Difference between revisions of "Team:Cambridge-JIC/Design"
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<center><img src="https://static.igem.org/mediawiki/2015/f/fa/CamJIC_applieddesign.png" style="width:100%; max-width: 800px"></center> | <center><img src="https://static.igem.org/mediawiki/2015/f/fa/CamJIC_applieddesign.png" style="width:100%; max-width: 800px"></center> | ||
<center><p><i><b>Fig. 1:</b> Comparison of characteristics for several microscopes.</i></p></center> | <center><p><i><b>Fig. 1:</b> Comparison of characteristics for several microscopes.</i></p></center> | ||
− | <p>In <i>Fig. 1 | + | <p>In <i>Fig. 1</i> each microscope has several attributes that make it well suited to its specific niche. It is well known that commercial microscopes are able to produce immensely high quality images and will always be indispensable research tools. However, it is also clear that they have several undesirable qualities, decreasing their appeal to some users. For comparison we have the low cost, light-weight and easy to use alternatives. These microscopes are created to specifically fulfil their one objective: The FoldScope (a disposable educational tool and potential diagnostic tool); the FlyPi (for fluorescence macro-imaging of Drosophila flies) and the smartphone microscope (for low resolution imaging using your phone). OpenScope is intended as a more general solution, with each user developing its different aspects to suit their current needs. In this respect, it differes greatly from conventional microscopes. </p> |
</div></div></section> | </div></div></section> | ||
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<h3>Integrated Design</h3> | <h3>Integrated Design</h3> | ||
<h3><b>Integration of Pre-Existing Microscope</b></h3> | <h3><b>Integration of Pre-Existing Microscope</b></h3> | ||
− | <p>Our design incorporates a number for key features that were developed as part of a contemporary at the University of Cambridge [1]. The PiScope is an inverted brightfield microscope that uses 3D printed parts in a flexure-based mechanism for sample translation.</p> | + | <p>Our design incorporates a number for key features that were developed as part of a contemporary project at the University of Cambridge [1]. The PiScope is an inverted brightfield microscope that uses 3D printed parts in a flexure-based mechanism for sample translation.</p> |
− | <p>Although OpenScope is an upright microscope, it makes use of plastic flexure in the microscope stage to give fine control of translation along the x- and y-axis. In this respect, it | + | <p>Although OpenScope is an upright microscope, it makes use of plastic flexure in the microscope stage to give fine control of translation along the x- and y-axis. In this respect, it uses Dr Bowman's design concepts and develops them in the context of a different microscope type. While the PiScope [1] uses the flexure mechanism for z-axis translation, this was seen as incompatible with the necessity for modularity in OpenScope. For this reason, OpenScope instead uses a more simple screw-based system for focusing up and down. For analysis of these systems, see the <a href="https://2015.igem.org/Team:Cambridge-JIC/Tech_Specs" class="blue">Specifications</a> page.</p> |
− | <h3><b> | + | <h3><b>Open-Source Hardware and Community Improvement</b></h3> |
− | <p>Based on research carried out as part of our <a href="https://2015.igem.org/Team:Cambridge-JIC/Practices" class="blue">Human Practices</a> project, it was decided that the most appropriate license for OpenScope’s documentation would be a Copyleft license. In using a Creative Commons Attribution-ShareAlike license, OpenScope’s designs have been made available to the community with the assurance that they, along with any derivative work, will remain accessible into the future. Importantly, this gives the community of ‘makers’ the freedom to modify, improve and re-distribute our designs.</p> | + | <p>Based on research carried out as part of our <a href="https://2015.igem.org/Team:Cambridge-JIC/Practices" class="blue">Human Practices</a> project, it was decided that the most appropriate license for OpenScope’s documentation would be a Copyleft license. In using a Creative Commons Attribution-ShareAlike license, OpenScope’s designs have been made available to the community with the assurance that they, along with any derivative work, will remain accessible into the future. Importantly, this gives the community of ‘makers’ the freedom to modify, improve and re-distribute our designs.</p><br> |
