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  • >>We all know something about fermentation.

  • It's a process used countless times each day to make a variety of dairy products, baked

  • goods and beverages. We sometimes think of it as letting foods

  • go bad, but in a controlled way. With a little help, milk becomes yogurt...

  • bread rises... and grains decompose, creating alcoholic beverages

  • and alternative fuels.

  • >>But looking at these examples only gives us a clue as to what's really happening and

  • how we can use the power of fermentation to cost-effectively create a broad array of biological

  • products.

  • >>So, what is fermentation?

  • A cell can be thought of as a micro-factory. These cells can be bacteria, fungi or specific

  • cells from mammals, plants or insects. In Biotechnology, these cells are used to manufacture

  • a product in a process called fermentation.

  • >>For yogurt, buttermilk and cheese, we use bacteria.

  • To make breads and alcoholic beverages we use yeast - a fungus!

  • And the production of some vaccines requires the growth of mammalian cells that are infected

  • with a specific virus.

  • >>The product the cells manufacture is usually a chemical the cells contain naturally...

  • or a substance that the cells have been genetically altered to create...

  • or even a metabolic waste product of the organism's growth - like one of our examples, alcohol!

  • >>There are too many everyday products created by commercial-scale fermentation to even list,

  • but some common ones include: amino acids, biopharmaceuticals, dyes, enzymes, food products,

  • lipids, steroids and vitamins.

  • [Music Fades, Nat Sound of Process Establishes, Under For VO]

  • >>Fermentation is a reasonably simple process. A cell is selected based on its ability to

  • produce the desired product. A seed stock of cells is put into a small

  • amount of media. Media provides the nutritional products the cell needs to grow.

  • When the population of cells has grown and consumed most of the nutrients, it's moved

  • into a larger vessel with more growth media, and the process repeats...

  • This "scaling-up" is complete when the quantity of cells is large and healthy enough to transfer

  • into a production vessel - often referred to as a bioreactor or fermentor.

  • >>With plenty of fresh media now available and under tightly controlled conditions, the

  • cells grow and manufacture product. When the fermentation is complete, the product

  • is harvested.

  • >>Fermentation is known as an "upstream" biotechnology process. It occurs early in the production

  • flow, before Recovery, Purification, Formulation, Filling and Packaging.

  • To better understand the fermentation process, we should first find out a little bit about

  • the cells we use and what they may require to reproduce and stay healthy.

  • Different cells have different needs. Some are aerobic - they need oxygen - while others

  • are anaerobic and do not require oxygen.

  • >>All cells require nutrition. A properly formulated media contains the necessary nutrients

  • to allow cells to grow and produce. The fermentor mixes the cells evenly throughout

  • the media to suspend the cells and supply the oxygen necessary for growth.

  • Effective and efficient fermentation requires rigorous monitoring and control of the environment

  • within the bioreactor. Key factors include temperature, pressure,

  • pH - which is a measure of how acidic or alkaline the media is, oxygen - usually measured as

  • dissolved oxygen within the media, and nutrient levels.

  • Although the environment and the media are tailored to the needs of specific cells, the

  • lifecycle of almost all batches follows a predictable pattern.

  • The growth pattern has four phases: Lag, Exponential or Log, Stationary and Death.

  • >>When a cell is first introduced to fresh media, it has to adapt to its new environment.

  • This creates a lull or Lag in the growth timeline. After the organism adapts, the batch takes

  • off! The cells begin dividing at a constant rate - an Exponential or Logarithmic (or "Log")

  • increase; doubling, then doubling again, and on and on...

  • As the nutrients in the media are consumed, toxic metabolic waste products build up, cells

  • begin to die, and growth slows. When it reaches the point that just as many

  • cells are dying as are dividing, the batch enters the Stationary phase.

  • This is the point at which the key nutrients are completely consumed, the fermentation

  • is stopped and the fermented broth is harvested. If the fermentation were allowed to continue,

  • the cells would enter the Death phase. More cells die than divide, and - similar to the

  • Exponential phase - the death rate increases logarithmically.

  • Now that we have a basic understanding of how Fermentation works, let's look at an actual

  • process and see how it all comes together.

  • For our sample process we will look at the production of Green Fluorescent Protein, or

  • GFP. GFP is broadly used as a biological marker.

  • It's a fluorescent dye that's very well tolerated by most cells and doesn't interfere with normal

  • cellular function..

  • In the GFP fermentation process, we'll need to add an antibiotic to protect the purity

  • of the batch, and then - late in the process - a biochemical inducer to "turn on" the GFP

  • gene Our materials for this process will include:

  • A bacteria seed stock - in this case E. coli - that has been genetically enhanced to produce

  • GFP... the basic ingredients for a compatible media

  • which include nutrients, stabilizers, an antibiotic and an antifoaming agent...

  • and IPTG which is the biochemical inducer that "switches-on" the GFP gene.

