Difference between revisions of "Team:Cambridge-JIC/Notebook"

graph.commit('optics', 'Optics', $('<div>20 July 2015: First prototype working. Very cheap, very poor quality… but we are working on it. The inverted-lens Raspberry Pi Cam definitely gives decent resolution, with its NA of about 0.15. Excited to see some cheek epidermis cells. Or maybe something else… Anyways excited!!!</div> <div class="team"><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/4/46/CamJIC-Notebook-Optics4.jpg)"><div class="blur"></div><div class="profile"><h3>Microscope</h3><p>The first image obtained with our microscope. Featuring a sample of epidermis from one of our team members. Thank you, Atti.</p></div></div> <div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/e/e9/CamJIC-Notebook-Optics5.jpg)"><div class="blur"></div><div class="profile"><h3>Microscope</h3><p>The first prototype in its whole glory.</p></div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/3/3b/CamJIC-Notebook-Software1.jpg)"><div class="blur"></div><div class="profile"><h3>Software</h3><p>face facen recognition working! Cell recognition coming soon.</p></div></div></div>'));

graph.commit('optics', 'Optics', $('<div>20 July 2015: First prototype working. Very cheap, very poor quality… but we are working on it. The inverted-lens Raspberry Pi Cam definitely gives decent resolution, with its NA of about 0.15. Excited to see some cheek epidermis cells. Or maybe something else… Anyways excited!!!</div> <div class="team"><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/4/46/CamJIC-Notebook-Optics4.jpg)"><div class="blur"></div><div class="profile"><h3>Microscope</h3><p>The first image obtained with our microscope. Featuring a sample of epidermis from one of our team members. Thank you, Atti.</p></div></div> <div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/e/e9/CamJIC-Notebook-Optics5.jpg)"><div class="blur"></div><div class="profile"><h3>Microscope</h3><p>The first prototype in its whole glory.</p></div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/3/3b/CamJIC-Notebook-Software1.jpg)"><div class="blur"></div><div class="profile"><h3>Software</h3><p>face facen recognition working! Cell recognition coming soon.</p></div></div></div>'));

graph.commit('sw', 'Software', $('<div>20 July 2015: Playing around with some face facen recognition software. If we can digitally recognise face facens, we could possibly also recognise cells, right?</div>'));

graph.commit('sw', 'Software', $('<div>20 July 2015: Playing around with some face facen recognition software. If we can digitally recognise face facens, we could possibly also recognise cells, right?</div>'));

graph.commit('design', 'Hardware Design', $('<div>20 July 2015: Currently designing and 3D printing some more holders for the optical bench setup. Just found out that OpenSCAD is not as easy to manipulate with as it seems. Aiming to be able to construct a proper model of the microscope within the next few days.</div>'));

graph.commit('design', 'Hardware Design', $('<div>20 July 2015: Currently designing and 3D printing some more holders for the optical bench setup. Just found out that OpenSCAD is not as easy to manipulate with as it seems. Aiming to be able to construct a proper model of the microscope within the next few days.</div>'));

graph.commit('sw', 'Software', $('<div>24 July 2015: Working on a Google Maps-like interface facen for our screening system. Coming soon! Never before has live observation of your samples from away been so smooth. Already being tested on a picture of <i>Marchantia</i>. Will be available in desktop/mobile versions.</div>'));

graph.commit('sw', 'Software', $('<div>24 July 2015: Working on a Google Maps-like interface facen for our screening system. Coming soon! Never before has live observation of your samples from away been so smooth. Already being tested on a picture of <i>Marchantia</i>. Will be available in desktop/mobile versions.</div>'));

graph.commit('optics', 'Optics', $('<div>24 July 2015: Assessment of our bright-field microscope prototype: field of view width 0.2mm, resolution - well under 10 microns. Also assessed different filters (cheap vs. more expensive options). A review of these coming next week, along with fluorescence microscopy setup. Finally managed to print and assemble the fluorescent cube today. As an aside, accidentally discovered how important illumination of the sample is, because the torch we were using went battery low, and made it pretty much impossible to focus on any image.</div>'));

graph.commit('optics', 'Optics', $('<div>24 July 2015: Assessment of our bright-field microscope prototype: field of view width 0.2mm, resolution - well under 10 microns. Also assessed different filters (cheap vs. more expensive options). A review of these coming next week, along with fluorescence microscopy setup. Finally managed to print and assemble the fluorescent cube today. As an aside, accidentally discovered how important illumination of the sample is, because the torch we were using went battery low, and made it pretty much impossible to focus on any image.</div>'));

