Team:Leeds/Essays
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==Ethics in Synthetic Biology== | ==Ethics in Synthetic Biology== | ||
'''By Jeni Shoesmith''' | '''By Jeni Shoesmith''' | ||
- | [[File:Leeds_controversy.png|300px|link=http://holisticwellnesscoach.ca/blog/wp-content/uploads/2013/01/GMO-protestors.jpg|For many people, GMOs are highly controversial|right|frameless]]Synthetic biology is a growing technology with many new and exciting applications. However along with any new technology comes new ethical issues that need to be addressed. Taking into account these concerns allows this new technology to progress in a safe and ethical manner. The public are highly concerned with what scientists get up to in their labs and if there is enough regulation and reasons, other than personal interest, behind their research. In this article we will discuss how synthetic biology can benefit society, the ethical issues that surround synthetic biology and how synthetic biology aims to address these issues and therefore conduct ethical research. | + | [[File:Leeds_controversy.png|300px|link=http://holisticwellnesscoach.ca/blog/wp-content/uploads/2013/01/GMO-protestors.jpg|For many people, GMOs are highly controversial|right|frameless]]Synthetic biology is a growing technology with many new and exciting applications. However along with any new technology comes new ethical issues that need to be addressed. Taking into account these concerns allows this new technology to progress in a safe and ethical manner. The public are highly concerned with what scientists get up to in their labs and if there is enough regulation and reasons, other than personal interest, behind their research. In this article we will discuss how synthetic biology can benefit society, the ethical issues that surround synthetic biology and how synthetic biology aims to address these issues and therefore conduct ethical research<sup>[[#References 2|[1,3]]]</sup>. |
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Synthetic biology is a new area of research that takes advantage of molecular genetics to create new devices not seen in nature to solve modern issues. DNA is taken from different organisms and put together in novel orders and re-inserted into a new chassis (Usually bacteria or yeast cells). This DNA codes for proteins which are then expressed in the cells for a particular function eg, proteins that convert cellulose into biofuels. The sequences of these DNA parts are open source; so can be accessed by many people. This means that anyone with an idea could create new exciting devices to help solve problems in society. | Synthetic biology is a new area of research that takes advantage of molecular genetics to create new devices not seen in nature to solve modern issues. DNA is taken from different organisms and put together in novel orders and re-inserted into a new chassis (Usually bacteria or yeast cells). This DNA codes for proteins which are then expressed in the cells for a particular function eg, proteins that convert cellulose into biofuels. The sequences of these DNA parts are open source; so can be accessed by many people. This means that anyone with an idea could create new exciting devices to help solve problems in society. | ||
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Of course, as with any scientific research, there are ethical issues that arise. One is the economical implications of using synthetic biology to solve problems. As discussed earlier, the applications of synthetic biology have the potential to do some amazing things, however if some of the solutions are implemented there is a potential for a large sector of work to lose jobs. This means companies will become obsolete and no longer be undertaking business and this is not good for economic growth, especially in the developing world. For example if Palm Oil is made synthetically, it is possible that the industry for farming Palm Oil may be affected. What will happen to the workers on the plantations? | Of course, as with any scientific research, there are ethical issues that arise. One is the economical implications of using synthetic biology to solve problems. As discussed earlier, the applications of synthetic biology have the potential to do some amazing things, however if some of the solutions are implemented there is a potential for a large sector of work to lose jobs. This means companies will become obsolete and no longer be undertaking business and this is not good for economic growth, especially in the developing world. For example if Palm Oil is made synthetically, it is possible that the industry for farming Palm Oil may be affected. What will happen to the workers on the plantations? | ||
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- | Another ethical issue to be considered is the ownership of devices and DNA sequences engineered. Recently a law has been passed stating that any naturally occurring sequence of DNA cannot be patented, only human designed sequences can be patented. Therefore none of the naturally occurring genes can be owned by any one person or organisation and anyone can use the sequences as they are open source. Once again there are economic implications to consider because of this. An example is business growth, any two companies could make the same device and neither would make a profit (although not everyone thinks a change in business practices would necessarily be a bad thing). | + | Another ethical issue to be considered is the ownership of devices and DNA sequences engineered. Recently a law has been passed stating that any naturally occurring sequence of DNA cannot be patented, only human designed sequences can be patented. Therefore none of the naturally occurring genes can be owned by any one person or organisation and anyone can use the sequences as they are open source. Once again there are economic implications to consider because of this. An example is business growth, any two companies could make the same device and neither would make a profit (although not everyone thinks a change in business practices would necessarily be a bad thing)<sup>[[References 2|[4,5]]]</sup>. |
