Spinning vs fast scanner systems

>Dear All
>Fast image acquisition can be done by resonant scanner (Nikon), Tandem
>scanner (Leica), sim scanner (Olympus) and duo scanner (Zeiss).
>Can anybody please let me know how comparable are the results in terms of
>image quality. I may be highly wrong but can each one of them be compared
>with the Yokogawa spinning disk system except the fact that these all are
>single point scanning system and yokogawa spinning disk is a multi point
>scanning system. How is the bleaching and phototoxicity effects???
>I know that we are capturing signals through a high end camera system
>(EMCCD) in Yokogawa and we use scanners in all these systems. But let us
>talk about the end result i.e. an image with the required information. DO WE
>REALLY GET COMPARABLE IMAGES because i think that these scanners are
>evolved or generated as a requirement of fast
>imaging. It is quite obvious that
>we ceratinly can not eliminate the requirement of fast imaging systems like
>yokogawa spinning disk by introducing all these scanners keeping in mind the
>benefits provided by yokogawa fast imaging system but what if we have these
>scanner sytem and we want them to produce a quality image through fast
>acquisition.
>I have seen images acquired by Nikon's resonant scanner and Leica's tandem
>scanner ( Calcium flux inside mammalian cell lines) and compared them with
>the images acquired by yokogawa spinning disk, they seem to be quite OK (at
>least in the presentation).
>
>I have an idea of the speed of all these scanner systems in filter mode but
>can any body let me know what is the speed of all these scanner systems
>(recent models i.e. Nikon A1R, Zeiss 710/780, Olympus FV1000 and leica SP5)
>in SPECTRAL MODE AT 512 x 512.
>
>Thanks in advance
>
>Charu Tanwar
>Imaging Specialist
>Advanced Instrumentation Research facility
>Jawaharlal Nehru University
>New Delhi
>India

> Dear Charu,
>
> You bring up some good points. A lot of folk are
> looking for the best way to image living
> specimens fast but there are a lot of practical
> variables to keep in mind.
>
> Basically, it comes down the number of photons
> involved. But the story is not a short one
> (Please excuse length. At least it is shorter
> than The Handbook)
>
> Because Poisson statistics limits the accuracy of
> any measurement of a photon signal, the
> statistical accuracy of any image depends on the
> number of photons detected. The "noisiness" of
> most confocal images is caused by this quantum
> mechanical conundrum.
>
> Regardless of scanning system, if you want to
> obtain an image of a given quality in 10x less
> time, then you will need to detect photons at a
> rate that is 10x higher. How can this be
> achieved? Assuming that we have already chosen
> the best objective (i.e., objective NA is fixed),
> we can collect more signal by using more laser
> power (up to a point), choosing a scan system
> with more points and/or lower dead time, use a
> larger effective pinhole size or employ a
> photodetector with a higher quantum efficiency
> (QE) (assuming that the photodetector used has a
> very low read noise, which is true for PMTs and
> EM-CCDs that are used properly).
>
> Scan deadtime is the fraction of the scan time
> when signal cannot be collected. On a single-beam
> scanner, this is usually the time when the
> horizontal scan mirror changes direction and
> returns the spot to the "left" side to start a
> new line. It can be about 30% of the line-scan
> time. This wasted time can be reduced by scanning
> in both directions but the signal still cannot be
> collected at each end of the scan and also must
> be digitally lined up to compensate for scan
> non-linearity.
>
> When a resonant scanner is used, the scan motion
> is a sine wave rather than something approaching
> a sawtooth (monodirectional) wave or pyramidal
> (bidirectional) wave. Consequently the real-space
> size of a fixed-time-length pixel in the center
> of a scan will be (much) smaller than one near
> either end of the line where the mirror slows
> down to turn around. Although this geometrical
> distortion can be linearized somewhat by varying
> the pixel clock with the scan position (i.e.,
> shorter pixel times in the center of the scan
> where the mirror moves fastest), doing so does
> not prevent the edges of the field from being
> exposed to more light (and producing both more
> signal photons and more damage). Scan systems in
> which a mask of pinholes moves over a raster
> pattern must have similar problems and these may
> show up, for instance in the form bright lines
> where the rasters from adjacent spots overlap (or
> dark lines where they don't).
>
> In terms of the number of scanning beams:
>
> Clearly using 1,000 beams (about right for a
> Yokogawa) should permit getting data at 1,000x
> the rate of systems using a single beam
> (especially as there is no dead time in a rotary
> scan system, although the EM-CCD cannot be read
> out continuously). However, in practice, using
> 1000 beams as bright as those used in a fast scan
> single-beam instrument would cause almost
> instantaneous bleaching of the specimen. In
> practice, Yokos tend to be used with maybe 10x
> more mW of power striking the specimen than with
> a single-beam instrument. The latter is limited
> to less than a mW in a 0.5µm spot by the need to
> avoid singlet-state saturation. However, all
> other things equal, more light at the excited
> area of the specimen means either better looking
> images or more of them in a given time period
>
> Line illumination can be thought of as a row of
> point illuminators: say 512, in a row. The Zeiss
> LIVE-5 uses cylindrical optics to always create a
> diffraction-limited line of illumination in the
> specimen, but the detection slit is variable in
> size. The larger slits (like larger pinholes) are
> mostly useful to "spoil" the z-resolution, which
> has the good effect of allowing signal from
> near-focus planes to be added to that from
> in-focus planes. More signal -> less apparent
> noise.
