Microscopy used equipment
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Hi all,
Looking for a good source of used microscopes or parts for microscopes. I need a smaller luminescent base for a nikon stereoscope. Collin -- Collin White Research Scientist Manager CEEH Cytometry Lab Building Facilities Manager Roosevelt 1 University of Washington Dept of Environmental and Occupational Health 4225 Roosevelt Way NE #100 Seattle, WA 98105 Phone 206-616-4982 email [hidden email] |
 
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Armstrong, Brian |
Re: Microscopy used equipment
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You could try LabX.
http://www.labx.com/v2/category_main.cfm?MainCatID=5&CatID=228 Brian Armstrong PhD Light Microscopy and Digital Imaging Beckman Research Institute Neuroscience X62872 -----Original Message----- From: Confocal Microscopy List [mailto:[hidden email]] On Behalf Of Collin White Sent: Thursday, February 18, 2010 12:26 PM To: [hidden email] Subject: Microscopy used equipment Hi all, Looking for a good source of used microscopes or parts for microscopes. I need a smaller luminescent base for a nikon stereoscope. Collin -- Collin White Research Scientist Manager CEEH Cytometry Lab Building Facilities Manager Roosevelt 1 University of Washington Dept of Environmental and Occupational Health 4225 Roosevelt Way NE #100 Seattle, WA 98105 Phone 206-616-4982 email [hidden email] --------------------------------------------------------------------- SECURITY/CONFIDENTIALITY WARNING: This message and any attachments are intended solely for the individual or entity to which they are addressed. This communication may contain information that is privileged, confidential, or exempt from disclosure under applicable law (e.g., personal health information, research data, financial information). Because this e-mail has been sent without encryption, individuals other than the intended recipient may be able to view the information, forward it to others or tamper with the information without the knowledge or consent of the sender. If you are not the intended recipient, or the employee or person responsible for delivering the message to the intended recipient, any dissemination, distribution or copying of the communication is strictly prohibited. If you received the communication in error, please notify the sender immediately by replying to this message and deleting the message and any accompanying files from your system. If, due to the security risks, you do not wish to receive further communications via e-mail, please reply to this message and inform the sender that you do not wish to receive further e-mail from the sender. --------------------------------------------------------------------- |
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Its not quite in your neck of the woods but try http://www.scopeshop.com/
> > >Hi all, >Looking for a good source of used microscopes or parts for microscopes. >I need a smaller luminescent base for a nikon stereoscope. >Collin > >-- >Collin White >Research Scientist >Manager CEEH Cytometry Lab >Building Facilities Manager Roosevelt 1 >University of Washington >Dept of Environmental and Occupational Health >4225 Roosevelt Way NE #100 >Seattle, WA 98105 >Phone 206-616-4982 >email [hidden email] > > >--------------------------------------------------------------------- >SECURITY/CONFIDENTIALITY WARNING: >This message and any attachments are intended solely for the >individual or entity to which they are addressed. This communication >may contain information that is privileged, confidential, or exempt >from disclosure under applicable law (e.g., personal health >information, research data, financial information). Because this >e-mail has been sent without encryption, individuals other than the >intended recipient may be able to view the information, forward it >to others or tamper with the information without the knowledge or >consent of the sender. If you are not the intended recipient, or the >employee or person responsible for delivering the message to the >intended recipient, any dissemination, distribution or copying of >the communication is strictly prohibited. If you received the >communication in error, please notify the sender immediately by >replying to this message and deleting the message and any >accompanying files from your system. If, due to the security risks, >you do not wish to receive further communications via e-mail, please >reply to this message and inform the sender that you do not wish to >receive further e-mail from the sender. > >--------------------------------------------------------------------- |
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Christian-103 |
chlorophyll and associated pigment spectra
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Rosemary.White |
Re: chlorophyll and associated pigment spectra
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If you use the 633 laser, you’ll get the expected emission peak at around 695 nm which is largely photosystem II emission, then a flat tail up to 760 or so which is mostly PSI. There are many absorption and emission spectra around, though I suspect quite a few of these are for isolated pigments in a polar solvent. The emission spectra depend very strongly on the wavelength(s) of the excitation light, so there isn’t really a standard emission spectrum. cheers, Rosemary Rosemary White CSIRO Plant Industry GPO Box 1600 Canberra, ACT 2601 Australia T 61 2 6246 5475 F 61 2 6246 5334 M 61 2 420 972 028 On 19/02/10 5:33 PM, "Christian" <celowsky21@...> wrote: Does anyone have the autofluorescent spectra for plants due to the pigments in the chloroplasts? |
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Christian-103 |
Re: chlorophyll and associated pigment spectra
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In reply to this post by Christian-103
