|
|
(9 intermediate revisions by the same user not shown) |
Line 36: |
Line 36: |
| <section class="human_practices"> | | <section class="human_practices"> |
| <span class="titulo_seccion">Human practices</span> | | <span class="titulo_seccion">Human practices</span> |
− | <img alt="Human practices overview" src="https://static.igem.org/mediawiki/2015/8/8e/HP_hoja1_overwiew.png" usemap="#overview" /> | + | <img alt="Human practices overview" src="https://static.igem.org/mediawiki/2015/5/5c/Overview_hp_test.png" |
| + | usemap="#overview" /> |
| <map name="overview"> | | <map name="overview"> |
| <area shape="circle" coords="419,114,108" alt="Awarness" href="#awareness" /> | | <area shape="circle" coords="419,114,108" alt="Awarness" href="#awareness" /> |
Line 131: |
Line 132: |
| <div class="division"> | | <div class="division"> |
| <div class="half"> | | <div class="half"> |
− | <p>The goal was to make the pupils collaboratively find solutions to the exposed problems, which difficulty grade increased as the workshop progressed. The workshop can be </p> <a href="insertar aqui" target="_blank">downloaded here</a><p>. The team also elaborated an </p> <a href="insertar aqui" target="_blank">electronic glossary</a><p> to make sure that the concepts wouldn’t be forgotten after the activity.</p> | + | <p>The goal was to make the pupils collaboratively find solutions to the exposed problems, which difficulty grade increased as the workshop progressed. The workshop can be </p> <a href="https://static.igem.org/mediawiki/2015/b/be/Taller_de_Biolog%C3%ADs_Sint%C3%A9tica_Spanish.pdf" target="_blank">downloaded here</a><p>. The team also elaborated an </p> <a href="https://static.igem.org/mediawiki/2015/0/09/Glosario-Colegios.pdf" target="_blank">electronic glossary</a><p> to make sure that the concepts wouldn’t be forgotten after the activity.</p> |
| <img class="" alt="The Goal" src="https://static.igem.org/mediawiki/2015/5/50/Hp_the_goal_1.jpg" /> | | <img class="" alt="The Goal" src="https://static.igem.org/mediawiki/2015/5/50/Hp_the_goal_1.jpg" /> |
| <label class="caption">Girls from the high school solving the challenges of the workshop.</label> | | <label class="caption">Girls from the high school solving the challenges of the workshop.</label> |
Line 145: |
Line 146: |
| <div class="division"> | | <div class="division"> |
| <div class="half"> | | <div class="half"> |
− | <p>If you are interested in knowing more about how the activity was received, here you can read some comments and see a video recorded at the end of the last activity. If you want to see more photos, please visit our gallery.</p> | + | <p>If you are interested in knowing more about how the activity was received, here you can read some comments and see a </p> <a href="https://static.igem.org/mediawiki/2015/4/4e/Feedback.mp4 " target="_blank">video</a><p> recorded at the end of the last activity.</p> |
| <img class="" alt="The Goal" src="https://static.igem.org/mediawiki/2015/b/bf/UChile_Openbio_pag7.png" /> | | <img class="" alt="The Goal" src="https://static.igem.org/mediawiki/2015/b/bf/UChile_Openbio_pag7.png" /> |
| | | |
Line 312: |
Line 313: |
| </div> | | </div> |
| <div class=half last"> | | <div class=half last"> |
− | <p><br>We also talked with Andres Briceño, co-founder of the Santiago Fab Lab, to make our project cross the frontier of the University and see if there was a real need or interest for biological PLA. There, we discovered other ways to use PLA, since in this Fab Lab they combine PLA with other biodegradable materials such as wood to make composite materials and help the technology to reach the market. Indeed, if PLA is quite used to build prototypes, product designers don’t like working with it because plastic products are not as attractive as wood products, for instance. So the idea of mixing PLA with a more “esthetical” material such as wood allows a friendly design for many objects, which makes composite PLA a good candidate for new 3D-printed products. Moreover, composite PLA can have better mechanical properties than PLA according to the material it is mixed with, and can last more than 2 years without losing its biodegradable properties, which allows a wider range of uses.</p> | + | <p><br>We also talked with Andres Briceño, co-founder of the Santiago Fab Lab, to make our project cross the frontier of the University and see if there was a real need or interest for biological PLA. There, we discovered other ways to use PLA, since in this Fab Lab they combine PLA with other biodegradable materials such as wood to make composite materials and help the technology to reach the market. Indeed, if PLA is quite used to build prototypes, product designers don’t like working with it because plastic products are not as attractive as wood products, for instance. So the idea of mixing PLA with a more “esthetical” material such as wood allows a friendly design for many objects, which makes composite PLA a good candidate for new 3D-printed products. Moreover, composite PLA can have better mechanical properties than PLA according to the material it is mixed with, and can last more than 2 years without losing its biodegradable properties, which allows a wider range of use.</p> |
