ECSE6963 Introduction to Subsurface Sensing and Imaging Systems - PowerPoint PPT Presentation

1 / 26

About This Presentation

Title:

ECSE6963 Introduction to Subsurface Sensing and Imaging Systems

Description:

ECSE6963 Introduction to Subsurface Sensing and Imaging Systems – PowerPoint PPT presentation

Number of Views:31

Avg rating:3.0/5.0

Slides: 27

Provided by: badrinat

Category:

more less

Transcript and Presenter's Notes

Title: ECSE6963 Introduction to Subsurface Sensing and Imaging Systems

1
ECSE-6963Introduction to Subsurface Sensing and
Imaging Systems

Lecture 17 Spectral Imaging Fluorescence
Kai Thomenius1 Badri Roysam2
1Chief Technologist, Imaging technologies,
General Electric Global Technology Center
2Professor, Rensselaer Polytechnic Institute

Center for Sub-Surface Imaging Sensing
2
Recap

Use of Phase in Imaging
Doppler ultrasound
Phase-contrast optical imaging
Differential interference contrast
Spectral imaging
Fluorescence and contrast agents

3
Recap EM Interaction with Matter
4
Recap Fluorescence Imaging
Courtesy William Shain Lab
5
Light Absorption
Absorption can only occur when
If the energy of the probing photon is mismatched
to the energy difference between the quantum
states, the material is transparent to the probe.
6
Emission Fluorescence

Opposite of absorption
Can be coherent (Raman)/incoherent (Fluorescence)
Typically, there is some loss in the molecule, so
the emitted energy is lower than the absorbed
energy
The difference is the Stokes Shift

Molar Concentration of fluorophore
Excitation intensity
Path length
Fluorescence intensity
Quantum Efficiency ( molecules that emit)
Molar absorptivity
7
Multi-photon Excitation

Use 2 or more infrared photons to excite
fluorophores ordinarily excitable with higher
frequencies
Much more detail in images collected deeper in
the sample.
No sample photobleaching outside focal plane.
Dramatic improvement in longevity of living
cells, tissues and organisms.
Ready determination of co-localising fluorescent
probes.
No need for confocal apertures.
Ability to image autofluorescence
UV flourophores may be excited using a lens that
is not corrected for UV as these wavelengths
never have to pass through the lens.
MPE also offers enhanced photoselection in
spectroscopy.

3-photon works the same way
8
Multi-photon Microscopy

Practical issues
The two photons need to arrive simultaneously a
low probability event
Use ultrafast, mode-locked near-infrared lasers
(i.e. Tisapphire 100-200 femtosecond pulse
duration, 76MHz repetition rate).
Under the appropriate conditions, these lasers
produce short duration pulses with the high peak
power required for a multi-photon effect and an
average power low enough to make specimen damage
negligible.
Such lasers are tunable over a range of
700nm-1000nm which permits optimal wavelength
selection to elicit an efficient multi-photon
effect.
Probability of simultaneous absorption falls off
steeply away from the focal volume

9
Skin Tumor Example
10
Observing Changes Over Time
Successive images are 24 hours apart
11
Limitations of Multi-photon

Slightly lower resolution with a given
fluorophore when compared to confocal imaging.
This loss in resolution can be eliminated by the
use of a confocal aperture at the expense of a
loss in signal.
Thermal damage can occur in a specimen if it
contains chromophores that absorb the excitation
wavelengths, such as the pigment melanin.
Only works with fluorescence imaging.
Currently rather expensive.

12
Second-harmonic Generation

Similar to 2-photon, but essentially lossless
Great for live imaging
E.g., collagen
Great for
Deep-tissue imaging
quantification along the frequency axis!

Virtual state
13
SHG Example
Extra-cellular matrix
Muscle filament lattice structure
Extra-cellular and intracellular structures
within native muscle tissue
An optical section at a depth of 250 µm into the
sample
http//www.biophysj.org/cgi/content/full/82/1/493
14
Improving Light Microscopy

Its Not Just About Resolution
Resolution Limited by Diffraction
Its About What Is Measured
Transmission, Reflection, Phase, Fluorescence,
Polarization, Non-Linear Properties
Minimizing specimen damage
And About How Data Are Processed
Registration, Deconvolution, Tomography,
Parameter Estimation
And About Measuring Everything at Once

15
What is Sensed by the Different Modes?
LSCM
SHG
Epi F
DIC
TPLSM
QTM
Staring
Scanning
Phase (optical path length)
16
What can be measured
Morphological Dynamics

Sensor Fusion
Different sensors have different strengths and
weaknesses
Combine them to take advantage of each

Space (x, y, z)
Time (t)
Structure
Dynamics
Function
Signaling Paths, Molecular Transport
Chemical Dynamics
Fluorescent labels
Other Physical Properties
e.g., Refractive index, strain
17
(Phase Fluorescence) Example
Data courtesy Gary Banker (U. Oregon)
18
Staring Modes Similar Embryos, Diverse Images
Thanks to Bill Warger
19
Multi-Modal Imaging of Mouse Embryos
2-photon
Confocal Fluorescence
Differential Interference Contrast
Quadrature Microscopy
20
Multi-Modal Imaging of Mouse Kidney Cells Using
a 3D Fusion Microscope
2-photon DAPI
2-photon Alexa Fluor 488
QTM
DIC
Thanks to Dan Townsend
21
Accessing Wider Regions
22
Current State of the Art

Fusion Microscopy Put Multiple modalities on
same platform

23
Current Trends

Ever increasing numbers of structural and
functional endpoints can be observed
simultaneously in 3-D
Growing libraries of organic fluorophores
quantum dots
Multi- and hyper-spectral microscopes
Spectral unmixing tools
Support for complex fluorescence phenomena
Easier to work with live cells
Sensitive, high-resolution, 3-D imaging
Minimally-damaging (MP, SHG), time-resolved
imaging
Better instrumentation better understanding of
biology
Fusion of multiple microscopy modalities
High-extent high-resolution high-throughput
imaging
High-throughput tissue prep imaging hardware