Posted by George McNamara on
URL: http://confocal-microscopy-list.275.s1.nabble.com/Service-contracts-tp7584891p7584913.html

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Hi Avi, -- and I am copying this to the listserv,

Back when I was in Miami, one of the Leica confocal applications
scientists (I forget his name - sorry!) showed me side by side
comparison of resonant scanner (RS) vs standard mode for as identical
acquisition settings as possible, on a couple of specimens. The bottom
line was that for the same total dwell time, RS gave as good (or better)
data, with less photobleaching of those particular specimens. My
recollection is that very slow dwell times in standard mode led to a lot
more photobleaching.
I encourage you / your lab / your users (maybe all late first year grad
students should do this and other exercises on shared instrumentation!)
to compare:
standard scanner:
* 80 Hz (if slowest dwell time)
* 800 Hz (I forget whether this is Leica SP5 default speed)
* max standard scanner speed (for say 512x512 pixel image)
RS = 8000 Hz
* no averaging
* 10 frame averaging (effectively 800 Hz)
* 100 frame averaging (effectively 80 Hz
Personally, I hate averaging on a confocal ... long ago I complained on
the Confocal Listserv that the confocal manufacturers should come up
with "more sophisticated" algorithms for denoising confocal PMT data ...
as the simplest improvement, I suggested odd number of acquisitions, and
taking the median for each pixel (this way would be a real pixel value,
not average of two intensity reads). For example, PMT at high gain might
output, 101, 1, 1, 1, 1, average = 21, median = 1.
Note: RS mode is even more fun with very few rows, single line, so 8000
linescans per second on Leica SP5.

One of my favorite papers (except for their acronym [it would work on
non-FRET data] and slow speed in 2008)
http://www.ncbi.nlm.nih.gov/pubmed/?term=hoppe+swanson+2008
PDF available at
http://www.ncbi.nlm.nih.gov/pmc/articles/PMC2426648/
61 lines of Matlab code (though needs a commercial library):
The computer simulations and algorithm development were carried out in
using MATLAB 7.3 (The Mathworks, Natick, MA) and the DIPImage toolbox
for MATLAB (http://www.diplib.org/, Quantitative Imaging Group, Delft
University of Technology, Netherlands) in the Linux operating system
(OpenSUSE 10.0, Novell, Waltham, MA). The computer was a custom-built
dual-Athlon (AMD) machine with 5 GB RAM. The MATLAB function for 3DFSR
can be found athttp://sitemaker.umich.edu/4dimagingcenter/3dfsr.
(oops, that UMich web site ended - email the authors for the .M code).

  -- what I refer to as "joint spatial deconvolution and spectral
unmixing" (JSDSU or JSDSUN) ... results in a 10x improvement in signal
to noise ratio. Spatial deconvolution is now "instant gratification"
with GPU(s):
www.microvolution.com (yes, that's my image on their home page - no
financial interest) and presumably (I've not tested it)
SVI Huygens w/ GPU ... https://svi.nl/HuygensGPU

NVidia top of the line GPU graphics card, GeForce GTC Titan-X, is around
$1000 (and drives an HD 4K monitor). By end of 2016 their next gen card
will be same $1000, but about 10x faster (more cores, somewhat higher
clock rate) and more RAM ... and some PC's could take 2 or 3 of these.

I hope both Microvolution and Huygens implemenet joint processing.

I would also like to see the microscope vendors implement many-cameras
to use the full spectral range of fluorescence, full field of view,
without moving parts. Also as compact as possible, and simple C-mount to
the microscope.

A good number of cameras would be eight sCMOS 82% QE cameras (i.e.
USB3). The usable fluorescence emission range is about 370-850 nm, so
480 nm range divided by 8 cameras is about 60 nm per emission band.
Probably narrower in the cyan-green-yellow bands, and much wider in the NIR.

One could today purchase two Cairn Research MultiCam LS's
https://www.cairn-research.co.uk/product/multicam-ls/
replace one of the eyepiece/camera mirrors with an appropriate dichroic,
and go 8plex.

S.J. Morris published in the early 1990's on 4 ICCDs for simultaneous
Ca++ and pH ratiometric imaging (Nikon splitter on the Diaphot, followed
by splitters on each of those ports).

Jeff Price (Sanford-Burnham) and Sally Ward & Raimund Ober (long time
UTSW, now at Texas A&M) have published on multi-focal setups. If
academics can do it, how about vendors stepping up?


George
p.s. one TITAN X price is $1251,
http://www.amazon.com/GeForce-Graphics-384-Bit-Express-GTXTITANX-12GD5/dp/B00V7C9N26
GeForce GTX TITAN X Graphics Card, 12GB GDDR5 384-Bit, PCI Express 3.0
HDCP Ready SLI Support Video Card (GTXTITANX-12GD5)
Academic pricing might be better.

p.p.s. Using a coverglass with a sparse distribution of
ThermoFisher/.../Molecular Probes TetraSpeck beads (40 or 100 nm
diameter), and/or MM2 nanoparticles (the latter also provides O2 data,
first emission band is similar to BV421, O2 sensitive band is narrow at
650 nm ... ok, so maybe 12 cameras, also Tb and Eu lanthanides
emissions, and might as well have a full time dedicated transmitted
light band, such as way out in NIR, re: Dodt's IR-VEC-DIC, though I
would just go brightfield + deconvolution and/or QPm),
http://luxcel.com/MitoImage%C2%AE+MM2+Description
http://ibidi.com/fileadmin/products/cells_reagents/R_741XX_NanO2_MM2/IN_74161_MM2.pdf
If the NIRvana Sciences chlroins/chlorphyll based dyes work well (their
academic cofounders, Jonathan Lindsey et al, are now at QY 0.3 for
some), these narrow emission peaks,
http://nirvanasciences.com/?page_id=3088
especially if could be tandem'd on the Brilliant's (BUV, BV, BB ...
maybe some day BG?) could enable imaging with as many plex (or more)
than the flow folks.


On 3/17/2016 1:02 AM, Avi Jacob wrote: