CONTINUOUS PROCESSING METHODS FOR BIOLOGICAL PRODUCTS
The present invention is directed to the development of continuous processing technology for the purification of biopharmaceuticals and biological products, such as monoclonal antibodies, protein therapeutics, and vaccines. Methods for continuous processing of a biological product in a feed stream toward formulation of a purified bulk product are described.
This application claims priority to U.S. Provisional Application No. 61/420,066 filed Dec. 6, 2010, the entire contents of which are incorporated herein by reference.
FIELD OF THE INVENTIONThe present invention is directed to the development of continuous processing technology for the production of biopharmaceutical and biological products, such as monoclonal antibodies and vaccines.
BACKGROUND OF THE INVENTIONContinuous processes are widely used in several industries, for instance the petrochemical, fine chemical, and agricultural processing industries. Distillation, plug flow reactions, chromatography, and adsorptive separations are all operated in continuous modes in large-scale industrial applications. For example, a well known large-scale simulated moving bed (SMB) purification process is the so-called Parex process, which separates para-xylene from a mixture of xylenes. This process is based on the Sorbex SMB technology developed and commercialized by UOP LLC (Des Plaines, Ill. (US)). Other notable examples of SMB or related continuous, counter-current chromatographic techniques are the purification of fructose from a mixture of glucose and fructose (which is used in the production of high fructose corn syrup); the recovery of sucrose and betaine from molasses; the purification of various carboxylic acids and amino acids; as well as the production of potassium nitrate for fertilizer.
One industry that has not benefitted significantly from continuous processing technology is the biopharmaceutical industry, where the final drug product is usually a large molecule (i.e., ≧3 kD) and must undergo several steps aimed at purification and, ultimately, sterilization. Until recently, the majority of biopharmaceutical and biological products have been manufactured and purified at very modest scale, obviating the need for moving away from inherently inefficient batch processing techniques. In recent years, however, the commercial success of the first monoclonal antibody therapeutics, coupled with the desire to implement fully disposable or single-use components in manufacturing processes, has driven increased interest in more efficient processing technologies.
Advances in simulated moving bed separation processes, such as the integrated BioSMB™ system (Tarpon Biosystems, Inc., Worcester, Mass. (US)), have made it possible to convert separation process steps that were traditionally operated in batch mode into SMB processes that can be run continuously, taking a clarified feed and purifying in a continuous fashion a target molecule such as a monoclonal antibody or a vaccine to yield a purified intermediate product ready for additional downstream processing toward a final, purified bulk drug product and finally a packaged, sterile pharmaceutical product. The BioSMB™ system provides a flexible, programmable system for replacing a batch purification process step. It provides the advantages of great reductions in scale of operations, great reductions in solvent use and the amount of chromatography media required, and the ability to employ fully disposable components (thereby reducing the investment in stainless steel components, as well as minimizing downtime otherwise taken up in cleaning and refurbishing permanent components).
The capabilities for continuous processing afforded by improved SMB systems has led to increased interest in converting other stages of the overall biopharmaceutical processing to continuous processing methods. Production of a biopharmaceutical typically begins with production of the proteinaceous product in a bioreactor, followed by many stages, or unit operations, each designed to separate the product from undesired components and impurities.
Interest in the use of single-use or “disposable” technologies has increased significantly in recent years due to the time and capital savings offered by these technologies along with other benefits. However, as the capacity of industrial scale disposable bioreactors has leapt forward, the equipment designs for disposable downstream processing (that is, processing of the culture grown in a bioreactor to end in a final packaged product) have lagged behind. For example, while new bioreactors capable of 2,000 liter cell cultures are now on the market and 5,000 liter capacity disposable bioreactors are being designed, the largest disposable downstream chromatography columns currently available are not large enough (ca. 30 cm diameter) to process the output from a modern “high titer” (e.g., 5 g/L of target protein) 2,000 liter disposable bioreactor run. A cell culture grown in a 2,000 liter bioreactor having a concentration of protein product at 5 g/liter or higher, may provide more than 10 kg of protein material for purification.
Continuous processing would permit significant reductions in the scale of equipment needed downstream from the bioreactor, and accordingly the need for novel methods of continuous processing for all phases of biopharmaceutical production is acute.
SUMMARY OF THE INVENTIONThe present invention is related to the development of a novel continuous processing technology (CPT) for the purification of biopharmaceuticals and biological products for increasing manufacturing productivity and efficiency in the biopharmaceutical industry.
The novel CPT processes described herein have been developed for the purification of biopharmaceuticals and will advantageously allow for an entire purification process to be operated continuously using disposable processing elements.
A preferred element for the design of continuous processing systems is the utilization of multi-valve arrays, preferably in the form of an integrated valve cassette or manifold. Such valve cassettes are illustrated by the BioSMB™ system, which integrates dozens of diaphragm-style valves into a single disposable block, resulting in an “integrated circuit” approach to fluid control in continuous chromatography applications. See, e.g.,
The block flow diagram shown in
In one embodiment, the present invention is directed to a process for the production of a biological product comprising:
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- (a) continuously transferring a biological product-containing solution to a first unit operation capable of separating the solution into two or more fractions comprising at least one fraction containing said biological product and at least one fraction containing one or more components of the biological product-containing solution desired to be separated from said biological product, wherein said first unit operation has at least one inlet and at least one outlet and is configured to permit continuous fluid flow between said at least one inlet and at least one outlet;
- (b) continuously transferring the flow from at least one outlet of said first unit operation to a second unit operation having at least one inlet for receiving flow from at least one outlet of said first unit operation, said flow from said first unit operation comprising said biological product, said second unit operation capable of separating the product received through said at least one inlet into two or more fractions comprising at least one fraction containing said biological product and at least one fraction containing one or more components of the product received through said at least one inlet desired to be removed from said biological product, and wherein said second unit operation further has at least one outlet and is configured to permit continuous flow between said at least one inlet and at least one outlet, and wherein the throughput of said second unit operation is equal to the output flow received from said first unit operation; and
- (c) recovering a fluid fraction containing said biological product.
According to this embodiment, independently for each transferring step, the transferring step comprises directing the flow from the preceding unit operation to an intermediate storage vessel, wherein the vessel has a holding capacity equal to or less than half of the volume received from the preceding unit operation during processing of one entire lot.
In another embodiment, the present invention is directed to a method for the manufacture of a biological product in a continuous process system comprising the steps of:
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- (a) producing conditioned media containing a biological product in a bioreactor;
- (b) continuously removing cells and cell debris from the conditioned media to produce a clarified solution comprising the biological product;
- (c) continuously transferring the clarified solution to a first unit operation, the operation comprising a capture chromatography process comprising
- (1) contacting said product solution with an affinity ligand capable of complexing with said biological product and
- (2) dissociating complexes of the affinity ligand and said biological product formed in said contacting step to produce a purified biological product solution;
- (d) continuously transferring the purified biological product solution to a second unit operation comprising a low pH incubation process comprising
- (1) collecting at least part of the purified biological product solution in an incubation receptacle,
- (2) adjusting the pH of the purified biological product solution to a pH calculated to inactivate any viruses contained in the solution, and
- (3) readjusting the pH of the purified biological product solution to produce a virus-inactivated biological product solution;
- (e) continuously transferring the virus-inactivated biological product solution to a series of additional downstream processing steps, which at least comprises one anion exchange chromatography process;
- (f) continuously transferring the product of the downstream process to a sixth unit operation comprising a nanofiltration process; and
- (g) continuously transferring the product of the nanofiltration process to a seventh unit operation comprising microfiltration through a 0.2 μm filter to produce a stable purified biological product.
