JP2008513013A - Perfusion bioreactor for cell culture - Google Patents

Abstract

  A bioreactor system with a multiwell platform that includes an array of multiple bioreactor units. The bioreactor system includes a perfusion unit (86) and a fluid source unit (92) interconnected fluidly by a pump unit (82). The perfusion unit comprises a multi-well plate that includes a plurality of main chambers (83) configured to contain or accommodate cell cultures, and each bioreactor unit can perform independent cell exploration or experiments. it can.

Description

  The present invention relates generally to the bioreactor field, and more particularly to systems and methods for culturing cells under perfusion in a single chamber or high throughput format.

  It has been recognized that recent developments in cell / tissue engineering benefit cell growth and exploration in a dynamic environment. Spinner flasks, rotating devices, perfusion bioreactors, or fluid shear chambers have all been used to enhance nutrient and metabolite diffusion into and out of cells. The mechanical aspects of fluid shear have also been shown to induce second messenger signals and alter cellular gene expression. Although these new culture conditions are recognized to affect cell function (growth, signaling, morphology, differentiation, etc.), devices that explore these environments have not become high-throughput platforms. Furthermore, no system has been established that incorporates three-dimensional scaffolds with highly aligned pores for long-term control of fluid flow paths.

  Fluid flow was first established as a regulator of cellular gene expression in a two-dimensional culture system in which the culture medium flows over the cells attached to the glass slide. Cells respond to fluid shear by orienting in the direction of the force and changing their gene expression. These two-dimensional devices are currently commercially available from, for example, Flex-Cell International as well as other vendors. Fluid flow exploration has recently turned into a three-dimensional scaffold, and fluid shearing has proven to be another important factor in maintaining hepatocyte and bone differentiation. However, but not limited to this, some examples include other excesses known to alter cell function, including signaling factors such as growth factors, ECM, cytokines, media factors, and small molecules. The true importance of fluid flow as an environmental signaling factor is not yet fully understood, as it is difficult to screen for and explore in conjunction with environmental stimuli. For example, to date, all devices designed to explore how these forces affect cell culture are one-pot or single chamber devices. These devices can be used to explore the effects of rotational or fluid shear forces on cells under one condition at a time, but cannot be explored under different or diverse conditions. , Which greatly limits the usefulness of these devices. Thus, current devices are unknown to alter specific functions for optimization of conditions for a controllable cell phenotype or in highly relevant cells or engineered tissue cultures. It is not suitable for performing medium or high throughput experiments to test substances such as functional molecules.

  Furthermore, in the field of new drug discovery, ADMETox of drugs (ADMETox is a series of analyzes that evaluate the absorption, distribution, metabolism, elimination, and toxicity of candidate drugs. It is highly desirable to use primary human cells to explore properties (which are acronyms). This is due to the fact that exploration of animal animals is expensive and the results do not always predict human response. In vitro exploration of primary human cells is attractive because of the economic aspects of the approach as well as the fact that data from human cells should be more relevant than animal data. Unfortunately, culturing primary human cells is extremely difficult for most cell types, and there are few model systems that can create related models of in vivo tissues and organs. In between intermediate animals and primary cells, tissue or organ sections maintain cells in their original environment (without leaving the cells detached from their microenvironment), while at the same time cell viability, metabolism, and others An alternative is provided that allows in vitro testing of the effects of xenobiotics on the desired ADMET type aspect of the present invention. For example, liver sections are often used to assess liver-specific drug toxicity as well as CYP induction.

  There are also some problems in in vitro culture of tissue sections. For example, one important challenge is the high metabolic rate and nutritional requirements that tissue sections require in vitro. Since tissue sections require high nutrient loads, these sections need to be cultured in a large volume of medium. However, as more media is added to the culture, the oxygen diffusion distance increases as the rate of oxygen consumption by the tissue becomes faster than the oxygen diffusion, leading to hypoxia and cell death. Therefore, there is a great need for bioreactor type devices that enhance nutrient and metabolite transport while maintaining a medium to high throughput parallel test format.

US Patent Application Publication No. 2004/0147016

  To test and / or know how the new environment changes the ability of cells to respond to other chemical or physical stimuli in the presence of fluid shear, and also for cell growth and differentiation In order to facilitate the systematic and high-throughput discovery of dynamic cell culture conditions for culturing cells under fluid perfusion in a medium to high throughput format, then using these optimized environments, What is needed is a system and method for creating engineered in vitro tissue for therapeutic, diagnostic, or exploratory purposes. There is also a need for a perfusion system that allows dynamic / multiple culture of various tissue or organ sections for ADMET and tissue culture applications.

  The present invention is directed to a bioreactor system including a perfusion unit, a pump unit in fluid communication with the perfusion unit, and a fluid source unit in fluid communication with the pump unit. The perfusion unit includes an array of a plurality of cell wells configured to receive a cell culture, and the fluid source unit includes an array of a plurality of medium wells configured to receive a cell culture medium. The pump unit includes an array of pump elements in fluid communication with the cell well and the media well and is configured to deliver cell culture media from the media well to the cell well.

  In a preferred embodiment, each of the cell wells is adapted and configured to accommodate a scaffold having a porous structure. In one embodiment, the scaffold is a two-dimensional scaffold. In other embodiments, the scaffold is a three-dimensional scaffold. In one embodiment, the three-dimensional scaffold can include pores aligned in one direction.

