signal to background ratios in multiphoton microscopy

> *****
> To join, leave or search the confocal microscopy listserv, go to:
> http://lists.umn.edu/cgi-bin/wa?A0=confocalmicroscopy
> Post images on http://www.imgur.com and include the link in your posting.
> *****
>
> I have been reading up on signal to background ratios in point
> scanning confocal and spinning disk confocal.   There are a number of
> very detailed papers that characterize the out of focus rejection in
> terms of the edge response function for a thick fluorescent sample in
> the one photon case (figure 14, [1] for instance) .
>
> What i have not been able to locate is a reasonably thorough treatment
> of the subject for multiphoton microscopy with non-descanned
> detection.  Instead most of the work I can find only looks at the
> signal to background ratios with depth into a tissue specimen.  This
> is helpful, but difficult to compare since you can't image deeply with
> confocal.
>
> Does anyone have a good reference they could suggest?
>
>
> [1]  Zimmermann, B., Kempe, M., & Wolleschensky, R. (2006). High-speed
> confocal fluorescence imaging with a novel line scanning microscope.
> Journal of Biomedical Optics, 11(6), 064011.
> http://doi.org/10.1117/1.2402110
>

> *****
> To join, leave or search the confocal microscopy listserv, go to:
> http://lists.umn.edu/cgi-bin/wa?A0=confocalmicroscopy
> Post images on http://www.imgur.com and include the link in your posting.
> *****
>
> Because the signal is only generated at the focal plane, multiphoton
> doesn't have the same kind of background issues as confocal. This means
> there is no out-of-focus signal to reject. The spatial restriction means
> that your laser's point spread function (in XYZ) is the limit of your
> detection and your signal generation volume. For instance in the edge
> response to a thick fluorescent sample, you won't get any signal generated
> until the PSF of your laser actually starts overlapping with the edge of
> the slab. Conversely in confocal, you will always have signal being
> generated and are relying on the pinhole to reject the out-of-plane light.
> As you take a volume stack into a slab In 2P you will get some entertaining
> edge effects due to spherical aberration if the index of your fluorescent
> slab isn't matched to your immersion media, but otherwise 2P just doesn't
> generate signal unless the sample is within the focal spot. Please keep in
> mind I am thinking about the Z direction in this, not XY.
>
> I hope this helps; I'm really tired and may not be as coherent as usual. :)
> Craig
>
> On Wed, May 11, 2016 at 3:01 PM, Michael Giacomelli <[hidden email]> wrote:
>
>> *****
>> To join, leave or search the confocal microscopy listserv, go to:
>> http://lists.umn.edu/cgi-bin/wa?A0=confocalmicroscopy
>> Post images on http://www.imgur.com and include the link in your posting.
>> *****
>>
>> I have been reading up on signal to background ratios in point
>> scanning confocal and spinning disk confocal.   There are a number of
>> very detailed papers that characterize the out of focus rejection in
>> terms of the edge response function for a thick fluorescent sample in
>> the one photon case (figure 14, [1] for instance) .
>>
>> What i have not been able to locate is a reasonably thorough treatment
>> of the subject for multiphoton microscopy with non-descanned
>> detection.  Instead most of the work I can find only looks at the
>> signal to background ratios with depth into a tissue specimen.  This
>> is helpful, but difficult to compare since you can't image deeply with
>> confocal.
>>
>> Does anyone have a good reference they could suggest?
>>
>>
>> [1]  Zimmermann, B., Kempe, M., & Wolleschensky, R. (2006). High-speed
>> confocal fluorescence imaging with a novel line scanning microscope.
>> Journal of Biomedical Optics, 11(6), 064011.
>> http://doi.org/10.1117/1.2402110
>>