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- | As mentioned above, most of the DNA sequences in synthetic biology are open source. This means anyone can access them and, if they have a molecular biology lab, can create devices containing these sequences. This means that potentially someone with enough knowledge and interest could take harmful genes and use these to create bio-weapons. This issue hoes by the name of bioterrorism. This concern leads to numerous questions; should all DNA sequences be made publicly available? Should some of the sequences be treated with caution and be regulated? And should these sequences only be available to people who are granted permission on certain terms agreed, ethical terms? | + | As mentioned above, most of the DNA sequences in synthetic biology are open source. This means anyone can access them and, if they have a molecular biology lab, can create devices containing these sequences. This means that potentially someone with enough knowledge and interest could take harmful genes and use these to create bio-weapons. This issue hoes by the name of bioterrorism. This concern leads to numerous questions; should all DNA sequences be made publicly available? Should some of the sequences be treated with caution and be regulated? And should these sequences only be available to people who are granted permission on certain terms agreed, ethical terms?<sup>[[References 2|[5]]]</sup>. |
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- | The issue of Bio-terrorism leads to the issue of regulation. Currently there are not many regulatory bodies around for Synthetic Biology because it is a relatively new field. However, there is self regulation ongoing in the field but many people are concerned that this is not enough. At the moment, Synthetic Biology practises are regulated by genetic modification laws and bodies etc. One of these organisations is the UN Bioweapons convention, which controls the convention of biological diversity on an international level. There are also many directives that apply to europe and a separate set of organisations for the USA. However these are all GMO (genetically modified organism) specific and not specific to Synthetic Biology techniques as such. | + | The issue of Bio-terrorism leads to the issue of regulation. Currently there are not many regulatory bodies around for Synthetic Biology because it is a relatively new field. However, there is self regulation ongoing in the field but many people are concerned that this is not enough. At the moment, Synthetic Biology practises are regulated by genetic modification laws and bodies etc. One of these organisations is the UN Bioweapons convention, which controls the convention of biological diversity on an international level. There are also many directives that apply to europe and a separate set of organisations for the USA. However these are all GMO (genetically modified organism) specific and not specific to Synthetic Biology techniques as such<sup>[[References 2|[3,5]]]</sup>. |
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- | Furthermore, there are concerns about the safety of the modified organisms that synthetic biology creates. As these organisms are classed as "new" it sometimes isn't possible to predict what they will do, or what they will effect if they are prematurely released into the environment. Genes for antibiotic resistance are inserted into bacteria in plasmids as a way to select for the colonies you want during transformation and growth of the bacterial strain; these could be passed on to virulent strains furthering problems with antibiotic resistance if the bacteria was not kept in a controlled area and accidentally released. Protocols need to be put in place to ensure safety when working with bacteria in the lab and that rigorous testing occurs before any release of these genetically modified bacteria, as well as approval from regulatory boards. | + | Furthermore, there are concerns about the safety of the modified organisms that synthetic biology creates. As these organisms are classed as "new" it sometimes isn't possible to predict what they will do, or what they will effect if they are prematurely released into the environment. Genes for antibiotic resistance are inserted into bacteria in plasmids as a way to select for the colonies you want during transformation and growth of the bacterial strain; these could be passed on to virulent strains furthering problems with antibiotic resistance if the bacteria was not kept in a controlled area and accidentally released. Protocols need to be put in place to ensure safety when working with bacteria in the lab and that rigorous testing occurs before any release of these genetically modified bacteria, as well as approval from regulatory boards[[References 2|[3]]]</sup>. |