In one embodiment the removal of cells and cell debris in step (b) is carried out by a centrifugation process.
In another embodiment of the method, the first unit operation is a simulated moving bed affinity chromatography process.
In another embodiment, the present invention is directed to a method for incubating a solution for a controlled period of time, the method comprising:
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- (a) continuously transferring the biological product solution into a first incubation receptacle;
- (b) adjusting the solution conditions to achieve the desired incubation conditions in the first receptacle;
- (c) continuously transferring the content of the first receptacle into a second receptacle or alternatively, into a series of receptacles, or a length of tubing, with a collective volume for a desired residence time;
- (d) continuously transferring the content of the second receptacle into a third receptacle; and
- (e) adjusting the solution conditions to the desired conditions for the subsequent or next unit operation.
In yet another embodiment, the present invention is directed to a method for incubating a biological product solution at desired solution conditions for a controlled period of time and within a desired tolerance time window, the method comprising:
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- (a) continuously transferring the biological product solution into a series of incubation receptacles wherein the volume of each receptacle is equal to or less than the flow rate times the desired tolerance time;
- (b) discontinuing flow to the inlet of said receptacle and adjusting the solution conditions to the desired incubation solution condition in said receptacle while mixing to ensure solution homogeneity;
- (c) holding each receptacle for the desired incubation time;
- (d) readjusting the solution conditions in each receptacle to the desired conditions for processing in the subsequent unit operation, while mixing to ensure solution homogeneity; and
- (e) transferring the incubated biological product solution from each receptacle to the subsequent unit operation
In yet another embodiment, the present invention is directed to an apparatus for connecting two or more unit operations of a manufacturing process for continuous processing, the apparatus comprising:
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- (a) a valve manifold providing at least three fluid transmission channels comprising a central channel traversing said valve manifold and having an inlet end and an outlet end, a priming channel connecting a separate inlet with said central channel, and a bypass channel connecting a separate outlet with said central channel, each of the channels having at least one independently actuatable valve for independently opening or closing the channel, the central channel inlet being suitable for receiving throughput from an upstream unit operation, and the priming channel inlet being suitable for receiving fluid for filling the priming channel and the central channel; and
- (b) at least one surge receptacle having at least one inlet and at least one outlet, said surge receptacle inlet being connected to the central channel outlet of said valve manifold, and said at least one surge receptacle having the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
In one embodiment, the surge receptacle further comprises a vent outlet communicating the inside of said receptacle with the ambient environment. In one embodiment, a filter may be interposed between said vent outlet and the ambient environment, and wherein the vent outlet further comprises a valve for opening and closing the outlet. Further, the surge receptacle outlet may be connected to a pump.
In another embodiment, the bypass channel of the apparatus is connected to a bypass collection receptacle having the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
In yet another embodiment, the present invention is directed to an apparatus for connecting two or more unit operations of a manufacturing process for continuous processing, the apparatus comprising:
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- (a) a valve manifold providing at least five fluid transmission channels comprising a central channel traversing the valve manifold and having an inlet end and an outlet end, a priming channel connecting a separate inlet with the central channel, a surge receptacle inlet channel connecting a separate inlet with the central channel, a surge receptacle outlet channel connecting a separate outlet with the central channel, and a bypass channel connecting a separate outlet with the central channel, and wherein each of the five channels has at least one independently actuatable valve for independently opening or closing the channel, the central channel inlet being suitable for receiving throughput from an upstream unit operation, said priming channel inlet being suitable for receiving fluid for filling said priming channel and said central channel;
- (b) at least one surge receptacle having at least one inlet and at least one outlet, wherein a surge receptacle inlet is connected to the surge receptacle outlet channel of the valve manifold, and a surge receptacle outlet is connected to the surge receptacle inlet channel of the valve manifold, and wherein the at least one surge receptacle has the capacity to hold the throughput of a unit operation connected to the valve manifold central channel inlet. The at least one surge receptacle may further comprise a vent outlet communicating the inside of said receptacle with the ambient environment. In one embodiment, a filter is interposed between the vent outlet and the ambient environment, and wherein the vent outlet further comprises a valve for opening and closing said outlet. In another embodiment, the connection between the surge receptacle outlet and the surge receptacle inlet channel of the valve manifold is equipped with a pump for regulating fluid flow along the connection.
In yet another embodiment, the bypass channel outlet of the apparatus is connected to a bypass collection receptacle having the capacity to hold the throughput of a unit operation connected to the valve manifold central channel inlet.
In another embodiment, the present invention is directed to a continuous processing system comprising:
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- (a) a first apparatus for carrying out a first unit operation, the apparatus comprising:
- (1) a plurality of valve modules, each module having a central channel traversing the module and a plurality of branch channels connecting the central channel with the outside of the valve module, wherein each of the channels has at least one independently actuatable valve for independently opening or closing the channel, and wherein the valve of the central channel separates the inlet end of the central channel from the outlet end of the central channel, and wherein at least two branch channels connect separate inlets to the valve module with the central channel on the inlet side of the central channel valve and at least two branch channels lead from the central channel on the outlet side of the central channel valve to separate outlets from the valve module;
- (2) a plurality of solution conduits, each conduit connecting to a separate branch channel of each valve module, and
- (3) a plurality of chromatography columns, each column having an inlet and an outlet, wherein the column inlet is connected to the inlet end of a valve module central channel and the column outlet is connected to the outlet end of the central channel of a different valve module, such that the plurality of columns is connected in series through intervening valve modules and wherein the outlet of the last column in the series is connected, via an intervening valve module, to the inlet of the first column in the series;
- (b) a second apparatus for carrying out a second unit operation comprising:
- (1) one or more incubation receptacles each having at least one inlet and at least one outlet, wherein collectively the one or more incubation receptacles has at least the capacity to hold the output of said first unit operation;
- (2) a valve module comprising an inlet and an outlet, an inlet channel connected to the valve module inlet, and one or more inlet branch channels connecting with the inlet channel, wherein each inlet branch channel leads from the inlet channel and connects to an inlet of one of the one or more incubation receptacles, and wherein each of the inlet branch channels has at least one independently actuatable valve for independently opening or closing the channel, the valve module further comprising an outlet channel leading to the valve module outlet, and one or more outlet branch channels connecting with the outlet channel, wherein each outlet branch channel leads from the outlet channel and connects to an outlet of one of the one or more incubation receptacles, wherein each of the outlet branch channels has at least one independently actuatable valve for independently opening or closing the channel; and
- (c) a third apparatus, for connecting the output of said first apparatus to the inlet of said second apparatus, the third apparatus comprising:
- (1) a valve module providing at least five fluid transmission channels comprising a central channel traversing the valve module and having an inlet end and an outlet end, a priming channel connecting a separate inlet with the central channel, a surge receptacle inlet channel connecting a separate inlet with the central channel, a surge receptacle outlet channel connecting a separate outlet with the central channel, and a bypass channel connecting a separate outlet with the central channel, and each of the five channels having at least one independently actuatable valve for independently opening or closing the channel, wherein the central channel inlet is connected to an outlet branch channel of each of the plurality of valve modules of the apparatus of said first unit operation, the priming channel inlet being suitable for receiving fluid for filling the priming channel and the central channel,
- (2) at least one surge receptacle having at least one inlet and at least one outlet, wherein a surge receptacle inlet is connected to the surge receptacle outlet channel of the valve module, and a surge receptacle outlet is connected to the surge receptacle inlet channel of the valve module, and wherein the at least one surge receptacle has the capacity to hold the output of the apparatus of the first unit operation, and wherein the central channel outlet of the valve module is connected to the inlet of the valve module of the apparatus for carrying out the second unit operation.
