Biology:Three photon microscopy

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Three-photon microscopy (3PEF) is a high-resolution fluorescence microscopy based on nonlinear excitation effect.[1][2][3] Different from two photon excitation microscopy, it uses three exciting photons. It typically uses 1300 nm or longer wavelength lasers to excite the fluorescent dyes with three simultaneously absorbed photons. The fluorescent dyes then emit one photon whose energy is (slightly smaller than) three times the energy of each incident photon. Compared to two-photon microscopy, three-photon microscopy reduces the fluorescence away from the focal plane by [math]\displaystyle{ 1/z^4 }[/math], which is much faster than that of two-photon microscopy by [math]\displaystyle{ 1/z^2 }[/math].[4] In addition, three-photon microscopy employs near-infrared light with less tissue scattering effect. This causes three photon microscopy to have higher resolution than conventional microscopy.

Concept

Three-photon excited fluorescence was first observed by Singh and Bradley in 1964 when they estimated the three-photon absorption cross section of naphthalene crystals.[5] In 1996, Stefan W. Hell designed experiments to validate the feasibility of applying three-photon excitation to scanning fluorescence microscopy, which further proved the concept of three-photon excited fluorescence.[6]

Three-photon microscopy shares a few similarities with Two-photon excitation microscopy. Both of them employ the point scanning method. Both are able to image 3D samples by adjusting the position of the focus lens along the axial and lateral directions. The structures of both systems do not require a pinhole to block out-focus light. However, three-photon microscopy differs from Two-photon excitation microscopy in their Point spread function, resolution, penetration depth, resistance to out-of-focus light and strength of photobleaching.

In three-photon excitation, the fluorophore absorbs three photons almost simultaneously. The wavelength of the excitation laser is about 1200 nm or more in three photon microscopy with the emission wavelength slightly longer than one-third of the excitation wavelength. Three photon microscopy has deeper tissue penetration because of the longer excitation wavelengths and the higher order nonlinear excitation. However, a three-photon microscope needs a laser with higher power due to relatively smaller cross-section of the dyes for three-photon excitation, which is on the order of [math]\displaystyle{ 10^{-82}\text{cm}^6(s/\text{photon})^2 }[/math]. This is much smaller than the typical two-photon excitation cross-sections of [math]\displaystyle{ 10^{-49}\text{cm}^4s/\text{photon} }[/math].[7] The Ultrashort pulses are usually around 100 fs.

Resolution

For three photon fluorescence scanning microscopy, the three dimensional intensity point-spread function(IPSF) can be denoted as,

[math]\displaystyle{ h_i(\nu,u) = \left|I_1(\nu/3,u/3)\right|^3I_2(\nu,u) \otimes_3 D }[/math],[8]

where [math]\displaystyle{ \otimes_3 }[/math]denotes the 3-D convolution operation, [math]\displaystyle{ D }[/math] denotes the intensity sensitivity of an incoherent detector, and [math]\displaystyle{ I_1(\nu,u) }[/math], [math]\displaystyle{ I_2(\nu,u) }[/math] denotes the 3-D IPSF for the objective lens and collector lens in single-photon fluorescence, respectively. The 3-D IPSF [math]\displaystyle{ I_1(\nu,u) }[/math] can be expressed in

[math]\displaystyle{ I_1(\nu,u) = \left|\int_{0}^{1}2J_0(\nu\rho)\exp(iu/2)\rho d\rho\right|^2 }[/math],[8]

where [math]\displaystyle{ J_0 }[/math] is a Bessel function of the first kind of order zero. The axial and radial coordinates [math]\displaystyle{ u }[/math] and [math]\displaystyle{ \nu }[/math] are defined by

[math]\displaystyle{ u = (8\pi/\lambda_f)z \sin^2(\alpha_0/2) }[/math]and
[math]\displaystyle{ \nu = (2\pi/\lambda_f)r\ \sin\ \alpha_0 }[/math],[8]

where [math]\displaystyle{ \alpha_0 }[/math]is the numerical aperture of the objective lens, [math]\displaystyle{ z }[/math] is the real defocus, and [math]\displaystyle{ r }[/math] is the radial coordinates.

Coupling with other multiphoton techniques

Correlative images can be obtained using different multiphoton schemes such as 2PEF, 3PEF, and Third harmonic generation (THG), in parallel (since the corresponding wavelengths are different, they can be easily separated onto different detectors). A multichannel image is then constructed.[9]

3PEF is also compared to 2PEF: it generally gives a smaller degradation of the signal-to-background ratio (SBR) with depth, even if the emitted signal is smaller than with 2PEF.[9]

Development

After three-photon excited fluorescence was observed by Singh and Bradley and further validated by Hell, Chris Xu reported measurement of excitation cross sections of several native chromophores and biological indicators, and implemented three-photon excited fluorescence in Laser Scanning Microscopy of living cells.[10] In November 1996, David Wokosin applied three photon excitation fluorescence for fixed in vivo biological specimen imaging.

