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Ultrafiltration for Bioprocessing
Herb Lutz
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eBook - ePub
Ultrafiltration for Bioprocessing
Herb Lutz
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Ă propos de ce livre
Ultrafiltration for Bioprocessing is key reading for all those involved in the biotechnology and biopharmaceutical areas. Written by a leading worker in the area, it includes many practical applications and case studies in the key process of ultrafiltration (UF), which is used in almost every bioprocess.
- Focuses on ultrafiltration for biopharmaceuticalsâother books look at general ultrafiltration or general biopharmaceuticals
- A mix of theory and practical applicationsâother books tend to be more theory-oriented
- Addresses the main issues encountered in development and scale-up through recommendations and case studies
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Informations
Sujet
NaturwissenschaftenSous-sujet
Analytische Chemie1
Fundamentals
Herb Lutz EMD Millipore, Biomanufacturing Sciences Network
Abstract
This chapter provides a high-level overview of ultrafiltration. This includes basic terminology, principles of operation, performance characteristics, and applications where it is used. It is intended to provide an overall perspective and furnish a background to enable the reader to more readily understand the subsequent in-depth chapters.
Keywords
cross-flow filtration
filtrate
flux
formulation
NFF
permeate
retentate
tangential flow filtration
TFF
TMP
ultrafiltration
UF applications
UF membrane
UF operation
UF processing steps
UF system
1.1. Membrane pore sizes
A membrane can be idealized as a film that readily passes solvents and small solutes but retains large solutes above a particular size. UF (Ultrafiltration) membranes retain solutes with hydraulic diameters in the 5â150 nm range. This roughly corresponds to molecular weights in the 1â1000 kDa range covering most proteins, nucleic acids, nanoparticles, viruses, and some polymers. In the field of membranes, the term nanofiltration refers to membranes tighter than ultrafiltration but more open than reverse osmosis (Figure 1.1). However, in biotechnology, it has come to refer to virus-retaining membranes that fall in the open ultrafiltration (roughly 100 kDa) to tight microfiltration range (roughly 0.1 ÎŒm).
1.2. Applications
In a biopharmaceutical manufacturing process, biopharmaceutical products are expressed in a bioreactor (for mammalian cells) or fermentor (for bacterial or yeast cells). Ultrafiltration has been used to retain colloids and cell debris while passing the expressed product. In a similar way, ultrafiltration has been used after a refold pool to retain refold aggregates while passing the refolded product. Following clarification, ultrafiltration has been used to remove the largest contaminant â water â by retaining the product in a concentration step. This can be to reduce the size of subsequent steps, which may have to be sized based on the batch volume rather than on product mass. In addition, volume reduction facilitates transport and storage. This can provide flexibility to a manufacturing operation by decoupling the upstream from downstream operations.
Ultrafiltration is used to purify large solutes, such as vaccines, by retaining the desired product and passing through unwanted smaller components. This can include passing unreacted PEG or unconjugated polymers. Ultrafiltration is also used to retain unwanted viruses or aggregates while letting the desired product pass through. When the desired product and unwanted solutes are close in size, this is a challenging fractionation operation. This book will not cover virus ultrafiltration, or nanofiltration as it is frequently called.
The most common application is the use of ultrafiltration for final product formulation. This involves retaining the product while concentrating it to the desired target, and conducting a buffer exchange using a diafiltration process. Small contaminants and the old buffer components pass through the membrane.
1.3. Modes of operation
Membranes are encased in modules for ease-of-operation. One could run the membrane in a static or dialysis mode where small buffer solutes can be exchanged by diffusion across the membrane (Figure 1.2). This is convenient at the bench scale but economical commercial operation requires bulk flow. UF can also be run in NFF (normal flow filtration) or TFF (tangential flow filtration) modes. NFF (Figure 1.2a) is the most common type of filtration. NFF mode involves passing the solvent through the filter under pressure where the fluid velocity is perpendicular (or normal) to the plane of the membrane. As the fluid passes through the membrane, it drags solutes with it to the membrane surface where they accumulate and cause the filter hydraulic resistance to increase. For high concentrations of retained solutes, NFF operation leads to relatively rapid plugging and low filter capacities. NFF is used at bench scale where low capacities pose less of a concern and the ease-of-use is convenient. NFF is also used for virus filtration.
TFF mode (Figure 1.2b) involves adding another fluid velocity component parallel to the plane of the membrane so the net solvent flow strikes the membrane at an angle. The presence of the tangential flow at the membrane surface facilitates backflow of solutes and prevents filter plugging. While there remains a region of high solute concentration at the membrane surface, steady-state operation is reached and TFF operation shows very high filter cap...