The subject matter disclosed herein relates to blending of multiple solutions. More specifically the subject matter relates to a system for blending of multiple solutions for inline condition in a chromatography application.
Chromatography is a well-established and valuable technique for separating chemical and biological substances and is widely used in research and industry, finding many applications in compound preparation, purification and analysis. There are many different forms of chromatography, liquid chromatography being of particular importance in the pharmaceutical and biological industries for the preparation, purification and analysis of proteins, peptides and nucleic acids.
A typical liquid chromatography apparatus has an upright housing in which a bed of packing material, which is usually particulate in nature and consists of a porous medium, rests against a permeable retaining layer. A liquid mobile phase enters through an inlet, for example at the top of the column, usually through a porous, perforated filter, mesh or frit, moves through the bed of packing material and is removed via an outlet, typically through a second filter, mesh or frit.
In many cases it is important to obtain liquids of precisely known composition and/or other characteristics, such as pH, ionic strength, viscosity, density etc. It is further not uncommon that the composition of the liquid should not only be at each moment precisely known and controlled, but also should vary with time in a precise and controlled manner. Such liquids are usually obtained by mixing or blending two or more liquids with each other, typically using a blending system, usually an on-site blending system, which may provide for both isocratic and gradient blending modes (step gradient and linear gradient). One application where the composition of liquids is of utmost importance is in the field of liquid chromatography, when buffers having a specified pH and optionally also ionic strength are utilized, the pH and ionic strength of the eluent being the two most important parameters that control selectivity of protein separations in chromatography, such as on ion exchange resins. Another such application is filtration.
The current systems include usage of multiple high pressure pumps to deliver different solutions/buffer solution such as acid, base and salt along with water to a mixer for forming a blended solution that needs to be delivered to the chromatography column. However characteristics of the blended solution such as pH level and conductivity cannot be determined before supplying to the chromatography column. As multiple solutions need to be supplied at varying quantity and concentration, a switch valve or a quaternary valve is used. The switch valve is capable of switching between different solutions and delivering the solutions to a blending unit. A high pressure pump is generally used to pump the solutions/buffer solution from their containers through the switch valve. The characteristics of the blended solution supplied to the chromatography column are important for performing separation of proteins in an efficient manner. Determining the characteristics of the blended solution is difficult and not accurate in current systems. The switch valve in the current systems provide inaccurate blendings and not accurate at low percentages. This is because sensors for determining these characteristics may not be able to tolerate a pressure level of the solution pumped by the high pressure pump. The sensors generally can accommodate only a pressure up to 7 bar i.e. 0.7 MPa. Thus the blended solutions may not have desired characteristics or may have variation in characteristics such as pH level and conductivity. The usage of more high pressure pumps also adds to cost of the chromatography system.
Accordingly, a need exists for an improved system for inline blending of solutions for chromatography.
The object of the invention is to provide an improved way of blending multiple solutions, which overcomes one or more drawbacks of the prior art. This is achieved by a system for inline blending of solutions for chromatography from multiple solutions and buffer solution with a simple and convenient design as defined in the independent claim.
One advantage with the disclosed system for blending of multiple solutions and a buffer solution. The system includes a switch valve capable of flowing at least one solution, a low pressure pump for pumping the one or more solutions through the switch valve and a T-joint capable of receiving the one or more solutions through the low pressure pump and blending the one or more solutions with a buffer solution. A high pressure pump is present for collecting a blended solution. As a low pressure pump is used the pressure of the buffer solution experienced at the sensors are less hence they can operate normally to determine the characteristics. Further the low pressure pump renders the system less expensive.
In an embodiment a system for blending of solutions and a buffer solution is disclosed. In this system a switch valve is present capable of flowing one or more solutions, a low pressure pump for pumping the one or more solutions through the switch valve and a T-joint capable of receiving the one or more solutions through the low pressure pump and blending the one or more solutions with a buffer solution. A high pressure pump is present for collecting a blended solution.