| </div> | | </div> |
| </div> | | </div> |
Line 323: |
Line 324: |
| <h2> <br><span style="color:#39B54A"> FabLab Santiago </span></h2> | | <h2> <br><span style="color:#39B54A"> FabLab Santiago </span></h2> |
| <div class="half"> | | <div class="half"> |
− | <p> When we presented our project, Andres Briceño agreed that although costs can vary a lot according to the country of origin, it is expensive to buy PLA. He added that if we could demonstrate our fabrication process is cheaper than the current ones, the project would turn very attractive for many digital fabrication laboratories, for he gave us his support at the end of the visit, signing us another letter of inquiry.</p> | + | <p> When we presented our project, Andres Briceño agreeded that although prices can vary a lot according to the country of origin, it is expensive to buy PLA. He added that if we could demonstrate our fabrication process is cheaper than the current ones, the project would turn very attractive for many digital fabrication laboratories, for he gave us his support at the end of the visit, sending us another letter of inquiry.</p> |
| <img src="https://static.igem.org/mediawiki/2015/8/86/HP_hoja14_anariky.png" usemap="#fbs"> | | <img src="https://static.igem.org/mediawiki/2015/8/86/HP_hoja14_anariky.png" usemap="#fbs"> |
| <map name="fbs"> | | <map name="fbs"> |
Line 331: |
Line 332: |
| </div> | | </div> |
| <div class="half last"> | | <div class="half last"> |
− | <p>We reached the Government through the Ministry of the Environment, which manifested its interest through a letter of inquiry, in which it recognizes the importance of “the fabrication of biodegradable materials which implies fewer possible impacts on the environment.</p> | + | <p>We reached the Government through the Ministry of the Environment, which manifested its interest through a letter of inquiry, in which it recognizes the importance of “the fabrication of biodegradable materials which implies fewer possible impacts on the environment".</p> |
| <img src="https://static.igem.org/mediawiki/2015/b/b2/HP_hoja14_anariky_2.png" usermap="mma" usemap="#mma" /> | | <img src="https://static.igem.org/mediawiki/2015/b/b2/HP_hoja14_anariky_2.png" usermap="mma" usemap="#mma" /> |
| <map name="mma"> | | <map name="mma"> |
Line 343: |
Line 344: |
| <div class="division"> | | <div class="division"> |
| <div class="half"> | | <div class="half"> |
− | <h2> <span style="color:#39B54A"> Discuss of the impact of producing PLA </span> </h2> | + | <h2> <span style="color:#39B54A"> Discussion about the impacts of PLA production </span> </h2> |
− | <p>In order to evaluate those impacts, the positive and negatives ones, we met with Claudia Mac Lean, in charge of the Sustainability Office of the Faculty. She let us to present our project to her pupils in the context of a Sustainable Project Workshop they have to do and she gave us some advice, like do a Life Cycle Assessment our ask us about the functionality of our plastic; will be use it to all things? What consequences could have this? This was useful to wonder us different question, for example:<br> </p> | + | <p>In order to evaluate those impacts, the positive and negatives ones, we met with Claudia Mac Lean, in charge of the Sustainability Office of the Faculty. She made us present our project to her pupils in the context of a Sustainable Project Workshop and she gave us some pieces of advice, like developping a Life Cycle Assessment analysis or asking us the functionality of our plastic; will it be used for every kind of plastic objects? What consequences could have such a production? This was useful to wonder, for example:<br> </p> |
− | <img src="https://static.igem.org/mediawiki/2015/6/62/UChile_Openbio_pag15_cycle.png"> | + | <img src="https://static.igem.org/mediawiki/2015/6/6e/Preguntas_bacterias.png"> |
| </div> | | </div> |
| <div class="half past"> | | <div class="half past"> |
− | <p> <br>After analyse and discuss this question our principal discussions and conclusions were: | + | <p> <br>After analysing and debating this problem, our main discussions and conclusions were: |
