filtration tutorial this tutorial is designed to enhance knowledge of the purification processes...
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Filtration TutorialFiltration Tutorial
This tutorial is designed to enhance knowledge of the This tutorial is designed to enhance knowledge of the purification processes used in biotechnology. The topics purification processes used in biotechnology. The topics covered in this tutorial are meant to provide a succinct covered in this tutorial are meant to provide a succinct
overview of microfiltration and ultrafiltration processes. A overview of microfiltration and ultrafiltration processes. A more in-depth study will be referenced throughout the tutorial. more in-depth study will be referenced throughout the tutorial. It is recommended that an examination of the references be It is recommended that an examination of the references be performed to further explain any of the concepts covered in performed to further explain any of the concepts covered in
this brief tutorial.this brief tutorial.
OverviewOverview
Types of FiltrationTypes of Filtration MicrofiltrationMicrofiltration
How it works?How it works? UltrafiltrationUltrafiltration
How it works?How it works? Microfiltration vs. UltrafiltrationMicrofiltration vs. Ultrafiltration ReferencesReferences
Types of FiltrationTypes of Filtration
2 Examples2 Examples::1.1. Cross FlowCross Flow 2.2. Dead End FlowDead End Flow
Types of flow images from: http://www.che.utexas.edu/nams/IUPAC/iupac.html
Type 1: Cross FiltrationType 1: Cross Filtration Flow parallel to Flow parallel to
membrane surfacemembrane surface
Does Does notnot cause buildup, cause buildup, therefore does not suffer therefore does not suffer from reduced flow from reduced flow overtimeovertime
F = feed; F = feed; M = membrane; M = membrane; P = permeate; P = permeate; R = retentate R = retentate (components that do NOT (components that do NOT pass through the pass through the membrane)membrane)
Cross Flow diagram from: http://www.che.utexas.edu/nams/IUPAC/iupac.html
Type 2: Dead End FlowType 2: Dead End Flow
Flow perpendicular to Flow perpendicular to membrane surface membrane surface
Causes build up of filter Causes build up of filter cake on membranecake on membrane
F = feed; F = feed; M = membrane; M = membrane; P =P = permeatepermeate (components that pass (components that pass through membrane)through membrane)
Dead-end Flow diagram from: http://www.che.utexas.edu/nams/IUPAC/iupac.html
MicrofiltrationMicrofiltration
Separates soluble contaminants remaining Separates soluble contaminants remaining within the within the supernatantsupernatant
SupernatantSupernatant may include: may include: Other proteinsOther proteins Bio-moleculesBio-molecules Un-used growth mediaUn-used growth media
Microfiltration image from: http://www.aaflow.de/filtertech/index.html
How does Microfiltration How does Microfiltration work?work?
Pressure driven processPressure driven process
Separates: Separates: Components in a solution Components in a solution
or suspension or suspension based on based on molecular sizemolecular size
Particles size range:Particles size range:
1010m (starches) to m (starches) to aprx. aprx. 0.040.04m (DNA, m (DNA, Viruses, Viruses, and and globular proteins)globular proteins)
Microfiltration image from: http://www.faireymicrofiltrex.com/Vokes%20Microfiltration/media/images/e-fluor.gif
UltrafiltrationUltrafiltration
Usually used to Usually used to furtherfurther separate any separate any contaminants able to contaminants able to pass through the pass through the microfiltration microfiltration membrane using a membrane using a pressure gradientpressure gradient
Ultrafiltration image from: http://www.awatec.ch/produkte/ultrafiltration.jpg
How does Ultrafiltration work?How does Ultrafiltration work?
Separates:Separates: Particle size range: Particle size range:
0.10.1m to m to 0.0010.001m m
Usually based on Usually based on molecular weightmolecular weight Typical range: Typical range:
200 to 300,000 200 to 300,000 g/moleg/mole
Ultrafiltration image from: http://www.toltecint.com/how_dialysis_works/how_hemodialysis_works.htm
Microfiltration vs. UltrafiltrationMicrofiltration vs. Ultrafiltration
Microfiltration:Microfiltration: Proteins act as the Proteins act as the
permeatepermeate
UltrafiltrationUltrafiltration Proteins act as the Proteins act as the
retentateretentateImages from: http://www.geafiltration.com/html/technology/ftechnology.html
Microfiltration vs. UltrafiltrationMicrofiltration vs. Ultrafiltration
Microfiltration:Microfiltration: Separates larger particles Separates larger particles For example- For example-
ColloidsColloids Fat globulesFat globules Cells Cells
Located upstream to Located upstream to reduce load and fouling reduce load and fouling capacity on ultrafiltration capacity on ultrafiltration membrane downstream membrane downstream
UltrafiltrationUltrafiltration Separates smaller particlesSeparates smaller particles For example-For example-
MacromoleculesMacromolecules
However, However, processes are processes are basically identicalbasically identical
ReferencesReferences
[1] Case Study Solution - [1] Case Study Solution - Facility Design for Antigenic Facility Design for Antigenic Co-proteinsCo-proteins (2003). CHE 451. NCSU (2003). CHE 451. NCSU
[2] Grandison, A. S. & Lewis, M. J. (Eds.). (1996) [2] Grandison, A. S. & Lewis, M. J. (Eds.). (1996) Separation Processes in the Food and Biotechnology Separation Processes in the Food and Biotechnology IndustriesIndustries. Woodhead Publishing. Retrieved November . Woodhead Publishing. Retrieved November 30, 2003 from Knovel Chemistry and Chemical 30, 2003 from Knovel Chemistry and Chemical Engineering Database.Engineering Database.
[3] Zeman, L. J. & Zydney, A. L. (1996) [3] Zeman, L. J. & Zydney, A. L. (1996) Microfiltration Microfiltration and Ultrafiltration: Principles and Applicationsand Ultrafiltration: Principles and Applications. New York: . New York: Marcel Dekker, Inc. Available via NCSU libraries as an Marcel Dekker, Inc. Available via NCSU libraries as an eBookeBook