  In one embodiment, fluid can be supplied directly to the internal structure of the scaffold. In other embodiments, a return path is provided so that fluid flows from the array of cell wells to the array of media wells. In a preferred embodiment, each pathway is in fluid communication with a single cell well and a single media well.

  In other embodiments, the perfusion unit can be removably coupled to the pump unit, and each pump element can include a fluid stem having a fluid port therein. Each stem can be configured to extend into the cell well. In other aspects of the invention, each cell well can include a scaffold coupled to it configured to receive a portion of the stem therein. The fluid source unit can also be removably coupled to the pump unit.

  The present invention also provides a method of growing cells comprising delivering a cell culture medium from a first array of a plurality of wells of a fluid source unit to a second array of a plurality of wells of a perfusion unit. And is directed to a method in which each well of the perfusion unit is adapted and configured to contain a cell adhesion structure. In one embodiment, the method further comprises perfusing the medium into the scaffold. In one embodiment, the cell adhesion structure comprises a two-dimensional scaffold, and in other embodiments the cell adhesion structure comprises a three-dimensional scaffold. The first array of multiple wells is in fluid communication with the second array of multiple wells such that the media returns to the second array of multiple wells. In other methods, each well of the first array of multiple wells is independently in fluid communication with a corresponding well of the second array of multiple wells.

  The present invention is also directed to a perfusion bioreactor system comprising an array of multiple bioreactor units. Each bioreactor unit includes a cell adhesion structure that is in fluid communication with the fluid stored in the fluid reservoir, and in operation, fluid flows directly from the fluid source into the cell adhesion structure. In one variation, the cell adhesion structure is a three-dimensional scaffold having a porous structure, and in another variation, the cell adhesion structure is a two-dimensional scaffold. In another preferred embodiment, the cell adhesion structure is fluidly interconnected with the fluid reservoir by a pump unit.

  The present invention relates generally to bioreactors, and more particularly, in a single chamber or high throughput format for discovering complex environments that control cellular function and engineered tissue development at high throughput. The present invention relates to a system and method for culturing cell samples under perfusion. The present invention can also be used to create relevant cell cultures and systems for performing drug tests directly on cells in dynamic cell culture for new drug discovery, drug testing, or ADMETox applications. it can.

  Referring to FIG. 1, a preferred embodiment of a bioreactor system 5 generally includes a multi-well platform with an array of a plurality of bioreactor units 10, each with independent cell exploration or experimentation. Can be implemented. As shown in FIG. 1, the bioreactor system 5 includes a perfusion unit 12 and a fluid source unit 14 that are fluidly interconnected by a pump unit or station 16.

  In a preferred embodiment, the perfusion unit 12 is a multi-well plate that includes a plurality of main chambers or wells 18 configured to contain or contain cell cultures. Similarly, the fluid source unit 14 can include one or more separate multi-well plates that include multiple fluid reservoir chambers or wells 20 for storing fluids such as cell culture media. In operation, each main chamber or well 18 is in fluid communication with a corresponding individual fluid reservoir chamber 20. In a preferred embodiment, upper perfusion unit 12 and fluid source unit 14 include 24 chambers or wells, but in alternative embodiments any number of chambers or wells may be provided. For example, the upper perfusion unit 12 and fluid source unit 14 wells can be miniaturized to include 48 or 96 wells per plate, or even smaller. Similarly, pump components can be miniaturized to form smaller bioreactor systems with similar footprints, and the installation area can be increased to allow more individual It can also have a perfusion unit. Referring to FIG. 2, an example of a multi-well perfusion plate 12 is shown, with each well including a passage or hole 15 extending through the bottom of the well to allow fluid to pass therethrough. A triangular post structure 17 is fixed to the bottom portion of each well 18 and extends above the hole 15. The post structure 17 promotes the attachment of the cell adhesion structure or scaffold 22 (shown in FIG. 4) to grow the cell culture. Each well can also include a fluid return path 19. In a preferred embodiment, the perfusion unit 12 and the fluid source unit 14 can be made from polystyrene, polycarbonate, polypropylene, other plastics, or any other suitable material, divided or totally injection molded. can do.

  In other preferred embodiments, the perfusion unit 12 and fluid source unit 14 are preferably configured and dimensioned to be removably coupled to the pump unit 16. Thus, the perfusion unit 12 and the fluid source unit 14 can be replaceable components of the system so that similar units or plates can be replaced and removed to the pump unit 16 if desired. Can be combined. For example, the fluid source unit 14 is configured to be removably coupled to the pump unit 16 so that the fluid source unit 14 can be reusable or disposable to add media. Similarly, the perfusion unit 12 can be removed from one pump unit 16 and transferred to another pump unit to relate the cell culture to various fluid / dynamic environments.