− | <p> | + | <p>As such, OpenScope has the potential to evolve over time and even diversify into different projects. Scientists and enthusiasts alike will be able to tailor both the hardware and software to their specific needs as a whole or independently. Essentially, the OpenScope project can continue long after the iGEM competition has finished.</p>,br> |
<h3><b>Desktop CNC integration</b></h3> | <h3><b>Desktop CNC integration</b></h3> | ||
− | <p>When considering <a href="https://2015.igem.org/Team:Cambridge-JIC/Stretch_Goals" class="blue">Stretch Goals</a> for our project, it was recognised that removing the chassis and replacing it with the headpiece of a desktop CNC machine could provide a sample screening system. This was tested in the lab, using the Raspberry Pi camera for macro imaging. As a proof of principle, this demonstrated that because of its modular and digital nature, the potential for developing the OpenScope project in different directions is huge.</p> | + | <p>When considering <a href="https://2015.igem.org/Team:Cambridge-JIC/Stretch_Goals" class="blue">Stretch Goals</a> for our project, it was recognised that removing the chassis and replacing it with the headpiece of a desktop CNC machine could provide a sample screening system. This was tested in the lab, using the Raspberry Pi camera for macro imaging. As a proof of principle, this demonstrated that because of its modular and digital nature, the potential for developing the OpenScope project in different directions is huge.</p><br> |
<h3><b>Modularity</b></h3> | <h3><b>Modularity</b></h3> | ||
− | <p>OpenScope makes use of two key open-source hardware components, namely the Arduino [2] (a microprocessor) and the Raspberry Pi [3]. The | + | <p>OpenScope makes use of two key open-source hardware components, namely the Arduino [2] (a microprocessor) and the Raspberry Pi [3] (a low-cost computer). The well-developed community of ‘makers’ associated with these components, and their versatility, are directly transferable to OpenScope itself. In addition, they represent a standardised aspect of our project that is compatible with an existing (and rapidly growing) array of hardware projects and scientific equipment. Examples include Arduino-based centrifuges and spectrometers [4] as well as the RepRap 3D printer [5].</p> |
<p>The Raspberry Pi makes OpenScope entirely digital, letting the user control and program it using specifically designed software. New software can easily be added to the arsenal of features already available, and the existing software can be modified and improved according to the Copyleft license it’s under.</p> | <p>The Raspberry Pi makes OpenScope entirely digital, letting the user control and program it using specifically designed software. New software can easily be added to the arsenal of features already available, and the existing software can be modified and improved according to the Copyleft license it’s under.</p> | ||
<p>ImageJ is a widely-used microscopy software that already has features such as cell-counting algorithms and annotation. To make OpenScope easy to integrate into standard scientific experiments, a plug-in for ImageJ has been developed that enables the user to implement programs to process images captured directly from OpenScope. In short, the transition between OpenScope and this standard laboratory software is seamless.</p> | <p>ImageJ is a widely-used microscopy software that already has features such as cell-counting algorithms and annotation. To make OpenScope easy to integrate into standard scientific experiments, a plug-in for ImageJ has been developed that enables the user to implement programs to process images captured directly from OpenScope. In short, the transition between OpenScope and this standard laboratory software is seamless.</p> | ||
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<div style="width: 80%; margin: 30px 50px;color:#000"> | <div style="width: 80%; margin: 30px 50px;color:#000"> | ||
<h3>Environmental Impact</h3> | <h3>Environmental Impact</h3> | ||
− | <p>A full life cycle analysis was carried out on OpenScope using using the Eco Audit tool on the CES Selector Program [6]. The program allows for the energy | + | <p>A full life cycle analysis was carried out on OpenScope using using the Eco Audit tool on the CES Selector Program [6]. The program allows for the energy (MJ) and carbon emissions (kg) to be calculated for the product over its lifetime. The Eco Audit tool calculates these by taking into consideration the materials and material processing used, the use of the product, the power consumption (calculations for power consumption are given <a href="https://static.igem.org/mediawiki/2015/7/73/CamJIC-Specs-Power.pdf" class="blue">here</a>) and any transportation involved.</p> |
