Add to ORKGWe introduce a compact, fast large area multiphoton exoscope (FLAME) system with enhanced molecular contrast for macroscopic imaging of human skin with microscopic resolution. A versatile imaging platform, FLAME combines optical and mechanical scanning mechanisms with deep learning image restoration to produce depth-resolved images that encompass sub-mm2 to cm2 scale areas of tissue within minutes and provide means for a comprehensive analysis of live or resected thick human skin tissue. The FLAME imaging platform, which expands on a design recently introduced by our group, also features time-resolved single photon counting detection to uniquely allow fast discrimination and 3D virtual staining of melanin. We demonstrate its performance and...
Two-photon excitation microscopy has the potential as an effective, noninvasive, diagnostic tool for...
Skin contains many autofluorescent components that can be studied using spectral imaging. We employe...
All living cells are dynamic machines that continuously adapt and respond to their local environment...
Melanin plays a significant role in the regulation of epidermal homeostasis and photoprotection of h...
We present a multiphoton microscope designed for mesoscale imaging of human skin. The system is base...
Human skin is a highly complex and dynamic biological organ providing many critical functions for th...
The development of clinical multiphoton technologies has led to new, labelfree approaches for non-in...
International audienceMultiphoton microscopy has emerged in the past decade as a promising non-invas...
Multiphoton imaging has developed into an important technique for in-vivo research in life sciences....
High resolution optical tomography studies on topically applied probes and UVA exposed skin were per...
The work presented in this thesis employed multiphoton microscopy of tissue autofluorescence to inve...
Medical imaging is a crucial tool in diagnosing and treating diseases, and by far the most common se...
PurposeTwo-photon excitation fluorescence (2PEF) reveals information about tissue function. Concerns...
Clinical multiphoton tomography and two-photon micro-endoscopy provide clinicians and researchers wi...
Various optical imaging technologies have been used to optically biopsy the skin tissue to make an e...
Two-photon excitation microscopy has the potential as an effective, noninvasive, diagnostic tool for...
Skin contains many autofluorescent components that can be studied using spectral imaging. We employe...
All living cells are dynamic machines that continuously adapt and respond to their local environment...
Melanin plays a significant role in the regulation of epidermal homeostasis and photoprotection of h...
We present a multiphoton microscope designed for mesoscale imaging of human skin. The system is base...
Human skin is a highly complex and dynamic biological organ providing many critical functions for th...
The development of clinical multiphoton technologies has led to new, labelfree approaches for non-in...
International audienceMultiphoton microscopy has emerged in the past decade as a promising non-invas...
Multiphoton imaging has developed into an important technique for in-vivo research in life sciences....
High resolution optical tomography studies on topically applied probes and UVA exposed skin were per...
The work presented in this thesis employed multiphoton microscopy of tissue autofluorescence to inve...
Medical imaging is a crucial tool in diagnosing and treating diseases, and by far the most common se...
PurposeTwo-photon excitation fluorescence (2PEF) reveals information about tissue function. Concerns...
Clinical multiphoton tomography and two-photon micro-endoscopy provide clinicians and researchers wi...
Various optical imaging technologies have been used to optically biopsy the skin tissue to make an e...
Two-photon excitation microscopy has the potential as an effective, noninvasive, diagnostic tool for...
Skin contains many autofluorescent components that can be studied using spectral imaging. We employe...
All living cells are dynamic machines that continuously adapt and respond to their local environment...