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Guy,
in any incoherent modality, the image formation is always composed out of
the product of emission and excitation psf's. In the special case of point
scanning confocal microscopy, its only that the (widefield) emission psf is
further convolved by the geometry of the pinhole before multiplication.
Therefore, of course you are right in saying that towards a more open
pinhole the emission psf component approaches a constant. In 2p, the
excitation psf is significantly smaller (approaching the square with no
aberrations present) and in theory a pinhole in the emission path could
further increase the sectioning resolution. However, numerically this is
insignificant as due to the square, the excitation psf already is much
smaller than the emission psf could possibly become, even with pinhole. On
top of all the often very low 2p SNR and present SA forbids to observe
minute improvements.
Regards
Lutz
-----Original Message-----
From: Guy Cox
Sent: Sunday, November 17, 2013 1:18 AM
To: [log in to unmask]
Subject: Re: 2P vs 1P psf
The confocal psf is not the product of excitation and emission psfs unless
the pinhole is very small (much less than 1 Airy unit). In normal use
(pinhole at 1 Airy) it is just the excitation psf. So it will actually be
quite similar to the 2p one. (At 800nm Rayleigh resolution is ~350nm and
350/1.4 gives ~250nm.)
I agree with an earlier correspondent that the greater background is almost
certainly due to the fact that 2p excitation spectra tend to be broader than
1p ones. If so it should be possible eliminate it by a more selective
detection filter.
Guy
-----Original Message-----
From: Confocal Microscopy List [mailto:[log in to unmask]] On
Behalf Of Jeff Reece
Sent: Sunday, 17 November 2013 1:13 AM
To: [log in to unmask]
Subject: Re: 2P vs 1P psf
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First I will assume that "all other things equal" means that the 2P and 1P
images have the same SNR. (A lower SNR will give you a lower effective
resolution.)
If you are within a few microns of the cover glass, resolution should be
worse with 2P than 1P. This is because the much longer excitation
wavelength in 2P creates a larger psf. Even though the effective psf in 2P
mode is the square of the raw excitation psf, the confocal psf is the
product of the excitation and emissions psfs.
Then, as you get away from the cover glass, at some point-- the resolution
in the 2P image will start to look better than 1P. This is because the
shorter excitation wavelength in 1P has a harder time focusing at the deeper
depths, due to the difference between immersion media RI and sample RI,
and/or the dispersion of the sample as a function of wavelength. Exactly
where the transition occurs depends on these factors, maybe others that have
escaped me at the moment. So I say "a few microns" but it is more likely in
the tens of microns when using water immersion with live sample.
Since your user is in the realm where 1P looks better then 2P, then it is
likely that there is also not much dispersion of the emission through the
sample, so one could collect the 2P emission on the descanned detector with
the pinhole closed down (to a little less than 1AU based on the 2P psf),
without losing much signal from the focal plane. Resolution in 2P could
then be increased, with the added benefit of removing other background from
OOF planes. Of course this doesn't work in thick tissue where there is
dispersion.
If the 2P "background" signal you mention is not due to nearby OOF signal,
but seems ever-present and non-changing as you move around a sparsely
stained sample in xy:
2P requires a lot more laser power at the sample than 1P to get the same
signal back; the extra power density in the focal volume is necessary in
order for 2P to
occur. Thus reflection of the laser on all optical interfaces, relative to
the fluorescence signal, is much higher with 2P than 1P at the point where
the emission hits the dichroic. So the dichroic and emission filter need to
be better at blocking the laser for 2P than 1P.
If you have this problem, then obviously the best fix is to replace or
double up the emission filter so you get better blocking of the laser. If
your user is in the ("thin sample") case mentioned above, then you could
alternatively use the quick fix of sending the 2P emission to the descanned
detector and closing down the pinhole.
I hope my lengthy explanation has helped.
Cheers,
Jeff
>________________________________
> From: "Laevsky, Gary S." <[log in to unmask]>
>To: [log in to unmask]
>Sent: Friday, November 15, 2013 9:00 AM
>Subject: 2P vs 1P psf
>
>
>*****
>To join, leave or search
the confocal microscopy listserv, go to:
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>
>Hi All,
>
>Iām sure there is going to be a simple answer here, but it alludes me.
>
>I know the psf is a function of NA and wavelength.
>
>Obviously, with 1P we use a pinhole to exclude out of focus light, and when
>set at ā1 Airy,ā you have maximized the pinhole for the particular
>wavelength you are using. With 2P, no pinhole is necessary because of the
>non-linear excitation mechanism.
>
>A user just approached me and asked if/why there would be more out of focus
>light in a 2P image then in a 1P image with a properly set pinhole. In a
>collaborators experiments, there seems to be more background in the 2P
>image (all other things equal).
>
>Only thing I can think of is a poor beam
profile on the 2P. Maybe a large pulse width would excite a larger spot?
>
>Thankful for the insight.
>
>
>Best,
>
>Gary
>
>
>
>Gary Laevsky, Ph.D.
>Confocal Imaging Facility Manager
>Dept. of Molecular Biology
>Washington Rd.
>Princeton University
>Princeton, New Jersey, 08544-1014
>(O) 609 258 5432
>(C) 508 507 1310
>
>
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