In 2010s, three photon microscopy was applied for deep tissue imaging using excitation wavelengths beyond 1060 nm. In January 2013, Horton, Wang and Kobat invented in vivo deep imaging of an intact mouse brain by employing point scanning method to three photon microscope at the long wavelength window of 1700 nm.[4] In February 2017, Dimitre Ouzounov and Tainyu Wang demonstrated deep activity imaging of GCaMP6-labeled neurons in the hippocampus of an intact, adult mouse brain using three-photon microscopy at the 1300 nm wavelength window.[11] In May 2017, Rowlands applied wide-field three-photon excitation to three photon microscope for larger penetration depth.[12] In Oct 2018, T Wang, D Ouzounov, and C Xu were able to image vasculature and GCaMP6 calcium activity using three photon microscope through the intact mouse skull.[13]

Applications

Three-photon microscopy has similar application fields with two-photon excitation microscopy including neuroscience,[14] and oncology.[15] However, compared to standard single-photon or two-photon excitation, three-photon excitation has several benefits such as the use of longer wavelengths reduces the effects of light scattering and increasing the penetration depth of the illumination beam into the sample.[16] The nonlinear nature of three photon microscopy confines the excitation target to a smaller volume, reducing out-of-focus light as well as minimizing photobleaching on the biological sample.[16] These advantages of three-photon microscopy gives it an edge in visualize in vivo and ex vivo tissue morphology and physiology at a cellular level deep within scattering tissue [4] and Rapid volumetric imaging.[17] In the recent study, Xu has demonstrated the potential of three-photon imaging for noninvasive studies of live biological systems.[13] The paper used three-photon fluorescence microscopy at a spectral excitation window of 1,320 nm to imaging the mouse brain structure and function through the intact skull with high spatial and temporal resolution(The lateral and axial FWHM was 0.96μm and 4.6μm) and large FOVs(hundreds of micrometers), and at substantial depth(>500 μm). This work demonstrates the advantage of higher-order nonlinear excitation for imaging through a highly scattering layer, in addition to the previously reported advantage of 3PM for deep imaging of densely labeled samples.

