2. Content
Introduction
Basics of Fluorescence
Epi-Fluorescent Microscope
Working
Applications in Biology
Advantages and Limitations
References
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3. Introduction
Generation of luminescence through excitation of
a molecule by ultraviolet or visible light photons is
a phenomenon termed photoluminescence,
which is formally divided into two categories,
fluorescence and phosphorescence
Fluorescence is the property of atoms and
molecules, so called fluorophores, to absorb light
at a particular wavelength and to subsequently
emit light of longer wavelength.
However, Phosphorescence occurs in a manner
similar to fluorescence, but with a much longer
excited state lifetime Figure 1: Aequorea Victoria aka Crystal Jelly [1]
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4. Stokes Shift
British Scientist Sir George G. Stokes who
first described fluorescence in 1852 and
was responsible for coining the term in
honour of the blue-white fluorescent
mineral fluorite (fluorspar)
He discovered the wavelength shift to
longer values in emission spectra that is
known as the Stokes Shift.
However, Plank’s Equation was derived in
1990.
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Figure 2: Fluorophore Absorption and Emission Profiles [2]
6. Parameters
Three fundamental parameters commonly used in describing and comparing
fluorophores are as follows:
Molar Extinction Coefficient (ε): a measure of how strongly a chemical species or
substance absorbs light at a particular wavelength.
Quantum Yield (Φ): the percentage of photons emitted versus the number
absorbed
Fluorescence lifetime (τ): the amount of time that a fluorophore spends in the
excited state without emitting a photon
Where the reference wavelength is usually the wavelength of maximum
absorption in the ultraviolet or visible portions of the light spectrum
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7. Glimpse of Fluorescence Microscope
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Figure 4: Epi-Fluorescent Microscope and some output images [3]
8. Filters
Fluorophores that can absorb a quantity of illumination,
the percentage that will emit secondary fluorescence is
even lower.
The fundamental problem in fluorescence microscopy is
to produce high-efficiency illumination of the specimen,
while simultaneously capturing weak fluorescence
emission that is effectively separated from the much
more intense illumination band.
These conditions are satisfied in modern fluorescence
instruments by a combination of filters that coordinate
excitation and emission requirements.
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Figure 5: Filters characteristics [2]
9. Dichromatic Mirror
It is positioned at 450
angle to both the incident illumination
arriving from the light source, as well as the optical axis of the
microscope
Light from the source passes through the defined bandpass
excitation filter, and is then reflected down into the objective
by the DM to be focused at the specimen plane
Fluorescence emission is captured by the objective and
directed back through the DM, which in turn reflects most of
the contaminating excitation light back toward the light source
Emission wavelengths passing through the DM are further
purified by the emission filter, before traveling to the eyepieces
or the camera image plane
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Figure 6: Dichromatic Mirror[2]
10. Filter and Dichromatic Mirror Characteristics
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Figure 7: Filter and Dichromatic Mirror Characteristics [2]
11. Epi-Fluorescent Microscope
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Figure 8: Epi-Fluorescent Microscope [3]
• Most fluorescence microscopes in
use are Epi-Fluorescence
microscopes, where excitation of
the fluorophore and detection of
the fluorescence are done
through the same light path (i.e.
through the objective).
• These microscopes are widely
used in biology and are the basis
for more advanced microscope
designs
12. Applications of Fluorescence Microscopy
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Figure 9: Application of Fluorescence Microscopy in 1985 [4]
13. Applications of Fluorescence Microscopy
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Figure 10: Application of Fluorescence Microscopy in 2023 [5]
14. Fluorescence Microscopy
ADVANTAGES
Live Cell Imaging
High contrast imaging and High specificity
Quantitative imaging
DISADVANTAGES
Photobleaching
Phototoxicity
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15. References
1. https://en.wikipedia.org/wiki/Aequorea_Victoria
2. https://zeiss-campus.magnet.fsu.edu/articles/basics/fluorescence.html
3. https://www.zeiss.com/microscopy/en/products/light-microscopes/widefield-microscopes/axioscope-5.html
4. Detection, Enumeration, and Sizing of Planktonic Bacteria by Image-Analyzed Epifluorescence Microscopy, MICHAEL E.
et.al., APPLIED AND ENVIRONMENTAL MICROBIOLOGY, Apr. 1985, p. 799-810
5. Pre-hyperglycemia immune cell trafficking underlies subclinical diabetic cataractogenesis, Ranaei Pirmardan et al. Journal of
Biomedical Science (2023) 30:6, https://doi.org/10.1186/s12929-023-00895-6.
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Excitation of a susceptible molecule by an incoming photon happens in femtoseconds (1015 seconds), while vibrational relaxation of excited state electrons to the lowest energy level is much slower and can be measured in picoseconds (1012 seconds). The final process, emission of a longer wavelength photon and return of the molecule to the ground state, occurs in the relatively long time period of nanoseconds (109 seconds).
A = εLc, Fluorescein and quinine are good examples of fluorophores
Our results establish a novel role for immune cells in LEC transformation and death. The fact that
cataract formation precedes hyperglycemia challenges the prevailing paradigm that glucose initiates or is necessary
for initiation of the pathogenesis. Novel evidence shows that molecular and cellular complications of diabetes start
during the prediabetic state. These results have foreseeable ramifcations for early diagnosis, prevention and develop‑
ment of new treatment strategies in patients with diabetes