Imperial/Cell by Date/Specification
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The dominant organisms leading to the spoilage of beef depend of the beef's composition and the environmental conditions under which the beef is stored. For refrigerated packaged beef Pseudomonas spp. were dominate areobically while Lactobacillus was dominant anaerobically. [[IGEM:IMPERIAL/2007/Cell By Date/References|(12.Labuza,1993)]] Because bacteria are responsible for the spoilage of beef it is unwise to use a bacteria based device eg. by using e.coli/yeast as a chassis as this would further add to the spoilage. | The dominant organisms leading to the spoilage of beef depend of the beef's composition and the environmental conditions under which the beef is stored. For refrigerated packaged beef Pseudomonas spp. were dominate areobically while Lactobacillus was dominant anaerobically. [[IGEM:IMPERIAL/2007/Cell By Date/References|(12.Labuza,1993)]] Because bacteria are responsible for the spoilage of beef it is unwise to use a bacteria based device eg. by using e.coli/yeast as a chassis as this would further add to the spoilage. | ||
- | There also seems to be a general rule for beef that when the bacterial count reaches 10<sup>7</sup>cm<sup>-2</sup>, off odours and slime production occur and the beef is considered off. [[IGEM:IMPERIAL/2007/Cell By Date/References|(13.Food Hygiene,Microbiology and HACCP)&(10.Leak,1999)]] For controlled isothermal conditions in a laboratory environment the time taken for beef to reach this spoilage point seems to be at most 7 days.(Koutsoumanis 2005) This implies that the shelf life of our system needs to be at least 7 days. | + | There also seems to be a general rule for beef that when the bacterial count reaches 10<sup>7</sup> cm<sup>-2</sup>, off odours and slime production occur and the beef is considered off. [[IGEM:IMPERIAL/2007/Cell By Date/References|(13.Food Hygiene,Microbiology and HACCP)&(10.Leak,1999)]] For controlled isothermal conditions in a laboratory environment the time taken for beef to reach this spoilage point seems to be at most 7 days.(Koutsoumanis 2005) This implies that the shelf life of our system needs to be at least 7 days. |
- | The Gompertz's model is widely used when considering beef spoilage as it has been shown to fit growth data very well[[IGEM:IMPERIAL/2007/Cell By Date/References|(12.Labuza,1993)]]. Using the Gompertz model we can get the specific growth rate, Lag phase duration (LPD) and maximum population density (MPD) for bacterial growth at a particular constant temperature. And then using these we can determine the Activation Energy (Ea) for the beef spoilage reaction. For U2 grade Argentinian beef stored in polyethylene and SARAN PVC, the Ea ranged from | + | The Gompertz's model is widely used when considering beef spoilage as it has been shown to fit growth data very well[[IGEM:IMPERIAL/2007/Cell By Date/References|(12.Labuza,1993)]]. Using the Gompertz model we can get the specific growth rate, Lag phase duration (LPD) and maximum population density (MPD) for bacterial growth at a particular constant temperature. And then using these we can determine the Activation Energy (Ea) for the beef spoilage reaction. For U2 grade Argentinian beef stored in polyethylene and SARAN PVC, the Ea ranged from 80kJ mol<sup>-1</sup> to 220kJ mol<sup>-1</sup> for a range of bacteria. [[IGEM:IMPERIAL/2007/Cell By Date/References|(11.Giannuzzi,1997)]] |
- | One contrary value for the Ea of the beef spoilage rxns is given by Leak [[IGEM:IMPERIAL/2007/Cell By Date/References|(10.Leak,1999)]] who calculated Ea = | + | One contrary value for the Ea of the beef spoilage rxns is given by Leak [[IGEM:IMPERIAL/2007/Cell By Date/References|(10.Leak,1999)]] who calculated Ea = 30kJ mol<sup>-1</sup>. The difference between Leak's value and that of Giannuzzi probably lies in their packaging methods, which is of importance as the project aims to target aerobically fresh gound beef. |
===== A Biological Temperature Time Integrator ===== | ===== A Biological Temperature Time Integrator ===== | ||
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Several Technologies have already been developed to address the problem of monitoring the thermal exposure of products in the cold chain. One particular family of these products are called Temperature Time Integrators (TTI).[[IGEM:IMPERIAL/2007/Cell By Date/References|(2.Labuza,2006)]] | Several Technologies have already been developed to address the problem of monitoring the thermal exposure of products in the cold chain. One particular family of these products are called Temperature Time Integrators (TTI).[[IGEM:IMPERIAL/2007/Cell By Date/References|(2.Labuza,2006)]] | ||
- | The key aspect of a TTI is that they are based on a phenomenon which can act as a signal to a consumer for example, eg. a colour change. The rate at which this change occours needs to be temperature dependant so it can mimic the effect temperature has on the spoiling of meat eg. change happens quicker at higher temperatures. In order for a TTI to accurately report the spoilage rxn of beef, the activation energy of the two rxns needs to be similar. For example a difference between the two Ea's less than | + | The key aspect of a TTI is that they are based on a phenomenon which can act as a signal to a consumer for example, eg. a colour change. The rate at which this change occours needs to be temperature dependant so it can mimic the effect temperature has on the spoiling of meat eg. change happens quicker at higher temperatures. In order for a TTI to accurately report the spoilage rxn of beef, the activation energy of the two rxns needs to be similar. For example a difference between the two Ea's less than 20kJ mol<sup>-1</sup> would result in the TTI estimating the thermal history of the beef to be within 1 degree C of the actual history.[[IGEM:IMPERIAL/2007/Cell By Date/References|(1.Taoukis,2006)]] |
