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S5015
Light microscopy methods in biology
Lecture 1: History and principles of light  microscopy
Milan Ešner
Cellular Imaging Core Facility, Ceitec MU
milan.esner@ceitec.muni.cz

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S5015 : Light microscopy methods in biology
Light microscopy methods in biology
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Lecture 1: September 30, 2021 at 9:00
History of microscopy, fundamentals of light microscopy. Contrasting techniques in transmitted
light microscopy – brightfield, darkfield, phase contrast, DIC.
Widefield fluorescence microscopy - deconvolution, point spread function, point spread function
measurements, description.
Detectors in widefield microscopy, filters, light sources.
Lecture 2: October 14, 2021 at 9:00
Confocal microscopy - principles, types of confocal microscopes – scanning, spinning disc, channel
vs spectral imaging, linear unmixing.
Lasers, detectors, beam splitters, optical sections. Lightsheet microscopy.
Lecture 3: October 25, 2021 at 9:00
Imaging below diffraction limits – SIM, SMLM, STED
Lecture 4: November 4, 2021 at 9:00
Basics of Image analysis – image types, pixels, voxels, basic filters, image processing, metadata,
deconvolution, 3D visualization,
objects detection, quantification.
Practical 1: December 14, 2021 at 9:00
Transmitted light microscopy, widefield fluorescence, confocal, Apotome, SIM
Practical 2: December 15, 2021 at 9:00
Sample preparation, single molecule localization microscopy acquisition and analysis,
deconvolution.

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Antonie van Leeuwenhoek (1632 – 1723)
Dutch businessman and scientist. Best known for his pioneering work in microscopy. Used single lens
microscope
of his own design.
[USEMAP] See caption
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Robert Hooke (1635 – 1703)
English scientist, philosopher, architect and polymath. Improved design of compound microscope and
use it
for scientific exploration – book Micrographia. Use term <cell> in biological context.
Současný portrét Roberta Hookea
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Carl Zeiss (1816 – 1888)
German scientific instrument maker, optician and businessman. Founder of Carl Zeiss workshop in
1864
together with Ernst Abbe and Otto Schott in Jena, Germany.
Die Anfänge des wissenschaftlichen Mikroskopbaus
Light microscopy methods in biology
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Ernst Abbe (1840 – 1905)
https://upload.wikimedia.org/wikipedia/commons/thumb/3/37/Ernst_Abbe_memorial.JPG/1280px-Ernst_Abbe
_memorial.JPG
German physicist, optical scientist, entrepreneur and social reformer. With Zeiss and
Schott he developed numerous optical instruments. Among his inventions are apochromatic lens,
Abbe condenser, refractometer.
He defined numerical aperture -> mathematically describing optical resolution of light microscopes.
He was also strongly implicated in unions and workers rights. In Zeiss he introduced 8-hour
workday.
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George Biddell Airy (1801 – 1892)
English mathematician and astronomer. He established Greenwich as the location
of the prime meridian. His main contribution to microscopy was explaining of
formation of concentric diffraction pattern around the bright spot of light,
named after him – Airy disc.
[USEMAP]
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August Koehler (1866 – 1948)
German optical scientist. He developed and improved light illumination of sample, Koehler
illumination.
Light microscopy methods in biology
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Siedentopf and Zsigmondy
First concept of light sheet microscope – illumination objective orthogonally to detection
objective. Zsigmondy received Nobel prize for chemistry in 1925 for his research on colloid
solutions.
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Frits Zernike
(1888 – 1966)
Dutch physicist. Invented phase contrast microscopy. Producing high contrast images of
transparent samples, hardly visible in standard bright field transmitted light imaging.
Widely used technique of contrast enhancing. Received Nobel prize in 1953.
Light microscopy methods in biology
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Georges Nomarski
(1919-1997)
Polish physicist. Developed differential interference contrast (DIC) –
contrast enhancing technique based on polarized light.
Molecular Expressions: Science, Optics and You - Timeline ...

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Marvin Minsky (1927-2016)
American scientist, doing mainly research of artificial intelligence. He is
Co-founder of Massachusetts Institute of Technology (MIT).
He developed first scanning confocal microscope in 1957.
Light microscopy methods in biology
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Mojmír Petráň (*1923)
Czechoslovak scientist. Studied medicine at Charles university, Prague.
With Milan Hadravsky he developed spinning disc confocal microscope in 1964, using Nipkow disc from
TV.
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Jan Huisken, Eric Stelzer
Developed fluorescence light sheet microscope (selective plane illumination microscope) in 2004.
Almost 100 years after Siedentopf and Zsigmony microscope they built first fluorescence microscope,
using different optical paths for illumination and detection. Today exists many variants of
lightsheet
microscopes and several commercial systems are available.
Ernst H.K. Stelzer | Physikalischebiologie.de Jan Huisken | Morgridge Institute for Research
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Mats Gustafsson (1960-2011)
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Developped method of structured illumination microscopy SIM. SIM surpass diffraction limit of
optical microscopes
and is able to achieve resolution below 100 nm.