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Rosemary.White |
Re: chlorophyll and associated pigment spectra
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Basically, you can see chlorophyll autofluorescence over much of the FP spectrum. I either collect autofluorescence in a chlorophyll-only region, often above 650 nm (except when using Cy5 or PI then have to split between these and Chl), and add to the total image in a contrasting colour, or subtract out chlorophyll autofluorescence. Depends on what you need to see and measure and how tricky your fluorescence quantification is if you’re going down that track. cheers, Rosemary On 19/02/10 6:07 PM, "Christian" <celowsky21@...> wrote: Rosemary, |
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Steffen Dietzel |
Fluorescence theory. was: chlorophyll and associated pigment spectra
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In reply to this post by Rosemary.White
At 07:51 19.02.2010, you wrote:
>Hi Christian, > >If you use the 633 laser, youll get the >expected emission peak at around 695 nm which is >largely photosystem II emission, then a flat >tail up to 760 or so which is mostly PSI. There >are many absorption and emission spectra around, >though I suspect quite a few of these are for >isolated pigments in a polar solvent. The >emission spectra depend very strongly on the >wavelength(s) of the excitation light, so there >isnt really a standard emission How does that fit to the theory of fluorescence? The theory says that fluorescence occurs when an electron is falling from the lowest energy level of the excited state to (any) energy level of the ground state, emitting a photon during the process. I thought because of that, the fluorescent spectrum wavelength is supposed to be always the same, independant of the mode of excitation. Did I miss something or is there a problem with the theory? While I am on it: If the theory is correct, how can excitation and emission spectra overlap without breaking the law of conversation of energy? (Example: If you would excite FITC with 510 nm, how could you obtain the part of the emission spectrum below 510? I am not sure one actually would get this part, but if not, this would seem to argue against the theory of fluorescence.) Steffen -- --------------------------------------------------- Steffen Dietzel, PD Dr. rer. nat Ludwig-Maximilians-Universität München Walter-Brendel-Zentrum für experimentelle Medizin (WBex) Marchioninistr. 15, D-81377 München |
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Howard Berg |
Re: Fluorescence theory. was: chlorophyll and associated pigment spectra
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To address the first part of your discussion, chlorophyll emission
detected in our Meta system is always the same from different plants and with different excitations, with a peak near 680. Howard On Feb 19, 2010, at 7:10 AM, Steffen Dietzel wrote: > At 07:51 19.02.2010, you wrote: >> Hi Christian, >> >> If you use the 633 laser, you’ll get the >> expected emission peak at around 695 nm which is >> largely photosystem II emission, then a flat >> tail up to 760 or so which is mostly PSI. There >> are many absorption and emission spectra around, >> though I suspect quite a few of these are for >> isolated pigments in a polar solvent. The >> emission spectra depend very strongly on the >> wavelength(s) of the excitation light, so there >> isn’t really a standard emission > > How does that fit to the theory of fluorescence? > The theory says that fluorescence occurs when an > electron is falling from the lowest energy level > of the excited state to (any) energy level of the > ground state, emitting a photon during the > process. I thought because of that, the > fluorescent spectrum wavelength is supposed to be > always the same, independant of the mode of excitation. > > Did I miss something or is there a problem with the theory? > > While I am on it: If the theory is correct, how > can excitation and emission spectra overlap > without breaking the law of conversation of > energy? (Example: If you would excite FITC with > 510 nm, how could you obtain the part of the > emission spectrum below 510? I am not sure one > actually would get this part, but if not, this > would seem to argue against the theory of fluorescence.) > > Steffen > -- --------------------------------------------------- > Steffen Dietzel, PD Dr. rer. nat > Ludwig-Maximilians-Universität München > Walter-Brendel-Zentrum für experimentelle Medizin (WBex) > Marchioninistr. 15, D-81377 München |
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Christian-103 |
Re: Fluorescence theory. was: chlorophyll and associated pigment spectra
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Emmanuel Gustin |
Re: Fluorescence theory. was: chlorophyll and associated pigment spectra
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In reply to this post by Steffen Dietzel
Steffen,
Simplified theories of fluorescence of course omit a lot of details. The Jablonski diagrams that are often presented to explain the principle, only have one ground state and one excited state, and perhaps a triplet state. But in reality there is a larger number of electronic states, and therefore more different transitions are possible, as far as quantum mechanical selection rules permit. We start at the bottom, in the ground state, and by putting in light energy, we move the electrons to a higher state. In first approximation, because of conservation of energy, the excitation wavelength selects a specific excited state -- one out of several possible ones, although the number is limited in practice by the stability of the molecule. Light is then emitted by a radiative transition to a lower state, but that lower state doesn't have to be the original ground state; it can be a state between the excited state and the original ground