of the pump which, by introducing the liquid into the first chamber, compresses the air in a closed system, generating an increase in pressure in the chamber which pushes the liquid from the first chamber to the second (Pascal's law).

According to the configurations illustrated in figures 4a and 4b, the pump 3 is connected as input to container 1 on the right and as output to container 1 on the left.

The container 1 on the right ? connected with its output to the input of container 1 on the left.

It follows that the fluid is pushed by the pump 3 into the lower chamber of the container 1 on the right, passes inside this lower chamber, to be pushed into the lower chamber of the container 1 on the left, to then be sucked in by the pump 3 through the outlet of the lower chamber of the left container 1.

Is the fluid therefore in equilibrium, i.e. is the same quantity pushed? of fluid being aspirated.

This condition remains verified, even in the case in which the container 1 on the right is open, ie in the condition of the lid 14 not fixed, as illustrated in figure 4b.

The configuration of figure 4b also allows to test the tightness of the container 1 on the left. In addition, the configuration of figure 4b allows debubbling the circuit, i.e. eliminating some bubbles that may have formed in the hydraulic circuit for any reason: these bubbles are free to travel throughout the circuit and then be expelled through the container 1 of right, not hermetically sealed.

Finally, it is specified that, according to a possible embodiment, the device object of the present invention can also provide a second hydraulic circuit, connected to the upper chamber 12 of the container 1.

In order to guarantee the seal, the cover 14 has a through hole, in which to insert the pipes 4 of the second hydraulic circuit, according to the variant illustrated in figures 5a and 5b.

According to these figures, the lid 14 provides for the insertion of pipes 4 inside the through hole.

The pipes 4 are surrounded by a gasket 41 which, as illustrated in figure 5a, has a profile such as to create a sealing lip which is arranged around the walls of the through hole made in the lid 14.

The gasket 41 has two external parts, which protrude above and below the through hole of the cover 14, which parts are connected through a central radial narrowing, housed entirely inside the hole.

While the invention? susceptible to various modifications and alternative constructions, some preferred embodiments have been shown in the drawings and described in detail.

It must be understood, however, that there is no no intention of limiting the invention to the specific embodiment illustrated, but, on the contrary, it is intended to cover all modifications, alternative constructions, and equivalents which fall within the scope of the invention as defined in the claims.

The use of ?for example?, ?etc.?, ?or? indicates non-exclusive alternatives without limitation unless otherwise indicated.

Using ?include? means ?includes, but not limited to? unless otherwise indicated

Claims (8)

1. Device for carrying out in vitro experiments on biological/synthetic materials comprising at least one container (1) which container has an internal chamber, since there is also a first hydraulic circuit (3, 31, 32) connected to the internal chamber, so as to generate a flow of fluid forced inside said internal chamber, characterized in that said inner chamber has an upper opening (13), which upper opening (13) ? closed by a cover (14) configured to be removably fixable at said opening (13), an elastic sealing element (2) being provided interposed between the lid (14) and the edge of the opening (13), in such a way that the elastic element (2) passes from a non-compressed condition, corresponding to the non-compressed condition fixed condition of the lid (14), to a compressed condition, corresponding to the fixed condition of the lid (14). 2. Device according to claim 1, wherein said elastic element (2) is consisting of an annular element. 3. Device according to claim 1 or claim 2, wherein said elastic element (2) ? made of a material that has a hardness lower than 40 shore A. 4. Device according to one or more? of the preceding claims, wherein said lid (14) has means for removable fastening to said container (1). 5. Device according to claim 4, wherein the lid (14) has a ring element, the inner surface (141) of which is? configured to cooperate with the external surfaces (121) of the container (1), being said fixing means constituted by a plurality? of ribs (143) arranged along the inner surface (141) of the ring element. 6. Device according to one or more? of the preceding claims, wherein the upper edge of the opening (13) of the container (1) has a housing seat (123) for the partial housing of said elastic element (2). 7. Device according to one or more? of the preceding claims, wherein the lid (14) has at least one through hole for connecting the internal chamber to a second hydraulic circuit (4), a gasket (41) being present along the walls of said through hole. 8. Device according to one or more? of the preceding claims, wherein at least two containers (1) are provided placed in series with each other, so that the outlet of the inner chamber of a container is ? connected to the entrance of the inner chamber of the other container.