Difference between revisions of "Team:Berlin/safety"

(Created page with "<html> <style> iGEM Paris Bettencourt 2015 style * Design by Jérémy Ferrando & Ewen Corre * It's FREE! But you can send us beer at * beer@corre.bio :-): /* RES...")
 
 
(12 intermediate revisions by one other user not shown)
Line 114: Line 114:
  
 
<!-- Begin Cover -->
 
<!-- Begin Cover -->
<div class="site-wrapper-sub-project">
+
<div class="site-wrapper-sub-safety">
 
</html>
 
</html>
 
{{Berlin/inc/main-menue.php}}
 
{{Berlin/inc/main-menue.php}}
Line 129: Line 129:
 
         <h2>SAFETY</h2>
 
         <h2>SAFETY</h2>
 
           <div class="teaser-text-sub">
 
           <div class="teaser-text-sub">
             <div class="col-md-12">Our country uses a four-part „Safety Level“ rating system for laboratories. Level 4 is used for the most dangerous organisms. <br/>This is equivalent to the WHO system. The Safety Level of our lab is Level 1 (low risk).<br/><br/></div>
+
             <div class="col-md-12">
 +
<strong>Our country uses a four-part „Safety Level“ rating system for laboratories. Level 4 is used for the most dangerous organisms. <br/>This is equivalent to the WHO system. The Safety Level of our lab is Level 1 (no risk).</strong>
 +
<br/><br/><br/></div>
 
           </div>
 
           </div>
 
       </div>
 
       </div>
Line 137: Line 139:
 
     <h1>About our lab</h1>
 
     <h1>About our lab</h1>
 
     <strong>Material used:</strong><br/>
 
     <strong>Material used:</strong><br/>
     We use open benches and Laminar flow hood / biosafety cabinet with open front to handle biological materials.<br/>
+
     We use open benches and Laminar flow hoods / biosafety cabinets with open fronts to handle biological materials.<br/>
     We handle cancerogenous materials such as ethidium bromide or polyacrylamide under separate closable hoods. Also acidic and basic solutions are handeled behind closable hoods. All radioactive materials or methods are located in a separate laboratory in the basement.<br/>
+
     We handle cancerogenous materials such as ethidium bromide or polyacrylamide under separate fume hoods. Also acidic and basic solutions are handeled behind fume hoods. All radioactive materials or methods are located in a separate laboratory in the basement.<br/>
 
     We also have a separate room for RNA work.<br/>
 
     We also have a separate room for RNA work.<br/>
 
     <br/>
 
     <br/>
 
     <strong>Protection:</strong><br/>
 
     <strong>Protection:</strong><br/>
     For protecting ourselves while doing lab chores, we use full face shields during cutting out gels or any work that involves longer exposure to UV radiation. We certainly use nitril gloves for handling any ethidium bromide and polyacrylamide contaminated materials. Safety glasses are frequently worn, especially if dangerous materials like acids, bases and liquid nitrogene are used or if there is anything that can splash like at the AKTA. Fur using -80°C freezers we use isolated gloves.<br/>
+
     For protecting ourselves while doing lab chores, we use full face shields during gel excision or any work that involves longer exposure to UV radiation. We certainly use nitril gloves for handling any ethidium bromide and polyacrylamide contaminated materials. Safety glasses are used, especially if dangerous materials like acids, bases and liquid nitrogene are handeled or if there is anything that can splash like at the AKTA. When using -80°C freezers we use isolated gloves.<br/>
 
     The laboratory safety training requirements of the Technical University Berlin can be found <a href="http://www.biophys-chemie.tu-berlin.de/menue/service/sicherheit/" target="blank">here</a> or <a href="http://bgi850-0.vur.jedermann.de/index.jsp?isbn=bgi850-0&alias=bgc_bi850_0_bi850_0e_1_" target="blank">here (BG RCI)</a>.<br/>
 
     The laboratory safety training requirements of the Technical University Berlin can be found <a href="http://www.biophys-chemie.tu-berlin.de/menue/service/sicherheit/" target="blank">here</a> or <a href="http://bgi850-0.vur.jedermann.de/index.jsp?isbn=bgi850-0&alias=bgc_bi850_0_bi850_0e_1_" target="blank">here (BG RCI)</a>.<br/>
 