state. Excitation and emission spectra can overlap slightly without breaking the law of conservation of energy because the energy that can be converted into light isn't exclusively electronic energy: The transition can include a change in vibrational energy as well. As long as the temperature is above absolute zero, the relaxed excited state is not really the lowest energy level of the excited state; instead there is a spread, given by the Boltzmann distribution, over a number of different vibrational levels associated with the excited state. Therefore it is possible to get out a bit more energy than you put in, by transiting from a high vibrational level in the excited state to a lower vibrational level in the ground state. This is known as anti-Stokes fluorescence. It converts heat into light, but statistically, of course, that is far less likely to happen than a net conversion of light into heat, unless under very special conditions. Best Regards, Emmanuel -- Emmanuel Gustin, Tel. (+32) 15 46 1586, e-mail: [hidden email] -----Original Message----- From: Confocal Microscopy List [mailto:[hidden email]] On Behalf Of Steffen Dietzel Sent: vrijdag 19 februari 2010 14:10 To: [hidden email] Subject: Fluorescence theory. was: chlorophyll and associated pigment spectra At 07:51 19.02.2010, you wrote: >Hi Christian, > >If you use the 633 laser, you'll get the >expected emission peak at around 695 nm which is >largely photosystem II emission, then a flat >tail up to 760 or so which is mostly PSI. There >are many absorption and emission spectra around, >though I suspect quite a few of these are for >isolated pigments in a polar solvent. The >emission spectra depend very strongly on the >wavelength(s) of the excitation light, so there >isn't really a standard emission How does that fit to the theory of fluorescence? The theory says that fluorescence occurs when an electron is falling from the lowest energy level of the excited state to (any) energy level of the ground state, emitting a photon during the process. I thought because of that, the fluorescent spectrum wavelength is supposed to be always the same, independant of the mode of excitation. Did I miss something or is there a problem with the theory? While I am on it: If the theory is correct, how can excitation and emission spectra overlap without breaking the law of conversation of energy? (Example: If you would excite FITC with 510 nm, how could you obtain the part of the emission spectrum below 510? I am not sure one actually would get this part, but if not, this would seem to argue against the theory of fluorescence.) Steffen -- --------------------------------------------------- Steffen Dietzel, PD Dr. rer. nat Ludwig-Maximilians-Universität München Walter-Brendel-Zentrum für experimentelle Medizin (WBex) Marchioninistr. 15, D-81377 München |
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In reply to this post by Steffen Dietzel
People here seem to be talking about imaging "chlorophyll" and imaging "chloroplasts" as if they are one and the same thing. This is far from the case.
Green plant chloroplasts contain chlorophyll a and chlorophyll b, which have different excitation and emission spectra. They also contain carotenoids which have the function of capturing energy outside the blue and red absorption bands of chlorophyll and transferring it to the chlorophyll system. There are also two modified forms of chlorophyll which form the reaction centres for photosystem1 and 2, and these have different spectra again.
Remember that the aim of all this is that it should not fluoresce - the energy is non-radiatively transferred to the two reactions of photosynthesis (which are spatially separated). If you get fluorescence it's because this system isn't working. The carotenoid system can uncouple itself in case of overload, in which case you'll get the fluorescence from these (quite a mix). Otherwise you'll get fluorescence from one or more of the forms of chlorophyll. But once this starts happening bleaching is quite quick, and then you'll get chlorophyll breakdown products with different fluorescence again. Badly bleached chloroplasts fluoresce in the green.
The moral is that you need to you need to be minimal with your excitation levels for successful chloroplast imaging.
Guy
Optical Imaging Techniques in Cell Biology
by Guy Cox CRC Press / Taylor & Francis http://www.guycox.com/optical.htm ______________________________________________ Associate Professor Guy Cox, MA, DPhil(Oxon) Electron Microscope Unit, Madsen Building F09, University of Sydney, NSW 2006 ______________________________________________ Phone +61 2 9351 3176 Fax +61 2 9351 7682 Mobile 0413 281 861 ______________________________________________ http://www.guycox.net From: Confocal Microscopy List on behalf of Steffen Dietzel Sent: Sat 20/02/2010 12:10 AM To: [hidden email] Subject: Fluorescence theory. was: chlorophyll and associated pigment spectra At 07:51 19.02.2010, you wrote: |
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Christian-103 |
Re: Fluorescence theory. was: chlorophyll and associated pigment spectra
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Rosemary.White |
Re: Fluorescence theory. was: chlorophyll and associated pigment spectra
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Imaging chloroplasts in intact tissues using red light, e.g. 633 nm laser, will give you quite long term steady fluorescence with little bleaching, if that’s what you’re after. I’ve always thought of chloroplast fluorescence as an energy-shedding mechanism, like heat loss. As Guy mentions, the loss of far-red emission means that you’ve killed off part of the energy transfer pathway to the photosystem core, so you now see fluorescence from accessory pigments. cheers, Rosemary On 20/02/10 1:08 PM, "Christian" <celowsky21@...> wrote: Guy, |
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