Two-Photon Microscopy of Cells and Tissue

Rubart, Michael

doi:10.1161/01.res.0000150593.30324.42

Cited by 283 publications

(224 citation statements)

References 80 publications

(131 reference statements)

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“…A high sensitivity of Di-4-ANEPPS to changes in V m was confirmed in the present study, whereas Fura-2 has a dissociation constant to free Ca 2+ of 224nM in the presence of 1mM Mg 2+ [16], which is close to diastolic intracellular [Ca 2+ ] in cardiomyocytes (150-300nM) [1]. This makes Di-4-ANEPPS and Fura-2/AM amenable to prolonged experiments in cardiac preparations, which coupled with the minimally invasive nature of 2P excitation [10][11][12] precedes other available techniques.…”

Section: Strengthssupporting

confidence: 73%

“…As such, laser power may be increased as focal depth is increased in order to maintain signal, as out-of-focus signal does not interfere [10,11]. Thus, deep imaging of multi-cellular preparations with high spatial resolution optical sectioning including along the Z-axis is achieved without the need for a F o r P e e r R e v i e w 4 detector pinhole (which is required in 1P excitation confocal microscopy to eliminate out-of-focus fluorescence emission), which further increases the fluorescence collection efficiency [11,12]. This, coupled with the availability of voltage-and Ca 2+ -sensitive dyes that fluoresce after 2P excitation [13,14] allowed us to develop protocols for high-resolution deep imaging of AP and intracellular Ca 2+ characteristics of in situ cardiomyocytes in intact, perfused whole hearts.…”

Section: Introductionmentioning

confidence: 99%

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2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca²⁺ in intact mice, rat, and rabbit hearts

Ghouri

Kelly

Burton³

et al. 2013

Journal of Biophotonics

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We describe a novel two-photon (2P) laser scanning microscopy (2PLSM) protocol that provides ratiometric transmural measurements of membrane voltage (V m ) via Di-4-ANEPPS in intact mouse, rat and rabbit hearts with subcellular resolution. The same cells were then imaged with Fura-2/AM for intracellular Ca 2+ recordings. Action potentials (APs) were accurately characterized by 2PLSM vs microelectrodes, albeit fast events (<1ms) were sub-optimally acquired by 2PLSM due to limited sampling frequencies (2.6kHz). The slower Ca 2+ transient (CaT) time course (>1ms) could be accurately described by 2PLSM. In conclusion, V m -and Ca 2+ -sensitive dyes can be 2P excited within the cardiac muscle wall to provide AP and Ca 2+ signals to ~400μm.Abstract Figure: 2P-excited images of Di-4-ANEPPS-and Fura-2/AM-loaded myocardium including the resultant AP and CaT extracted from the presented protocols.

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Section: Strengthssupporting

confidence: 73%

Section: Introductionmentioning

confidence: 99%

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca²⁺ in intact mice, rat, and rabbit hearts

Ghouri

Kelly

Burton³

et al. 2013

Journal of Biophotonics

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“…When the fluorescence techniques are applied on the level of tissues or whole organisms, strong limitations appear due to low penetration of light in these media because of high absorbance and light-scattering. Presently in this case the 'labeling' technology has definite advantages, since it allows free selection of fluorescence reporters including the dyes excited in the near-IR range 800-1,000 nm (the wavelength range of maximal transparency of living tissues) (Ntziachristos et al 2004;Smith et al 2011b), the fluorescent nanoparticles exhibiting upconversion phenomenon (Nagarajan and Zhang 2011) or applying two-photon excitation (Rubart 2004). In the case of deeply located cells and dense tissues the probing with radioactive or MRI contrast agents (Blankenberg and Norfray 2011) or smart nanoparticles that combine MRI and fluorescence responses (van Tilborg et al 2006) was suggested.…”