graph.commit('optics', 'Optics', $('<div>27 July 2015: Comparison of our prototype with a lab bench microscope Nikon Labophot (retail price around 1,500$). See photos of Pinus stem crossection below. Quality achieved is totally comparable, magnification 400x. We still have some issues with colour, probably due to the illumination by UV LED torch. Resolved temporarily by putting in a yellow filter. Also, first attempts on fluorescence today. Failed. More tomorrow.. </div> <div class="team"><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/0/02/CamJIC-Notebook-PinusStem.jpg)"><div class="blur"></div><div class="profile"><h3>Our Image</h3><p>Achieved coloured image.</div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/f/fa/CamJIC-Notebook_PinusStemNikon.JPG)"><div class="blur"></div><div class="profile"><h3>Nikon Image</h3><p>Image obtained with Nikon microscope and digital camera mount. Compare the quality yourself (and the price).</div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/8/8b/CamJIC-Notebook-Lab.jpg)"><div class="blur"></div><div class="profile"><h3>Wet Lab</h3><p>A biologist and an engineer in the wet lab. Sounds like the start of a joke, but they are actually preparing Marchantia for observation under our to-be-constructed fluorescent microscope. Fully dressed, according to all safety regulations.</div></div></div>'));

graph.commit('optics', 'Optics', $('<div>27 July 2015: Comparison of our prototype with a lab bench microscope Nikon Labophot (retail price around 1,500$). See photos of Pinus stem crossection below. Quality achieved is totally comparable, magnification 400x. We still have some issues with colour, probably due to the illumination by UV LED torch. Resolved temporarily by putting in a yellow filter. Also, first attempts on fluorescence today. Failed. More tomorrow.. </div> <div class="team"><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/0/02/CamJIC-Notebook-PinusStem.jpg)"><div class="blur"></div><div class="profile"><h3>Our Image</h3><p>Achieved coloured image.</div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/f/fa/CamJIC-Notebook_PinusStemNikon.JPG)"><div class="blur"></div><div class="profile"><h3>Nikon Image</h3><p>Image obtained with Nikon microscope and digital camera mount. Compare the quality yourself (and the price).</div></div><div class="face facen" style="background-image: url(//2015.igem.org/wiki/images/8/8b/CamJIC-Notebook-Lab.jpg)"><div class="blur"></div><div class="profile"><h3>Wet Lab</h3><p>A biologist and an engineer in the wet lab. Sounds like the start of a joke, but they are actually preparing Marchantia for observation under our to-be-constructed fluorescent microscope. Fully dressed, according to all safety regulations.</div></div></div>'));

graph.commit('march', 'Marchantia', $('<div>27 July 2015: Prepared some microscopic slides with fluorescent <i>Marchantia</i> transformants (express GFP), generously provided by the Hasseloff Lab. However, able to look at them only through the lab fluorescence microscope for now. In the meantime, enjoy this simple <i>Marchantia</i> sample prep protocol: <ol> <li>Use No. 8 cork borer to cut cylinders of carrot core approx. 50 mm long.</li> <li>Place in 70% ethanol and leave overnight (will lose colour).</li> <li>Cut cylinders in half, and place sample between halves (thin sample e.g. <i>Marchantia</i> leaf).</li> <li>Put halves back together with sample at one end, sandwiched in place.</li> <li>Insert the cylinder of carrot into a hand-held microtome.</li> <li>Cut thin slices of carrot + sample using microtome knife.</li> <li>Wash thin sections into beaker using deionised water.</li> <li>Use a pasteur pipette to pick up sample in a drop of water, and drop onto a slide (note: do not include carrot tissue).</li> <li>Cover with glass slip and visualise (brightfield or fluorescence).</li></ol></div>'));*/

graph.commit('march', 'Marchantia', $('<div>27 July 2015: Prepared some microscopic slides with fluorescent <i>Marchantia</i> transformants (express GFP), generously provided by the Hasseloff Lab. However, able to look at them only through the lab fluorescence microscope for now. In the meantime, enjoy this simple <i>Marchantia</i> sample prep protocol: <ol> <li>Use No. 8 cork borer to cut cylinders of carrot core approx. 50 mm long.</li> <li>Place in 70% ethanol and leave overnight (will lose colour).</li> <li>Cut cylinders in half, and place sample between halves (thin sample e.g. <i>Marchantia</i> leaf).</li> <li>Put halves back together with sample at one end, sandwiched in place.</li> <li>Insert the cylinder of carrot into a hand-held microtome.</li> <li>Cut thin slices of carrot + sample using microtome knife.</li> <li>Wash thin sections into beaker using deionised water.</li> <li>Use a pasteur pipette to pick up sample in a drop of water, and drop onto a slide (note: do not include carrot tissue).</li> <li>Cover with glass slip and visualise (brightfield or fluorescence).</li></ol></div>'));*/

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