- | Applying this to our TTI this would mean that the Activation Energy of our system needs to be 30 +/- 20 kJ | + | Applying this to our TTI this would mean that the Activation Energy of our system needs to be 30 +/- 20 kJ mol<sup>-1</sup> if we are considering the most easily achieved activation energy found by Leak, which is most likely for aerobically fresh beef. |
In addition, to correctly coupld the Ea of our system to that of the dominant spoilage reaction in beef, we also have to consider the response time of our sytem. Our system needs to have a rapid response time, so in other words it needs to be able to quickly switch between states eg. low output and high output. This is so our system can capture small variations of temperature in the cold chain and report them in a meangingful way. Specifically, a response time in the order of a few hours would ensure that if there are any problems in the cold chain this will arise in our system very quickly. | In addition, to correctly coupld the Ea of our system to that of the dominant spoilage reaction in beef, we also have to consider the response time of our sytem. Our system needs to have a rapid response time, so in other words it needs to be able to quickly switch between states eg. low output and high output. This is so our system can capture small variations of temperature in the cold chain and report them in a meangingful way. Specifically, a response time in the order of a few hours would ensure that if there are any problems in the cold chain this will arise in our system very quickly. |
Revision as of 18:13, 21 October 2007
Cell by Date: Specifications
Inputs | |
Outputs | |
Activation Energy | |
Health Regulations | |
Response Time | |
Lifespan |
Project Plan
Targetting Aerobically Fresh Ground Beef
The dominant organisms leading to the spoilage of beef depend of the beef's composition and the environmental conditions under which the beef is stored. For refrigerated packaged beef Pseudomonas spp. were dominate areobically while Lactobacillus was dominant anaerobically. (12.Labuza,1993) Because bacteria are responsible for the spoilage of beef it is unwise to use a bacteria based device eg. by using e.coli/yeast as a chassis as this would further add to the spoilage.
There also seems to be a general rule for beef that when the bacterial count reaches 107 cm-2, off odours and slime production occur and the beef is considered off. (13.Food Hygiene,Microbiology and HACCP)&(10.Leak,1999) For controlled isothermal conditions in a laboratory environment the time taken for beef to reach this spoilage point seems to be at most 7 days.(Koutsoumanis 2005) This implies that the shelf life of our system needs to be at least 7 days.
The Gompertz's model is widely used when considering beef spoilage as it has been shown to fit growth data very well(12.Labuza,1993). Using the Gompertz model we can get the specific growth rate, Lag phase duration (LPD) and maximum population density (MPD) for bacterial growth at a particular constant temperature. And then using these we can determine the Activation Energy (Ea) for the beef spoilage reaction. For U2 grade Argentinian beef stored in polyethylene and SARAN PVC, the Ea ranged from 80kJ mol-1 to 220kJ mol-1 for a range of bacteria. (11.Giannuzzi,1997)
One contrary value for the Ea of the beef spoilage rxns is given by Leak (10.Leak,1999) who calculated Ea = 30kJ mol-1. The difference between Leak's value and that of Giannuzzi probably lies in their packaging methods, which is of importance as the project aims to target aerobically fresh gound beef.
A Biological Temperature Time Integrator
Temperature is considered to be the major factor in beef spoilage and although industry tries to keep temperature low during transportaion exposure of the beef to 10 degrees celcius are not unusual. It is therefore important that our that we look at the performance of our system in isothermal conditions eg. in the cold chain, and dynamic temperature scenarios eg. a break in the cold chain.
Several Technologies have already been developed to address the problem of monitoring the thermal exposure of products in the cold chain. One particular family of these products are called Temperature Time Integrators (TTI).(2.Labuza,2006)
The key aspect of a TTI is that they are based on a phenomenon which can act as a signal to a consumer for example, eg. a colour change. The rate at which this change occours needs to be temperature dependant so it can mimic the effect temperature has on the spoiling of meat eg. change happens quicker at higher temperatures. In order for a TTI to accurately report the spoilage rxn of beef, the activation energy of the two rxns needs to be similar. For example a difference between the two Ea's less than 20kJ mol-1 would result in the TTI estimating the thermal history of the beef to be within 1 degree C of the actual history.(1.Taoukis,2006)
Applying this to our TTI this would mean that the Activation Energy of our system needs to be 30 +/- 20 kJ mol-1 if we are considering the most easily achieved activation energy found by Leak, which is most likely for aerobically fresh beef.
In addition, to correctly coupld the Ea of our system to that of the dominant spoilage reaction in beef, we also have to consider the response time of our sytem. Our system needs to have a rapid response time, so in other words it needs to be able to quickly switch between states eg. low output and high output. This is so our system can capture small variations of temperature in the cold chain and report them in a meangingful way. Specifically, a response time in the order of a few hours would ensure that if there are any problems in the cold chain this will arise in our system very quickly.
References
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