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Confocal & Two-photon Microscopy. Contents 1.Two-Photon Microscopy : Basic principles and Architectures 2. Resolution and Contrast in Confocal and Two-Photon.

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Presentation on theme: "Confocal & Two-photon Microscopy. Contents 1.Two-Photon Microscopy : Basic principles and Architectures 2. Resolution and Contrast in Confocal and Two-Photon."— Presentation transcript:

1 Confocal & Two-photon Microscopy

2 Contents 1.Two-Photon Microscopy : Basic principles and Architectures 2. Resolution and Contrast in Confocal and Two-Photon microscopy 3. Example of two-photon images 4. Extensive application : Fluorescence Correlation Microscopy, Life-time imaging

3 Figure 2, Relevant time scale. 1. Two-Photon Microscopy (vs One-photon) Figure 1. Jablonski diagram

4 Nonlinear optical excitation, I 2p  P 2 1. Two-Photon Microscopy (vs One-photon) Figure 3. Quadratic dependence.

5  3D localized uncaging and photobleaching in subfemto-liter volume 1. Two-Photon Microscopy (vs One-photon) Figure 4. Excitation region in one & two-photon microscopy Z-axis

6 1. Two-Photon Microscopy (vs One-photon) Figure 3. Photobleaching in one & two-photon microscopy

7 1. Two-Photon Microscopy (vs One-photon) One-photon Two-photon Figure 5. Z-direction scanning spectra in One & Two-photon microscopy

8 Quantum Theory of Two-photon excitation P ~ <f  E r  r  m><m  E r  r i>i>   r -  mi 2  m * Multi-Photon transition probability (P) 1. Two-Photon Microscopy (vs One-photon)

9 Two-Photon transition Probability * Time-averaged two-photon fluorescence intensity per molecule  1. Two-Photon Microscopy (vs One-photon)

10 a. Continuous Wave Laser where b. Pulsed Laser where 0 < t <  for 1  < t < fpfp for 1. Two-Photon Microscopy (vs One-photon)

11 Architecture of Two-Photon microscopy 1. Two-Photon Microscopy (vs One-photon) Safety Box Beamrouting Supplement Mira Mira-900 DMIR Verdi

12 1. Two-Photon Microscopy (vs One-photon) Leica confocal systems : TCS SP2 2. Two-photon confocal microscopy combined with femtosecond laser  Thickness, depth and more precise images measurement by 3D sectioning 1. The spectral detector for brilliant confocal 2D, 3D images by emitted fluorescence

13 : Femtosecond Ti-Sapphire system with 80MHz, 100fs  delivering peak powers of over 100kW !!  wide tuning range, 700~1000nm !!  At the entrance of scanning head, ~20mW Before the objective lens, 9~13mW At the sample, 3~5mW  Picosecond, CW (required higher average power !!) Light source 1. Two-Photon Microscopy (vs One-photon)  Mira 900 : 76MHz, 180fs, 400~500mW,

14 1. Two-Photon Microscopy (vs One-photon) Advantages of Two-photon Deep-specimen imaging a.Lower absorption & scattering coefficient due to IR : Deeper penetration effect ! b. Excitation only in a subfemtoliter-sized focal volume : It reduce photodamage !

15 The resolution, defined as the minimum separation of two Point objects that provides a certain contrast between them, depends on The wavelength of the light ! Numerical Aperture of the optical arrangement ! Specimen ! 2. Resolution and Contrast (confocal vs two-photon)

16 Three-dimensional distribution of light near the focus of lens  Point Spread Function Where, The intensity PSF ( related to its FWHM), 2. Resolution and Contrast (confocal vs two-photon)

17 * Confocal system Pointwise-illumination Pointwise-detection Cf) Cf) Uniform detector 2. Resolution and Contrast (confocal vs two-photon)

18 Table1, FWHM 2. Resolution and Contrast (confocal vs two-photon) Figure 3. Calculated Point Spread Function FWHM extent (  m) Illumination (ill) Detection (det) LateralAxialPSF Confocal=ill  det Two-photon=(ill) 2 2p-confocal=(ill) 2 xdet 0.20 0.84 0.190.78 0.140.57 0.23 0.16 0.93 0.63

19 * Lateral Resolution 2. Resolution and Contrast (confocal vs two-photon) * Axial Resolution

20 Depth discrimination ! 2. Resolution and Contrast (confocal vs two-photon)

21 3. Examples 1 4 352 OP Top Bottom TP Z-scanning range : ~28  m (5 sections, 7.0417  m step)

22 3. Examples : Neuron cell imaging Lysosome (DND-189) Nucleus (Propidium iodide)

23 3. Examples : Neuron cell imaging

24 Side-view3D-reconstruction 50  m

25 4. Application : Fluorescence Correlation Microscopy Where  F(t)=F(t)- D ~ r 0 2 / 4  D

26 4. Application : Life-time two-photon imaging

27 Steady state intensity image Time resolved intensity image Autofluorescence of human skin : 2-photon image Ca image of Cortex neutron : 2-photon image

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