Section: Conclusion and Prospectsmentioning

confidence: 99%

Beyond annexin V: fluorescence response of cellular membranes to apoptosis

2012

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Dramatic changes in the structure of cell membranes on apoptosis allow easy, sensitive and non-destructive analysis of this process with the application of fluorescence methods. The strong plasma membrane asymmetry is present in living cells, and its loss on apoptosis is commonly detected with the probes interacting strongly and specifically with phosphatidylserine (PS). This phospholipid becomes exposed to the cell surface, and the application of annexin V labeled with fluorescent dye is presently the most popular tool for its detection. Several methods have been suggested recently that offer important advantages over annexin V assay with the ability to study apoptosis by spectroscopy of cell suspensions, flow cytometry and confocal or twophoton microscopy. The PS exposure marks the integrated changes in the outer leaflet of cell membrane that involve electrostatic potential and hydration, and the attempts are being made to provide direct probing of these changes. This review describes the basic mechanisms underlying the loss of membrane asymmetry during apoptosis and discusses, in comparison with the annexin V-binding assay, the novel fluorescence techniques of detecting apoptosis on cellular membrane level. In more detail we describe the detection method based on smart fluorescent dye F2N12S incorporated into outer leaflet of cell membrane and reporting on apoptotic cell transformation by easily detectable change of the spectral distribution of fluorescent emission. It can be adapted to any assay format.

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“…The first 2-photon excitation of electronic states was found for blue fluorescence emission with CaF 2 :Eu 2+ crystals based on the availability of lasers in 1961 (Kaiser & Garrett, 1961). To date, tunable mode-locked Ti:sapphire lasers operating at high repetition rate (typically 80-90 MHz) and a ultrashort pulse duration (less than 200 fs) are typically used as near infrared (NIR) sources in multiphoton excitation imaging (König & Riemann, 2003;Zipfel et al, 2003b;Rubart, 2004;Wang et al, 2005a). The required transient high irradiance can be obtained by tightly focusing ultrashort laser pulses within a sub-femtolitre focal volume provided by a special objective with high numerical aperture.…”

Section: Introductionmentioning

confidence: 99%

Two‐photon microscopy of deep intravital tissues and its merits in clinical research

Wang

König

2010

Journal of Microscopy

176

131

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SummaryMultiphoton excitation laser scanning microscopy, relying on the simultaneous absorption of two or more photons by a molecule, is one of the most exciting recent developments in biomedical imaging. Thanks to its superior imaging capability of deeper tissue penetration and efficient light detection, this system becomes more and more an inspiring tool for intravital bulk tissue imaging. Two-photon excitation microscopy including 2-photon fluorescence and second harmonic generated signal microscopy is the most common multiphoton microscopic application. In the present review we take diverse ocular tissues as intravital samples to demonstrate the advantages of this approach. Experiments with registration of intracellular 2-photon fluorescence and extracellular collagen second harmonic generated signal microscopy in native ocular tissues are focused. Data show that the in-tandem combination of 2-photon fluorescence and second harmonic generated signal microscopy as two-modality microscopy allows for in situ co-localization imaging of various microstructural components in the whole-mount deep intravital tissues. New applications and recent developments of this high technology in clinical studies such as 2-photon-controlled drug release, in vivo drug screening and administration in skin and kidney, as well as its uses in tumourous tissues such as melanoma and glioma, in diseased lung, brain and heart are additionally reviewed. Intrinsic emission two-modal 2-photon microscopy/tomography, acting as an efficient and sensitive non-injurious imaging approach featured by high contrast and subcellular spatial resolution, has been proved to be a promising tool for intravital deep tissue imaging and clinical studies. Given the level of its performance, we believe Correspondence to B.-G. Wang. Tel: +49 3641 938496; fax: +49 3641 938552; e-mail: Baogui.Wang@mti.uni-jena.de that the non-linear optical imaging technique has tremendous potentials to find more applications in biomedical fundamental and clinical research in the near future.

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Two-Photon Microscopy of Cells and Tissue

Cited by 283 publications

References 80 publications

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca²⁺ in intact mice, rat, and rabbit hearts

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca²⁺ in intact mice, rat, and rabbit hearts

Beyond annexin V: fluorescence response of cellular membranes to apoptosis

Two‐photon microscopy of deep intravital tissues and its merits in clinical research

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Two-Photon Microscopy of Cells and Tissue

Cited by 283 publications

References 80 publications

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca2+ in intact mice, rat, and rabbit hearts

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca2+ in intact mice, rat, and rabbit hearts

Beyond annexin V: fluorescence response of cellular membranes to apoptosis

Two‐photon microscopy of deep intravital tissues and its merits in clinical research

Contact Info

Product

Resources

About

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca²⁺ in intact mice, rat, and rabbit hearts

2‐photon excitation fluorescence microscopy enables deeper high‐resolution imaging of voltage and Ca²⁺ in intact mice, rat, and rabbit hearts