Disposable bioreactor/fermenter

Abstract

The present invention is a bioreactor or fermenter formed of a container having two or more walled. One or more inlets and one or more outlets are formed in one or more of the walls of the container. At least one of the one or more inlets is formed in the bottom wall of the container and used for the introduction of one or more gases. A gas distribution device is formed within the body of the container adjacent the bottom gas inlet and a hydrophobic filter is mounted to the bottom wall gas inlet, upstream of the gas inlet. The distribution device is formed such as by bonding the two facing wall surfaces of the container together at discrete and spaced apart locations to form a series of gas ports into the remainder of the container. The hydrophobic filter acts to purify the gas entering the container so as to prevent the introduction of contaminants such as microbes into the container. It also acts as a valve, preventing liquid in the bag from passing through its hydrophobic structure thus preventing any back flow when positive pressure from the gas supply is not being imposed upon the bag.

Description

BACKGROUND OF THE INVENTION

The biopharmaceutical industry has traditionally used stainless steel systems and piping in their manufacturing process as they are capable of being steam sterilized and reused.

The cost of such a system is often prohibitive. Moreover, such systems are static, often being welded together and not easily reconfigured.

The industry has begun to explore an alternative approach, namely to use plastic, single disposable bags and tubing to replace the traditional stainless steel. This allows one the flexibility to rearrange these systems at minimal cost. Additionally, the initial capital cost is several times less than that of stainless steel allowing one to manufacture biopharmaceuticals in smaller amounts, making available new therapeutic agents that prior to this advancement were not economically justified and allowing for the expansion of contract manufacturing of such products or when demand requires additional capacity quickly.

One aspect of the disposable biopharmaceutical plant has been the bioreactor, which needs a steady supply of gas and nutrients and removal of waste products and expelled gases. Additionally, a constant movement of the cells in the reactor helps to provide a constant mixing of the contents.

One system for a bioreactor has been to use a large table, equipped with motors or hydraulics onto which a bioreactor bag is placed. The motors/hydraulics rock the bag providing constant movement of the cells. Additionally, the bag has a gas and nutrient supply tube and waste gas and waste product tube which allow for the supply of nutrients and gases such as air for aerobic organisms and the removal of waste such as respired gases, carbon dioxide and the like. The tubes are arranged to work with the motion of the bag to allow for a uniform movement of the gases and fluids/solids. See U.S. Pat. No. 6,191,913.

Such a system requires the use of capital-intensive equipment, with components that are susceptible to wear. Additionally, the size of the bag that can be used with the table is limited by the size of table and the lifting capability of its motors/hydraulics.

An alternative system uses a long flexible tube-like bag that has both ends attached to movable arms such that the bag after filling is suspended downwardly from the movable arms in the shape of a U. The arms are then alternately moved upward or downward relative to the other so as to cause a rocking motion and fluid movement within the bag. If desired the mid section may contain a restriction to cause a more intimate mixing action.

This system requires the use of a specially shaped bag and hydraulic or other lifting equipment to cause the movement of the liquid. Additionally, due to weight considerations, the bag size and volume is restricted by the lifting capacity of the equipment and the strength of the bag.

An improvement has been shown through the use of one or more bags that are capable of being selectively pressurized and deflated in conjunction with a disposable bio bag such as a fermenter, mixing bag, storage bag and the like. The pressure bag(s) may surround a selected outer portion of the bag or may be contained within an inner portion of such a bag. By selectively pressurizing and deflating the pressure bag(s), one is able to achieve fluid motion in the bag thereby ensuring cell suspension, mixing and/or gas and/or nutrient/excrement transfer within the bag without damaging shear forces or foam generation.

Alternatively, one can select a static (non-moving) bag that contains a sparger or other device for introducing a gas into the bag. The gas causes the movement of the fluid in the bag as well to cause the mixing and transfer of gases, nutrients and waste products.

U.S. Pat. No. 5,565,015 uses a flat, inflatable porous tube that is sealed into a plastic container. The tube inflates under gas pressure and allows gas to flow into the bag. When the gas is not applied the tube collapses and substantially closes off the pores of the flat tube to prevent leakage from the bag.