     <br/>
 
     <br/>
     All Team members received a safety training.<br/>
+
     All Team members received a safety briefing from a faculty member.<br/>
 
     <br/>
 
     <br/>
 
     <strong>Disposal:</strong><br/>
 
     <strong>Disposal:</strong><br/>
     We collect biological waste in big containers within the lab and autoclave it later. The autoclaved waste is then taken care of by the institute. Contaminated and non-contaminated broken glas are collected separately. There is also a separate waste for cancerogenous and environmental hazardous waste like ethidium bromide gels etc.<br/>
+
     We collect biological waste in big containers within the lab and autoclave it later. The autoclaved waste is then taken care of by the institute. Contaminated and non-contaminated broken glasware is collected separately. There is also a separate waste for cancerogenous and environmentally hazardous waste like ethidium bromide gels etc.<br/>
 
     <br/>
 
     <br/>
 
     <strong>Biosafety guidelines of the Technical University Berlin:</strong><br/>
 
     <strong>Biosafety guidelines of the Technical University Berlin:</strong><br/>
     The Institutional Biosafety Officer (BSO) is responsible for ensuring that laboratories are working safetly with biohazardous materials. This includes the periodic inspection of laboratories, developing emergency plans for handling spills and accidents and investigating laboratory accidents involving biohazardous materials. The BSO also provides technical consultation for researchers on conducting risk assessments, safety practices, and security. Environmental Health and Safety provides services necessary for biological research. These services include biomedical waste disposal, autoclave quality assurance, biosafety cabinet certification, biosafety inspections, training and emergency response. Know the hazards associated with the biological materials and procedures used in the laboratory. Follow approved lab procedures and safety guidelines. Know the emergency procedures. Complete all required training before conducting any lab activity. Utilize all required Personal Protective Equipment. Do not work alone in the laboratory.<br/>
+
     The Institutional Biosafety Officer (BSO) is responsible for ensuring that laboratories are working safetly with biohazardous materials. This includes the periodic inspection of laboratories, developing emergency plans for handling spills and accidents and investigating laboratory accidents involving biohazardous materials. The BSO also provides technical consultation for researchers on conducting risk assessments, safety practices, and security. Environmental Health and Safety provides services necessary for biological research. These services include biomedical waste disposal, autoclave quality assurance, biosafety cabinet certification, biosafety inspections, training and emergency response. Know the hazards associated with the biological materials and procedures used within the laboratories. Follow approved lab procedures and safety guidelines. Know the emergency procedures. Complete all required training before conducting any lab activity. Utilize all required Personal Protective Equipment. Do not work alone in the laboratory.<br/>
 
     <br/>
 
     <br/>
 
     <strong>German regulations that govern biosafety in research laboratories:</strong><br/>
 
     <strong>German regulations that govern biosafety in research laboratories:</strong><br/>
Line 160: Line 162:
 
     <br/>
 
     <br/>
 
     <br/>
 
     <br/>
    <h1>Identified possible risks<br/> of our project</h1>
 
    At this point we want to show that we have dealt with the possible risks of our project.<br/>
 
    <strong>Risks to the safety and health of team members, or other people working in the lab:</strong><br/>
 
    We are working with E.coli, the strains we are using are characterized as non-pathogenic, BSL 1. However, we try to modify E.coli by knocking out genes - therefore, every person who is working in the lab has to take care of the possible risks. Consequently, it is mandatory to wear labcoats and gloves to minimize any risk of contamination. Also for other labwork e.g. dealing with chemicals such as Ethidium bromide, team members have to use the Personal Protective Equipment (PPE) and have to be personally instructed.<br/>
 
    <strong>Risks to the safety and health of the general public (if any biological materials escaped from our lab):</strong><br/>
 
    We are using non-pathogenic E. coli strains and even our genetically modified E.coli strains are not changing the risk of pathogenic influences on human beings. Nevertheless, we are taking care to avoid any possibility of contaminating the environment with our E.coli strain or any kind of non-natural agents.<br/>
 
    <strong>Risks to the environment (from waste disposal, or from materials escaping from our lab):</strong><br/>
 
    Material which was in contact with any organisms is autoclaved by normal BSL-1 procedures. Organic solvents, solutions as well as agarose gels and gloves containing Ethidium bromide are separately disposed according to the guidelines of our institution. We are strictly trying to reduce the amount of contaminated material and also the amount of consumables which are made of plastic.<br/>
 