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- | The final issue that will be discussed is the religious problems surrounding Synthetic Biology. Some Religious organisations feel that work done in fields such as Synthetic Biology and Genetic Engineering is “playing God”. Synthetic biology manipulates genetic material of single celled organisms and can be deemed wrong because it is “unnatural” to do such things. An argument against this is that these tools are placed on the earth and we are utislising them to the best of our ability as God would have wanted us to. Synthetic biologists need to address this and give reassurance to show that although we are changing organisms our motives and intentions are to improve society. | + | The final issue that will be discussed is the religious problems surrounding Synthetic Biology. Some Religious organisations feel that work done in fields such as Synthetic Biology and Genetic Engineering is “playing God”. Synthetic biology manipulates genetic material of single celled organisms and can be deemed wrong because it is “unnatural” to do such things. An argument against this is that these tools are placed on the earth and we are utislising them to the best of our ability as God would have wanted us to. Synthetic biologists need to address this and give reassurance to show that although we are changing organisms our motives and intentions are to improve society[[References 2|[3]]]</sup>. |
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In Synthetic Biology we work towards overcoming these ethical issues, and strive for excellence within our research. | In Synthetic Biology we work towards overcoming these ethical issues, and strive for excellence within our research. | ||
- | There are currently laws that regulate what can and can’t be done in Synthetic Biology, however it has been suggested that an independent regulatory body should be employed to govern Synthetic Biology and make sure there are no, from the perspective of non-scientists, unethical research projects that go ahead. This is something that is currently being worked on in the SynBio community. | + | There are currently laws that regulate what can and can’t be done in Synthetic Biology, however it has been suggested that an independent regulatory body should be employed to govern Synthetic Biology and make sure there are no, from the perspective of non-scientists, unethical research projects that go ahead. This is something that is currently being worked on in the SynBio community[[References 2|[2,3,4]]]</sup>. |
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- | A way to overcome the ethical issue of bioterrorism and dangerous biological parts is to regulate their distribution. This means that DNA sequences that code for toxin producing enzymes or other similar dangerous biological elements are more highly controlled and only accessible when specific permissions are granted and there is a good reason for needing to undergo research using those parts. | + | A way to overcome the ethical issue of bioterrorism and dangerous biological parts is to regulate their distribution. This means that DNA sequences that code for toxin producing enzymes or other similar dangerous biological elements are more highly controlled and only accessible when specific permissions are granted and there is a good reason for needing to undergo research using those parts[[References 2|[4]]]</sup>. |
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- | The economic issues caused by Synthetic Biology are a little more difficult to overcome. As it is a new field most of the products it offers are in early development so for the time being potential job losses will not occur. If some products do become widely available, the hope is that the jobs will be transferred to a different sector of work based around the new device. Although by making the technology open source and free from patents, profit will be hard to reach and no boost in the economy will occur in this way. Therefore some form of business strategy would need to be developed to ensure money is made. It could be seen that in keeping the prices low, by lack of patents and open source genes, will aid developing countries, solve worldwide problems and still have the ability to make money as it would be available to a wider audience. | + | The economic issues caused by Synthetic Biology are a little more difficult to overcome. As it is a new field most of the products it offers are in early development so for the time being potential job losses will not occur. If some products do become widely available, the hope is that the jobs will be transferred to a different sector of work based around the new device. Although by making the technology open source and free from patents, profit will be hard to reach and no boost in the economy will occur in this way. Therefore some form of business strategy would need to be developed to ensure money is made. It could be seen that in keeping the prices low, by lack of patents and open source genes, will aid developing countries, solve worldwide problems and still have the ability to make money as it would be available to a wider audience[[References 2|[3]]]</sup>. |
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Synthetic Biology is a new and exciting technology with many useful applications that would be beneficial for society if it were to be embraced. There are ethical and economical issues that come with this new field of research, which are not to be ignored but these can be overcome and the potential benefits outweigh the harms and disadvantages of the research. | Synthetic Biology is a new and exciting technology with many useful applications that would be beneficial for society if it were to be embraced. There are ethical and economical issues that come with this new field of research, which are not to be ignored but these can be overcome and the potential benefits outweigh the harms and disadvantages of the research. | ||