− | A Life Cycle Assessment (LCA) would bring us a lot quantitative information about our project, because could us to know the specific impact in term of equivalent CO2 (carbon dioxide) generation[1] . Nevertheless, we knew LCA late in the project so we didn’t have the necessary time to do this quantitative analyse because we should look for all input and output of CO2 of each stage of our system which is complex.</p> | + | A Life Cycle Assessment (LCA) analysis would bring us a lot of quantitative information about our project, because it would make us know the specific impacts of the production process in term of equivalent CO2 (carbon dioxide) generation[1] . Nevertheless, we discovered LCA in a late phase of the project, so we didn’t have enough time to do this quantitative analysis because we should have looked for all the inputs and outputs of equivalent CO2 of feedstock and energy, for each stage of our process, which is a complex task.</p> |
| </div> | | </div> |
| <div> | | <div> |
Line 357: |
Line 358: |
| <div class="division"> | | <div class="division"> |
| <div class="half"> | | <div class="half"> |
− | <p> We infer PLA can degrade to lactate that could enter into metabolic cycle of anaerobic bacteria, generating CH4 (methane) and/or CO2[2] . This condition with no oxygen could be found it at typical landfills so in a hypothetical situation where PLA would be established in our society (it means we would use PLA instead of fossil plastic) huge amount of PLA could aggravate the global warming (due to greenhouse gases)[3] . Nevertheless, a controlling degradation of PLA would permit take advantage of CH4 generation to produce energy if it is combusted and would help reduce the effects of climate change[4]. If we implemented our project in long term we would promote cultivation of macroalgae which could contribute to economic development of Chile. Also, macroalgae don’t require arable land, fertilizer or fresh water resources and is a renewable resource , so it is a better alternative than corn cultivation. Nevertheless, a Chilean regulation of macroalgae uses should be constantly checked to avoid overexploitation and imbalance of natural ecosystem where macroalgae live. </p> | + | <p> We infer PLA can be degraded into lactate, which could enter into the metabolic cycle of anaerobic bacteria, generating CH4 (methane) and/or CO2[2] . Environments without oxygen could be found in typical landfills, so in a hypothetical situation where PLA would be established in our society (it means PLA would have totally replaced plastic from fossil origin), huge amounts of PLA could worsen the global warming (due to greenhouse gases emissions)[3] . Nevertheless, a controlled degradation of PLA would allow to take advantage of CH4 generation by producing energy from its combustion and would help to reduce the effects of climate change[4]. If we implemented our project in the long term we would promote cultivation of macroalgae which could contribute to economic development of Chile. Also, macroalgae don’t require any farmland, fertilizer or fresh water and is a renewable resource, so it is a better alternative than corn cultivation (which is one of the main current production modes). Nevertheless, the Chilean regulation of macroalgae uses should be constantly checked to avoid overexploitation and imbalance of natural ecosystem where macroalgae live. </p> |
| </div> | | </div> |
| <div class="half last"> | | <div class="half last"> |
− | <p>We think one advantage of using macroalgae it we could make a close-cycle; it means macroalgae would consume environmental CO2 generated in the PLA production process, allowing global reduction of CO2. In the case of fossils plastic this wouldn’t occur due to fossils plastic are made of fossil combustible which positively contribute to global CO2 amount if they are partially degraded or combusted . </p> | + | <p>We think one advantage of using macroalgae is that it could close the carbon cycle; it means macroalgae would consume environmental CO2 generated in the PLA production process, allowing global reduction of CO2. In the case of fossil plastic this wouldn’t occur because current plastics are made of fossil combustible, which positively contributes to increase global CO2 amounts if they are partially degraded or combusted . </p> |
| <img src="https://static.igem.org/mediawiki/2015/5/56/UChile_Openbio_pag15_questions.png"> | | <img src="https://static.igem.org/mediawiki/2015/5/56/UChile_Openbio_pag15_questions.png"> |
| </div> | | </div> |
Line 368: |
Line 369: |
