High-resolution multiphoton tomography of human skin with subcellular spatial resolution and picosecond time resolution

Koenig, Karsten; Riemann, Iris

doi:10.1117/1.1577349

Cited by 509 publications

(457 citation statements)

References 14 publications

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“…Excitation: 800-860 nm; emission: one half of the excitation wavelength (Zoumi et al, 2002;König & Riemann, 2003;Zipfel et al, 2003b;Wang et al, 2008a).…”

Section: Keratinmentioning

confidence: 99%

“…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%

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

Wang

König

2010

Journal of Microscopy

180

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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“…Excitation: 800-860 nm; emission: one half of the excitation wavelength (Zoumi et al, 2002;König & Riemann, 2003;Zipfel et al, 2003b;Wang et al, 2008a).…”

Section: Keratinmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

Wang

König

2010

Journal of Microscopy

180

131

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“…Further, the human tumour samples underwent similar processing compared to the experimental tissue obtained from immuno-deficient NMRI mice, which lacked these cell types. The problem of unidentified cell [13,14,19,30]. Furthermore, experimental glioma tissue showed significantly longer fluorescence lifetimes than normal cortex or white matter [8].…”

Section: Discussionmentioning

confidence: 99%

Multi-photon excitation fluorescence microscopy of brain-tumour tissue and analysis of cell density

Kantelhardt

Leppert

Kantelhardt

et al. 2009

Acta Neurochir (Wien)

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Background Recent studies have highlighted the importance of the complete resection of a brain tumour but the task often remains a challenge for the neurosurgeon. New technologies which add objective information beyond visualisation provided by the traditional operating microscope are required. In this study, we have analysed the cellular density of the tumour/brain interface using three dimensional multi-photon microscopy intensity-images of experimental gliomas and human brain-tumour biopsy samples. Methods The density of cellular nuclei was determined in specimens of experimental gliomas in a mouse model and human brain tumour biopsies by analysis of optical tissue sections. Three dimensional multi-photon microscopy image stacks were compared to serial H&E stained sections of conventional histolopathology. Findings Both techniques consistently showed a good correlation of cell density values in solid tumour tissue of experimental gliomas versus adjacent brain. The multiphoton microscopy analysis of human biopsy specimens showed that optical analysis of native tissue provided information on the cellular density. Conclusions Multi-photon microscopy is an efficient and rapid tool for the study of brain and brain tumour tissue. Multi-photon microscopy allows the detection of individual tumour cells and tumour cell clusters in native tissue biopsies and may therefore provide a tool in the identification of highly cellular lesions during the resection of brain tumours.

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“…interactions between proteins in living cells 48,[82][83][84][85][86] , photophysics of complexes involved in plant photosynthesis 87 or the redox metabolism 38,50,[88][89][90] . In the last years, FLIM gained on interest in the biomedicine, as well 27,49,78,[91][92][93][94][95][96] . For instance, a FLIM device for the clinical diagnosis of malign skin tissue is commercially available (DermaInspect, JenLab, Jena, Germany) 27 .…”

Section: Bioscientific Applicationsmentioning

confidence: 99%

“…In the last years, FLIM gained on interest in the biomedicine, as well 27,49,78,[91][92][93][94][95][96] . For instance, a FLIM device for the clinical diagnosis of malign skin tissue is commercially available (DermaInspect, JenLab, Jena, Germany) 27 . In the following we do not intend to review all these applications, more we focus our attention on some experiments based on time-gated FLIM where single-beam as well as multi-focal TPLSM were used.…”

Section: Bioscientific Applicationsmentioning

confidence: 99%

Fluorescence lifetime imaging in biosciences: technologies and applications

Niesner

Gericke

2008

Front. Phys. China

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The biosciences require the development of methods, which allow a non-invasive and rapid investigation of biological systems. In this frame high-end imaging techniques allow an intravital microscopy in real-time, providing information on a molecular basis. Far-field fluorescence imaging techniques are some of the most adequate methods for such investigations. However, there are great differences between the common fluorescence imaging techniques, i.e. wide-field, confocal one-photon and two-photon microscopy, respectively, as far as their applicability in diverse bioscientific research areas is concerned. In the first part of this work, we briefly compare these techniques. Standard methods used in the biosciences, i.e. steady-state techniques based on the analysis of the total fluorescence signal originating from the sample, can successfully be employed in the study of cell, tissue and organ morphology as well as in monitoring the macroscopic tissue function. However, they are mostly inadequate for the quantitative investigation of the cellular function at molecular level. The intrinsic disadvantages of steady-state techniques are counteracted by using time-resolved techniques. Among these the fluorescence lifetime imaging (FLIM) is currently the most common. Different FLIM principles as well as applications of particular relevance for the biosciences, especially for fast intravital studies are discussed in this work.

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High-resolution multiphoton tomography of human skin with subcellular spatial resolution and picosecond time resolution

Cited by 509 publications

References 14 publications

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

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

Multi-photon excitation fluorescence microscopy of brain-tumour tissue and analysis of cell density

Fluorescence lifetime imaging in biosciences: technologies and applications

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