  • The equipment that we'll be using includes a 300 liter bioreactor,

  • a UV/Vis Spectrophotometer to monitor the optical density, which is a measure of the

  • concentration of cells in the bioreactor - a glucose analyzer, to measure glucose, a

  • key nutrient - an off-line, pH meter to help track the acid/base

  • balance, and adjust on-line measurements, if needed...

  • and a Broth Tank for our final product.

  • The bioreactor is equipped with a water jacket around the vessel to regulate temperature,

  • and integrated sensors to monitor key environmental factors, including dissolved oxygen, pH, internal

  • temperature, water-jacket temperature and vessel pressure.

  • The reactor also has an agitator, dedicated ports for adding seed stock and media ingredients,

  • separate ports for acid and base supplement, air filters for supply and exhaust, and valves

  • for drawing samples and for harvesting. Most fermentation and monitoring functions

  • can be managed from the bioreactor's dedicated process controller.

  • Before the fermentation process can begin, the area must be prepared.

  • Preparation includes removing equipment and material that won't be used in the process...

  • Cleaning and sanitizing the area and equipment... and sterilizing equipment as required by the

  • SOPs - Standard Operating Procedures. Sterilization is used to eliminate unwanted

  • microorganisms which can grow naturally in the fermentation media and process equipment.

  • Also, all required materials and documentation should be gathered and prepared...

  • and all Process Control software should be loaded and verified.

  • The Fermentation batch process will be guided and documented with the BPR - Batch Process

  • Record. The Batch Record leads the operator through

  • the process, step-by-step... with each step requiring a sign-off and separate

  • verification. This record also includes spaces for documenting

  • key times, activities and instrument readings.

  • The GFP fermentation process really begins with the expansion of our bacteria seed stock.

  • After removing the specially modified E-coli from the freezer and thawing it...

  • It's used to inoculate a small amount of fresh media in a shaker flask.

  • After the number of cells has reached the target amount, the thriving cells are ready

  • for fermentation. Meanwhile, in the Fermentation area, operators

  • begin with a complete check of all critical equipment.

  • Valves, caps and lines are checked, hoses are tightened...

  • probes are verified and calibrated. and 10 kilograms of HPW - High Purity Water

  • - is added to the vessel.

  • The bioreactor is brought up to normal process pressure and held there in order to check

  • for leaks. The pressure is monitored over a 30 minute

  • period. If a leak is detected, the problem is corrected

  • and the test is run again. Once the reactor passes the test, we are ready

  • to mix the media in the vessel. The agitator is turned on, and the ingredients

  • are added: Yeast Extract...

  • Tryptic Soy Broth... Ammonium chloride...

  • Sodium biphosphate... Monopotassium phosphate...

  • and an Antifoam compound.

  • Once all the initial ingredients are in, another 10 kilograms of High Purity Water is added...

  • all ports and valves are closed... all condensate valves are opened...

  • and the bioreactor begins an SIP - Sterilize-In-Place cycle.

  • The target for sterilization is 121 degrees Celsius for 30 minutes.

  • As soon as the temperature climbs to the targeted temperature, the condensate valves are closed,

  • and the SIP cycle completes automatically.

  • Both the vessel and the media are now sterile -

  • And we're ready to add the final ingredients to our media.

  • The glucose hose is attached to the vessel the connection is steamed to sterilize it

  • and the separately sterilized glucose-antibiotic solution is pumped into the vessel.

  • Then a manual pH reading of the media is taken and the bioreactor is set up for its fermentation

  • cycle. After the inoculation hose is connected to

  • the reactor and steamed for 20 minutes

  • the expanded seed stock is pumped into the reactor containing the media.

  • Fermentation now begins. The operator takes zero hour readings and begins to regularly

  • monitor batch temperature, agitator RPMs, dissolved oxygen levels, pH, vessel pressure,

  • optical density, air flow rate and glucose concentrations.

  • Optical Densities and glucose concentrations are of particular interest, so they're graphed

  • as well as documented. When the targeted levels of glucose and optical

  • density are achieved, it's time to add IPTG to the vessel to activate

  • or turn on the expression of the Green Fluorescent Protein in the cells.

  • After allowing enough time for the cells to produce green fluorescent protein usually

  • 5 hours more, final readings are taken and a sample is drawn to check the percentage

  • of cell solids.

  • The product is now referred to as "broth." The broth, which contains spent media and

  • cells, is complete when the key nutrient, glucose, is mostly consumed, and the batch

  • has reached the desired concentration.

  • The batch is then cooled down, pumped into a broth tank...

  • and labeled with the batch number, volume, time and date.

  • [Bright, Rhythm-Driven Music Establishes, Then Under For VO]

  • The Fermentation process is now complete!

  • The harvested broth will now move downstream to the Recovery process where the cells will

  • be ruptured to free the Green Fluorescent Protein

  • and the protein will be separated from the other broth components.

>>We all know something about fermentation.

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