| <div class="division"> | | <div class="division"> |
| <div class="half"> | | <div class="half"> |
− | <p> On the other hand, the big problem of fossil plastic is it accumulation[5] . For example, if we suppose a constantly production of the same amount of PLA and PET (a fossil plastic), after 5 years, it would expect find a higher amount of PET than PLA due to a percentage of PLA should be degraded in the first two years[6] . But if PLA had a short degradation time, we guess people maybe would replace it more frequently, so higher amount of PLA product could be thrown away and maybe accumulation rate could be higher than degradation rate. We think this kind of trade off should need further analysis to evaluate the real impact of uses of PLA. | + | <p> On the other hand, the big problem of fossil plastic is its accumulation[5] . For example, if we suppose a constant production of the same amount of PLA and PET (a fossil plastic), after 5 years, higher amounts of PET would b expected to be found because a percentage of PLA should be degraded in the first two years[5] . But if PLA had a short degradation time, we guess people would replace it more frequently by buying more PA products, so higher amounts of PLA could be thrown away and the accumulation rate would increase. We think the trade off between replacing fossil plastics and avoiding an overproduction of PLA should need further analysis to evaluate the real impact of the PLA production process. |
| | | |
− | According to functionality of PLA, we recommend it to products which will have a short life-time (<2 years), for example plastic glasses or bags. Contrarily, to products that need a long life-time, for examples piping, big structures, it would be appropriate to remain using fossils plastic. On the particular case of medical use, we think PLA should be used like suture, because sutures need to be degraded in a short time [ref suture].</p> | + | According to the previous reflection, we recommend to use PLA for products which will have a short life-time (<2 years), for example plastic cups or bags. On the contrary, for long life-time products such as pipes, chairs or big structures, it would be appropriate to keep using fossil plastics. On the particular case of medical use, we think PLA should be used like suture, because sutures need to be degraded in a short time. Moreover, the degradation would have no nefast consequences on the organism as PLA is a biocompatible material.[6]</p> |
| </div> | | </div> |
| <div class="half last"> | | <div class="half last"> |
Line 380: |
Line 381: |
| <p> <span style="color:#39B54A"> Referencias </span> <br> [1]CRA Europe. 12 Benefits of Life Cycle Assessment. [online]<www.cra.co.uk/news/12-benefits-of-life-cycle-assessment> [consulted: 16-09-2015] | | <p> <span style="color:#39B54A"> Referencias </span> <br> [1]CRA Europe. 12 Benefits of Life Cycle Assessment. [online]<www.cra.co.uk/news/12-benefits-of-life-cycle-assessment> [consulted: 16-09-2015] |
| | | |
− | Shang-Tian Yang, I-Ching Tang. Methanogenesis from lactate by a co-culture of Clostridium formicoaceticum and Methanosarcina mazei (1991) Applied Microbiology and Biotechnology. Volume 35, Issue 1, pp 119-123
| + | [2] Shang-Tian Yang, I-Ching Tang. Methanogenesis from lactate by a co-culture of Clostridium formicoaceticum and Methanosarcina mazei (1991) Applied Microbiology and Biotechnology. Volume 35, Issue 1, pp 119-123 |
| | | |
− | Com. Nacional del Medio Ambiente de Chile. GUIA METODOLOGICA ESTUDIO DE CICLO DE VIDA ECV: Proyecto Minimización de Residuos provenientes de Envases y Embalajes. 2001. pp31
| + | [3] Com. Nacional del Medio Ambiente de Chile. GUIA METODOLOGICA ESTUDIO DE CICLO DE VIDA ECV: Proyecto Minimización de Residuos provenientes de Envases y Embalajes. 2001. pp31 |
− | Methane Capture and Use. [online]<epa.gov/climatestudents/solutions/technologies/methane.html> [consulted: 16-09-2015]
| + | |
− | Garlotta, 2002. A Literature Review of PolyLactic Acid. Journal of Polymers and the Environment, Vol. 9, No. 2.
| + | [4] Methane Capture and Use. [online]<epa.gov/climatestudents/solutions/technologies/methane.html> [consulted: 16-09-2015] |
− | Garlotta, 2002. A Literature Review of PolyLactic Acid. Journal of Polymers and the Environment, Vol. 9, No. 2.
| + | |
| + | [5] Garlotta, 2002. A Literature Review of PolyLactic Acid. Journal of Polymers and the Environment, Vol. 9, No. 2. |
| + | [6] Athanasiou, Niederauer and Agrawal, 1996 . Sterilization, toxicity, biocompatibility and clinical polyglycolic acid copolymers. Biomoterials N° 17 pp:93-102. |
| </p> | | </p> |
| </article> | | </article> |