===References=== | ===References=== | ||
- | # ''[http://www.synbioproject.org/topics/synbio101/definition/ Synthetic Biology 101: What is synthetic biology?]'' (Accessed 29/07/2013) | + | # ''Synthetic biology 101: What is synthetic biology? (2013) see: [http://www.synbioproject.org/topics/synbio101/definition/ Synthetic Biology 101: What is synthetic biology?]'' (Accessed 29/07/2013) |
# ''[http://www.bbsrc.ac.uk/web/files/reviews/0806_synthetic_biology.pdf '''Balmer, A. P. Martin (2008)''' Synthetic Biology, Social and Ethical challenges. BBSRC]'' (Accessed 29/07/2013) | # ''[http://www.bbsrc.ac.uk/web/files/reviews/0806_synthetic_biology.pdf '''Balmer, A. P. Martin (2008)''' Synthetic Biology, Social and Ethical challenges. BBSRC]'' (Accessed 29/07/2013) | ||
- | # ''[http://synberc.org/sites/default/files/Concise%20Guide%20to%20Synbio%20Regulation%20OYE%20Jan%202012_0.pdf '''Bar-Yam, S. et al (2012)''' The regulation of | + | # ''[http://synberc.org/sites/default/files/Concise%20Guide%20to%20Synbio%20Regulation%20OYE%20Jan%202012_0.pdf '''Bar-Yam, S. et al (2012)''' The regulation of Synthetic Biology a Guide to the United States/European Union regulations, rules, and guidelines]'' (Accessed 29/07/2013) |
# ''[http://www.actionbioscience.org/biotechnology/schmidt.html#prime '''M. Scmidt (2011)''' Synthetic biology: Planning for a secure future]'' (Accessed 29/07/2013) | # ''[http://www.actionbioscience.org/biotechnology/schmidt.html#prime '''M. Scmidt (2011)''' Synthetic biology: Planning for a secure future]'' (Accessed 29/07/2013) | ||
- | # '''Guan Z, Schmidt M, Pei L, Wei W, Ma K. (2013)''' ''Biosafety considerations of synthetic biology in the international Genetically Engineered Machine (iGEM) competition''. Bioscience: Vol: 63 (1):25-34 | + | # '''Guan Z, Schmidt M, Pei L, Wei W, Ma K. (2013)''' ''[http://www.biofaction.com/wp-content/uploads/2012/04/igem-biosafety-2013.pdf Biosafety considerations of synthetic biology in the international Genetically Engineered Machine (iGEM) competition''. Bioscience: Vol: 63 (1):25-34] |
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==What can Synthetic Biology do for neuroscience?== | ==What can Synthetic Biology do for neuroscience?== | ||
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One of the aims of synthetic neurobiology is to create novel synthetic neural pathways which can then be studied. Scientists are currently in the early stages of experimenting with this, and in the future it is possible that complex circuits can be created that can mimic disease states, allowing scientists to understand them in more detail. And who knows, perhaps in the future there may be scope for synthetic implants (computer implants have been used to restore vision, and can be used to control prosthetic limbs!). | One of the aims of synthetic neurobiology is to create novel synthetic neural pathways which can then be studied. Scientists are currently in the early stages of experimenting with this, and in the future it is possible that complex circuits can be created that can mimic disease states, allowing scientists to understand them in more detail. And who knows, perhaps in the future there may be scope for synthetic implants (computer implants have been used to restore vision, and can be used to control prosthetic limbs!). | ||
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- | Currently drug therapies have been the main method of treating neurological diseases, along with more invasive treatments such as deep brain stimulation.<sup>[[#References 3|[4]]]</sup> But what about synthetic biology? Could inserting genes into neurons alter their electrical activity? Or prevent cell death and therefore neurodegeneration? Scientists from a wide range of backgrounds have been studying and researching in this new field of synthetic neurobiology, and have found some exciting results.<sup>[ | + | Currently drug therapies have been the main method of treating neurological diseases, along with more invasive treatments such as deep brain stimulation.<sup>[[#References 3|[4]]]</sup> But what about synthetic biology? Could inserting genes into neurons alter their electrical activity? Or prevent cell death and therefore neurodegeneration? Scientists from a wide range of backgrounds have been studying and researching in this new field of synthetic neurobiology, and have found some exciting results.<sup>[[#References 3|[2,3]]]</sup> |
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Optogenetics, the process of inserting genes into neurons which encode light sensitive ion channels called 'opsins', has revolutionised neuroscience research.<sup>[[#References 3|[1,2]]]</sup> This method allows only selected neurons to be activated or silenced by specific wavelengths of light in experimental setups, a major advantage over the traditional method of electrical stimulation which is not neuron specific.<sup>[[#References 3|[3]]]</sup> Along with the advantages it provides to research (it’s a lot easier to find out what a specific neuron type is doing if you know that it’s the only one being activated or inhibited), it also shows therapeutic advantages. Researchers at MIT and the University of Southern California have successfully inserted DNA from light sensitive algae into retinal neurons in blind mice,<sup>[[#References 3|[2]]]</sup> restoring their ability to navigate towards light. Furthermore spontaneous epileptic seizures in mice have been stopped rapidly using optogenetics, by activating inhibitory neurons and also inhibiting excitatory neurons.