OBJECTIVE: this study proposes and evaluates a technique for in vivo deep-tissue superresolution imaging in the light-scattering mouse brain at up to a 3.5 Hz 2-D imaging rate with a 21×21 μm2 field of view. METHODS: we combine the deep-tissue penetration and high imaging speed of resonant laser scanning two-photon (2P) microscopy with the superresolution ability of patterned excitation microscopy. Using high-frequency intensity modulation of the scanned two-photon excitation beam, we generate patterned illumination at the imaging plane. Using the principles of structured illumination, the high-frequency components in the collected images are then used to reconstruct images with an approximate twofold increase in optical resolution. RESULTS: using our technique, resonant 2P superresolution patterned excitation reconstruction microscopy, we demonstrate our ability to investigate nanoscopic neuronal architecture in the cerebral cortex of the mouse brain at a depth of 120 μm in vivo and 210 μm ex vivo with a resolution of 119 nm. This technique optimizes the combination of speed and depth for improved in vivo imaging in the rodent neocortex. CONCLUSION: this study demonstrates a potentially useful technique for superresolution in vivo investigations in the rodent brain in deep tissue, creating a platform for investigating nanoscopic neuronal dynamics. SIGNIFICANCE: this technique optimizes the combination of speed and depth for improved superresolution in vivo imaging in the rodent neocortex.
OBJECTIVE: this study proposes and evaluates a technique for in vivo deep-tissue superresolution imaging in the light-scattering mouse brain at up to a 3.5 Hz 2-D imaging rate with a 21×21 μm2 field of view. METHODS: we combine the deep-tissue penetration and high imaging speed of resonant laser scanning two-photon (2P) microscopy with the superresolution ability of patterned excitation microscopy. Using high-frequency intensity modulation of the scanned two-photon excitation beam, we generate patterned illumination at the imaging plane. Using the principles of structured illumination, the high-frequency components in the collected images are then used to reconstruct images with an approximate twofold increase in optical resolution. RESULTS: using our technique, resonant 2P superresolution patterned excitation reconstruction microscopy, we demonstrate our ability to investigate nanoscopic neuronal architecture in the cerebral cortex of the mouse brain at a depth of 120 μm in vivo and 210 μm ex vivo with a resolution of 119 nm. This technique optimizes the combination of speed and depth for improved in vivo imaging in the rodent neocortex. CONCLUSION: this study demonstrates a potentially useful technique for superresolution in vivo investigations in the rodent brain in deep tissue, creating a platform for investigating nanoscopic neuronal dynamics. SIGNIFICANCE: this technique optimizes the combination of speed and depth for improved superresolution in vivo imaging in the rodent neocortex.
Authors: Jan Tønnesen; Fabien Nadrigny; Katrin I Willig; Roland Wedlich-Söldner; U Valentin Nägerl Journal: Biophys J Date: 2011-11-15 Impact factor: 4.033
Authors: William A Toy; Giselle M Petzinger; Brian J Leyshon; Garnik K Akopian; John P Walsh; Matilde V Hoffman; Marta G Vučković; Michael W Jakowec Journal: Neurobiol Dis Date: 2013-12-05 Impact factor: 5.996
Authors: Ignacio Izeddin; Christian G Specht; Mickaël Lelek; Xavier Darzacq; Antoine Triller; Christophe Zimmer; Maxime Dahan Journal: PLoS One Date: 2011-01-17 Impact factor: 3.240
Authors: Tsai-Wen Chen; Trevor J Wardill; Yi Sun; Stefan R Pulver; Sabine L Renninger; Amy Baohan; Eric R Schreiter; Rex A Kerr; Michael B Orger; Vivek Jayaraman; Loren L Looger; Karel Svoboda; Douglas S Kim Journal: Nature Date: 2013-07-18 Impact factor: 49.962