  The pump unit 16 includes a plurality of fluid connectors and / or an array of metal components to fluidly connect each main chamber 18 and each fluid reservoir chamber 20. In a preferred embodiment, the pump unit or station 16 is from a fluid source unit 14 such as, for example, a motored pump (s), valves, tubes, pipes, other devices or means for delivering or transferring fluid. Any metal component suitable for transferring or delivering fluid to the perfusion unit 12 can be included. In general, any type of pumping mechanism can be used, including but not limited to peristaltic, centrifugal, vibration, piezo, or air or fluid driven pumping mechanisms, or individual electronic pumps. Each perfusion unit can be programmed with a different pump speed. In the particular preferred embodiment shown in FIG. 3, the pump unit or station 16 uses a peristaltic pump mechanism that includes an array of a plurality of pumping plates 30 mounted on a drive rod 32. The rod 32 is slidably mounted on the housing 34 in the bearing 36 and is driven back and forth along the axis of the rod 32 by a motor attached to the coupling plate 38 in operation. When the rod 32 is driven, the pumping plate 30 squeezes the flexible tubing 40 against the fixed plate 42 and sends out the fluid contained in the flexible tubing 40. As best seen in FIG. 4, a unidirectional valve 41 is flexible to direct or direct fluid flow from the fluid reservoir chamber 20 of the fluid source unit 14 to the main chamber 18 of the perfusion unit 12. It is provided on both sides of the sex tubing 40 and is placed between the inlet tube 47 and the outlet tube 49. A return path 19 that fluidly couples the pump unit 16 to the return path 25 to provide fluid return from the perfusion unit 12 to the fluid source unit 14 is incorporated into each main chamber 18 of the perfusion unit 12, thereby providing a plurality of Alternatively, it is preferable to create a series of individual separation bioreactor units 10. In this regard, when the perfusion unit 12 and the fluid source unit 14 are coupled to the pump unit 16, each bioreactor unit 10 becomes a fluidly self-contained entity.

  Referring to FIG. 4, a cross-sectional view of an exemplary individual bioreactor unit 10 is shown, wherein each bioreactor unit is typically a fluid source, eg, contained within a single fluid reservoir chamber or well 20. A single main chamber or well 18 is in fluid communication with. Cell adhesion structures or scaffolds 22 are preferably housed within each main chamber 18 to facilitate the growth of high density cell cultures. In this embodiment, the cell adhesion structure is a three-dimensional scaffold, such as a porous body having a plurality of three-dimensional cell adhesion surfaces, but in an alternative embodiment, the cell adhesion structure is a two-dimensional cell adhesion surface. It can be two-dimensional, such as a slide or plate having. In other alternative embodiments, the cell adhesion structure can be engineered, eg, tubular or cylindrical, so that an implantable medical device / implant with biological components can be engineered with a high-throughput device. It can be of various shapes. In this regard, a tube containing cells or tissues, such as vascular grafts, stents, neural tubes, shunts, etc., for adhering or growing cells and / or tissues on a tubular structure, for example, for implantation into a patient's body. It can be developed. In other embodiments, the cartilage and / or bone can be grown into a predetermined shape or engineered.

  In a preferred embodiment, the cell adhesion structure is coupled to the main chamber around the fluid port 44 so that fluid flows directly into or around the cell adhesion structure. For example, when the perfusion plate 12 is coupled to the pump unit 16, for example, the three-dimensional scaffold 22 is molded to the main chamber 18 so that the stem or fluid port 44 extends into the central portion or interior of the scaffold. , Glue, synthesize, or attach in some other way. In other preferred embodiments, each main chamber 18 of perfusion plate 12 is coupled to, secured to, or otherwise connected to a portion of each main chamber 18 by any suitable means known to those skilled in the art. It is configured to receive a possible scaffold. In a preferred embodiment, the scaffold 22 can be removably inserted or attached to the main chamber 18.

  Scaffolds can be made from any type of polymer, ceramic, metal, or any type of mixture suitable for adhering cells to them. In a preferred embodiment, the scaffold is made from a hydrogel-based material that can be synthesized from a covalently crosslinked alginate, hyaluronic acid, or a blend of two polysaccharides in any desired mixed percentage. For example, the mixing percentage can be adjusted to achieve the desired degradation profile for the end use. In an alternative embodiment, the scaffold can be made of other suitable materials such as those disclosed in US Pat. No. 6,077,097 entitled “Programmable scaffold and methods for making and using same”. The entirety is incorporated herein by reference. In a preferred embodiment, the scaffold can be a porous structure with randomly oriented pores. An alternative embodiment uses a scaffold with unidirectionally aligned pores to obtain a less random pore pattern and to further ensure that fluid flow flows through all of the scaffold pores. can do. In an alternative embodiment, the scaffold is modified by any number or type of cell signaling or cell interacting molecules as disclosed in US Pat. can do.

  In operation, fluid is pumped directly into the internal scaffold structure and can perfuse or flow from the interior 46 of the scaffold 22 to the exterior 48 of the scaffold 22. In a preferred embodiment, the fluid is delivered at a rate in the range of about 10 to 0.1 milliliters per minute. In this regard, the fluid can easily flow through the pores inside the scaffold, rather than bypassing the scaffold and mainly flowing along the exterior of the scaffold. The enhanced diffusion mass transport provided by the perfused fluid flow advantageously diffuses metabolites and nutrients into and out of the scaffold 22. In this regard, perfusion culture allows for long-term tissue engineering experiments, allowing high-density cell culture growth to mimic tissue.

  In prior art devices where fluid is allowed to bypass the scaffold, oxygen is consumed by cells attached to the outside of the scaffold, and cells attached to the inside of the scaffold can become oxygen deficient Oxygen limitation may be caused.