In another embodiment a chromatography system is disclosed. The chromatography system includes a switch valve capable of flowing at least one solution; a low pressure pump for pumping the one or more solutions through the switch valve. A T-joint is capable of receiving the one or more solutions through the low pressure pump and blending the one or more solutions with a buffer solution. A high pressure pump collects and delivers a blended solution to a chromatography column.
A more complete understanding of the present invention, as well as further features and advantages thereof, will be obtained by reference to the following detailed description and drawings.
In the following detailed description, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration specific embodiments that may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the embodiments, and it is to be understood that other embodiments may be utilized and that logical, mechanical and other changes may be made without departing from the scope of the embodiments. The following detailed description is, therefore, not to be taken as limiting the scope of the invention.
As discussed in detail below, embodiments of a system for blending of solutions and a buffer solution is disclosed. In this system a switch valve is present that is capable of flowing one or more solutions, a low pressure pump for pumping the one or more solutions through the switch valve and a T-joint capable of receiving the one or more solutions through the low pressure pump and blending the one or more solutions with a buffer solution. A high pressure pump is present for collecting a blended solution.
The solution in the container 104 flows through a switch valve 106 due to pumping pressure developed by a low pressure pump 108 connected to the switch valve 106. In an embodiment the switch valve 106 may be a quaternary valve that can switch between multiple solutions for instance the switch valve 106 switches to allow supply of the solution and the buffer solution interchangeably based on requirement. The switch valve 106 is capable of opening and closing faster so that switching between different solutions is possible. The solution pumped by the low pressure pump 108 is supplied to a T-joint 110. The T-joint 110 also receives the buffer solution from a container 112. The T-joint 110 is directly connected to the container 112 hence the buffer solution flows freely into the blending unit 110. In an embodiment a high pressure pump 114 may be configured to pump the buffer solution from the container 112 into the T-joint 110. In other ways the suction pressure created by the high pressure pump 114 may enable the buffer solution to flow from the container 112 into the T-joint 110. In other ways a difference between the pressure created by the low pressure pump 108 and the high pressure pump 114 creates the suction pressure for allowing the buffer solution to flow the container 112 into the T-joint 110. The pressure developed by the high pressure pump 114 can be varied based on requirement of the blended solution that needs to be prepared. In the T-joint 110 the solution and the buffer solution are blended or mixed to form a blended solution. The blended solution may be a buffer that is required for various purposes for instance for chromatography applications for purifying mixtures of proteins. However it may be envisioned that the buffer can be used for any other purposes as well. In an embodiment the T-joint 110 may be a magnetic stirrer that can blend the solution with the buffer solution. However it may be envisioned that the T-joint 110 may have any other structural and functional configuration or arrangement known in the art for performing the blending of the solutions.
For instance the container 112 may store water and the container 104 may store an acid. The low pressure pump 108 pumps at low pressure to supply the acid into the T-joint 110. The switch valve 106 opens to allow the acid to flow into the T-joint 110. The water present in the container 112 flows directly into the T-joint 110. In another instance the switch valve 106 may also switch its connection to allow the water to flow into the T-joint 110. Here the low pressure pump 108 can develop the pressure to pump the water into the T-joint 110. In an embodiment the T-joint may be a blending unit. The blending unit may blend the acid with water.