<sup>[[#References 3|[2]]]</sup> | Optogenetics, the process of inserting genes into neurons which encode light sensitive ion channels called 'opsins', has revolutionised neuroscience research.<sup>[[#References 3|[1,2]]]</sup> This method allows only selected neurons to be activated or silenced by specific wavelengths of light in experimental setups, a major advantage over the traditional method of electrical stimulation which is not neuron specific.<sup>[[#References 3|[3]]]</sup> Along with the advantages it provides to research (it’s a lot easier to find out what a specific neuron type is doing if you know that it’s the only one being activated or inhibited), it also shows therapeutic advantages. Researchers at MIT and the University of Southern California have successfully inserted DNA from light sensitive algae into retinal neurons in blind mice,<sup>[[#References 3|[2]]]</sup> restoring their ability to navigate towards light. Furthermore spontaneous epileptic seizures in mice have been stopped rapidly using optogenetics, by activating inhibitory neurons and also inhibiting excitatory neurons.<sup>[[#References 3|[2]]]</sup> |
Latest revision as of 03:33, 5 October 2013
The team have been writing a few essays on the effects and implications of Synthetic Biology - discussing the ethics, saftey concerns and economical or human impacts that SynBio can have. Please do have a read through below:
What is Synthetic BiologyBy Emily Taylor Synthetic Biology is a new and developing field in biology that combines the areas of biology, technology and engineering. In 2005 the European Commission convened a high-level expert group to define and examine the development of the new field. The report begins by defining Synthetic Biology as "the engineering of biology: the synthesis of complex, biologically-based (or inspired) systems which display functions that do not exist in nature. This engineering perspective may be applied at all levels of the hierarchy of biological structures – from individual molecules to whole cells, tissues and organisms. In essence, Synthetic Biology will enable the design of 'biological systems' in a rational and systematic way".[1] The biological devices that can be utilised in Synthetic Biology include enzymes, genetic circuits and even the redesign of existing biological systems. Synthetic Biology draws knowledge from Molecular, Cell and Systems Biology in order to create this new field of highly-scientific engineering. The main focus of the field is in design and construction of things that can be modelled, understood and tuned to meet specific performance criteria. "With Synthetic Biology, conceptual tools and language of engineering become the actual method for approaching biology so that engineering now is more than an analogy, as it was for genetic engineering".[2]
Synthetic Biology arose from four different intellectual agendas:
The popularity of Synthetic Biology has grown over the last few years as a result of DNA synthesis technology becoming more accessible and cheaper; it is now more affordable to synthesise DNA rather than to clone it. Advances in the field also rely on progress in other technologies increasing speed and lowering costs. This includes DNA sequencing, synthesis of genes and modelling how synthetic genes behave. DNA sequencing increased the understanding of components and organisation of natural biological systems, and the technology that synthesises genes provides the ability to test designs of new parts. Without these advances in technology and their lower costs, Synthetic Biology would not have made as much progression!
References
Ethics in Synthetic BiologyBy Jeni Shoesmith Synthetic biology is a growing technology with many new and exciting applications. However along with any new technology comes new ethical issues that need to be addressed. Taking into account these concerns allows this new technology to progress in a safe and ethical manner. The public are highly concerned with what scientists get up to in their labs and if there is enough regulation and reasons, other than personal interest, behind their research. In this article we will discuss how synthetic biology can benefit society, the ethical issues that surround synthetic biology and how synthetic biology aims to address these issues and therefore conduct ethical research[1,3].
References
What can Synthetic Biology do for neuroscience?By Sabrina Knight For most neurological and psychiatric disorders there are limited options for treatment with few or no cures[4]. Considering that 1 in 6 people suffer from a neurological disorder[4], this may be the time to find alternative ways of researching and treating these disorders. Could the up and coming field of synthetic biology provide therapeutic contribution to the treatment of these diseases? Could it become a valuable tool for neuroscience research?Synthetic biology, the ability to construct new biological parts or systems, has the potential to revolutionise neuroscience. The basis of synthetic biology is incorporating DNA into cells, such as neurons, for useful purposes.
One of the aims of synthetic neurobiology is to create novel synthetic neural pathways which can then be studied. Scientists are currently in the early stages of experimenting with this, and in the future it is possible that complex circuits can be created that can mimic disease states, allowing scientists to understand them in more detail. And who knows, perhaps in the future there may be scope for synthetic implants (computer implants have been used to restore vision, and can be used to control prosthetic limbs!).
References
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