  Referring to FIG. 5, an alternative embodiment of the main chamber 18 is shown where the fluid flow 50 is directed from the inlet 52 and through the alternative scaffold 54 rather than flowing randomly throughout the scaffold. Exit the scaffold and chamber at exit 56.

  Referring to FIG. 6, another alternative embodiment of the bioreactor unit 10 is shown in which the main chamber 18 includes a two-dimensional cell adhesion structure 62 with a cell adhesion top surface. In this embodiment, the cell adhesion structure 62 enters the chamber 18 so that fluid can flow through the fluid port 44 along the path 63, traverse the two-dimensional surface of the structure 62, and return through the return passage 64. Combined. The plate 66 covers the structure 62 and is spaced from the structure 62 for fluid to enter so that the fluid flows directly over the cell adhesion surface.

  Referring to FIG. 7, of the main chamber 18 in which the cell sample 70 can be coupled, secured, or otherwise connected to a portion of each main chamber 18 by any suitable means known to those skilled in the art. Other alternative embodiments are shown. In some embodiments, the cell sample 70 can be a cell adhesion structure or scaffold, and in other embodiments, the cell sample 70 can include a portion or section of tissue. For example, cell sample 70 may be a liver slice, islet, liver spheroid, 3-D tissue model (such as commercially available from Mattek, Inc. or Regenemed, Inc.), 3-D cancer model (such as commercially available from Mina Bissell) ), Cells on microcarriers or fiber disks (such as those commercially available from fibracell), or any other cell body that can be grown in vitro.

  In one embodiment, the cell sample 70 is cylindrical or disk shaped and can be held in place in the main chamber 18 between, for example, a pair of washers 72. Washer 72 includes a central opening for allowing fluid to flow therethrough. In operation, fluid can flow through port 44, perfused through cell sample 70, exit through the central opening of upper washer 72, and return through return path 75. In this regard, this embodiment always keeps the section or cell sample in an elevated state in the medium while at the same time exposing the tissue or cell sample to fluid flow similar to in vivo conditions to provide gas and nutrient transport. Configured to improve. In a preferred embodiment, the system facilitates maintenance of cell viability as well as sample or tissue sections in a drug testing format. The configuration of this embodiment can advantageously be used, for example, with tissue sections or with scaffolds made of polymer or ceramic materials or other materials that cannot be synthesized in place.

  With reference to FIGS. 8-10, another embodiment of a bioreactor system 80 is shown. In general, the bioreactor system 80 includes three parts or components that are disposable or reusable: a bottom reservoir plate 82 configured to contain a medium, a pump device 84 that induces movement of the medium, and a bottom reservoir. A top configured to maintain the position of the tissue section or cell sample 70 in the media flow and to create a closed flow path for the media to return to the bottom reservoir plate 82, mating with the plate and pump device A pneumatic system including a perfusion plate 86. The bottom reservoir plate and the top perfusion plate typically include a number of wells or chambers 83, each plate being injection mouldable and can be a disposable or reusable item. The plate can also be sterilized using any suitable sterilization method known to those skilled in the art. Each well of the perfusion plate 86 generally includes an inlet portion 88 and an outlet portion 90. Each well of the bottom reservoir plate 82 generally includes a fluid reservoir 92 and a pair of one-way or check valves 94. In one embodiment, the one-way valve can be molded into a one-part plate. In order to direct and / or cause fluid or medium to flow from the fluid reservoir 92 to the inlet 88, exit the outlet 90, and back to the fluid reservoir 92, a pair of one-way valves Each is aligned with a corresponding inlet portion 88 and outlet portion 90 of the perfusion plate. In one embodiment, the cell sample 70 can be positioned in the inlet portion 88 of each well of the perfusion plate 86. In one variation, two mesh disks and one retaining ring can be used to hold the tissue section or cell sample 70 in place on the perfusion plate. The optimal geometry and orientation of the cell sample may vary depending on the tissue type. For example, the tissue can be oriented perpendicular or horizontal to the fluid flow.

  The pump device 84 in this embodiment generally includes a pressure chamber 96 having an air inlet 98 and a flexible diaphragm 100 that interacts with the bottom reservoir plate 82. As best seen in FIG. 9, in operation, air pressure is introduced into the pressure chamber 96 through the inlet 98 and the flexible diaphragm 100 expands and exerts pressure on the fluid reservoir 92 of the bottom plate 82 to cause media or fluid flow. Causes upward flow. As shown in FIG. 10, when air pressure is released through the inlet 98, the diaphragm 100 contracts, releasing the pressure applied to the fluid reservoir 92 and drawing or triggering the downward flow or return flow of the medium or fluid. To do. One advantageous feature of this embodiment is that the medium or fluid is not gravity driven but is self-purging or active draining. In this regard, after the perfusion plate wells are filled with media or fluid, the pump device 84 purges the perfusion plate wells during operation. In one embodiment, the pump device can be disposable or reusable. The pump device can also be sterilized using any suitable sterilization method known to those skilled in the art. Several variations of multi-well plate pump devices can also be used, including electrical, peristaltic, and other diaphragm pump technologies known to those skilled in the art.