- (a) a first apparatus for carrying out a first unit operation, the apparatus comprising:
In one embodiment of the continuous processing system, the at least one surge receptacle and/or the one or more incubation receptacles further comprises a vent outlet communicating the inside of the receptacle with the ambient environment. In one embodiment, a filter is interposed between the vent outlet and the ambient environment, and wherein the vent outlet further comprises a valve for opening and closing the outlet. In yet another embodiment, the connection between the surge receptacle outlet and the surge receptacle inlet channel of the valve manifold is equipped with a pump for regulating fluid flow along said connection.
In another embodiment of the continuous processing system of the present invention, the bypass channel outlet is connected to a bypass collection receptacle having the capacity to hold the throughput of a unit operation connected to the valve manifold central channel inlet.
In yet another embodiment of the continuous processing system described herein, the plurality of valve modules of the apparatus for carrying out the first unit operation are integrated into a master valve manifold.
In yet another embodiment of the continuous processing system described herein, the one or more incubation receptacles is equipped with means for mixing the contents of the receptacle. For example, the means for mixing the contents of the receptacle may be a rocker table.
In another embodiment of the continuous processing system described herein, any of said receptacles may be a single-use receptacle.
The novel CPT processes described herein have been developed for the purification of biopharmaceuticals and will advantageously allow for an entire purification process to be operated continuously using disposable processing elements.
A preferred element for the design of continuous processing systems is the utilization of multi-valve arrays, preferably in the form of an integrated valve cassette or manifold. Such valve cassettes are illustrated by the BioSMB™ system, which integrates dozens of diaphragm-style valves into a single disposable block, resulting in an “integrated circuit” approach to fluid control in continuous chromatography applications. See, e.g.,
The block flow diagram shown in
The present invention provides processes that can be adapted to the manufacture of a biological product which make at least two or more steps of the processing of the biological product continuous. Continuous processing allows the manufacturer to conduct the manufacturing process using less material and relying on equipment of a reduced scaled compared to the equipment that would be required for batch operations. Continuous processing reduces downtime in the overall manufacturing process and thus reduces cycle times from the beginning of a manufacturing run to production of bulk drug substance or packaging of the final product.
In order that the invention may be more clearly understood, the following abbreviations and terms are used as defined below.
The term “biological product” as used herein refers to a product of interest created via biological processes or via the chemical or catalytic modification of an existing biological product. Biological processes include cell culture, fermentation, metabolization, respiration, and the like. Biological products are typically comprised of proteins. Biological products of interest include, for example, antibodies, antibody fragments, proteins, hormones, vaccines, fragments of natural proteins (such as fragments of bacterial toxins used as vaccines, e.g., tetanus toxoid), fusion proteins or peptide conjugates (e.g., such as subunit vaccines), virus-like particles (VLPs) and the like.
The term “biopharmaceutical” as used herein refers to a biological product purified and formulated so as to be physiologically acceptable for use as a drug or therapeutic agent.
The term “unit operation” as used herein refers to a manufacturing process step designed to separate an undesired element from a product of interest or designed to ensure that a composition containing a product of interest is substantially free of an undesired component. Such unit operations in the manufacture of a biopharmaceutical after creation, e.g., in a bioreactor, may include, without limitation: primary recovery operations, such as centrifugation, microfiltration, depth filtration, etc., for clarification of the output from a cell culture bioreactor; capture chromatography, for example by affinity chromatography, size exclusion chromatography, ion exchange chromatography, hydrophobic interaction chromatography (HIC), immobilized metal affinity chromatography (IMAC), and the like; incubation at low pH (e.g., pH 3.0-3.5) or other solution conditions for achieving, e.g., inactivation of viruses, protein refolding, aggregate dissociation, and the like; micro- or nano-filtration, etc., for filtration of viruses, bacteria, particulates and other contaminants or impurities; tangential flow filtration for product concentration (e.g., by ultrafiltration); buffer exchange (e.g., by diafiltration); “polishing” or intermediate chromatography or membrane adsorption operations (e.g., by ion exchange), for clearance of variant products (e.g., heavy chain dimers in solution with a tetrameric antibody product); clearance of aggregates; clearance of DNA or host cell proteins; virus adsorption; removal of product-specific impurities; filtration for bulk storage (e.g., 0.2 micron filtration); and similar operations. A single unit operation may be designed to accomplish multiple objectives in the same operation.
The term “upstream” or “upstream process” refers to the step(s) of biopharmaceutical manufacture relating to the creation of the active biological product by a biological process or other reaction. Ordinarily, the biological product to be isolated and processed into a biopharmaceutical is the result of a fermentation or is the expression product of a recombinantly transformed host cell. Thus, the upstream portion of the manufacturing process typically relates to the production of a target protein (such as an antibody, an active protein or protein fragment, a fusion protein, virus-like particle, etc.) either in a prokaryotic or eukaryotic cell that naturally produces the (endogenous) target protein or, more commonly, in a prokaryotic or eukaryotic host cell which has been transformed by recombinant DNA technology to express an exogenous target protein or proteins. Upstream processes involving creation of a biological product in cell culture will be conducted in a fermentor or bioreactor, and the upstream process may be a batch process (e.g., batch or fed-batch cell culture grown in a fermentor) or a continuous process (e.g, perfusion cell culture).
The term “downstream” or “downstream processing” refers to the steps following “upstream” processing of a biological product that are required to separate the biological product from impurities and contaminants, typically resulting in production of a bulk drug substance. Downstream processing refers to some or all the steps necessary for capture of a biological product from the original solution in which it was created, for purification of the biological product away from undesired components and impurities, for filtration or deactivation of pathogens (e.g., viruses, endotoxins), and for formulation and packaging. The term “continuous process” as used herein refers to any process having two or more processing steps in series, wherein the output from an upstream step (unit operation) is transferred to a downstream step (unit operation) and wherein it is not necessary for the upstream processing step to run to completion before the next processing step is started. In a continuous process some portion of the target product is always moving through the processing system. Ideally, the flow through a continuous process is regulated so that, to the greatest extent possible, every step or unit operation of the continuous process is running at the same time and at substantially the same production rate. In this way, compression of the cycle time is maximized and the shortest possible completion time is achieved. Accordingly, the expressions “continuous transfer” or “transferred continuously”, referring to a product stream moving from an upstream unit operation to a downstream unit operation, means that the connections or links between the two unit operations are such that the upstream unit operation transfers a product stream (directly or through other components) to the second (downstream) unit operation, and that the downstream unit operation begins before the upstream unit operation runs to completion (that is, the two successive unit operations are processing the product streams flowing into them simultaneously for at least part of the overall process run of which the two unit operations comprise a part).