    <strong>Risks to security through malicious mis-use by individuals, groups, or countries:</strong><br/>
 
    None. The entry of the BSL-1 are of our building is restricted and continuously controlled by security personnel. As our project does not create any E. coli strains or BioBricks with harmful or toxic properties, malicious mis-use by other individuals is ruled out.<br/>
 
    <strong>What new risks might arise from our project's growth?</strong><br/>
 
    If all of our dreams became true, one possible application of our project would be gut cancer treatment. The strains we are using are E.coli. This microorganism is ubiquitous in the human gut-system. Nobody is capable to say what would happen when our modified strains are in fact applied to a human being. It could for instance occur that the applied strain is interacting with the natural bacterial strains in the gut-system - this might provoke irritations and lead to stomach/intestinal problems. However, every developed system will change through evolution - so, nobody is capable to say what exactly will happen by application of the genetically modified E.coli. Any application should be under strict supervision and only be done by professional medical personnel.<br/>
 
    For our possible application one could use inducible promoters. When you apply the modified E.coli strain the desired effects from BioBrick gene expression are then only induced in presence of a special non-harming chemical substance (e.g. IPTG).<br/>
 
    <br/> 
 
   
 
    <h1>Literature:</h1>
 
    <strong>The WHO website: <a href="http://www.who.int/topics/biosafety/en/" target="blank">http://www.who.int/topics/biosafety/en/</a></strong><br/>
 
    Especially:
 
    <a href="http://www.who.int/csr/resources/publications/HSE_GAR_BDP_2010_2/en/" target="blank">http://www.who.int/csr/resources/publications/HSE_GAR_BDP_2010_2/en/</a><br/>
 
    <a href="http://www.who.int/ihr/publications/who_hse_ihr_2012.12/en/" target="blank"> http://www.who.int/ihr/publications/who_hse_ihr_2012.12/en/</a><br/>
 
    <a href="http://www.who.int/ihr/publications/biosafety/en/" target="blank">http://www.who.int/ihr/publications/biosafety/en/ </a><br/>
 
    <br/>
 
    <strong><p id="show-B">Show Papers dealing with different aspects of synthetic biology  &nbsp;<img src="img/Team_Berlin_igem_arrow_downsmall.png" id="B-down"> <img src="img/Team_Berlin_igem_arrow_upsmall.png" id="B-up"></p> </strong>
 
    <div id="section-B">
 
      - Zheng-jun Guan, Markus Schmidt, Lei Pei, Wei Wei, and Ke-ping Ma, 2013:<br/>
 
      - Biosafety Considerations of Synthetic Biology in the International Genetically Engineered Machine (iGEM) Competition. BioScience 63(1): 25-34  (http://bioscience.oxfordjournals.org/content/63/1/25.full , online 17.08.2014)<br/>
 
      - Acevedo-Rocha CG, Fang G, Schmidt M, Ussery DW, Danchin A, 2012: From essential to persistent genes: a functional approach to constructing synthetic life. Trends in Genetics.<br/>
 
      - Guan Z, Pei L, Schmidt M, Wei W, 2012: Assessment and management of biosafety in synthetic biology. Biodiversity Science 20(2): 138-150.<br/>
 
      - Schmidt M, de Lorenzo V, 2012: Synthetic constructs in/for the environment: Managing the interplay between natural and engineered Biology. FEBSLetters. Vol. 586: 2199-2206.<br/>
 
      - Schmidt M, 2012: Synthetic Biology: Industrial and Environmental Applications. Wiley-VCH.<br/>
 
      - Pei L, Gaisser S, Schmidt M, 2011: Synthetic Biology in the view of European public funding organisation. Public Understanding of Sciences 1: 1–14.<br/>
 
      - Schmidt M, Pei L, 2011: Synthetic Toxicology: Where engineering meets biology and toxicology.Toxicological Sciences 120(1): 204–24.<br/>
 
      - Schmidt M, Giersch G, 2011: DNA Synthesis and Security, in: Campbell M J, 2011: DNA Microarrays, Synthesis and Synthetic DNA. <br/>
 
      - Schmidt M, 2011: Synthetic biology: planning for a secure future. American Institute for the Biological Sciences.<br/>
 