>
> Although the Olympus DSU (and perhaps the
> CARV-2?) allows one to use disks having a variety
> of patterns and slit-widths, on average the slits
> tend to be larger and the overall "transparency"
> greater than most other mask systems, probably
> because the mercury arc sources they are used
> with have much lower brightness than the lasers
> used in other systems.
>
> Although the Yokogawa uses fixed pinholes, their
> effective size can be crudely adjusted by
> utilizing objectives of differing magnification
> (but the same NA. Usually, higher mag objectives
> provide closer to "one Airy" pinhole sizes.).
> There is however, some question as to the size
> and shape of the illuminating spots in a the
> Yokogawa. If we assume that the lenslets are
> "perfect lenses", then they should form a
> diffraction-limited spot centered on (and about
> 2x smaller than) each pinhole in the lower disk.
> These spots will then be focused into
> diffraction-limited spots in the specimen of
> roughly the same size and shape as those produced
> in a single-beam instrument. (I say roughly
> because it is not quite clear how well the BFP of
> the objective will be filled in either case.)
> However, if the lenslet is not "perfect" (i.e,
> has spherical aberration; is misfocused because
> of chromatic aberration; or is somewhat
> misaligned with its pinhole), then the light will
> be focused into a larger "blob" at (or near) the
> plane of the lower disk and this blob will be
> first truncated by the pinhole in this disk and
> then focused into a blob in the specimen that is
> somewhat larger than the diffraction-limited spot
> of the single-beam instrument.
>
> Similar considerations apply to other swept-field
> systems that use lenslets. These considerations
> are worth mentioning because, depending on the
> precision of the implementation, they give rise
> to various forms of fixed-pattern noise. (i.e.,
> as all lenslet-pinhole combinations may not be
> identical, the part of the image scanned by one
> lenselet may be brighter or dimmer than that of
> another lenslet, something that is easily visible
> as the faint, curved scan lines visible when
> looking at a specimen of uniform fluorescence
> with a disk-scanner. Likewise the scanned-line
> systems can develop horizontal streaks if (even
> out-of-focus) dust particles partially obscure a
> segment of the detection slit.).
>
> Although this artifact may be acceptable in the
> Yoko if all 20,000 lenslets have a chance to scan
> the field, it may be less acceptable as the
> exposure becomes shorter and a each part of the
> specimen is scanned only a few times. (i.e., For
> instance, if it takes 1ms for a spot to move from
> one side of the field to the other and that the
> lenslet pattern repeats every "fields-worth",
> then using an exposure of 1.1 ms will have the
> effect that about 10% of the field has twice the
> exposure of the rest [where the scan lines from
> the first set of lenslets overlaps with that from
> the next set], and there may be other differences
> depending on the relative efficiency of the
> individual lenslets, either in conveying light to
> the specimen or back to the camera. Although the
> Yoko disk rotates fast enough (1800 rpm, or about
> 3 ms, pattern) that this is a minor problem,
> similar considerations may be important for some
> of the other systems.).
>
> So far however, the multi-beam/- systems are
> broadly similar in terms of the total amount of
> light "usually" striking the specimen. However,
> as this amount can be adjusted, and more light
> will give better looking images (less statistical
> noise), it is always important to know how much
> light was striking the specimen when a demo image
> is provided. (i.e. you need to measure this.)
>
> The fraction of the evoked fluorescent signal
> that gets to the detector will depend on the
> effective size of the detection slit/pinhole and
> these too can be adjusted (with different
> pinholes, different disks, or objectives with
> different mags), at least to some extent. Again,
> more photons will produce "better looking"
> images. However, images with bigger pinhole/slits
> will also have less depth resolution. The best
> plan is to image something you know. Like a 0.2
> µm fluorescent bead, and then look at the result
> in 3D. (or as an xz image, to check the
> z-resolution.)
>
> Finally, the detectors: The LIVE_5 still uses a
> conventional CCD and therefore has at least +/-
> 8-10 electrons of noise in each pixel
> measurement. The best EM-CCDs, have essentially
> no read noise but the multiplicative noise of the
> electron multiplier register effectively reduces
> the raw QE of the detector by 50% (compared to
> that of the a normal CCD, such as that used in
> the LIVE-5). Even so, the QE of the best EM-CCDs
> is still at least 5x better than that of the best
> PMTs in the green/yellow and probably 10-15x
> better as you go into the red.
>
> Things to watch out for.
>
> During demos, the easiest way to "make the
> picture look better" is to use more laser power.
> Buy (or make
> http://www.repairfaq.org/sam/laserioi.htm#ioisg1)
> a cheap laser power meter and measure the beam
> power coming out of the lens (Do this with the
> same relatively low mag, low-NA objective in each
> case and account for possible differences in the
> field of view: Larger field = more pixels, will
> require more light.) Remember, it is power
> reaching the specimen (not that out of the laser)
> that causes bleaching and phototoxicty.