The Continuous Processing Technology (“CPT”) described herein represents a fundamental improvement over existing batch biopharmaceutical manufacturing processes and will deliver substantial benefits in capital and time savings and in process flexibility and scalability. The adoption of CPT enables biopharmaceutical production facilities to handle biological product production runs at ton-scale levels with far less capital investment than in conventional batch manufacturing processes. CPT also enables the manufacture of biopharmaceuticals for clinical testing to be achieved more quickly and cost-effectively.
Reducing the capital investment required to establish biomanufacturing capacity improves return on capital and reduces operating costs, which should eventually lead to lower biopharmaceutical prices. By improving the efficiency of early-stage clinical trial manufacturing, more new biopharmaceuticals will be able to enter clinical trials, improving development pipelines for larger companies and reducing the time and cost to achieving proof-of-concept for smaller companies. Speeding the development of new medicines and reducing their cost of production has a significant impact on both the quality and affordability of biopharmaceuticals.
The CPT processes described herein provide the means to handle the ton-scale output which is now possible by utilization of multiple disposable bioreactors. By adopting the continuous processing methods described herein, manufacturers of a biological product can avoid the typical $500 million/5-year investment required to build a new facility capable of ton-scale biopharmaceutical production by conventional batch methods using large scale, stainless steel equipment. Reduction in capital investment of up to 80% and compression of the time to scaled-up production capacity to approximately 2 years can be achieved based on the reduced scale of equipment required to operate continuous processes. A company that is developing a new biological product faces the challenge of funding the scale-up and manufacture of the product from laboratory scale quantities to the much larger quantities necessary for preclinical experiments and clinical trials. Since the risk of failure at this point in development is high (i.e., fewer than 20% of biopharmaceuticals that enter clinical trials receive approval for commercial sale), companies developing new drug candidates (and their investors) are reluctant to spend any more capital than is absolutely necessary to advance product candidates into clinical trials. Additionally, since manufacturing and development activities are almost always on the critical path prior to initiation of human clinical testing for new biopharmaceuticals, the ability to streamline and increase the speed of producing clinical supplies has significant value in the pre-IND stage of development.
The requirements for GMP manufacturing of clinical supplies for use in human clinical testing translate to a significant cost for most early-stage programs, and delay or failure in achieving GMP standards can contribute to difficulty in financing or gaining approval to proceed with planned clinical studies. The use of continuous processing, coupled with the use of disposable technologies such as described herein, has helped reduce capital outlays and has increased the speed for achieving clinical manufacturing. Construction of a disposables-based clinical manufacturing facility may cost as little as $15-20 million, as compared to a cost of $30-50 million for conventional clinical manufacturing facilities. The CPT processes described herein can further reduce these costs and also speed up the clinical manufacturing process by shrinking the scale of equipment required to produce the needed quantities of product, and by making the entire manufacturing process more flexible and more portable.
Because these improvements disclosed herein lead to lower investment requirements and shorter times for clinical supply manufacturing, the return profile for development of early-stage biopharmaceuticals will be improved for both large companies with in-house manufacturing capacity as well as for smaller companies who may outsource the manufacture of their products. This improved return profile will enable more promising biological product candidates to enter clinical testing: larger companies will be able to move more product candidates into early-stage testing, expanding the number of drug candidates entering drug development pipelines; and small or start-up biopharmaceutical companies seeking to demonstrate proof-of-concept based on human clinical studies as a prerequisite to financing or partnering objectives will be more able to pass this hurdle.
Enabling Implementation of DisposablesThe introduction of disposables (or single-use technologies) into biopharmaceutical manufacturing processes constitutes an important shift away from standard reusable technologies. The use of disposables technology is driven by industry-wide needs to reduce capital investment, to increase speed of development, and to reduce contamination due to re-use of production equipment. Adoption of disposable technologies in small-scale, clinical manufacturing applications has been relatively rapid, owing to both the relative ease of implementation as well as to the significant benefits of capital and time savings. As described above, the lack of availability of sufficiently large disposable purification equipment presents a “bottleneck” to implementation of larger-scale processes using disposable technology.
The CPT processes described herein enable more complete use of disposables. Continuous processing permits reduction in the scale of equipment necessary to process the currently large and increasing capacity of bioreactors (2,000 liters presently, moving to 5,000 liters and above). Continuous processing allows downstream processing to proceed utilizing available equipment, including single-use (disposable) equipment; also, the flow-through capacity of CPT allows for productivities matching and significantly exceeding that of the largest bioreactors, enabling greater penetration of fully-disposable processes. The switch from traditional batch processing to continuous processing fundamentally changes the way the biopharmaceutical industry develops and manufactures its products.
Configurations for continuous processing are disclosed herein which are specifically adapted to the use of disposable components. In many instances disposable components will have lower tolerances or reduced capacity in comparison to permanent, reusable equipment, and several features for continuous processing have been designed so that the disposable components can be used and any differences in their properties accommodated by the system. As one example, single-use plastic tubing may be used to replace stainless steel tubing, however the tolerance to systemic pressure drops from unit operation to unit operation is much lower for plastic tubing than for stainless steel tubing. In the present invention, features such as surge receptacles useful to vent the system and return a given connection to atmospheric pressure are incorporated so that no tubing failures or loss of system performance results from the substitution of plastic tubing for stainless steel tubing.
Continuous Unit OperationsUnit operations in the manufacturing process of a biological product can benefit from continuous multicolumn or multistage operation. This has been demonstrated for the capture chromatography step by conversion from a batch operation to continuous counter-current simulated moving bed (SMB) chromatography. In a batch operation, the several steps of a capture chromatography operation, such as Protein A capture of an IgG target using Protein A affinity chromatography, are performed serially: Clarified conditioned media from a bioreactor is applied to a capture chromatography column, followed by wash, elution, cleaning (regeneration), and equilibration steps, with each step being completed before the next step is begun. In a SMB multicolumn system, multiple columns are employed and the multiple steps are run simultaneously on different columns Utilizing a continuous flow, multicolumn system permits the capacity of the columns to be reduced, thus allowing a large bioreactor volume to be processed using small diameter columns (instead of scaling up column size to accommodate the feed of a bioreactor by batch capture chromatography). The operation of such a SMB multicolumn system is illustrated in
A commercial SMB system (BioSMB™ system, Tarpon Biosystems, Inc., Worcester, Mass. (US)) has been developed which provides an integrated array of valves and connections (valve cassette) for coordinating flow of multiple solutions and buffers to a multiplicity of interconnected columns, enabling scalable, continuous chromatography operation using a wide range of separation media. The BioSMB™ system is programmable and adjustable, and it is useful for converting virtually any single-column batch operation to a continuous multicolumn operation. The BioSMB™ system also makes full use of disposable components by featuring replaceable tubing, columns, and valve membrane, all of which can be quickly disconnected from the system for installation of new components, thereby reducing or virtually eliminating system downtime.
At the heart of the BioSMB™ system is a valve cassette that acts as an integrated circuit for fluid handling, incorporating the many valves required to enable continuous processing into a single disposable-format valve array. (Such a valve array is illustrated schematically in
The size of the bioreactor sets the initial volume of medium that will have to be processed in a biological product manufacturing process. In a batch process, the mass of the product is the most significant factor, however in a continuous process the volume of medium to be processed determines the scale of all the downstream operations. Therefore the greater the titer of product, the greater are the advantages gained by adopting a continuous process. Currently, 5 grams of product per liter (5 g/L) is considered a high titer for protein products such as monoclonal antibodies, although optimizing host cell production, media conditions, growth cycles, etc. has yielded titers of 10-13 g/L or higher.
It is pointed out that continuous processing systems according to the invention do not require constant flow from one unit operation to the next or constant flow through all of the interconnected unit operations. For any number of reasons, the rate of flow through a unit operation or between unit operations may need to be adjusted or halted. Continuous processing only requires that the links between two unit operations are such that the first or upstream unit operation transfers a product stream (directly or through other components) to the second (downstream) unit operation, and that the downstream unit operation begins before the upstream unit operation runs to completion (that is, for at least part of the manufacturing run, the two successive unit operations are processing product simultaneously). Although continuous processing does not require uniform or uninterrupted flow through all of a series of connect unit operations, it is preferable if the processing system can be operated so as to maintain as continuous a flow through the system as possible. Features are described herein that allow a high degree of uninterrupted flow between unit operations of an overall continuous process to be achieved.
Referring again to the monoclonal antibody process illustrated in
In a manufacturing process such as illustrated in
Referring to
Referring to
In continuous processes utilizing single-use equipment, suitable surge receptacles (7) and transmission lines (tubing, 2) will commonly be made out of less durable materials, such as plastic. In such instances, the receptacle (7) may be a plastic bag (surge bag) or a vented plastic bottle. Such plastic materials and their connections between unit operations will have less resistance to back pressure build-up than, for instance, stainless steel containers and tubing; therefore, the use of surge receptacles to alleviate systemic pressure and lower the pressure drop necessary to maintain flow from one operation to the next is highly advantageous not only for regulating continuity of flow but for preserving the integrity of the system and avoiding material or connection failures.
Referring again to
Referring to
Referring to
Referring to
Referring to
The connection schemes illustrated in
The surge receptables will have a volume that permits the operator to minimize the effect of any fluctuations in flow resulting from the previous unit operation. For instance, in case the previous unit operation is a multicolumn chromatography process, such as an SMB process, the capacity of the surge receptacle is preferably chosen such that it can accommodate multiple (e.g., three) consecutive peaks of the eluate of the SMB process. The surge receptacle preferably is equipped with means to release air from the surge receptacle without allowing contaminants to enter the surge receptable. One way to achieve this (illustrated in
One of the initial unit operations in any biological product manufacturing process will be a capture step, which typically follows the primary recovery step of a manufacturing process. As noted above, the capture unit operation is commonly an affinity chromatography process, but depending on the target biological product it can also advantageously utilize any other suitable separation technique, such as hydrophobic interaction chromatography (HIC), immobilized metal affinity chromatography (IMAC), ion exchange chromatography, and the like. Affinity capture and elution requires a series of steps, including column loading (i.e., with a feed stream containing the target), washing, and elution, and after elution cleaning (regeneration) of the chromatography media and equilibration is often desired, so that the system can undergo repeated cycles without replacement of columns.
Simulated moving bed chromatography provides a way of continuous processing in a capture unit operation. The continuous purification of a capture target is aided by adoption of integrated valve modules, such as the valve manifold featured in the BioSMB™ chromatography system (Tarpon Biosystems, Inc.). The computer-assisted valve manifold can be programmed for automatic switching of column feeds between feed stream, wash buffer, elution buffer, cleaning buffer, and equilibration buffer, to create the simulated moving bed separation. Such a system is illustrated schematically in
Referring to
Continuous operation of a column chromatography purification process is illustrated by consideration of
Referring to
Preferably, the valve actuation and consequent channel switching within the valve manifold is coordinated along the whole series of columns More preferably, the valve switching is controlled by a computer program, so that the switching occurs authomatically, and the successive stages of capture chromatography are performed without interruption or system downtime. Such programmable switching and automated, coordinated switching is achieved in the aforementioned BioSMB™ purification system. Accordingly, the BioSMB™ system, or a coordinated system having its features, may be adapted to other unit operations in a biopharmaceutical purification process and thus provide equipment suitable for making all unit operations of a manufacturing process continuous processes.
Referring to
Referring again to
Referring to
Referring to
Continuous capture chromatography processes have been described above wherein the multicolumn operation of the chromatography process steps are regulated using an valve manifold “integrated circuit” of switchable channels, that is, an array of actuatable valves that can be programmed to create switching flowpaths for feeds to a series of columns in a multicolumn unit operation having several steps. For the purposes of illustration, such systems have been described in the context of a Protein A affinity chromatography separation of an antibody product from a feed stream, however it will be appreciated that such equipment as the illustrated valve array of
As mentioned above, in designing a manufacturing process for a biopharmaceutical comprising a series of unit operations, an early step will commonly be a capture chromatography step. In the antibody production process illustrated in
Referring to
Referring again to
To monitor the pH of the solution closely, each receptacle will be equipped with a pH sensor (not shown), as well as inlet ports (not shown) for receiving acidic and/or basic solutions for adjusting the pH to within a desired range. It may be important that the antibody product solution introduced into the receptacles (50, 51, 52) remains well mixed, e.g., so that accurate pH readings may be made and any pH adjustment affects the entire aliquot collected in the receptacle. In such instances, the receptacles will be equipped with mixing means, which are represented in
The variable intake channels through the valve module (40) can direct incoming flow to each of the holding/incubation receptacles (50, 51, 52). The contents of each of the incubation receptacles can be separately directed to the outlet (55) of this unit operation. In the diagram of
The acceptable time window for exposure of a proteinaceous product to low pH is typically narrow (e.g., 30±5 minutes). Exposure times that are too short do not provide sufficient viral inactivation, and exposure times that are too long lead to higher levels of degradation of the product. Continuous processing permits operating a low pH viral inactivation unit operation within tight time tolerances. A preferred methodology involves moving “packets” or aliquots of a product solution through the unit operation in a semi-continuous manner. Where the unit operation preceding the low pH viral inactivation step is a capture chromatography operation (e.g., Protein A affinity chromatography, for an antibody product), the product enters the low pH virus inactivation unit operation as a continuous series of eluate peaks. By pooling the number of eluate peaks for low pH processing that can be collected within the predetermined incubation period (e.g., 30 min.±5 min. in the examples discussed above), the proper incubation time is imposed and a continuous transfer out to the next unit operation can be implemented.