      - Schmidt M, Dando M, Deplazes A, 2010: Dealing with the outer reaches of synthetic biology. Biosafety, biosecurity, IPR and ethical challenges of chemical synthetic biology. In: Luisi PL, 2011: Chemical Synthetic Biology.<br/>
 
      - Schmidt M, Torgersen H, Schneider-Voss S, Gaszo A, 2010: Perception of Complexity, Trust, Knowledge, and Communication Skills in Gene Science: A Survey among Different Stakeholders in Austria. In Lavino J, Neumann R, 2010: Psychology of Risk Perception.<br/>
 
      - Schmidt M, 2010: Xenobiology: A new form of life as the ultimate biosafety tool. BioEssays 32(4): 322-331.<br/>
 
      - Schmidt M, 2009: Special issue: societal aspects of synthetic biology. Systems and Synthetic Biology 3(1-4): 1-2.<br/>
 
      - Schmidt et al., 2009: A priority paper for the societal and ethical aspects of synthetic biology. Systems and Synthetic Biology 3(1-4): 3-7.<br/>
 
      - Schmidt M, 2009: Do I understand what I can create? Biosafety issues in synthetic biology. Chapter 6,  in: Schmidt M, Kelle A, Ganguli A, de Vriend H, 2009: Synthetic Biology. The Technoscience and its Societal Consequences.<br/>
 
      - Schmidt M, Kelle A, Ganguli A, de Vriend H, 2009: Synthetic Biology. The Technoscience and its Societal Consequences.<br/>
 
      - Torgersen H, 2009: Synthetic biology in society: learning from past experience? Systems and Synthetic Biology 3(1-4): 9-17.<br/>
 
      - Kelle A, 2009: Ensuring the security of synthetic biology—towards a 5P governance strategy. Systems and Synthetic Biology 3(1-4): 85-90.<br/>
 
      - Marliere P, 2009: The farther, the safer: a manifesto for securely navigating synthetic species away from the old living world. Systems and Synthetic Biology 3(1-4): 77-84.<br/>
 
      - Deplazes A, Huppenbauer M, 2009: Synthetic organisms and living machines: Positioning the products of synthetic biology at the borderline between living and non-living matter. Systems and Synthetic Biology 3(1-4): 55-63.<br/>
 
      - Kelle A, 2009: Synthetic biology and biosecurity. From low levels of awareness to a comprehensive strategy. EMBO Reports 10: 1; 23–7.<br/>
 
      - Deplazes A, 2009: Piecing together a puzzle. An exposition of synthetic biology. EMBO Reports 10: 428-432.<br/>
 
      - Ganguli-Mitra A, Schmidt M, Torgersen H, Deplazes A, Biller-Andorno N, 2009: Of Newtons and heretics. Nature Biotechnology 27(4): 321– 2.<br/>
 
      - Schmidt M, Torgersen H, Ganguli-Mitra A, Kelle A, Deplazes A, Biller-Andorno N, 2008: SYNBIOSAFE e-conference: online community discussion on the societal aspects of synthetic biology. Systems and Synthetic Biology 2(1-2): 7-17.<br/>
 
      - Schmidt M, Biller-Andorno N, Deplazes A, Ganguli-Mitra A, Kelle A, Torgersen H, 2008: Background document for the SYNBIOSAFE e-conference. Organisation for International Dialogue and Conflict Management.<br/>
 
      - SYNBIOSAFE, 2008: Compilation of all SYNBIOSAFE e-conference contributions.<br/>
 
      - Schmidt M, 2008: Diffusion of synthetic biology: a challenge to biosafety. Systems and Synthetic Biology 2(1-2): 1-6.<br/>
 
      - Schmidt M, 2008: Microbesoft? Biomaschinen und ihre Auswirkungen. 14(7).<br/>
 
      - Kelle A, 2007: Synthetic Biology and Biosecurity Awareness In Europe. Bradford Science and Technology Report 9.<br/>
 
      - Meinhart C, Schmidt M, 2007: Interviews with 15 key synthetic biology experts.<br/>
 
      - Schmidt M, 2006: Public will fear biological accidents, not just attacks. Nature 441(7097): 1048.<br/>
 