U.S. Pat. No. 6,432,698 also inserts and seals a tube to a gas diffuser within the bag. It appears that a constant positive gas pressure must be maintained in order to prevent any liquid within the bag from entering the diffuser and then the gas line and eventually the air pump as no valve or other means for preventing backflow is shown.

Both have the potential for leakage of the liquid in the container which can potentially contaminate the contents of the bag of the upstream components of the system such as the gas supply system. Additionally, both introduce a separate component for the gas distribution.

The present invention provides a device that overcomes these deficiencies.

SUMMARY OF THE INVENTION

The present invention relates to the field of fermentation. More particularly it relates to a disposable fermenter or bioreactor having a built-in gas distributor and a device for inhibiting backflow or leakage through the gas distributor.

The present invention is a bioreactor or fermenter formed of a container having two or more walled. One or more inlets and one or more outlets are formed in one or more of the walls of the container. At least one of the one or more inlets is formed in the bottom wall of the container and used for the introduction of one or more gases. A gas distribution device is formed within the body of the container adjacent the bottom gas inlet and a hydrophobic filter is mounted to the bottom wall gas inlet, upstream of the gas inlet. The distribution device is formed such as by bonding the two facing wall surfaces of the container together at discrete and spaced apart locations to form a series of gas ports into the remainder of the container. The hydrophobic filter acts to purify the gas entering the container so as to prevent the introduction of contaminants such as microbes into the container. It also acts as a valve, preventing liquid in the bag from passing through its hydrophobic structure thus preventing any back flow when positive pressure from the gas supply is not being imposed upon the bag.

In one embodiment, the device is formed of flexible or semi-rigid plastic with its one or more wall edges sealed together to form a closed container. The one or more inlets and outlets can either be formed in the plastic as made or they can be added as needed with the appropriate sealing.

In another embodiment, the bottom wall of the container has an upward taper, either to one side or both sides or a rounded bottom wall to eliminate any deadspace in corners.

In a further embodiment the container is formed of semi-rigid plastic in a two piece clam shell design that is sealed to each other by their adjacent wall edges.

It is an object of the present invention to provide a fermenter comprising a plastic container having sealed walls, one or more inlets and one or more outlets are formed in the container, at least one of the one or more inlets is formed in the bottom wall of the container and is connected to a source of one or more gases, a gas distribution device formed within the body of the container adjacent the bottom gas inlet and a hydrophobic filter mounted upstream of the gas inlet.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a cross-sectional view of a first embodiment of the present invention.

FIG. 2A shows a cross-sectional view of a second embodiment of the present invention.

FIG. 2B shows a cross-sectional view of another embodiment of the present invention.

FIG. 3 shows a cross-sectional view of another embodiment of the present invention.

FIG. 4 shows a cross-sectional view of another embodiment of the present invention.

FIG. 5 shows a cross-sectional view of another embodiment of the present invention.

FIG. 6 shows a cross-sectional view of another embodiment of the present invention.

DETAILED DESCRIPTION

The present invention relates to a disposable fermenter or bioreactor. FIG. 1 shows a first embodiment of the present invention. As shown the device is comprised of a bag 2 having two substantially vertical sidewalls 4, a top wall 6 and a bottom wall 8. One or more inlets 10A-B and one or more outlets 12 are formed one or more walls of the in the bag 2. One inlet for gas 10A is located at the lowermost portion of the bottom wall 8 of the container 2. Attached to the inlet 10A and upstream of the inlet 10A is a hydrophobic filter 16. Connected to the other end of the filter 16 is a gas line 18 for supplying air and/or other gases to the container 2. A series of one or more gas distribution devices 20 are formed in the container adjacent the bottom wall 8. The one or more devices are designed to allow gas to enter the container adjacent the inlet 10A. The devices form one or more gas ports 22 which distribute the gas through out the container before it enters the remainder of the container. Preferably as shown, there are a plurality of these devices 20 that form a series of two or more gas ports 22 so as to maximize this distribution effect.