>
> In addition, one can always make a noisy image
> look better by using time or spatial averaging,
> or by binning the output of the various CCD and
> EM-CCD sensors. But, assuming that the pixel size
> was originally chosen to meet the Nyquist
> criteria,  binning reduces the spatial
> resolution. A better solution is a (so far only
> imaginary) system that "deconvolves" the the data
> (in 3D or Gaussian filters in 2D) as it comes in.
> This can produce a MARKED improvement in the
> apparent noisiness of the final data (i.e., Once
> you adjust the contrast/brightness up to a useful
> level, you can get the same image quality with
> 10-20x less signal.)
>
> Don't forget the importance of looking at a
> specimen that you know: my favorite is Nothing.
> Obstruct the laser (or turn it off) and then see
> what your detector records (probably the room
> light). With an EM-CCD, it should be <10
> single-photoelectron counts per 512-pixel line
> (make sure that the gain is turned up enough to
> easily see these peaks in a line scan through the
> data). With a good PMT, you should get a similar
> result (<10 spikes in a 2 mS line scan).
> Although, because of multiplicative noise, the
> spikes will NOT all be the same size, you should
> still be able to discriminate them from the
> electronic background noise by eye.
>
> Finally, know your specimen. A specimen with 10x
> more dye will produce about 10x more signal and
> look a lot better. If you start viewing a thin
> specimen mounted in oil and situated close to the
> coverslip with a 1.4NA oil lens, you will get a
> much better signal (and a nicer picture!) than
> you get when you switch to a wet specimen in the
> same set up (because the water will cause
> spherical aberration (SA) and also reduce the
> effective aperture of your objective). Even with
> a water lens, the image will be worse (because
> the signal goes with NA squared and you are now
> at NA1.2, not 1.4), especially if you don't
> adjust the correction ring very carefully to make
> sure that you have no SA (+/- 2µm or
> water-replaced-by-glass)
>
> Tell us what you find.
>
> Happy 2010,
>
> Jim Pawley
>
>
>                **********************************************
> Prof. James B. Pawley,                             Ph.  608-263-3147
> Room 223, Zoology Research
> Building,                           FAX
> 608-265-5315
> 1117 Johnson Ave., Madison, WI, 53706
> [hidden email]
> 3D Microscopy of Living Cells Course, June 12-24, 2010, UBC, Vancouver Canada
> Info: http://www.3dcourse.ubc.ca/      Applications due by March 15, 2010
>       "If it ain't diffraction, it must be statistics." Anon.
>
>
>> Dear All
>> Fast image acquisition can be done by resonant scanner (Nikon), Tandem
>> scanner (Leica), sim scanner (Olympus) and duo scanner (Zeiss).
>> Can anybody please let me know how comparable are the results in terms of
>> image quality. I may be highly wrong but can each one of them be compared
>> with the Yokogawa spinning disk system except the fact that these all are
>> single point scanning system and yokogawa spinning disk is a multi point
>> scanning system. How is the bleaching and phototoxicity effects???
>> I know that we are capturing signals through a high end camera system
>> (EMCCD) in Yokogawa and we use scanners in all these systems. But let us
>> talk about the end result i.e. an image with the required information. DO WE
>> REALLY GET COMPARABLE IMAGES because i think that these scanners are
>> evolved or generated as a requirement of fast
>> imaging. It is quite obvious that
>> we ceratinly can not eliminate the requirement of fast imaging systems like
>> yokogawa spinning disk by introducing all these scanners keeping in mind the
>> benefits provided by yokogawa fast imaging system but what if we have these
>> scanner sytem and we want them to produce a quality image through fast
>> acquisition.
>> I have seen images acquired by Nikon's resonant scanner and Leica's tandem
>> scanner ( Calcium flux inside mammalian cell lines) and compared them with
>> the images acquired by yokogawa spinning disk, they seem to be quite OK (at
>> least in the presentation).
>>
>> I have an idea of the speed of all these scanner systems in filter mode but
>> can any body let me know what is the speed of all these scanner systems
>> (recent models i.e. Nikon A1R, Zeiss 710/780, Olympus FV1000 and leica SP5)
>> in SPECTRAL MODE AT 512 x 512.
>>
>> Thanks in advance
>>
>> Charu Tanwar
>> Imaging Specialist
>> Advanced Instrumentation Research facility
>> Jawaharlal Nehru University
>> New Delhi
>> India
>
>
> --
>                **********************************************
> Prof. James B. Pawley,                             Ph.  608-263-3147
> Room 223, Zoology Research
> Building,                           FAX
> 608-265-5315
> 1117 Johnson Ave., Madison, WI, 53706
> [hidden email]
> 3D Microscopy of Living Cells Course, June 12-24, 2010, UBC, Vancouver Canada
> Info: http://www.3dcourse.ubc.ca/      Applications due by March 15, 2010
>       "If it ain't diffraction, it must be statistics." Anon.