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Eric Betzig (*1960)
Inventor of single molecule localization technique STORM/PALM together with William Moerner and
lattice light sheet technology. Received Nobel prize in 2014 together with Eric Betzig and Stephen
Hell
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William Moerner
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Contributed to development of sinlge molecule localization microscopy. Received Nobel prize in 2014
together
with Eric Betzig and Stephen Hell

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Steffen Hell
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Invented stimulated emission depletion (STED) microscopy. Received Nobel prize in 2014 together
with Eric Betzig and Stephen Hell

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Principles of light microscopy
Light microscopy methods in biology
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-In microscopy you don’t observe an OBJECT, you observe an IMAGE of the object
-1) Light diffraction by the specimen
-2) collection of diffracted/non-diffracted rays by objective
-3) interference of diffracted and non-diffracted rays in the image plane.
Three steps in image formation
•Magnification
•Resolution
•Contrast
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Image formation
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http://www.eyelighting.com/_CE/pagecontent/Images/Lamp%20Technology%20Education/quality%20of%20a%20
light%20source.jpg
Monochromatic - single wavelength (color).
Polychromatic
Coherent – waves of the same wavelength that maintain the same phase relation.
Noncoherent
Polarized – waves with E-vectors in parallel.
Nonpolarized
Collimated – waves with the same coaxial paths of propagation (same direction).
Divergent
Visible electromagnetic radiation with electric and magnetic fields whose amplitudes
oscillate as a sine function over dimensions of space and time.
Dual character: waves – amplitude and phase
particles – photons.
shorter wavelength = higher energy
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Light
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Light diffraction
When light passes at the edge of object (opening, aperture, specimen),
light is bended on edges and passes to the area of geometrical shadow.
-Due to the diffraction, Image of a point is not a point
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Light microscopy methods in biology
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Constructive interference
Light diffraction and interference
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Light microscopy methods in biology
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Destructive interference
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Light diffraction and interference
Light microscopy methods in biology
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0
1st
1st
2nd
2nd
3nd
3nd
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Light diffraction and interference
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Air objective
Oil immersion
 objective
Immersion objectives have higher NA and therefore higher resolution.
Adjust refractive index of immersion to your medium!!!
Mowiol, prolong, vectashield –> oil immersion
Glycerol -> glycerol immersion
PBS, medium –> water immersion
Mismatch = high spherical aberrations
From P. Evennett
Výsledek obrázku pro numerical aperture
www.zeiss-campus.magnet.fsu.edu
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Numerical aperture
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Refractive index
Medium
R. Index (n)
Air
1
Water
1.333
Glycerol
1.46
Immersion Oil
1.515
Cover glass
1.515
- Determines how much light is bent (refracted), when entering the material
n1 * sin(a1) = n2 * sin(a2)
Snell’s law:
n1
n2
a1
a2
RI is different for every wavelength – light dispersion on prism.
A white beam of light dispersed into different colors when passing through a triangular prism.
air
water
Light entering to different medium changes the speed
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Refraction
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Image

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Ernst Karl Abbe
https://upload.wikimedia.org/wikipedia/commons/thumb/3/37/Ernst_Abbe_memorial.JPG/1280px-Ernst_Abbe
_memorial.JPG Ernst Abbe.jpg
https://upload.wikimedia.org/wikipedia/commons/thumb/4/46/Ernst-Abbe-Denkmal_Jena_F%C3%BCrstengrabe
n_-_20140802_125709.jpg/170px-Ernst-Abbe-Denkmal_Jena_F%C3%BCrstengraben_-_20140802_125709.jpg
(1840 – 1905)
Microscope
Numerical aperture
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Resolution
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By Spencer Bliven - Own work, Public Domain,
https://commons.wikimedia.org/w/index.php?curid=31456019
https://upload.wikimedia.org/wikipedia/commons/a/ae/Airy_disk_spacing_near_Rayleigh_criterion.png
Two point sources are regarded as just resolved when the principal diffraction maximum of one image
coincides with the first minimum of the other.
Rayleigh criterion
R: resolution/distance
λ: wavelength of light
NA: numerical aperture
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Resolution
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Magnification does not play a role in resolution!
Only NA and l are taken into account!
For green light (550 nm and 1.4 NA objective) d @ 240 nm
Limiting resolution of light microscopes (diffraction limited).
Objective
Resolved distance d (nm)
5x/0.15
2200
10x/0.3
1100
20x/0.5
700
40x/0.75
450
40x/1.3
260
63x/1.4
240
100x/1.3
260
Confocal microscope
1 AU pinhole
Confocal microscope
0.25 AU pinhole
Conventional microscope
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Lateral resolution
29

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⍺
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Objective coding
Light microscopy methods in biology
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Chromatic aberrations
Spherical aberrations
F
F
F
F
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Most frequent lens abberations
Apochromatic objectives
Use correct coverslip
Refraction media match
Light microscopy methods in biology
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Adobe Systems OSRAM HXP 120W/45 CVIS
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Transmitted light microscopy
Light microscopy methods in biology
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Conjugated planes
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Light microscopy methods in biology
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Field set
Aperture set

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Light passing directly through specimen to eys ot other detector
BF – bright field, some microscopes H on condensor
+ Easy to setup, no special requirements
- Low contrast
Bright field
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Closed illuminating aperture
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Only diffracted light from specimen passing to objective
DF – bright field
+ Easy to setup, no special requirements, for high NA
Special condenser required
Dark field
Dark field
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Light microscopy methods in biology
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Transparent objects not visible in the transmitted light mode still
diffract light path and cause phase shift
Phase contrast imaging transform phase differences into
amplitude differences.
Ph1, Ph2, Ph3 – phase contrast
+ Easy to setup, nice contrast, working on plastic dish
- Special objectives required, halo effect around objects
Phase contrast
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Differential interference contrast (DIC)
Based on polarised light. Transform local gradient in optical path
length (refractive index and thickness) in an object into regions of
contrast in the object image. Amplitude differences in the image
due to refractive index and/or thickness of the specimen.
+ nice contrast, 3D perspectives, no halos around objects
- Works on glass only, not trivial to setup
https://www.olympus-lifescience.com
Light microscopy methods in biology
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Reflected light
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Fluorescence microscopy
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Emisní
filtr
Excitation
filter
light

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Fluorescein
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Fluorescence
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-widefield (epifluorescence)
-
-confocal microscopes
-point scanning microscopes
-spinning disc microscopes
-
-lightsheet microscopes
Diffraction limited resolution
Resolution below diffraction limit - nanoscopes
-Structured illumination (SIM)
-
-Stimulated emission depletion (STED)
-
-Stochastic optical reconstruction (STORM)
Types of fluorescent microscopes
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Fluorescein
https://en.wikipedia.org/wiki
Difference between positions of the band maxima of the absorption and emission spectra
Stokes shift
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Fluorescence
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Fluorescein
Jablonski diagram
S0
S1
S2
ground state
excited state
Radiation - fluorescence
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Fluorescence
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-George Biddell Airy (1801-1892)

-Best focused point source of light won’t appear as a point, but as a spot
surrounded by series of concentric bright rings – Airy pattern.
-Size of Airy disc depend on the light wavelength and the size of aperture.
Imaging
Device
(circular aperture)
Airy disc (d)
https://upload.wikimedia.org/wikipedia/commons/thumb/2/21/George_Biddell_Airy2.jpg/220px-George_Bid
dell_Airy2.jpg
- Airy disc contain ~84% of the light from the point source
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Airy disc
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-Three dimensional diffraction pattern of light emitted from an infinitely small point source
     in the specimen and transmitted to image plane
object
Point Spread Function (PSF)
Image
convolution
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Point spread function
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-Three dimensional diffraction pattern of light emitted from an infinitely small point source
     in the specimen and transmitted to image plane
object
Point Spread Function (PSF)
Image
deconvolution
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Deconvolution
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convolution