  With reference to FIGS. 11-12, another embodiment of a bioreactor system 110 is shown. In general, the bioreactor system 110, like the bioreactor system 80, induces movement of the medium with three parts or components that are disposable or reusable: a bottom reservoir plate 112 configured to contain the medium. A pump device 114 that mates with the pump device to maintain the position of the tissue section or cell sample 70 in the media flow and to create a closed flow path for the media to return to the bottom reservoir plate 112 A pneumatic system that includes a configured upper perfusion plate 116. The bottom reservoir plate 112 and the top perfusion plate 116 are substantially similar to the previously described plates 82, 86 and generally include a number of wells or chambers 113. Each plate can be injection molded and can be a disposable or reusable item. The plate can also be sterilized using any suitable sterilization method known to those skilled in the art. Each well of perfusion plate 116 generally includes an inlet portion 118 and an outlet portion 120. Each well of the bottom reservoir plate 112 generally includes a fluid reservoir 122 and a pair of one-way or check valves 124. In one embodiment, the one-way valve can be molded into a one-part plate. A pair of one-way valves 124 are used to direct and / or flow fluid or medium from the fluid reservoir 122 to the inlet 118, exit the outlet 120, and back to the fluid reservoir 122. , Respectively, through a flexible passage or tubing 132 and another pair of one-way valves 125, coupled to corresponding inlet and outlet portions 118 and 120 of the perfusion plate. In one embodiment, the cell sample 70 can be positioned in the inlet portion 118 of each well of the perfusion plate 116. In one variation, two mesh disks and one retaining ring can be used to hold the tissue section or cell sample 70 in place on the perfusion plate. The optimal geometry and orientation of the cell sample may vary depending on the tissue type. For example, the tissue can be oriented perpendicular or horizontal to the fluid flow.

  The pump device 114 of this embodiment generally includes a pressure chamber 126 having an air inlet 128 and a plurality of flexible diaphragms 130 surrounding the flexible passageway 132. The flexible passageway 132 extends between the bottom plate fluid reservoir 122 and a pair of one-way or check valves 125 aligned with the inlet portion 118 and outlet portion 120 of the perfusion plate 116. As best seen in FIG. 12, in operation, air pressure is introduced into the pressure chamber 126 through the inlet 128, causing the flexible diaphragm 130 to expand and exert pressure on the flexible passage or tubing 132, causing the perfusion plate 116 to It causes an upward flow of media or fluid through the inlet portion 118 and simultaneously a downward flow of media or fluid exiting the perfusion plate 116 and through the outlet portion 120 to the fluid reservoir 122. One advantageous feature of this embodiment is that the medium or fluid is not gravity driven but is self-purging or active draining. In this regard, after the perfusion plate well has been filled with media or fluid, the pump device 114 purges the perfusion plate well during operation. In one embodiment, the pump device can be disposable or reusable. The pump device can also be sterilized using any suitable sterilization method known to those skilled in the art. Several variations of multi-well plate pump devices can also be used, including electrical, peristaltic, and other diaphragm pump technologies known to those skilled in the art.

  For all the multi-well bioreactor systems described above, various cell types can be cultured in the same set of wells. For example, in the embodiment of FIG. 4, hepatocytes can be cultured in the fluid reservoir chamber 20 while islet cells can be cultured in the main chamber 18. The cells are in fluid communication with the medium contained in the bioreactor unit 10 of FIG. In other variations, multiple parallel wells can be in fluid communication with each other. For example, referring to the embodiment of FIG. 1, hepatocytes can be cultured in well A1 of FIG. 1, while islet cells can be cultured in well D6 of FIG. Since all wells can be flowably connected together by channels or other fluid pathways, after a certain amount of time, the media from wells A1, D6 and many of the fluidly communicating wells mix together and become stationary May be in a state.

  Using the multi-well bioreactor system of the present invention described above, unique experiments incorporating fluid flow can be performed. For example, a number of parallel experiments with approximately similar fluid flow characteristics can be performed. In this regard, very complex environments can be created to perform experiments in medium or high throughput formats. Also, those skilled in the art will create a culture consisting of several types of cells and tissue systems in fluid communication to explore complex metabolic diseases such as diabetes, obesity and cardiovascular disease, to name a few. You can also. One particular application of optimizing the cell signaling environment includes growth factors, cytokines, extracellular matrix molecules to facilitate the discovery of the optimal combination of factors to obtain a fully differentiated cell culture in vitro. Various soluble and non-soluble signaling molecules consisting of, etc. can be tested at various concentrations, at various mixing ratios, and at various time points. These environments can be created using a variety of parenchymal and non-parenchymal cells from tissues including bone marrow, vasculature, skin, pancreas, liver, bone, cartilage, smooth muscle, cardiac muscle, skeletal muscle, kidney, etc. it can. In other embodiments, cells such as endothelial cells can be used to effect vascularization by the host. In alternative embodiments, one skilled in the art can also create cultures consisting of several types of tissue systems to explore complex metabolic diseases such as metabolic syndrome. In alternative applications, several cells are used to explore fluid shear and perfusion, for example to determine the fluid flow most likely to promote cell type separation for angiogenesis and tissue development. You can incorporate types. In other applications, cells or tissues grown in a multi-well design can be used to perform drug tests directly on cells in dynamic cell culture, either in drug discovery, drug testing, or ADMETox applications, It can be used as a platform for testing drugs in medium to high throughput formats. In addition, sensing technology can be incorporated into the bioreactor system. For example, biosensing techniques that sense important cell culture variables such as glucose, ammonia, urea, pH, or general fluorescence detectors that monitor the metabolism of fluorescent compounds can be used with the system.