By way of example, in a system for continuous viral inactivation where the product feed is a monoclonal antibody eluted from a Protein A chromatography column, the viral inactivation unit operation may be advantageously conducted as follows:
- 1. Eluate from Protein A will have a pH in the range of pH 3.5-pH 4.5. After collection of the pool to be processed (e.g., elution peaks from Protein A over a period equal to the low pH incubation period), the pH will be adjusted in the holding/incubation receptacle to the low pH viral inactivation conditions (e.g., pH 3.3) by titration with acid;
- 2. Acid titration will be accomplished by adding dilute acid (e.g., 1M HCl) until the pH setpoint for the low pH viral inactivation has been achieved with gentle mixing and continuous pH monitoring;
- 3. Once the appropriate pH has been reached, the product solution contents in the receptacle will be held for the required inactivation time (e.g., 30 min);
- 4. After the required incubation time, another pH adjustment step will be used (preferably after transfer to another (downstream) holding receptacle) to bring the pH of the inactivated solution up to a pH (e.g., pH 5.0) suitable for transfer to a subsequent unit operation, such as loading onto a cation exchange chromatography column (see, e.g.,
FIG. 2A , item 13); - 5. After the product solution has been transferred to the next unit operation, the holding receptacle(s) can be cleaned and rinsed for loading with another Protein A eluate pool, or the receptacle(s) can be discarded and fresh receptacles connected to the system to receive subsequent Protein A eluate pools and carry them through the low pH inactivation step.
To avoid physical transfer of the product solution from receptacle to receptacle, the “movement” of a receptacle containing the pooled Protein A eluate that is described in the sequence above can be achieved with a suitable controller and valve cassette. This is directly analogous to the simulated “movement” of chromatography columns achieved using the valve cassette in the system illustrated in
In an alternative embodiment, the Protein A eluate can be flowed through a cascading series of continuously mixed holding bags (receptacles), the first of which would accomplish the pH adjustment of the Protein A eluate, and the last of which would accomplish the pH readjustment of the inactivated solution prior to the next unit operation. The bags are sized to ensure that the appropriate residence time for low pH viral inactivation is achieved.
Continuous Processing DesignIt may be appreciated that in order to effectively link unit operations of an overall manufacturing process so that they can be run in a continuous manner, quantitative analysis of the performance at each stage of the operation is necessary. Analytical methods for yield and purity of the product must be developed and implemented. Such methods may include an SDS-PAGE (reduced and non-reduced) method to assess product purity throughout the process, a host cell protein ELISA to assess clearance of host cell proteins by the purification process, and an HPLC or ultraviolet absorbance methods to determine product concentration and yields.
The design of a multicolumn counter-current continuous chromatography process, such as a SMB process, requires the same basic process information as for a batch process. This includes the product concentration in the feed solution (titer), the equilibrium binding capacity (static binding capacity) and the overall process sequence. Information about the mass transfer kinetics, which depend on the chromatography media, product and solution conditions, is also required for sizing the system. Generally, this can be obtained from breakthrough curve analysis. For this reason, a well-designed batch process is a very good starting point for the design of a continuous multicolumn or multistage purification process.
For a low pH inactivation step, analytical methods are needed for determination and confirmation of the acceptable time range for virus inactivation. For an ultrafiltration/diafiltration (UF/DF) step (see
Using such batch process data obtained for each unit operation of the process, a continuous processing operation can be designed. The first design choice is the processing time. Contrary to a batch process, where the processing time is a result of the process design, a continuous process allows preselection of the processing time. The longer the processing time, the lower the flow rates through the unit operation series and the more compact the overall system can be (in terms of the scale of equipment utilized). On the other hand, processing times that are too long may result in product degradation at some stages that reach unacceptable levels. The feed flow rate is a result of the volume that needs to be processed and the processing time. The volume that needs to be processed is referred to as the “batch” or “lot size”.
The minimum feed flow rate into the CPT process, Qm, is calculated from the maximum processing time, t, using the following equation:
where Ap is the amount of product required; Cp is the product concentration in the feed; and Y is the overall process yield. Assuming the initial titer of an antibody product in cell culture supernatant is 1 g/L, and the overall process yield of the purification process is 60%, the minimum feed flow rate to achieve the 3 day, 100 g productivity objective is 39 mL/min. In order to ensure that the system can operate to comfortably achieve the productivity goal, the target CPT process feed flow rate will be set at a value at least 10% higher than the minimum flow rate, or about 45 mL/min.
Once the feed flow rate has been determined, the CPT process design can begin with the design of the first unit operation, for example a capture step such as a Protein A affinity chromatography step. For a continuous SMB chromatography step, the design algorithm starts with determining the minimum (simulated) transport rate of the chromatography media. This is the transport rate of the media that would allow binding all product in case there would be no mass transfer resistance, in case there would be ideal plug flow and in the absence of any other non-ideal parameters. In order to accommodate mass transfer resistance and deal with other non-ideal factors or limits, the actual simulated transport rate of chromatography media is chosen to be above the minimum transport rate. Typically, the practitioner selects safety margins in the range of 5-40%. The volume of chromatography media in the loading zone then depends on the flow rate going through the columns in the loading zone and the required residence time, which mainly depends on mass transfer phenomena such as diffusion. Knowing the required residence time and the feed flow rate, the required resin volume in the loading zone can be calculated.
Once the design for the first unit operation has been completed, the outlet product flow rate from this step can be set to equal the inlet flow rate for the second unit operation in the process, so that the hydraulic capacities of each connecting step are matched. Similar design algorithms as for the first unit operation can be applied to each unit operation in the process. Batch data for each unit operation can be used to develop a continuous operation design for that unit operation, which allows it to be linked to the previous and subsequent unit operations. When this process is completed for all unit operations in the overall purification process, the initial CPT process design is complete. From this initial design, suitable equipment and disposables for all steps of the manufacturing process can be sized, specified, and ordered to fit the parameters and demands of the initial CPT design.
Once the initial design has been established, each process step can then be optimized through iterative experimentation to maximize any desired attribute, such as volumetric productivity or buffer utilization. In order to establish a seamless streamlined continuous process, the size and throughput of each unit operation will be governed by the flow rate (hydraulic capacity) instead of by total volume or mass to be processed. For each step, optimization will involve a study of the principles and phenomena that govern size and hydraulic capacity of the unit operation. For instance, the optimization of the chromatography steps using continuous multicolumn SMB will involve a study of the impact of the separation factor, S, and number of transport units, NTU, on performance of the process step.
The separation factor, S, is a measure of transport capacity caused by the bed transport rate in relation to the product feed rate and is defined as:
where Øfeed and Øbed are the flow rates of the liquid and stationary phases respectively (in the case of the bed, Øbed is the simulated transport rate), Qstatic is the binding capacity of the media, and Cfeed is the concentration in the feed.
The number of transfer units, NTU, is used as a measure of the mass transfer kinetics for countercurrent chromatography systems and is defined as:
NTU=koL×a×V/Φfeed
where koL is the overall mass transfer coefficient of the system, V is the column volume, and a is the specific surface area, which equals the surface area of the particles divided by column volume. The NTU is the ratio of the residence time in the system and the characteristic mass transfer time.
Through experimental studies evaluating performance at different values of NTU and S, the optimal processing conditions can be identified for each step, in order to achieve the desired productivity while meeting the separation or performance objectives (e.g., host cell protein removal for a Protein A chromatography step). In addition to this optimization, it will be advantageous to investigate the stability of the unit operation and the sensitivity to disturbances, in order to establish some preliminary parameters for robustness of the integrated process. For example, the optimal processing conditions may be too close to conditions that would result in unacceptable performance, in which case the conditions are adjusted to provide optimal and acceptably robust performance.
Finally, during this stage, particular attention should be paid to the pressure drop of each individual unit operation. As this may become a limiting factor in the cascade of unit operations, the installation of surge receptacles will be an important device for equalization of system pressure at critical points in the cascade and thereby adjusting the pressure drop required to maintain a desired downstream flow rate.
The robustness of each step to inlet feed rates will be important to ensure the ability to adapt to the range of operating conditions that will be experienced during actual operation. Included in this objective is the development of shut-down and start-up procedures for an entire continuous line, including procedures for use of emergency collection receptacles described herein.
During continuous operation of the manufacturing process, samples may be taken at each point in the process to verify that the anticipated product and process attributes (i.e., purity, yield) are being achieved by the CPT process. Final purified bulk product may be analyzed to determine product purity by SDS-PAGE and HPLC, clearance of specific impurities (e.g., host cell proteins) by ELISA, and product concentration to enable overall yield determination.
REFERENCES
- Rosset A J, Neuzil R W and Broughton D B. Industrial application of preparative chromatography, in: Rodrigues A E, Tondeur D (eds.), Percolation Processes: Theory and Application, Rockville, Md., Sijthoff & Noordhoff Press; 1981.
- Van Walsem H J and Thompson M C, Simulated moving bed in the production of lysine, J. Biotech, 1997; 59:127-132.
- Trout B and Bisson W, Continuous manufacturing of small molecule pharmaceuticals: the ultra lean way of manufacturing, presented at MIT Leaders for Global Operations Conference; Cambridge, Mass.; Dec. 3-4, 2009.
- Bisschops M et al, Single-use continuous, counter-current, multicolumn chromatography. BioProcess International, June 2009; 7(Supp 5):18-23.
- Coffman J. Development of a Protein A SMB step for a Mab with up to 10 g/L titers, presented at BioManufacturing and Development conference; Boston, Mass.; Nov. 1-3, 2010.
From the foregoing description it is evident that flexible and serviceable continuous processing methods can be implemented to make virtually any biopharmaceutical manufacturing process more efficient and less costly to run. The continuous processing features described herein also allow the run time of manufacturing processes to be significantly compressed.
Although a number of embodiments have been described above, it will be understood by those skilled in the art that modifications and variations of the described processes and apparatuses may be made without departing from the disclosure of the invention or the scope of the appended claims. The articles and publications cited above are hereby incorporated by reference.
Claims
1. A process for production of a biological product comprising:
- (a) continuously transferring a biological product-containing solution to a first unit operation capable of separating the solution into two or more fractions comprising at least one fraction containing said biological product and at least one fraction containing one or more components of the biological product-containing solution desired to be separated from said biological product, wherein said first unit operation has at least one inlet and at least one outlet and is configured to permit continuous fluid flow between said at least one inlet and at least one outlet;
- (b) continuously transferring the flow from at least one outlet of said first unit operation to a second unit operation having at least one inlet for receiving flow from at least one outlet of said first unit operation, said flow from said first unit operation comprising said biological product, said second unit operation capable of separating the product received through said at least one inlet into two or more fractions comprising at least one fraction containing said biological product and at least one fraction containing one or more components of the product received through said at least one inlet desired to be removed from said biological product, wherein said second unit operation further has at least one outlet and is configured to permit continuous flow between said at least one inlet and at least one outlet, and wherein the throughput of said second unit operation is equal to the output flow received from said first unit operation;
- (c) recovering a solution containing said biological product.
2. The process according to claim 1, wherein, independently for each transferring step, the transferring step comprises directing the flow from the preceding unit operation to an intermediate storage vessel, wherein said vessel has a holding capacity equal to or less than half of the volume received from the preceding unit operation during processing of one entire lot.
3. A method for the manufacture of a biological product in a continuous process system comprising the steps:
- (a) producing conditioned media containing a biological product in a bioreactor;
- (b) continuously removing cells and cell debris from said conditioned media to produce a clarified solution comprising said biological product;
- (c) continuously transferring said clarified solution to a first unit operation comprising a capture chromatography process comprising (1) contacting said product solution with an affinity ligand capable of complexing with said biological product and (2) dissociating complexes of said affinity ligand and said biological product formed in said contacting step to produce a purified biological product solution;
- (d) continuously transferring the purified biological product solution to a second unit operation comprising a low pH incubation process comprising (1) collecting at least part of said purified biological product solution in an incubation receptacle, (2) adjusting the pH of said purified biological product solution to a pH calculated to inactivate any viruses contained in said solution, and (3) readjusting the pH of said purified biological product solution to produce a virus-inactivated biological product solution;
- (e) continuously transferring said virus-inactivated biological product solution to at least one addition unit operation comprising a process selected from anion exchange chromatography, cation exchange chromatography, nanofiltration, ultrafiltration/difiltration, microfiltration, or combinations thereof in any order; and
- (f) recovering a solution containing said biological product.
4. The method according to claim 3, wherein said removal of cells and cell debris in step (b) comprises centrifugation.
5. The method according to claim 3, wherein said first unit operation is a simulated moving bed affinity chromatography process.
6. A method for incubating a solution for a predetermined period of time at desired solution conditions, comprising:
- (a) continuously transferring a biological product solution into a first incubation receptacle;
- (b) adjusting the solution conditions to desired incubation conditions in said first receptacle;
- (c) continuously transferring the biological product solution from said first receptacle into at least one holding receptacle and holding the solution in said at least one holding receptacle;
- (d) continuously transferring the biological product solution from a holding receptacle into a readjustment receptacle;
- (e) adjusting the solution conditions in said readjustment receptacle to desired post-incubation conditions for the biological product solution;
- wherein the residence time of the biological product solution in said at least one holding receptacle, plus the transfer time from said first receptacle to said at least one holding receptacle, plus the transfer time from said at least one holding receptacle to said readjustment receptacle is controlled to match said predetermined period of time, and wherein said incubation conditions are different from said post-incubation conditions.
7. A method for incubating a biological product solution at desired solution conditions for a controlled period of time and within a desired tolerance time window, comprising:
- (a) continuously transferring a biological product solution into a series of incubation receptacles such that (the volume of each receptacle) (the flow rate)×(the desired tolerance time),
- (b) after filling of each individual receptacle, discontinuing transfer to that receptacle and adjusting the solution conditions to the desired incubation condition in said receptacle,
- (c) after achieving the desired incubation condition in step (b), holding that receptacle for the controlled period of incubation,
- (d) after said period of incubation in step (c), readjusting the solution conditions in that receptacle to a desired post-incubation condition different from said incubation condition, and
- (e) after achieving the desired post-incubation condition, continuously transferring the biological product solution out of said series of incubation receptacles.
8. The method according to claim 6 or claim 7, wherein one or more of said receptacles further comprises mixing means for ensuring a homogenous solution within said receptacle.
9. The method according to claim 8, wherein said mixing means is a rocking table.
10. The method of claim 6 or claim 7, wherein one or more of said receptacles further comprises a vent outlet communicating the inside of said receptacle with the ambient environment.
11. The method of claim 10, wherein a filter is interposed between said vent outlet and the ambient environment, and wherein said vent outlet further comprises a valve for opening and closing said outlet.
12. An apparatus for connecting two or more unit operations of a manufacturing process for continuous processing comprising:
- (a) a valve manifold providing at least three fluid transmission channels comprising a central channel traversing said valve manifold and having an inlet end and an outlet end, a priming channel connecting a separate inlet with said central channel, and a bypass channel connecting a separate outlet with said central channel, each of said channels having at least one independently actuatable valve for independently opening or closing the channel, said central channel inlet being suitable for receiving throughput from an upstream unit operation, and said priming channel inlet being suitable for receiving fluid for filling said priming channel and said central channel,
- (b) at least one surge receptacle having at least one inlet and at least one outlet, said surge receptacle inlet being connected to the central channel outlet of said valve manifold, and said at least one surge receptacle having the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
13. The apparatus of claim 12, wherein said surge receptacle further comprises a vent outlet communicating the inside of said receptacle with the ambient environment.
14. The apparatus of claim 13, wherein a filter is interposed between said vent outlet and the ambient environment, and wherein said vent outlet further comprises a valve for opening and closing said outlet.
15. The apparatus of claim 14, wherein the surge receptacle outlet is connected to a pump.
16. The apparatus of any of claims 12-15, wherein said bypass channel outlet is connected to a bypass collection receptacle having the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
17. An apparatus for connecting two or more unit operations of a manufacturing process for continuous processing comprising:
- (a) a valve manifold providing at least five fluid transmission channels comprising a central channel traversing said valve manifold and having an inlet end and an outlet end, a priming channel connecting a separate inlet with said central channel, a surge receptacle inlet channel connecting a separate inlet with said central channel, a surge receptacle outlet channel connecting a separate outlet with said central channel, and a bypass channel connecting a separate outlet with said central channel, each of said five channels having at least one independently actuatable valve for independently opening or closing the channel, said central channel inlet being suitable for receiving throughput from an upstream unit operation, said priming channel inlet being suitable for receiving fluid for filling said priming channel and said central channel,
- (b) at least one surge receptacle having at least one inlet and at least one outlet, wherein a surge receptacle inlet is connected to the surge receptacle outlet channel of said valve manifold, and a surge receptacle outlet is connected to the surge receptacle inlet channel of said valve manifold, and wherein said at least one surge receptacle has the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
18. The apparatus of claim 17, wherein said at least one surge receptacle further comprises a vent outlet communicating the inside of said receptacle with the ambient environment.
19. The apparatus of claim 18, wherein a filter is interposed between said vent outlet and the ambient environment, and wherein said vent outlet further comprises a valve for opening and closing said outlet.
20. The apparatus of claim 19, wherein the connection between said surge receptacle outlet and the surge receptacle inlet channel of said valve manifold is equipped with a pump for regulating fluid flow along said connection.
21. The apparatus of any of claims 17-20, wherein said bypass channel outlet is connected to a bypass collection receptacle having the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
22. A continuous processing system comprising:
- (a) a first apparatus for carrying out a first unit operation comprising: (1) a plurality of valve modules, each module having a central channel traversing the module and a plurality of branch channels connecting the central channel with the outside of the valve module, wherein each of said channels has at least one independently actuatable valve for independently opening or closing the channel, wherein the valve of said central channel separates the inlet end of said central channel from the outlet end of said central channel, wherein at least two branch channels connect separate inlets to the valve module with the central channel on the inlet side of the central channel valve and at least two branch channels lead from the central channel on the outlet side of the central channel valve to separate outlets from the valve module; (2) a plurality of solution conduits, each conduit connecting to a separate branch channel of each valve module, and (3) a plurality of chromatography columns, each column having an inlet and an outlet, wherein said column inlet is connected to the inlet end of a valve module central channel and said column outlet is connected to the outlet end of the central channel of a different valve module, such that said plurality of columns is connected in series through invening valve modules and wherein the outlet of the last column in the series is connected, via an intervening valve module, to the inlet of the first column in the series;
- (b) a second apparatus for carrying out a second unit operation comprising: (1) one or more incubation receptacles each having at least one inlet and at least one outlet, wherein collectively said one or more incubation receptacles has at least the capacity to hold the output of said first unit operation; (2) a valve module comprising an inlet and an outlet, an inlet channel connected to said valve module inlet, and one or more inlet branch channels connecting with said inlet channel, wherein each inlet branch channel leads from said inlet channel and connects to an inlet of one of said one or more incubation receptacles, wherein each of said inlet branch channels has at least one independently actuatable valve for independently opening or closing the channel, the valve module further comprising an outlet channel leading to the valve module outlet, and one or more outlet branch channels connecting with said outlet channel, wherein each outlet branch channel leads from said outlet channel and connects to an outlet of one of said one or more incubation receptacles, wherein each of said outlet branch channels has at least one independently actuatable valve for independently opening or closing the channel; and
- (c) a third apparatus, for connecting the output of said first apparatus to the inlet of said second apparatus, said third apparatus comprising: (1) a valve module providing at least five fluid transmission channels comprising a central channel traversing said valve module and having an inlet end and an outlet end, a priming channel connecting a separate inlet with said central channel, a surge receptacle inlet channel connecting a separate inlet with said central channel, a surge receptacle outlet channel connecting a separate outlet with said central channel, and a bypass channel connecting a separate outlet with said central channel, each of said five channels having at least one independently actuatable valve for independently opening or closing the channel, wherein said central channel inlet is connected to an outlet branch channel of each of said plurality of valve modules of the apparatus of said first unit operation, said priming channel inlet being suitable for receiving fluid for filling said priming channel and said central channel, (2) at least one surge receptacle having at least one inlet and at least one outlet, wherein a surge receptacle inlet is connected to the surge receptacle outlet channel of said valve module, and a surge receptacle outlet is connected to the surge receptacle inlet channel of said valve module, and wherein said at least one surge receptacle has the capacity to hold the output of the apparatus of said first unit operation, and wherein said central channel outlet of said valve module is connected to the inlet of the valve module of said apparatus for carrying out said second unit operation.
23. The system of claim 22, wherein said at least one surge receptacle and/or said one or more incubation receptacles further comprises a vent outlet communicating the inside of said receptacle with the ambient environment.
24. The system of claim 23, wherein a filter is interposed between said vent outlet and the ambient environment, and wherein said vent outlet further comprises a valve for opening and closing said outlet.
25. The system of claim 24, wherein the connection between said surge receptacle outlet and the surge receptacle inlet channel of said valve manifold is equipped with a pump for regulating fluid flow along said connection.
26. The system of any of claims 22-25, wherein said bypass channel outlet is connected to a bypass collection receptacle having the capacity to hold the throughput of a unit operation connected to said valve manifold central channel inlet.
27. The system of claim 22, wherein the plurality of valve modules of said apparatus for carrying out said first unit operation is are integrated into a master valve manifold.
28. The system of claim 27, wherein said one or more incubation receptacles is equipped with means for mixing the contents of the receptacle.
29. The system of claim 28, wherein said means is a rocker table.
30. The system of claim 22, wherein any of said receptacles is a single-use receptacle.
Type: Application
Filed: Dec 6, 2011
Publication Date: Oct 3, 2013
Inventors: Thomas C. Ransohoff (Lexington, MA), Marc A. T. Bisschops (Breda)
Application Number: 13/991,604
International Classification: C12P 21/00 (20060101);