    </div>
 
    <br/>
 
    <strong><p id="show-C">Show Papers dealing with sociotal issues of synthetic biology &nbsp;<img src="img/Team_Berlin_igem_arrow_downsmall.png" id="C-down"><img src="img/Team_Berlin_igem_arrow_upsmall.png" id="C-up"></p></strong>
 
    <div id="section-C">
 
      - Markus Schmidt, Agomoni Ganguli-Mitra, Helge Torgersen, Alexander Kelle, Anna Deplazes, Nikola Biller-Andorno, 2009: A priority paper for the societal and ethical aspects of synthetic biology. Systems and Synthetic Biology 3(1-4): 3-7.<br/>
 
      - Calvert J, Martin P, 2009: The role of social scientists in synthetic biology. EMBO reports 10(3): 201–204.<br/>
 
      - Bedau M, Parke, EC, 2008: The Ethics of Protocells. Moral and Social Implications of Creating Life in the Laboratory. MIT Press.<br/>
 
      - Pauwels E, 2008: Trends in American and European Press Coverage of Synthetic Biology.Woodrow Wilson International Center for Scholars.<br/>
 
      - Boldt J and Müller O, 2008: Newtons of the leaves of grass. Nature Biotechnology 4: 387-389.<br/>
 
      - O’Malley M, Powell A, Davies JF, Calvert J, 2008: Knowledge-making distinctions in synthetic biology. BioEssays 30(1): 57.<br/>
 
      - Bernauer H et al., 2008: Technical solutions for biosecurity in synthetic biology. IASB Industry Association Synthetic Biology.<br/>
 
      - Garfinkel M, Endy D, Epstein GL, Friedman RM, 2007: Synthetic Genomics – Options for Governance.<br/>
 
      - Selgelid M, 2007: The tale of two studies: Ethics, Bioterrorism, and the Censorship of Science. Hastings Center Report 37(3): 35-43.<br/>
 
      - van Est R, de Vriend H, Walhout B, 2007: The world of synthetic biology. Rathenau Institute, The Hague Netherlands.<br/>
 
      - Rai A, and Boyle J, 2007: Synthetic Biology: Caught between Property Rights, the Public Domain, and the Commons. PLoS Biol. 13;5(3): e58.<br/>
 
      - ETC Group, 2007: Extreme Genetic Engineering: ETC Group Releases Report on Synthetic Biology.<br/>
 
      - Tucker JB and Zilinska RA., 2006: The Promise and Perils of Synthetic Biology. The new Atlantis: 25-45.<br/>
 
      - Check E, 2006: Synthetic biologists try to calm fears. Nature 441( 7092): 388-389.<br/>
 
      - Bhutkar A, 2005: Synthetic Biology: Navigating the Challenges Ahead. J. BIOLAW & BUS 8(2): 19-29.<br/>
 
      - Tumpej TM et al., 2005: Characterization of the Reconstructed 1918 Spanish Influenza Pandemic Virus. Science 310(5745): 77-80.<br/>
 
      - Sharp P A, 2005: 1918 Flu and Responsible Science. Science 310(5745): 17.<br/>
 
      - Church G, 2005: Let us go forth and safely multiply. Nature 438: 423.<br/>
 
      - Balmer A, Martin P, 2008: Synthetic Biology. Social and Ethical Challenges. Institute for Science and Society. University of Nottingham<br/>
 
      - IRGC, 2008: Concept note: Synthetic Biology. Risks and opportunities of an emerging field. International Risk Governance Council, Geneva:<br/>
 
      - De Vriend, H, 2006: Constructing Life. Early social reflections on the emerging field of synthetic biology. The Hague: Rathenau Institute;Working Document 97.<br/>
 
      - European Commission, 2005: Synthetic Biology: Applying Engineering to Biology ). Report 21796.<br/>
 
    </div>
 
    <br/>
 
    <br/>
 
  </div>
 
</section> 
 
  
 +
<strong>What are the risks?</strong> <br/>
 +
One very positive aspect of our Enzymatic Flagellulose is that it does not consist of any
  
<?php include("inc/footer.php"); ?>
+
microorganisms, but of their products or parts.  
  