The blended solution pumped by the high pressure pump 114 is analyzed for determining its characteristics such as but not limited to pH, conductivity and so on. In an embodiment a sensor 116 and a sensor 118 may be present between the blending unit 110 and the high pressure pump 114. The sensor 116 may be a pH sensor to determine a pH level of the blended solution and the sensor 118 may be a conductivity sensor for determining the conductivity associated with the blended solution. In the event of any variation in the desired pH level and conductivity level associated with the blended solution, the flow rate of the solution through the low pressure pump 108 and the flow rate of the buffer solution from the container 112 to the T-joint 110 are also varied. The flow rate of the buffer solution may be controlled by varying the pressure developed by the high pressure pump 114. Further the flow rate of the solution present in the container 104 passing through the switch valve 106 can be varied by varying the pressure developed by the low pressure pump 108. As the sensors 116 and 118 are positioned at a low pressure side proximate to the low pressure pump 108 the operation or functioning of these sensors is not affected by any high pressure and thus monitoring the characteristics of the blended solution can be performed accurately. Even though only two sensors i.e. the sensor 116 and the sensor 118 are explained here and represented in
The solution received in the T-joint 214 is mixed together to form a blended solution that is pumped by a high pressure pump 216. As the solutions and the buffer solution are mixed in the T-joint 214 at a low pressure side closer to the low pressure pump 210 they can be mixed well and determining the characteristics is more convenient. The high pressure pump 216 may create a pressure that is more than the low pressure pump 210. The blended solution is analyzed for determining its characteristics such as but not limited to pH, conductivity and so on. In an embodiment a sensor 218 and a sensor 220 may be present between the T-joint 214 and the high pressure pump 216. The sensor 218 may be a pH sensor to determine a pH level of the blended solution and the sensor 220 may be a conductivity sensor for determining the conductivity associated with the blended solution. In the event of any variation in the desired pH level and conductivity level associated with the blended solution, the flow rate of the solution through the low pressure pump 210 and the flow rate of the buffer solution from the container 208 to the T-joint 214 are also varied. The flow rate of the buffer solution through a direct connection between the container 208 and the T-joint 214 may be controlled by varying the pressure developed by the high pressure pump 216. Further the flow rate of one or more solutions present in any of the containers 202, 204 and 206, passing through the switch valve 212 can be varied by varying the pressure developed by the low pressure pump 210. As the sensors 218 and 220 are positioned at a low pressure side proximate to the low pressure pump 210 the operation or functioning of these sensors is not affected by any high pressure and thus monitoring the characteristics of the blended solution can be performed accurately. Even though only two sensors i.e. the sensor 218 and the sensor 220 are explained here and represented in
Further
Considering an example of the setup in
The operation and functioning of the switch valve 212, the low pressure pump 210, the sensors 218 and 220 and the high pressure pump 216 is controlled by a control system 222. The sensors 218 and 220 may provide feedback associated with the characteristics of the blended solution received from the T-joint 214 to the control system 222. Accordingly the control system 222 controls the functioning of the switch valve 212, the low pressure pump 210 and the high pressure pump 216 to vary its flow rate and the pressure developed for producing the blended solution. The characteristics of the blended solution such as a buffer solution used in chromatography needs to have desired buffering capacity for purification of any proteins otherwise can lead to lesser yields. The buffering capacity may be associated with multiple factors such as pKa values which correspond to pH value.
The blended solution as described before can be used for a chromatography application. The blended solution may be a buffer solution that is allowed to pass through a chromatography column.
From the foregoing, it will be appreciated that the above system for blending of solutions is disclosed. In this system as low pressure pumps are used to collect and deliver solutions to a blending unit through a switch valve, sensors placed between the low pressure pumps and a high pressure pump can determine the characteristics of the buffer solution. As a low pressure pump is used to pump the solution from the containers the switch valve can accommodate to supply the solution at a low flow rate. The mixing of the solutions occurs in a blending unit at a low pressure side closer to the low pressure pump. The sensors are present near to the low pressure pump so they are not affected by high pressure and thus characteristics of the blended solution can be conveniently and accurately determined. Further due to a direction connection between the container holding the buffer solution and the blending unit a major portion of the required buffer solution can be supplied through this connection and hence more time of the switch valve cycle time will be available for other solutions to be delivered through the switch valve and the low pressure pump. As the buffer solution is the major percentage of the blended solution formed and supplied through this direct connection a low pressure pump can be used to pump the other solutions into the blending unit. Due to the presence of the low pressure pump any desired flow rate of the solution through the switch valve can be accommodated. Moreover the low pressure pump enables the blending of solutions to occur at a low pressure environment.
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any computing system or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.
Number | Date | Country | Kind |
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1451561-3 | Dec 2014 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/080200 | 12/17/2015 | WO | 00 |