Team:Grenoble/Safety/Assesment
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- | <a href="https://2012.igem.org/Team:Grenoble/Safety/Assesment#72">second approach</a> | + | <li><a href="https://2012.igem.org/Team:Grenoble/Safety/Assesment#72">second approach</a></li> |
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Revision as of 14:09, 29 August 2012
Get deeper into safety
Information you have to read
Explanation of methods
RISK ASSESSMENT
In this part we explain the method and results of the risk prevention made during the project.Explanation
Before explaining what was done, here are defined some terms.A risk
It is a possibility that a dangerous phenomenon can cause damage to a given target.A risk assessment
A risk assessment tries to define all risks in presence , evaluates the probability and the gravity of each one.Safety and Security
A difference should be made between Safety and Security. Safety intends to reduce risks in terms of accidents, incidents, damage due to them and consequences of these activities on health. On the other hand, Security deals with the misuse of devices and voluntary acts which creates risks for others. We only worked on the safety during the project.The context
We worked in the CIME-Nanotech. The laboratory belongs to the INPG safety department which took care of the team during the project. This department has the following structure:
To prevent any problems with the team, each member signed a regulation that compelled us to respect some rules:
- Work between 7 A.M. and 7 P.M. because of safety problems
- Use and do not lend the personal badge which permits to enter in the laboratory
- Do not work alone in the laboratory
- Do not eat nor drink in the laboratory
- Do not smoke in the laboratory
- Use good laboratory practices
- All products must be tagged and a stock status has to be regularly updated
what has been done
In the context of iGEM we have:- Spotted the main risks
- Reduced the chemical risk
- Checked if the UV risk was under control
- Improved the safety in biology
Spotting main risks
In order to improve the safety of our project and to be efficient, we focused first on spotting the main risks due to laboratory manipulations. To this end, we made an inventory of all devices and manipulations which would be used and done. Chemical risk Explosion risk Mechanical risk Risk due to devices under pressure Risk related to ionizing radiation Biological risk We made a parallel between our risk assessment and the one made by the safety department of the CIME.How to read a risk assessment grid?
This study led us to three main risks:
- The chemical risk
- The risk related to ionizing radiation (UV)
- And the biological risk
Reduction of the chemical risk
It appears that it is essentially the revelation of the DNA with the ethidium bromide (EtBr) which is dangerous. Indeed, EtBr is a mutagen product of level 2, meaning that its mutagenicity effect was confirmed on animals at low concentration (no exposure limit value is given by the manufacturer). We must therefore follow the precautionary principle, especially because it is stored in its purest form. Regarding contamination, direct contact with skin is the only way to be exposed. Indeed, the saturation vapor pressure of ethidium bromide is relatively low. In theory no exposure occurs.How are chemical products classified
In the laboratory the risk is taken very seriously. An area is exclusively devoted for its use. Moreover nitrile gloves are available as well as full face protections. Finally a specific dustbin is in place for disposal. (For more details see the safety manual practice).
To find information, we sought the EtBr MSDS. We first wanted to know where EtBr was, to check if there is any risk of being in contact with the product. To detect its presence we used an UltraViolet (UV) lamp. Red circled areas were positively controlled.
To prevent the use of EtBr, we tried to find substitutes. We found the NANCY-520 and the SYBER-SAFE. However the NANCY 520 could not be used because we did not have the appropriate wavelength on our lamp. As far as the SYBER-SAFE® is concerned, it appears to be safer, but the revelation takes too much time. It did not meet our needs. Therefore we did not change the product.
Then we used regulation and we managed to improve the workstation via three ways:
- Work organization
- Technic
- Training
Our work led us to put in place these things:
Moreover a protocol was set up. Here you have a video, that shows the main things to know. (in a funny way)
Check if the UV risk is under control
The revelation needs to use an UV lamp (312nm at 48W). But biologists need to be very close to the lamp to cut gels. Therefore we checked if PPE (Personal Protective Equipment) were efficient. The verification confirmed that our equipment meets the standard requirements, thus we can say that the risk is under control .Improve the safety in biology
Synthetic biology is a new field in biology and intends to develop new organisms with new genetic systems. Therefore it could also be a new way of developing technologies. However for every new activity, there are new risks. The dangerous effect assessment needs to be split into two parts. The first one deals with direct effect due to the recognized pathogenicity of the biological elements that we used. The second part takes care of potential effects that could be due to genetic modifications.First approach
The first thing on which we focused was the spreading of microorganisms. Indeed, we are not able to know if potential effects can occur, thus we tried to figure out how we could get in contact with microorganisms.
To achieve this characterization, we followed those steps
Thanks to their study we focused on the ones where microorganisms are present. By using a grid of assessment we found steps that generate possible aerosols. This grid is available here.
This approach led us to do a failure modes and effects analysis.
what is a failure modes and effect analysis
It is a technique which consists in focusing on each equipment and material used. The goal is to understand what happens when something goes wrong. The result is given as following. Finally we put all important information in a fault tree analysis.What is a fault tree analysis
A fault tree analysis is another technique, which consists in listing all elements that can cause a dreaded phenomenon. These events are then linked thanks to Boolean logic connectors. The assembly is then placed in a scheme which allows you to draw all the scenarios involved in the dreaded phenomenon or situation.
In the following fault tree analysis we represented the steps in which we could have a potential propagation of microorganisms.
The tree emphasizes the fact that we have three different kinds of situations which could lead to microorganisms propagation:
- normal situations
- situations caused by human errors, or failures to internal manipulations
- situations induced by events unrelated to manipulations’ mistakes
Second approach
To deal with the issue of biological risks, we focused our work on the first step of prevention which is the identification of all information to assess the risk. Prevention can only be put in place thank to feedbacks. Thus, we needed a device or an organization which enabled us to record them. In the context of iGEM, we had an idea that we called the BioBrick Safety Sheet (BSS). This sheet aims at:- Improving the way of collecting information on how BioBricks can be used safely
- Assisting biologists in their work
- Establishing a standardized system to collect information in synthetic biology