  In one exemplary variation or application, the perfusion unit 12 can be used to grow cell cultures with preset conditions or particularly desirable characteristics, which are later used for further experimentation and / or discovery. be able to. The modularity and interchangeability of the perfusion unit 12 advantageously allows multiple cells that can be easily re-installed on another pump station 16 or similar device for further experimentation and / or drug testing or discovery. Allows the shipment and / or transfer of the culture.

  Referring now to FIGS. 17-22, systems and methods for manipulating or handling a scaffold in a platform for performing biological experiments in a high throughput and / or parallel screening environment are shown. As shown in FIGS. 17 and 18, one preferred embodiment of the scaffold handling system 201 generally includes a multi-well cartridge or carrier 205 comprising an array of a plurality of well units 210, with each well unit being independent. Scaffolding 220 can be retained and biological experiments can be performed. As shown in FIG. 17, in one embodiment, the carrier 205 of the scaffold handling system 201 includes four well units 211, 212, 213, and 214, and is distal from the side end of the cross member 217. And include sidewalls or flanges 216 and 218 for mating with the multi-well plate. However, in alternative embodiments, any number or multiple well units 210 can be included in the carrier 205. For example, in one variation, the carrier 205 can have one well unit. In other exemplary embodiments, the carrier 205 can have eight well units. In other embodiments, the carrier 205 can have three well units.

  Each well unit 210 generally includes a frustoconical or tapered body 230 extending distally from the top of the carrier 205 and includes a scaffold holding chamber 232 at the distal end 234. A cell adhesion structure or scaffold 220 is preferably housed or retained within each well unit 210 to facilitate the growth of high density cell cultures. In a preferred embodiment, the cell adhesion structure is coupled to or packed into the well unit 210 around the distal end 234. For example, the three-dimensional scaffold 220 can be coupled, molded, glued, synthesized, or attached in some other manner to the distal chamber 232. In a preferred embodiment, the scaffold 220 can be removably inserted or attached to the chamber 232, for example, by a friction fit.

  Referring to FIG. 19, a bottom perspective view of the carrier 205 depicting one of the well units 210 is shown. In one embodiment, the scaffold holding chamber 232 is tapered, ie, wide at the distal end of the well unit and narrow at the top or proximal end of the chamber. This taper feature of chamber 232 can accommodate a wide range of scaffold sizes. For example, in one embodiment, chamber 232 can accommodate a scaffold in the range of about 4.8 mm to about 5.1 mm in diameter. In addition, one or more nubs or protrusions 236 can extend radially inward from the periphery of the chamber 232 to further grip or hold the scaffold within the chamber by friction.

  Referring to FIG. 20, a top perspective view of the carrier 205 depicting one of the well units 210 is shown. The upper or proximal end of each well unit 210 defines an opening 237 to allow physical and visual access to the scaffold 220 held therein. In addition, a window 238 extends in the carrier 205 adjacent to the well unit 210 to provide access to the bottom of the well therethrough. In this regard, the open top of each well unit 210, ie, opening 237 and window 238, facilitates aspiration or pipetting within the well unit. As best seen in FIGS. 20 and 21, in one embodiment, longitudinal slots, channels, or openings 239 extend along the sides of the body 230. The opening 239 facilitates fluid overflow and allows perfusion circulation when the carrier 205 is used in conjunction with a perfusion bioreactor. This will be described in more detail below. As can also be seen from FIG. 21, the ledge 241 is adjacent to the distal end of the body 230 to hold the scaffold 220 longitudinally, contain cells and contain a screen to minimize particulate flow. Can be provided. For example, as shown in FIG. 22, the screen 250 can be positioned and / or molded adjacent to the ledge 241 to prevent movement of the proximal scaffold 220 while allowing fluid to flow therethrough.

  The scaffold handling system 201 and carrier 205 of FIGS. 17 and 18 are configured and dimensioned to be used with a multi-well plate having a plurality of main chambers or wells to contain or contain a cell culture or cell culture laboratory apparatus. Is set. Multiwell plates are well known to those skilled in the art. Exemplary multi-well plates include BD Falcon ™ multi-well plates, where 24-well plates and 96-well plates are available. In this regard, the carrier 205 of this embodiment is configured and dimensioned to be inserted into and / or mated with such a 24-well plate. In operation, the carrier 205 is transferred to a single well of the 24-well plate with each well unit 211, 212, 213, and 214 extending to the corresponding well of the 24-well plate so that biological experiments can be performed. Can be installed across rows. A number of carriers 205 can be placed over another row of the multi-well plate so that the scaffold can be held within each well of the multi-well plate. In other words, in the case of a 24-well plate, six carriers 205 can be used with the 24-well plate. Of course, those skilled in the art will appreciate that any number of arrays and configurations can be used so that the entire multi-well plate can include a cell adhesion scaffold.

