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>
> George,
> thanks for the note re: AausFP1. I will definitively check it out.
>
> In a spectrum that goes from (slowest speed / highest 3D SNR) to (highest
> speed / lowest 3D SNR), my understanding is that MPEF < Scanning confocal <
> Spinning confocal. That is, one has to trade 3D SNR for speed and I need to
> be able to hit 100s fps in certain important applications. Am I wrong? (I
> understand AasusFP1 increased brightness with help SNR and potentially
> enable faster recordings, but I am not sure how linear that
> relationship would be given photobleaching...)
>
> Another option would be (lattice) light-sheet microscopy but I have not
> found an implementation that works well on multi-well plates. The possible
> exceptions are the 3i implementations and Luxendo QuVi but they are pretty
> untested at this point. Does anyone have any experience with these
> platforms?
>
> Thanks,
> Francesco
>
>
> On Mon, Dec 16, 2019 at 3:57 AM George McNamara <[hidden email]
> >
> wrote:
>
> > Hi Francesco,
> >
> > since >50 um thick, think about multiphoton excitation fluorescence
> > microscopy ... second harmonic generation (some types of collagen).
> >
> > Fiber lasers that output single wavelength, typically ~100 femtoseconds,
> > 80 MHz repetition rate, are in the $10K - $60K range, each. If only one
> > microscope rig, implies point scanning (or TriMscope or similar). That
> > is, 1 or 3 lasers for potentially a lot less than a tunable Ti:Sapphire
> > laser (and could start with one fiber laser at most important wavelength
> > ... could be launched into a conventional 1p confocal scanner).
> >
> > You could have both point scanning (MPEF) and spinning disk confocal on
> > same microscope. I strongly urge investing in GPU deconvolution
> > software, optimized for each mode you will use.
> >
> > FYI - In May 2019 at JHU, Nathan Shaner (UCSD) started his talk on
> > AausFP1 -- 5x brighter than EGFP -- with a multi-day timelapse video
> > acquired at 6 min intervals (sped up on playback).
> >
> > I suggest starting to make AausFP1 constructs, amino acid sequence in
> > https://www.biorxiv.org/content/10.1101/677344v2 (obligate dimer ... so
> > tandem dimer and/or monomerization mutation should be installed ... also
> > codon optimize). Preprint does not discuss Yellow version, should be
> > doable with one mutation (re: EGFP --> EYFP), so could have two colors.
> > Tandem dimer of G-->Y should be outstanding for FRET (3rd color).
> >
> > Also start thinking about optimized filter set(s) and/or confocal/MPEF
> > capabilities, to get the most of the narrow excitation and emission
> > peaks of AausFP1(green), AausFP1(Yellow), AausFP1(green-->Yellow).
> >
> > FYI - our Olympus FV3000RS confocal microscope worked well for GCaMP6,
> > https://www.physiology.org/doi/abs/10.1152/ajpcell.00351.2018 (our Leica
> > SP8 confocal would have worked fine, but purchased without 37 C and
> > environmental control). Here in the U.S., the microscope vendors often
> > provide a nice trade-in credit, so I encourage asking your new place if
> > they have an old confocal to trade in toward purchase.
> >
> > best wishes,
> >
> > George
> >
> > p.s. see also current optical clearing methods for fixed specimens, and
> > expansion microscopy.
> >
> >
> > On 12/13/2019 12:18 PM, Francesco Pasqualini 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.
> > > *****
> > >
> > > Hi,
> > > I will start my ERC-funded lab in Italy in 2020, which means I am
> > fortunate
> > > to be shopping for a confocal instrument right about now.
> > >
> > > Since I do mostly live experiments (more details below) I was going to
> > get
> > > a spinning disk system. But, I realized that the new scanning confocals
> > are
> > > also relatively fast and gentle. The question is how much (if at all)
> > > slower and harsher are they with respect to spinning disks?
> > >
> > > More details:
> > > - I do a lot of live experiments (traction force microscopy and
> > > voltage/calcium-sensitive dyes) on engineered cells (300x300 um FOV)
> and
> > > tissues (600x600 um FOV) in 2D or 3D (<300 um thick) that I complement
> > with
> > > immunostainings after fixation. Needed acquisition rates go from <1 fps
> > to
> > > 100s depending on the application.
> > >
> > > - Originally, I was oriented towards a spinning disk confocal
> > > (Yokogawa/SORA, Crest) and was looking at ways to deal with the issues
> of
> > > confocality on the 3D tissue (600x600x300 um volumes) case. But, I
> > realized
> > > all vendors have new point scanning confocal (980+Airyscan2, FV3000,
> A1R)
> > > with resonant scanners that acquire full frames/ROIs at 10s/100s of fps
> > >
> > > - Of course, structured illumination (Elyra-7, N-SIM) and light-sheet
> > > microscopes (QuVi) are also appealing but relatively untested in my
> > > applications of interests....
> > >
> > > The application specialists from all vendors in my area have been great
> > to
> > > work with but since my lab is not up and running, yet, I can't demo
> these
> > > systems directly. Therefore, I could use help and feedback, especially
> > from
> > > people who have had related experiences in the recent past.
> > >
> > > Thanks,
> > > Francesco
> > >
> >
>
>
> --
> Francesco S. Pasqualini
> Visiting Professor University of Pavia
> Associate Harvard University
>
> tel: +39 351-521-7788 (IT)
> tel: +1 617-401-5243 (USA)
>