The one or more inlets 10 and outlets 12 may be formed as part of the container itself or they may be attached to the bag and liquid tightly sealed to the walls so as to prevent any leakage. The use of plastic tubes, hose barbs and luer fittings that can be sealed to the container wall(s) are the most common devices that can be used to form the one or more inlets and outlets. Others will also be readily apparent and are meant to be incorporated herein. They may be sealed to the wall(s) by heat sealing or vibration welding, adhesives, solvents, overmolding of plastic seals and the like, as are commonly used in the container industry.

As shown in FIG. 1, the bottom wall 8 has an upward taper 14 to each of the sidewalls 4. This is used to avoid the formation of dead zones for circulation within the container. While this is a preferred design, a flat bottom wall may also be used, especially if the mixing is deemed to be adequate or not necessary to its use. Other alternative embodiments include a bottom wall 8 having a single upward linear taper 14A toward one of the side walls 4 as shown in FIG. 2A or it may have a rounded bottom wall 8B as shown in FIG. 2B. Other designs may also be used.

The one or more gas distribution devices 20 are formed from the walls of the container itself. This can be accomplished for example by selectively sealing adjacent, opposite wall portions together such as by the use of heat sealing, vibration welding, adhesives and the like so they are permanently attached to each other and gas must flow around them in order to rise up through the container. Preferably, the arrangement of the devices conforms to the shape of the bottom wall 8. Alternatively as shown in FIG. 3 they may be arranged in a horizontal row regardless of the bottom wall 8 configuration.

Any hydrophobic membrane containing filter may be used in the present invention. The membrane may be inherently hydrophobic such as polyvinylidene fluoride (PVDF), polyethersulfone (PES) or PTFE resin or it may be treated, such as by a crosslinked coating or graft polymerization of a surface treatment, either to render the polymer hydrophobic or to provide the desired level of hydrophobicity. Such filters are well-known in the art and include for example DURAPORE® filter cartridge filters or AERVENT® hydrophobic cartridge filters available from Millipore Corporation of Billerica, Mass. The filter provides duel functionality in the present invention. It acts as a filter for any gas entering the fermenter to keep dust, particles or bacteria (when one selects a filter having a nominal pore size of less than 0.22 micron) from entering and potentially contaminating the fermenter. More importantly, as it is hydrophobic, it will prevent liquid from leaving the fermenter through the gas inlet in the event that either the gas pressure is off or is lower than the static or head pressure applied by the liquid in the fermenter. In most applications, selecting a suitably sized filter with the desired level of hydrophobicity also means that one need not use a valve between the fermenter and the gas supply and can use the inherent resistance of the filter's membrane to act as a valve instead. For example, a DURAPORE® filter cartridge is capable of withstanding about 30 psi pressure differential of water meaning that it is capable of supporting a large column of water or similar liquids. The key is to select a filter and use it with a volume of liquid such that the head pressure of the liquid in the fermenter doesn't meet or exceed the intrusion pressure of the membrane within the filter cartridge.

The container can be formed of two flat sheets of material which are heat bonded, vibration welded, adhered or solvated along their adjacent outer edges. Alternatively, it can be formed of a plastic tube so that only the top 6 and bottom wall 8 need to seal to each other. In another embodiment, a single sheet may be used and folded in half on itself so that the sidewalls 4 and top wall 6 need to be sealed together.

In the embodiment of FIG. 4, the container is formed of two molded halves, 30A and B that are then sealed to other along their adjacent outer edges. The gas distributing devices 32A and 32B are also molded into the respective halves 30A and 30B. When the two halves 30A and B are sealed together the two distributor halves 32A and B are also preferably in contact with each other. If desired they may be sealed to other as well by heat, solvents, adhesives or vibration welding. Alternatively, they may be molded with features that interlock to each other such as male/female portions (e.g. key and keyway) on the respective halves to hold them together.

Preferably in the design of the embodiment of FIG. 4, the device is a single molded piece connected by a hinged portion 34 as shown. This is commonly referred to as a clamshell housing. Alternatively, they can be two separate pieces if desired.

FIG. 5 shows the design of FIG. 4 in a face on planar view after assembly. As can be seen it is essentially identical in design to that of FIGS. 1-3 and operates in the same manner. Also shown are the gas ports 36 between the gas distribution devices 32 A/B.

FIG. 6 shows the design of FIG. 4 in a cross-sectional view through the centerline after assembly. As can be seen it is essentially identical in design to that of FIGS. 1-3 and operates in the same manner. While not shown due the cross sectional slice chosen, the gas ports 36 exist on either side of the distribution device 32A/B.

The materials used in the present invention to make the container can be those typically used in the biopharmaceutical industry for disposable bioreactors, fermenters, storage bags and the like. Such materials and/or bags are available from a variety of suppliers such as Stedim SA of France and Hyclone of Logan, Utah. These bags range in size from a few liters to 2000 liters or more. They typically are made from multiple layered (extruded or laminated) plastic film such as polyethylene, polypropylene, EVA copolymers, EVOH, PET, PETG, specialty or proprietary polymers such as the HyQ CX5-14 film available from Hyclone which is a coextruded multilayer film with an outer layer of elastomer with an EVOH barrier layer and an ultra-low density polyethylene product contact layer, blends of polymers and the like. The polymer(s) selected are chosen for the desired combination of cleanliness, strength and visibility.

When used in the clam shell format of FIG. 4-6, one can use polymers that are capable of being formed by vacuum or injected molded such as polyethylene, polypropylene, polycarbonates, polystyrenes, various acrylics and methacrylics and copolymers thereof, and the like.

The present invention is shown in several embodiments and others can be easily contemplated by those of ordinary skill in the art. It meant to include those embodiments as well in the description and claims of the present invention.

The present invention provides one with a simple system for the growth of microbes in a fermenter or bioreactor as a disposable system with good gas and fluid distribution. It allows one to achieve the adequate movement and/or mixing of components as desired without the need for capital and maintenance intensive equipment such as rocking tables or hydraulic hoists or cranes. While contemplated for use in the biopharmaceutical industry, it is clear that the device of the present invention has applications in other fields such as beer brewing, wine making and the like in disposable bags.

Claims

1) A fermenter comprising a plastic container having one or more sealed walls, one or more inlets and one or more outlets are formed in the one or more walls of the container, at least one of the one or more inlets is formed in a bottom wall of the container and is connected to a source of one or more gases, a series of one or more gas distribution devices formed within the body of the container adjacent the bottom gas inlet and a hydrophobic filter mounted between the gas inlet and the source of the one or more gases.

2) The fermenter of claim 1 wherein the one or more gas distribution devices are formed by bonding the two facing wall surfaces of the container together at one or more locations to form a series of one or more gas ports into the remainder of the container.

3) The fermenter of claim 1 wherein the one or more gas distribution devices are formed by bonding the two facing wall surfaces of the container together at two or more discrete locations spaced apart from each other so as to form a series of two or more gas ports into the remainder of the container.

4) The fermenter of claim 1 wherein the hydrophobic filter has a bubble point of at least 20 psi and an average pore size of about 0.22 micron.

5) The fermenter of claim 1 wherein the hydrophobic filter has a bubble point of at least 25 psi and an average pore size of about 0.22 micron.

6) The fermenter of claim 1 wherein the hydrophobic filter has a bubble point of at least 30 psi and an average pore size of about 0.22 micron.

7) The fermenter of claim 1 wherein the bottom wall of the container is upwardly tapered toward one or more of the sidewalls.

8) The fermenter of claim 1 wherein the bottom wall of the container is upwardly tapered in the form of a V.

9) The fermenter of claim 1 wherein the bottom wall of the container is upwardly tapered toward one sidewall of the container.

10) The fermenter of claim 1 wherein the bottom wall of the container is tapered in the form of a rounded shape toward the sidewalls.

11) The fermenter of claim 1 wherein the plastic container is a flexible plastic bag.

12) The fermenter of claim 1 wherein the plastic container is a molded plastic container.

13) The fermenter of claim 1 wherein the plastic container is a molded plastic container comprised of two halves that are sealed to each other along their adjacent outer edges.

14) The fermenter of claim 1 wherein the plastic container is a molded plastic container comprised of two halves connected together by a hinge portion and the two halves are sealed to each other along their adjacent outer edges.