  The side walls or flanges 216, 218 of the carrier 205 extend distally from the sides of the carrier 205 and are configured to extend around the outer portion of the multi-well plate to precisely mate the carrier 205 with the 24-well plate and Dimensions are set. As best seen in FIG. 18, the flanges 216 and 218 can have chamfered edges 219 to facilitate repositioning relative to the multiwell plate. In addition, as best seen in FIG. 19, one or more nabs, locating pins, or protrusions 240 are attached to the carrier 205 to facilitate alignment of the carrier 5 with individual wells of the multi-well plate. It can be provided on the back surface of. In this regard, the combination of protrusions 240, flanges 216 and 218, and carrier 205 geometry provides a reliable and reproducible system for holding the scaffold in place against the multiwell plate. .

  In other embodiments, the scaffold handling system 201 and carrier 205 of FIGS. 17 and 18 can also be used with the multi-well plate of the perfusion bioreactor described above. In this regard, the carrier 205 of this embodiment is configured and dimensioned to be inserted into and / or mated with such a multiwell plate of a perfusion bioreactor. In the same manner as described above for the 24-well plate, in which each well unit 211, 212, 213, and 214 extends to a corresponding well of the bioreactor multi-well plate so that biological experiments can be performed. Thus, the carrier 205 can be placed across a single row of multi-well plates of a perfusion bioreactor. In this regard, the configuration and design of the handling system 201 is advantageously configured to allow perfusion of the cell culture medium through the scaffold. For example, reliable and reproducible positioning of the carrier 205 is within the flow line of the perfusion bioreactor so that cell culture medium flows from the distal end through the scaffold to the proximal end of each well unit 210. It is configured to hold the scaffold (s) 220. The overflow channel or opening 239 facilitates the return flow of the perfusion medium through the proximal side of the scaffold 220.

  Referring again to FIG. 17, an exemplary method for handling or manipulating one or more scaffolds 220 in accordance with the present invention is shown. As shown with respect to the well unit 211, as an initial step, a scaffold 220 or multiple scaffolds can be packed or inserted into the well unit 210 of the carrier 205. As shown with respect to the well unit 212, once installed or packed into the carrier 205, the scaffold (s) 220 may be treated with chemicals, UV sterilization, cell seeding, or other treatments, etc. Can be operated by. Similarly, as shown with respect to well unit 213, a biological experiment can be performed with the scaffold inserted into a multi-well plate with cell culture medium or biological agent. As shown with respect to the well unit 214 of FIG. 17, the medium can be perfused through the scaffold (s) 220. Also, if microscopy is required, the carrier 205 can be easily transferred to a separate or new dry plate for microscopy without the need to handle the scaffold directly.

  Referring to FIG. 8, an example of a cell biology experiment performed in accordance with the present invention is shown, in which primary rat hepatocytes are seeded on an alginate scaffold in a perfusion chamber and Hepatostim medium is added. And cultured under perfusion. The same cells are also seeded on a Matrigel alginate substrate (usually known to maintain the basal CYP 3A1 activity of rat hepatocytes), and a passively coated collagen type 1 substrate is used as a negative control. (Usually known to reduce basal CYP 3A1 activity in rat hepatocytes). After 48 hours, 100 uM cortexolone was added to the medium to induce CYP 3A1 expression. Once weekly, HPLC analysis was used to monitor basal 3A1 activity by metabolizing testosterone to 6B-hydroxytestosterone. Thus, the level of 6B-hydroxytestosterone in the culture is indicative of CYP 3A1 expression and activity. Collagen cultures did not express CYP 3A1, and Matrigel cultures helped hepatocytes maintain CYP 3A1 expression for 3 weeks, but expression decreased at 3 weeks. Hepatocytes cultured under flow conditions on an alginate scaffold still maintained high CYP 3A1 activity, but did not decrease at 4 weeks, but increased dramatically compared to Matrigel. This example demonstrates that cells can be grown with this device configuration, and the new culture conditions allow long-term and higher expression of differentiation-specific cell functions for primary rat cells It is suggested that Under perfusion, critical p450 3A1 function is maintained over a 4 week period longer than industry standard Matrigel cultures.

  Referring to FIG. 14, an example of a cell biology experiment performed in accordance with the present invention is shown, in which mouse osteoblasts (MC3T3) are seeded on a calcium phosphate scaffold and used with Gibco Alpha medium. And cultured under perfusion. The same cells were also seeded on calcium phosphate scaffolds under static conditions. The metabolic activity of the cells was probed by absorbance under static and perfusion conditions for 15 days. After 15 days, perfused cells show a statistically significant 34% increase in metabolic activity over cells in static conditions.

  Referring to FIG. 15, an example of a cell biology experiment performed in accordance with the present invention is shown, in which human mesenchymal stem cells (MSCs) are seeded on a calcium phosphate scaffold and osteogenic medium is used. And cultured under perfusion. The same cells were also seeded on calcium phosphate scaffolds under static conditions. The metabolic activity of the cells was probed by absorbance under static and perfusion conditions for 10 days. After 10 days, perfused cells show a statistically significant 42% increase in metabolic activity over cells in static conditions.

  Referring to FIG. 16, an example of a cell biology experiment performed in accordance with the present invention is shown in which rat liver sections were cultured under perfusion flow using Gibco medium. Sections were also cultured under static conditions. The metabolic activity of the cells was probed by absorbance under static and perfusion conditions for 5 days. After 5 days, the perfused section shows a statistically significant increase in metabolic activity of 136% over that of the static condition.