> Hi Craig,
>
> I realize that 2 photon excitation is most likely in the focal plane,
> but the probability of it happening is nonzero everywhere the beam
> reaches, so you do get some signal from out of focus light as in the
> confocal case.  This is an issue in deep brain imaging for instance.
> I spent a little while searching on Google scholar but didn't see very
> much on signal to background ratios derived or measured for the step
> test though, just deep tissue imaging.
>
> For what it's worth, I'm curious because I do see some depth dependent
> background when Z-stacking the air above a fluorescent slide.  It's
> weak, but I'm curious if what I measure is reasonable, or if I should
> be double checking my PSF and filter rejection.
>
> Mike
>
> On Wed, May 11, 2016 at 9:01 PM, Craig Brideau <[hidden email]> wrote:
>> *****
>> To join, leave or search the confocal microscopy listserv, go to:
>> http://lists.umn.edu/cgi-bin/wa?A0=confocalmicroscopy
>> Post images on http://www.imgur.com and include the link in your posting.
>> *****
>>
>> Because the signal is only generated at the focal plane, multiphoton
>> doesn't have the same kind of background issues as confocal. This means
>> there is no out-of-focus signal to reject. The spatial restriction means
>> that your laser's point spread function (in XYZ) is the limit of your
>> detection and your signal generation volume. For instance in the edge
>> response to a thick fluorescent sample, you won't get any signal generated
>> until the PSF of your laser actually starts overlapping with the edge of
>> the slab. Conversely in confocal, you will always have signal being
>> generated and are relying on the pinhole to reject the out-of-plane light.
>> As you take a volume stack into a slab In 2P you will get some entertaining
>> edge effects due to spherical aberration if the index of your fluorescent
>> slab isn't matched to your immersion media, but otherwise 2P just doesn't
>> generate signal unless the sample is within the focal spot. Please keep in
>> mind I am thinking about the Z direction in this, not XY.
>>
>> I hope this helps; I'm really tired and may not be as coherent as usual. :)
>> Craig
>>
>> On Wed, May 11, 2016 at 3:01 PM, Michael Giacomelli <[hidden email]> wrote:
>>
>>> *****
>>> To join, leave or search the confocal microscopy listserv, go to:
>>> http://lists.umn.edu/cgi-bin/wa?A0=confocalmicroscopy
>>> Post images on http://www.imgur.com and include the link in your posting.
>>> *****
>>>
>>> I have been reading up on signal to background ratios in point
>>> scanning confocal and spinning disk confocal.   There are a number of
>>> very detailed papers that characterize the out of focus rejection in
>>> terms of the edge response function for a thick fluorescent sample in
>>> the one photon case (figure 14, [1] for instance) .
>>>
>>> What i have not been able to locate is a reasonably thorough treatment
>>> of the subject for multiphoton microscopy with non-descanned
>>> detection.  Instead most of the work I can find only looks at the
>>> signal to background ratios with depth into a tissue specimen.  This
>>> is helpful, but difficult to compare since you can't image deeply with
>>> confocal.
>>>
>>> Does anyone have a good reference they could suggest?
>>>
>>>
>>> [1]  Zimmermann, B., Kempe, M., & Wolleschensky, R. (2006). High-speed
>>> confocal fluorescence imaging with a novel line scanning microscope.
>>> Journal of Biomedical Optics, 11(6), 064011.
>>> http://doi.org/10.1117/1.2402110
>>>

> Hi Craig,
>
> I realize that 2 photon excitation is most likely in the focal plane,
> but the probability of it happening is nonzero everywhere the beam
> reaches, so you do get some signal from out of focus light as in the
> confocal case.  This is an issue in deep brain imaging for instance.
> I spent a little while searching on Google scholar but didn't see very
> much on signal to background ratios derived or measured for the step
> test though, just deep tissue imaging.
>
> For what it's worth, I'm curious because I do see some depth dependent
> background when Z-stacking the air above a fluorescent slide.  It's
> weak, but I'm curious if what I measure is reasonable, or if I should
> be double checking my PSF and filter rejection.
>
> Mike
>
> On Wed, May 11, 2016 at 9:01 PM, Craig Brideau <[hidden email]>

>> *****
>> To join, leave or search the confocal microscopy listserv, go to:
>> http://lists.umn.edu/cgi-bin/wa?A0=confocalmicroscopy
>> Post images on http://www.imgur.com and include the link in your posting.
>> *****
>>
>> Because the signal is only generated at the focal plane, multiphoton
>> doesn't have the same kind of background issues as confocal. This means
>> there is no out-of-focus signal to reject. The spatial restriction means
>> that your laser's point spread function (in XYZ) is the limit of your
>> detection and your signal generation volume. For instance in the edge
>> response to a thick fluorescent sample, you won't get any signal

>>> *****
>>>
>>> I have been reading up on signal to background ratios in point
>>> scanning confocal and spinning disk confocal.   There are a number of
>>> very detailed papers that characterize the out of focus rejection in
>>> terms of the edge response function for a thick fluorescent sample in
>>> the one photon case (figure 14, [1] for instance) .
>>>
>>> What i have not been able to locate is a reasonably thorough treatment
>>> of the subject for multiphoton microscopy with non-descanned
>>> detection.  Instead most of the work I can find only looks at the
>>> signal to background ratios with depth into a tissue specimen.  This
>>> is helpful, but difficult to compare since you can't image deeply with
>>> confocal.
>>>
>>> Does anyone have a good reference they could suggest?
>>>
>>>
>>> [1]  Zimmermann, B., Kempe, M., & Wolleschensky, R. (2006). High-speed
>>> confocal fluorescence imaging with a novel line scanning microscope.
>>> Journal of Biomedical Optics, 11(6), 064011.
>>> http://doi.org/10.1117/1.2402110
>>>