See also

References

  1. Horton, Nicholas G.; Wang, Ke; Kobat, Demirhan; Clark, Catharine G.; Wise, Frank W.; Schaffer, Chris B.; Xu, Chris (2013-03-01). "In vivo three-photon microscopy of subcortical structures within an intact mouse brain". Nature Photonics 7 (3): 205–209. doi:10.1038/nphoton.2012.336. PMID 24353743. Bibcode2013NaPho...7..205H. 
  2. Chen, Bingying; Huang, Xiaoshuai; Gou, Dongzhou; Zeng, Jianzhi; Chen, Guoqing; Pang, Meijun; Hu, Yanhui; Zhao, Zhe et al. (2018-03-29). "Rapid volumetric imaging with Bessel-Beam three-photon microscopy" (in en). Biomedical Optics Express 9 (4): 1992–2000. doi:10.1364/BOE.9.001992. PMID 29675334. 
  3. Williams, Rebecca M.; Shear, Jason B.; Zipfel, Warren R.; Maiti, Sudipta; Webb, Watt W. (1999-04-01). "Mucosal Mast Cell Secretion Processes Imaged Using Three-Photon Microscopy of 5-Hydroxytryptamine Autofluorescence" (in en). Biophysical Journal 76 (4): 1835–1846. doi:10.1016/S0006-3495(99)77343-1. PMID 10096882. Bibcode1999BpJ....76.1835W. 
  4. 4.0 4.1 4.2 Horton, Nicholas; Wang, Ke; Kobat, Demirhan; Clark, Catharine; Wise, Frank; Schaffer, Chris; Xu, Chris (20 Jan 2013). "In vivo three-photon microscopy of subcortical structures within an intact mouse brain". Nature Photonics 7 (3): 205–209. doi:10.1038/nphoton.2012.336. PMID 24353743. Bibcode2013NaPho...7..205H. 
  5. Singh, S.; Bradley, L. T. (1 Jun 1964). "Three-Photon Absorption in Napthalene Crystals by Laser Excitation". Physical Review Letters 12 (22): 612–614. doi:10.1103/PhysRevLett.12.612. Bibcode1964PhRvL..12..612S. 
  6. Hell, S W; Bahlmann, K; Schrader, M; Soini, A; Malak, H M; Gryczynski, I; Lakowicz, J R (1 Jan 1996). "Three-photon excitation in fluorescence microscopy". Journal of Biomedical Optics 1 (1): 71–74. doi:10.1117/12.229062. PMID 23014645. Bibcode1996JBO.....1...71H. 
  7. Toda, Keisuke; Isobe, Keisuke; Namiki, Kana; Kawano, Hiroyuki; Miyawaki, Atsushi; Midorikawa, Katsumi (June 2017). "Temporal focusing microscopy using three-photon excitation fluorescence with a 92-fs Yb-fiber chirped pulse amplifier". Biomedical Optics Express 8 (6): 2796–2806. doi:10.1364/BOE.8.002796. PMID 28663907. 
  8. 8.0 8.1 8.2 Gu, Min (1 Jul 1996). "Resolution in three-photon fluorescence scanning microscopy". Optics Letters 21 (13): 988–990. doi:10.1364/OL.21.000988. PMID 19876227. Bibcode1996OptL...21..988G. 
  9. 9.0 9.1 Guesmi, Khmaies; Abdeladim, Lamiae; Tozer, Samuel; Mahou, Pierre; Kumamoto, Takuma; Jurkus, Karolis; Rigaud, Philippe; Loulier, Karine et al. (2018). "Dual-color deep-tissue three-photon microscopy with a multiband infrared laser". Light: Science & Applications 7 (1): 12. doi:10.1038/s41377-018-0012-2. ISSN 2047-7538. PMID 30839589. Bibcode2018LSA.....7...12G. open access
  10. Xu, C; Zipfel, W; Shear, J B; Williams, R M; Webb, W W (1 Oct 1996). "Multiphoton fluorescence excitation: new spectral windows for biological nonlinear microscopy.". Proc Natl Acad Sci U S A 93 (20): 10763–10768. doi:10.1073/pnas.93.20.10763. PMID 8855254. Bibcode1996PNAS...9310763X. 
  11. Ouzounov, Dimitre; Wang, Tianyu; Wang, Mengran; Feng, Danielle; Horton, Nicholas; Cruz-Hernández, Jean; Cheng, Yuting; Reimer, Jacob et al. (20 February 2017). "In vivo three-photon imaging of activity of GCaMP6-labeled neurons deep in intact mouse brain". Nature Methods 14 (4): 388–390. doi:10.1038/nmeth.4183. PMID 28218900. 
  12. Rowlands, Christopher; Park, Demian; Bruns, Oliver; Piatkevich, Kiryl; Fukumura, Dai; Jain, Rakesh; Bawendi, Moungi; Boyden, Edward et al. (5 May 2017). "Wide-field three-photon excitation in biological samples". Light: Science & Applications 6 (5): e16255. doi:10.1038/lsa.2016.255. ProQuest 1917694404. PMID 29152380. Bibcode2017LSA.....6E6255R. 
  13. 13.0 13.1 Wang, Tianyu; Ouzounov, Dimitre; Wu, Chunyan; Horton, Nicholas; Zhang, Bin; Wu, Cheng-Hsun; Zhang, Yanping; Schnitzer, Mark et al. (10 Sep 2018). "Three-photon imaging of mouse brain structure and function through the intact skull". Nature Methods 15 (10): 789–792. doi:10.1038/s41592-018-0115-y. PMID 30202059. 
  14. Kerr, Jason; Denk, Winfried (Mar 2008). "Imaging in vivo: watching the brain in action". Nature Reviews Neuroscience 9 (3): 195–205. doi:10.1038/nrn2338. PMID 18270513. 
  15. Williams, Rebecca M.; Flesken-Nikitin, Andrea; Ellenson, Lora Hedrick; Connolly, Denise C.; Hamilton, Thomas C.; Nikitin, Alexander Yu.; Zipfel, Warren R. (Jun 2010). "Strategies for High Resolution Imaging of Epithelial Ovarian Cancer by Laparoscopic Nonlinear Microscopy". Translational Oncology 3 (3): 181–194. doi:10.1593/tlo.09310. PMID 20563260. 
  16. 16.0 16.1 Escobet-Montalbán, Adrià; Gasparoli, Federico M.; Nylk, Jonathan; Liu, Pengfei; Yang, Zhengyi; Dholakia, Kishan (Oct 2018). "Three-photon light-sheet fluorescence microscopy". Optics Letters 43 (21): 5484–5487. doi:10.1364/ol.43.005484. PMID 30383037. Bibcode2018OptL...43.5484E. 
  17. Chen, Bingying; Huang, Xiaoshuai; Gou, Dongzhou; Zeng, Jianzhi; Chen, Guoqing; Pang, Meijun; Hu, Yanhui; Zhao, Zhe et al. (Apr 2018). "Rapid volumetric imaging with Bessel-Beam three-photon microscopy". Biomedical Optics Express 9 (4): 1992–2000. doi:10.1364/boe.9.001992. PMID 29675334.