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Integration of Chemical and Biological Engineering In The Undergraduate Curriculum: A Seamless Approach

Integration of Chemical and Biological Engineering In The Undergraduate Curriculum: A Seamless Approach. Howard Saltsburg Maria Flytzani-Stephanopoulos Kyongbum Lee David Kaplan Gregory Botsaris Aurelie Edwards Department of Chemical & Biological Engineering

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Integration of Chemical and Biological Engineering In The Undergraduate Curriculum: A Seamless Approach

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  1. Integration of Chemical and Biological Engineering In The Undergraduate Curriculum: A Seamless Approach Howard Saltsburg Maria Flytzani-Stephanopoulos Kyongbum Lee David Kaplan Gregory Botsaris Aurelie Edwards Department of Chemical & Biological Engineering Tufts University Medford MA ASEE 18 March 2006

  2. The Need For Change • ChE paradigm useful for more than 100 years • Response to industry based on • commodity chemicals(20s), petroleum (30s), • polymers (40-70s), traditional pharmaceuticals • All mature industries- little growth • Chemical engineering is flexible • new technologies accommodated with same core material • Biotechnology is major new growth area • Chemical Engineering can play an important role

  3. The Role of Chemical Engineering In Biological Engineering • All known life forms involve cells. • A cell is the smallest self-preserving and self-reproducing unit. • Many complex chemical reactions and complex transport processes occur • A cell looks like a chemical plant • Chemical engineers routinely work with that type of system.

  4. ANIMAL CELL: A CHEMICAL FACTORY Animal Cell: A Chemical Factory

  5. How To Optimize Education To Take Advantage Of The Opportunity • Biology becomes an integral part of the curriculum • Enabling sciences go from the • Traditional three legs • Chemistry, Math, Physics • To four legs • Chemistry, Math, Physics, Biology • ( basic understanding of molecular and • cellular biology) Some courses must be revised/altered/dropped to make room

  6. Molecular and Cellular Biology • “Biology is complex chemistry that works” • Chemical engineers will not become biologists • Must understand molecular biology and cell structures • Molecular biology is insufficient to understand cell function • Interaction of components defines the system. • A systems approach is necessary • Welcome to chemical engineering • .

  7. The “Patch” Approach • Problems in courses inadequate • Often disguise the real system problem by oversimplifying: • Kidney as simple separator • Body as pump and tubes • Liver as reactor • Modules as add-ons tend to be self-contained • Biological problems can be disconnected from the rest of the curriculum • Neither approach adds to the solution of a real problem Integrating the curriculum

  8. Fermentor System as a Patch LIQUID FEED KOH 5g/l LIQUID FEED LIQUID PRODUCTS Ethanol Sorbitol Glucose Fructose Byproducts Fermentor Zymomonas mobilis Yeast Extract 10g/l KH2PO4 1g/l MgSO4.7H2O .5g/l (NH4)2SO4 1g/l Glucose XgF g/l Fructose XfF g/l GASEOUS FEED Sterile Air 46.5 l/h

  9. Fermentor Patch Example as a Generic System LIQUID FEED LIQUID FEED LIQUID PRODUCTS Reactor GASEOUS FEED

  10. Another Patch ExampleRecycling in the LiverCO2 + 2NH4+ = urea and byproducts INPUT FROM BLOOD RECYCLE STREAM LIVER OUTPUT

  11. Simple Recycle With ReactionMethanol Synthesis RECYCLE STREAM FEED CO, H2,N2 REACTOR PRODUCT STREAM Methanol

  12. LIVER FUNCTIONS

  13. Urea Recycling in Kidney EFFERENT BLOOD FLOW RENAL BLOOD FLOW GENERAL CIRCULATION GLOMERULAR CAPILLARIES FILTRATE RECYCLE STREAM WATER NEPHRON LOOPS URINE

  14. Separation With Recycle OUTPUT FLOW INPUT FLOW COLLECTOR PRIMARYSEPARATOR FILTRATE RECYCLE LSTREAM SOLVENT SEPARATOR WASTE

  15. Kidney : Another Factory

  16. Urine Formation: Separation

  17. Transport Processes

  18. Appropriate Approaches for Chemical Engineering • Ground rule: • Since future “hot topics” are unknown, we do not want to destroy the traditional base as there is a fundamental intellectual core to the subject. • The biological and biomedical engineering approach is too narrow as they are derivatives of the chemical engineering core • Chemical engineers will not become molecular biologists but must understand it

  19. The Seamless Approach • A biological system is simply another system • Usual approach to problem solving by chemical engineers is applicable • Traditional approaches and material must be included • Students must be able to function in a wide variety of technical situations involving chemistry and biology • Students will work on both types of systems (biological and chemical) simultaneously in each core course • Similarities as well as differences can be exposed. • We develop an understanding of multiscale issues and systems.

  20. The Thread • Comparison between a biological system • cell, organ, organism and • traditional chemical plant (specialty, commodity) is examined in the first course. • Choice of the chemical system can introduce new material (polymers, semiconductors). . • Subsequent courses examine same systems with the detail appropriate to the new course material. • The content of the entire curriculum is connected • The overall program is brought into context. • Issues of scale and complexity are introduced naturally

  21. Term Projects ChBE 10 Chemical Process Calculations • . • To what extent can the behavior of a biological cell (as a chemical manufacturing plant) be described by a series of unit operations comparable to those considered in traditional chemical industry. • You are to describe a traditional chemical process in terms of relevant unit operations and do the same type of analysis for a biological cell.. Then, compare the two analyses. • What are similarities and dissimilarities? What do you need to know to carry out such an analysis? Include both material and energy balance considerations. What is the role of thermodynamics in this discussion?

  22. Types of Cells • Prokaryotes: single-celled organisms without nucleus (e.g. bacteria) • 1-10 microns, • very few cytoplasmic structures • Eukaryotes: organisms whose cells have membrane bound nuclei • that contain their genetic material, single cells to higher organisms • 10-100 microns • highly structured (intercellular membranes, cytoskeleton) • Archaea: prokaryotes often living in extreme environments • (geysers; alkaline, salty, or acid water) • Unusual biochemistry (CO2 to CH4; H2S to H2SO4)

  23. Projects 2003 Biological Cell Type Chemical Process Archaea Prokaryote Eukaryote Archaea Procaryote Eucaryote Archaea Ammonia production Polyethylene Pennicillin Sulfuric Acid Crude Oil to Gasoline Ethanol Bakers Yeast

  24. A PROCESS ANALYSIS OF SULFURIC ACID PRODUCTION & ARCHAEAL CELLS NUCLEOID DNA + mRNA CYTOPLASM tRNA tRNA mRNA AMINO ACIDS GLUCOSE TRANSPORT PROTEIN H2S REACTION UNIT H2S + O2 H2SO4 RIBOSOME ATP O2 PROTEIN H2SO4 H2SO4 ENZYMES ADP INORGANIC P PLASMA MEMBRANE

  25. Ethanol Production

  26. Student Projects 2004 Ethanol production Biological: Zymomonas mobilis CP4 Chemical(macro): Continous fermentation of corn mash with the product stream processed Ammonia Synthesis Biological ADS positive bacteria Chemical Haber process

  27. Fermentor System LIQUID FEED KOH 5g/l LIQUID FEED LIQUID PRODUCTS Ethanol Sorbitol Glucose Fructose Byproducts Fermentor Zymomonas mobilis Yeast Extract 10g/l KH2PO4 1g/l MgSO4.7H2O .5g/l (NH4)2SO4 1g/l Glucose XgF g/l Fructose XfF g/l GASEOUS FEED Sterile Air 46.5 l/h

  28. Macro Bioprocessing CONDENSER GLUCOSE CO2 STRIPPER CORN MASH FERMENTOR BLOWER S T EAM CO2 RECYCLE BACK FEED

  29. Details of Thread • As students proceed to the next course, they will take on a new “pair”, one previously studied in the previous class by another group. • To avoid a new start, the student team responsible for this previous study will tutor the new group just as they will be tutored for their new project • This insures teamwork and peer instruction • After three years, students will have seen a variety of chemical and biological systems. The sequence will form the thread connecting the components of the curriculum and placing it in context.

  30. Ammonia Clearance from BloodThe Reactor Analysis • Free ammonium ion (NH4+) is toxic at high concentrations • In the body, the liver removes NH4+ by forming urea (CO(NH2)2); this process is not an elementary reaction; it involves multiple enzyme-catalyzed steps. • Net stoichiometry:

  31. Rate Law • Simplified power-law approximation (assumes CO2 is in excess):

  32. Reaction Order Estimate from Batch Data Culture conditions: 10×106 cells/mL, 1 mL culture volume n = 1 n = 2 ka = 0.08 min-1 Max rate:

  33. Cell Mass Requirement • Elimination of nitrogen through urine in average adult: 10 g/day • NH3 elimination: 12 g/day (assuming 100 % association with urea) Possible liver bioreactor perfusion configurations: Are there any limitations on bioreactor size and density (cell-to-volume ratio)?

  34. Caveats From a Molecular Biologist Shape counts Simple decomposition into units will not provide all answers From a Chemical Engineer Is this biology or what engineers think is biology ?

  35. Summary • A “ new” approach to integrating biology into chemical engineering based on a “threaded” curriculum is described • This approach provides integration of material over all four years coupling content with context • Students discover that they can learn new material not taught in courses even at the sophomore level • As we provide a general chemistry background, we also provide a general biology background • Details of curriculum development workshops on web • http://ase.tufts.edu/chemical// • Supported by an NSF Curriculum Planning Grant

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