<h3>Assumptions</h3> | <h3>Assumptions</h3> | ||
<ul> | <ul> | ||
− | <li><p><b>Materials and Processing: </b> For each part of the microscope only the main materials, making up the majority of the part, were considered. Materials and manufacturing processes were collated from online and are accurate to the best of our knowledge. There is not an option on the tool for 3D printing as a materials process and so | + | <li><p><b>Materials and Processing: </b> For each part of the microscope only the main materials, making up the majority of the part, were considered. Materials and manufacturing processes were collated from online and are accurate to the best of our knowledge. There is not an option on the tool for 3D printing as a materials process and so the chassis was instead described as being made using polymer moulding, the most similar process.</p></li> |
− | <li><p><b>Transportation: </b>All parts for the microscope are being sourced locally, many parts can be bought in bulk and it | + | <li><p><b>Transportation: </b>All parts for the microscope are being sourced locally, many parts can be bought in bulk and it assumes the only transportation would be by light goods vehicles, travelling across England.</p></li> |
<li><p><b>Use: </b>We assumed the average person would use our microscope 4 days a week and use it for 2 hours each of these days. It was also assumed that the microscope would have a lifetime of 1 year.</p></li> | <li><p><b>Use: </b>We assumed the average person would use our microscope 4 days a week and use it for 2 hours each of these days. It was also assumed that the microscope would have a lifetime of 1 year.</p></li> | ||
− | <li><p><b>Disposal: </b> | + | <li><p><b>Disposal: </b>It was assumed that all materials that could be recycled were recycled, the rest were disposed of in landfill</p></li> |
</ul> | </ul> | ||
<center><img src="https://static.igem.org/mediawiki/2015/2/26/CamJIC_ecoaudigraph.png"></center> | <center><img src="https://static.igem.org/mediawiki/2015/2/26/CamJIC_ecoaudigraph.png"></center> | ||
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− | <center><a class="btn btn-default" href="https://static.igem.org/mediawiki/2015/0/07/CamJIC_ecoaudit.pdf" role="button" style="color:#123a68;border-color:#123a68">download full | + | <center><a class="btn btn-default" href="https://static.igem.org/mediawiki/2015/0/07/CamJIC_ecoaudit.pdf" role="button" style="color:#123a68;border-color:#123a68">download full report</a></center> |
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− | <p>Most energy is | + | <p>Most energy is consumed from the materials used to make the microscope, at approximately 10 times that of the 'use' energy cosumption. It is likely that with a commercial microscope the use and material energy would be closer matched due to the commercial microscope having a much longer lifetime. Although it may seem that a lot of material is used on OpenScope for its short lifetime, much of the material used can be recycled or reused directly. The thermoplastic PLA used to make the majority of the microscope chassis can be recycled to be made into many different products. PLA is derived from sugarcane, and is also fully biodegradable. The other main components of the microscope are the printed circuit boards used in the Raspberry Pi and Arduino. These are modular and open-source and so when no longer needed for use in the microscope can be reprogrammed to carry out other tasks in a different product.</p> |
− | <p>There are | + | <p>There are further ways to increase the sustainability of OpenScope that were not implemented within our project. The RecycleBot is a piece of open source hardware which has the capability to recycle plastic waste and make it into 3D printing filament [7]. The main power consumption for our project was in fact from the 3D printer (not accounted for in the manufacturing process report). In order to improve sustainability in this case there is the possibility of using renewable energies. The first community-scale solar powered printer was developed by White Gator Labs and was based on a Mendel RepRap variant running RAMPS1.3 [8]. This would also allow for printing in developing countries and isolated regions where access to electricity may be limited. To find out more about the development of 3D printing and personal manufacturing download the pdf below.</p> |
<center><a class="btn btn-default" href="" role="button" style="color:#123a68;border-color:#123a68">download 3D printing pdf</a></center> | <center><a class="btn btn-default" href="" role="button" style="color:#123a68;border-color:#123a68">download 3D printing pdf</a></center> |
Revision as of 10:43, 18 September 2015