  Although the invention has been described with reference to particular embodiments and examples thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art upon reading this disclosure. Accordingly, it is intended to embrace all such alternatives, modifications and variations that fall within the spirit and broad scope of the appended claims.

1 is an exploded view of a first embodiment of a bioreactor system according to the present invention. FIG. FIG. 2 is a perspective view of an embodiment of the perfusion unit of the bioreactor system shown in FIG. 1. It is a perspective view of one Embodiment of the pump unit of the bioreactor system shown in FIG. FIG. 2 is a cross-sectional exploded view of the bioreactor unit of the system of FIG. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. FIG. 6 is a cross-sectional view of another embodiment of a bioreactor system according to the present invention. 2 is a graphical representation of an example of a cell biology experiment performed in accordance with the present invention showing hepatocyte growth on a scaffold using perfusion. 4 is a graphical representation of another example of a cell biology experiment performed in accordance with the present invention. 4 is a graphical representation of another example of a cell biology experiment performed in accordance with the present invention. 4 is a graphical representation of another example of a cell biology experiment performed in accordance with the present invention. 1 is a side view of an embodiment of a system according to the present invention. FIG. 18 is a perspective view of one embodiment of the carrier of the system of FIG. FIG. 19 is a partial perspective view of the carrier of FIG. 18 depicting a single well as seen from the bottom. FIG. 19 is a partial perspective view of the carrier of FIG. 18 depicting a single well as viewed from the top. FIG. 19 is a partial side view of a single well of the carrier of FIG. 18 shown without a screen. FIG. 19 is a partial side view of a single well of the carrier of FIG. 18 shown with a screen.

Claims (27)

A bioreactor system comprising:
A perfusion unit comprising an array of a plurality of cell wells configured to receive a cell culture;
A pump unit comprising an array of pump elements in fluid communication with the cell well;
A fluid source unit comprising an array of a plurality of media wells configured to contain cell culture media;
The system wherein the medium well is in fluid communication with the pump element, the pump element being configured to deliver cell culture medium from the medium well to the cell well.   The system of claim 1, wherein each of the cell wells is adapted and configured to receive a scaffold having a porous structure.   The system of claim 2, wherein each of the cell wells is adapted and configured to accommodate a two-dimensional scaffold.   The system of claim 2, wherein each of the cell wells is adapted and configured to accommodate a three-dimensional scaffold.   The system of claim 4, wherein the three-dimensional scaffold includes pores aligned in one direction.   The system according to claim 4, wherein the scaffold has a tubular shape.   The system of claim 2, wherein fluid can be directly supplied to the internal structure of the scaffold.   8. The system of claim 7, further comprising at least one return path for the fluid to flow from the array of cell wells to the array of media wells.   9. The system of claim 8, further comprising a plurality of return paths, each return path in fluid communication with a single cell well and a single media well.   The system of claim 1, wherein the perfusion unit is removably coupled to the pump unit.   11. The system of claim 10, wherein each pump element includes a fluid stem having a fluid port therein, each stem adapted and configured to extend into the cell well.   The system of claim 11, wherein each cell well includes a scaffold coupled to it configured to receive a portion of the stem therein.   The system of claim 1, wherein the fluid source unit is removably coupled to the pump unit.   The system of claim 1, wherein the pump element includes at least one one-way valve and is operable by air pressure.   And further comprising a scaffold carrier cartridge comprising an array of a plurality of well units, wherein a cell adhesion scaffold can be positioned within each well unit, wherein the cartridge is aligned with the cell wells of the perfusion unit. The system of claim 1, wherein the system can be coupled to the perfusion unit. A method of growing cells,
Delivering a cell culture medium from a first array of wells of the fluid source unit to a second array of wells of the perfusion unit, each well of the perfusion unit containing a cell sample A method characterized in that it is adapted and configured.   The method of claim 16, wherein the cell sample comprises a cell adhesion structure.   The method of claim 17, wherein the cell adhesion structure is a scaffold, and the method further comprises the step of perfusing the medium into the scaffold. A perfusion bioreactor system comprising:
An array of bioreactor units, each bioreactor unit including a cell adhesion structure in fluid communication with a fluid stored in a fluid reservoir, wherein in operation fluid flows from the fluid source to the cells System that flows directly into the adhesive structure.   The system of claim 19, wherein the first bioreactor unit is in fluid communication with the second bioreactor unit.   The system of claim 19, wherein the cell adhesion structure is fluidly interconnected with the fluid reservoir by a pump unit. A plate for use in cell culture experiments,
A plurality of chambers configured to contain cell cultures;
Each chamber includes a fluid port and a cell sample attached to the chamber around the fluid port.   The plate according to claim 22, wherein the cell sample includes a cell adhesion structure.   23. The plate of claim 22, wherein the cell culture is grown under flow conditions.   The plate according to claim 23, wherein the cell adhesion structure is a three-dimensional scaffold having a porous structure.   The plate according to claim 23, wherein the cell adhesion structure has a tubular shape.   The plate according to claim 23, wherein the cell adhesion structure is a two-dimensional scaffold.

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