 +
Our modular filter is biocompatible, which means it is environmentally friendly — our product
  
<!-- Script -->
+
should not affect the environment negatively, nor should it pose a threat to humans since no
<script src="//code.jquery.com/jquery-1.11.0.min.js"></script>
+
<script src="js/bootstrap.min.js"></script>
+
<script src="js/igemScript.js"></script>
+
  
<script src="js/jasny-bootstrap.min.js"></script> 
+
dangerous compounds are involved. One negative and environmentally harmful aspect might
  
<script>
+
occur during the degradation of microplastics. Since many toxic compounds attach to these
$(document).ready(function() {
+
document.title = 'iGEM Berlin 2014 | Safety';
+
});
+
  
$(window).scroll(function() {
+
particles, the degradation process might set them free at high levels. Also the plastic compounds
  
    if ($(this).scrollTop() >= 310) {
+
themselves could turn into environmentally harmful compounds while degradation takes place.  
$(".main-menue").css("background-color","rgb(255, 255, 255)");
+
    }
+
   
+
    if ($(this).scrollTop() < 310) { // this refers to window
+
$(".main-menue").css("background-color","none");
+
    }   
+
   
+
});
+
</script>
+
  
 +
But another good point is that it is made of natural products that can be degraded by using the
  
</body>
+
right enzymes and reactions. We only use harmless microorganisms to produce our modules,
  
 +
meaning the microorganisms aren’t pathogenic but rather belong to the natural flora of human
 +
 +
bodies.<br/><br/>
 +
 +
One major risk might be that the enzymes do not degrade the plastic into biodegradable
 +
 +
compounds but rather just into even smaller pieces of particles. This would negatively affect the
 +
 +
current situation even more. As it is already problematic, that the particles are too small to filter
 +
 +
them out of the wastewater treatment plant or the oceans, it will be even more problematic if they
 +
 +
turn into smaller pieces. Then, it definitely will be extremely hard to find a solution for this
 +
 +
problem.<br/><br/>
 +
 +
As we only have studied the cutinase so far, we can only say that one compound definitely can
 +
 +
be utilized by several organisms. The harmfulness of the other degraded compound has not been
 +
 +
researched yet. But even high concentrations of ethylene glycol might be toxic to E. coli as well
 +
 +
as to vertebrates.<br/><br/>
 +
 +
Our Enzymatic Flagellulose might also unwantedly degrade some other components during the
 +
 +
wastewater treatment. Since we cannot possibly know what it might attack, this is an uncertain
 +
 +
risk factor. Richard Feyman says “What I cannot create, I do not understand.” But do I
 +
 +
understand what I can create? (Prof. Dr.-Ing. Vera Meyer)
 +
 +
Also, the cellulose might be a habitat for bacteria and should be examined about the cultivation
 +
 +
of pathogens on it. <br/><br/>
 +
 +
We also have to examine whether the degraded compounds of microplastics (e.g. ethylene
 +
 +
glycol) might inhibit other biological reactions in the wastewater treatment process. Since many
 +
 +
different bacteria are used in the treatment for various purposes, it is easily possible to co-
 +
 +
cultivate these bacteria with our product in a batch reactor to determine the effects.
 +
 +
Other possible risks that we see are societal. Though our filter helps to filter microplastics, it
 +
 +
does not make up for the excessive plastic consumption. It is thought to be a short-time solution
 +
 +
for the environmental pollution with plastic. We are afraid that the people might rest on this and
 +
 +
start consuming plastic even more recklessly, since they know it will be biodegraded anyway.
 +
 +
</div>
 +
 +
</section>
 +
<!-- Fussabschnitt -->
 +
</html>
 +
{{Berlin/inc/footer.php}}
 +
<html>
 +
</body>
 
</html>
 
</html>

Latest revision as of 21:34, 18 September 2015

SAFETY

Our country uses a four-part „Safety Level“ rating system for laboratories. Level 4 is used for the most dangerous organisms.
This is equivalent to the WHO system. The Safety Level of our lab is Level 1 (no risk).



About our lab

Material used:
We use open benches and Laminar flow hoods / biosafety cabinets with open fronts to handle biological materials.
We handle cancerogenous materials such as ethidium bromide or polyacrylamide under separate fume hoods. Also acidic and basic solutions are handeled behind fume hoods. All radioactive materials or methods are located in a separate laboratory in the basement.
We also have a separate room for RNA work.