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https://upload.wikimedia.org/wikipedia/commons/thumb/f/f6/Diversity_of_fluorescent_patterns_and_col
ors_in_marine_fishes_-_journal.pone.0083259.g001.png/800px-Diversity_of_fluorescent_patterns_and_co
lors_in_marine_fishes_-_journal.pone.0083259.g001.png
https://en.wikipedia.org/wiki/Fluorescence
https://stephenslab.files.wordpress.com/2012/12/aequorea-spectra.jpg
Fluorescent proteins in living organisms
Roger Y. Tsien
Roger
Tsien
Nobel prize in chemistry 2008
Discovery and development
of the green fluorescent protein
GFP
Martin Chalfie Osamu Shimomura
Martin
Chalfie
Osamu
Shinomura
Aequorea victoria
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generated
Fluorescence
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Excitation light
Emission spectrum
Sample
Excitation
filter
Emission
filter
Dichromatic
mirror
Detector
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Components of fluorescent microscope
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Adobe Systems Související obrázek Výsledek obrázku pro chroma filters
Single bandpass (limitations min and max)
Longpass filter
Shortpass filter
Multi bandpass filter
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Filters and beam splitters
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Crosstalk/bleed through
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Filters and beam splitters
Light microscopy methods in biology
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Mercury short arc lamp:
Obsolete, short life time – 200 hours, toxic wapors
Manual alignmnent
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Light sources
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Metal halide lamp:
Longer life time – 2000 hours
No alignment, contains also mercury
http://zeiss-campus.magnet.fsu.edu/articles/lightsources/images/metalhalidelampsfigure1.jpg OSRAM
HXP 120W/45 CVIS A close up of a logo Description automatically generated
Light sources
Light microscopy methods in biology
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Xenon lamp
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Light sources
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LED – light emmiting diodes
Single wavelength, or combination of several LED‘s
Instantly switching ON/OFF
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Light sources
Light microscopy methods in biology
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Widefield microscopes – CCD or sCMOS sensors
Pixel number, pixel size, bit depth, quantum efficiency, spectral response
photons
electrons
photodiode
Photoactive part
(photodiode)
Isolated interline device
(charge transfer)
- Smallest unit of sensor with defined size (x,y dimensions)
- Sensor consists of many pixels
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Detectors
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Binning and resolution
-Several neighborhoods pixels are accumulated together and readed as one unit
-Increasing sensitivity, decreasing resolution, decreasing size of image
Binning 1 – full resolution
Resolution = 12 x 12 pixels
Pixel size = 6 x 6 μm
Binning 2
Resolution = 6 x 6 pixels
Pixel size = 12 x 12 μm
Binning 4
Resolution = 3 x 3 pixels
Pixel size = 24 x 24 μm
Pixels
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Detectors
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Spectral response and quantum efficiency
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Detectors
Light microscopy methods in biology
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Analog to digital converter (ADC) – convert analog signal (current in Voltage) to discrete
digital values - number of grey values.
Number of bits
1
2
4
8
12
14
16
Number of grey values
2
4
16
256
4,096
16,384
65,536
Bit depth
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Detectors
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Correct exposure – read histogram
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Exposure
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1 sec
2 sec
4 sec
8 sec
Saturation - blooming
Correct exposure – read histogram
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Exposure
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-Important to know resolution of the system, avoid oversampling and undersampling
-Pixel size should be 2-3 x smaller than the actual resolution of the system
Objectiv: Zeiss Plan-Apochromat 100x/1.4
Optovar:1.6x
C-mount: 1x
Camera: Hamamatsu Flash 4.0
https://upload.wikimedia.org/wikipedia/commons/thumb/4/46/Ernst-Abbe-Denkmal_Jena_F%C3%BCrstengrabe
n_-_20140802_125709.jpg/170px-Ernst-Abbe-Denkmal_Jena_F%C3%BCrstengraben_-_20140802_125709.jpg
Resolution (GFP) = 0.51 * 550/1.4 = 200 nm
Camera pixel size = 6.5 x 6.5 μm
Magnification = 100 x 1.6 x 1 = 160
Oversampled: Max. resolution = 200 nm, image pixel = 40 nm
Nyquist requirement = 2.3 times the resolution = 85 nm
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Digital sampling
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-Important! Acts as external part of the objective
-
-Standard thickness is 0.17 mm (170 mm) == grade 1.5, best 1.5H (high precision 170 mm ± 0.05 mm)
-
-Variability should not exceed ±0.1 for objective with high NA
-
-Some objectives have correction collar to adjust for different thickness of cover slip
Grade Number
Thickness (mm)
0
83-130
1
130-160
1.5
160-190
2
190-250
Refraction index should be close to refraction index of glass == 1.5168
Home made – Mowiol solution
Commercial solutions – VectaShield, Prolong glass
Mounting media
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Coverslips
Light microscopy methods in biology
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Thank you for your attention
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Lecture 2: October 14, 2021 at 9:00
Confocal microscopy - principles, types of confocal microscopes – scanning, spinning disc, channel
vs spectral imaging, linear unmixing.
Lasers, detectors, beam splitters, optical sections. Lightsheet microscopy.