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− | < | + | <center><h1><b>CHEESEMAKER FROM BURT'S CHEESE</b></h1></center> |
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− | < | + | <li><p>When we learned of the problems with <i>Listeria</i> contamination in food we were eager to learn more about the cheesemaking industry tackles this problem. We first visited a local cheese maker Claire Burt to get to know about the cheese making process and a local cheesemaker’s perspective about our idea.</p></li> |
− | < | + | <li><p>We found that the commercial cheese making process is very sensitive and needs to be highly controlled.</p></li> |
− | <li>We found that the commercial cheese making process is very sensitive and needs to be highly controlled.</li> | + | <li><p>Claire explained to us that <i>Listeria</i> contamination can occur in the very first stages of cheese production, which indicated to us that having a biosensor which could detect contamination in these early stages (i.e., by being incorporated into cheese starter culture) would be invaluable. She also told us that there is possibility for contamination on various surfaces or water used in the process. That suggested us that having a cell-free or an isolated-cell test would be more convenient than a biosensor integrated into the product. Hearing that, we started modelling an isolated-cell system to be able to predict how quickly such test could detect pathogenic bacteria (<a target="_blank" href="https://2018.igem.org/Team:Manchester/Model"/>read more</a>).</p></li> |
− | <li>Claire explained to us that | + | |
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+ | <center><img src="https://static.igem.org/mediawiki/2018/1/11/T--Manchester--Burts.png" width="300px" height=auto/></center> | ||
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+ | <center><p>Ryan at Burt's Cheese, Cheshire </p></center> | ||
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+ | <p>On the 5th of June, we were kindly invited to ‘Burt’s Cheese’ in Cheshire. The owner, Claire Burt, was generous enough to give us a full demonstration of the cheese making process where we learned the importance of pH and temperature control in cheese manufacture. With this data, we were able to amend our planned cheese making protocol to fit better for a soft, white mould cheese. Claire told us that contamination can occur from the beginning of the cheese making process, so we decided our biosensor should be present from the earliest stage of the cheese making process i.e. the starter culture. Our original cheese making protocol did not use any other live culture besides <i>E. coli</i> Nissle 1917 (a probiotic strain) but Claire advised us to include other cultures. These other cultures are used to produce flavors and/or CO<sub>2</sub> in cheese with eyes (holes). This meant we now needed to control for pH and temperature more strictly. For example, culture must be added at 17°C and increased slowly to 30°C rather than simply heating to 32°C. We were also informed that it was important to check the pH of the milk is as close to 6.74 as possible for an optimal batch.</p> | ||
+ | <p>Claire Burt also gave us a good insight into the hygiene practices she must adhere to ensure her cheese is safe. For example, Claire uses an ozone producing machine in order to control phage contamination. There is also a strict hygiene checkpoint at which hairnets, lab coats and shoes are changed to minimise the introduction of outside contaminants. We discovered where and how any foodborne pathogens can enter the process. Of particular concern to Mrs. Burt was the hygiene quality of the large metal vat that the farm used to store pasteurised milk. She also stated that <i>Listeria</i>, when present, is often on surfaces and within the water. In addition to this, we learnt that small-scale cheese producers often only send swab samples to labs every 3 months due to the high costs associated with testing. An outbreak of <i>Listeria</i> can be extremely damaging within this space of time. For example, a recent <i>L. monocytogenes</i> outbreak in South Africa lasted 15 months, infecting over 1000 and killing over 200 people (Blomfield, 2018). <br>As a result, we started considering an isolated-cell test which could be used to detect any surface contamination. The detection system should be very precise and quick and so we started modelling one to see how many <i>Listeria</i> the test could detect or how quickly (<a target="_blank" href="https://2018.igem.org/Team:Manchester/Model"/>read more</a>).</p> | ||
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Latest revision as of 00:20, 18 October 2018
CHEESEMAKER FROM BURT'S CHEESE
When we learned of the problems with Listeria contamination in food we were eager to learn more about the cheesemaking industry tackles this problem. We first visited a local cheese maker Claire Burt to get to know about the cheese making process and a local cheesemaker’s perspective about our idea.
We found that the commercial cheese making process is very sensitive and needs to be highly controlled.
Claire explained to us that Listeria contamination can occur in the very first stages of cheese production, which indicated to us that having a biosensor which could detect contamination in these early stages (i.e., by being incorporated into cheese starter culture) would be invaluable. She also told us that there is possibility for contamination on various surfaces or water used in the process. That suggested us that having a cell-free or an isolated-cell test would be more convenient than a biosensor integrated into the product. Hearing that, we started modelling an isolated-cell system to be able to predict how quickly such test could detect pathogenic bacteria (read more).
Ryan at Burt's Cheese, Cheshire
On the 5th of June, we were kindly invited to ‘Burt’s Cheese’ in Cheshire. The owner, Claire Burt, was generous enough to give us a full demonstration of the cheese making process where we learned the importance of pH and temperature control in cheese manufacture. With this data, we were able to amend our planned cheese making protocol to fit better for a soft, white mould cheese. Claire told us that contamination can occur from the beginning of the cheese making process, so we decided our biosensor should be present from the earliest stage of the cheese making process i.e. the starter culture. Our original cheese making protocol did not use any other live culture besides E. coli Nissle 1917 (a probiotic strain) but Claire advised us to include other cultures. These other cultures are used to produce flavors and/or CO2 in cheese with eyes (holes). This meant we now needed to control for pH and temperature more strictly. For example, culture must be added at 17°C and increased slowly to 30°C rather than simply heating to 32°C. We were also informed that it was important to check the pH of the milk is as close to 6.74 as possible for an optimal batch.
Claire Burt also gave us a good insight into the hygiene practices she must adhere to ensure her cheese is safe. For example, Claire uses an ozone producing machine in order to control phage contamination. There is also a strict hygiene checkpoint at which hairnets, lab coats and shoes are changed to minimise the introduction of outside contaminants. We discovered where and how any foodborne pathogens can enter the process. Of particular concern to Mrs. Burt was the hygiene quality of the large metal vat that the farm used to store pasteurised milk. She also stated that Listeria, when present, is often on surfaces and within the water. In addition to this, we learnt that small-scale cheese producers often only send swab samples to labs every 3 months due to the high costs associated with testing. An outbreak of Listeria can be extremely damaging within this space of time. For example, a recent L. monocytogenes outbreak in South Africa lasted 15 months, infecting over 1000 and killing over 200 people (Blomfield, 2018).
As a result, we started considering an isolated-cell test which could be used to detect any surface contamination. The detection system should be very precise and quick and so we started modelling one to see how many Listeria the test could detect or how quickly (read more).