Protection:
For protecting ourselves while doing lab chores, we use full face shields during gel excision or any work that involves longer exposure to UV radiation. We certainly use nitril gloves for handling any ethidium bromide and polyacrylamide contaminated materials. Safety glasses are used, especially if dangerous materials like acids, bases and liquid nitrogene are handeled or if there is anything that can splash like at the AKTA. When using -80°C freezers we use isolated gloves.
The laboratory safety training requirements of the Technical University Berlin can be found here or here (BG RCI).

All Team members received a safety briefing from a faculty member.

Disposal:
We collect biological waste in big containers within the lab and autoclave it later. The autoclaved waste is then taken care of by the institute. Contaminated and non-contaminated broken glasware is collected separately. There is also a separate waste for cancerogenous and environmentally hazardous waste like ethidium bromide gels etc.

Biosafety guidelines of the Technical University Berlin:
The Institutional Biosafety Officer (BSO) is responsible for ensuring that laboratories are working safetly with biohazardous materials. This includes the periodic inspection of laboratories, developing emergency plans for handling spills and accidents and investigating laboratory accidents involving biohazardous materials. The BSO also provides technical consultation for researchers on conducting risk assessments, safety practices, and security. Environmental Health and Safety provides services necessary for biological research. These services include biomedical waste disposal, autoclave quality assurance, biosafety cabinet certification, biosafety inspections, training and emergency response. Know the hazards associated with the biological materials and procedures used within the laboratories. Follow approved lab procedures and safety guidelines. Know the emergency procedures. Complete all required training before conducting any lab activity. Utilize all required Personal Protective Equipment. Do not work alone in the laboratory.

German regulations that govern biosafety in research laboratories:
http://www.gmo-safety.eu/
http://www.gmo-safety.eu/links.html
http://ec.europa.eu/food/food/biotechnology/gmfood/qanda_en.pdf
http://www.baua.de/nn_15226/de/Themen-von-A-Z/Biologische-Arbeitsstoffe/TRBA/pdf/TRBA-466.pdf


What are the risks?
One very positive aspect of our Enzymatic Flagellulose is that it does not consist of any microorganisms, but of their products or parts. Our modular filter is biocompatible, which means it is environmentally friendly — our product should not affect the environment negatively, nor should it pose a threat to humans since no dangerous compounds are involved. One negative and environmentally harmful aspect might occur during the degradation of microplastics. Since many toxic compounds attach to these particles, the degradation process might set them free at high levels. Also the plastic compounds themselves could turn into environmentally harmful compounds while degradation takes place. But another good point is that it is made of natural products that can be degraded by using the right enzymes and reactions. We only use harmless microorganisms to produce our modules, meaning the microorganisms aren’t pathogenic but rather belong to the natural flora of human bodies.

One major risk might be that the enzymes do not degrade the plastic into biodegradable compounds but rather just into even smaller pieces of particles. This would negatively affect the current situation even more. As it is already problematic, that the particles are too small to filter them out of the wastewater treatment plant or the oceans, it will be even more problematic if they turn into smaller pieces. Then, it definitely will be extremely hard to find a solution for this problem.

As we only have studied the cutinase so far, we can only say that one compound definitely can be utilized by several organisms. The harmfulness of the other degraded compound has not been researched yet. But even high concentrations of ethylene glycol might be toxic to E. coli as well as to vertebrates.

Our Enzymatic Flagellulose might also unwantedly degrade some other components during the wastewater treatment. Since we cannot possibly know what it might attack, this is an uncertain risk factor. Richard Feyman says “What I cannot create, I do not understand.” But do I understand what I can create? (Prof. Dr.-Ing. Vera Meyer) Also, the cellulose might be a habitat for bacteria and should be examined about the cultivation of pathogens on it.

We also have to examine whether the degraded compounds of microplastics (e.g. ethylene glycol) might inhibit other biological reactions in the wastewater treatment process. Since many different bacteria are used in the treatment for various purposes, it is easily possible to co- cultivate these bacteria with our product in a batch reactor to determine the effects. Other possible risks that we see are societal. Though our filter helps to filter microplastics, it does not make up for the excessive plastic consumption. It is thought to be a short-time solution for the environmental pollution with plastic. We are afraid that the people might rest on this and start consuming plastic even more recklessly, since they know it will be biodegraded anyway.