Access the full text.
Sign up today, get DeepDyve free for 14 days.
H. Deschout, F. Zanacchi, Michael Mlodzianoski, A. Diaspro, J. Bewersdorf, S. Hess, K. Braeckmans (2014)
Precisely and accurately localizing single emitters in fluorescence microscopyNature Methods, 11
M. Heilemann, E. Margeat, R. Kasper, M. Sauer, P. Tinnefeld (2005)
Carbocyanine dyes as efficient reversible single-molecule optical switch.Journal of the American Chemical Society, 127 11
R. Heintzmann, C. Cremer (1999)
Laterally modulated excitation microscopy: improvement of resolution by using a diffraction grating, 3568
K. Wake, K. Decker, A. Kirn, D. Knook, R. McCuskey, L. Bouwens, E. Wisse (1989)
Cell biology and kinetics of Kupffer cells in the liver.International review of cytology, 118
D. Svistounov, A. Warren, G. McNerney, D. Owen, D. Zencak, S. Zykova, Harry Crane, T. Huser, R. Quinn, B. Smedsrød, D. Couteur, V. Cogger (2012)
The Relationship between Fenestrations, Sieve Plates and Rafts in Liver Sinusoidal Endothelial CellsPLoS ONE, 7
Jérémy Meyer, C. Gonelle-Gispert, P. Morel, L. Bühler (2016)
Methods for Isolation and Purification of Murine Liver Sinusoidal Endothelial Cells: A Systematic ReviewPLoS ONE, 11
Mark Bates, Timothy Blosser, X. Zhuang (2005)
Short-range spectroscopic ruler based on a single-molecule optical switch.Physical review letters, 94 10
S. Hell (2003)
Toward fluorescence nanoscopyNature Biotechnology, 21
V. Mennella (2016)
Structured Illumination Microscopy
Dong Li, L. Shao, Bi-Chang Chen, Xi Zhang, Mingshu Zhang, Brian Moses, D. Milkie, Jordan Beach, J. Hammer, Mithun Pasham, T. Kirchhausen, M. Baird, M. Davidson, P. Xu, E. Betzig (2015)
Extended-resolution structured illumination imaging of endocytic and cytoskeletal dynamicsScience, 349
M. Gustafsson (2000)
Surpassing the lateral resolution limit by a factor of two using structured illumination microscopyJournal of Microscopy, 198
V. Pérez, Bo-Jui Chang, E. Stelzer (2016)
Optimal 2D-SIM reconstruction by two filtering steps with Richardson-Lucy deconvolutionScientific Reports, 6
J. Pawley (1990)
Handbook of Biological Confocal Microscopy
R. Heintzmann, T. Jovin, C. Cremer (2002)
Saturated patterned excitation microscopy--a concept for optical resolution improvement.Journal of the Optical Society of America. A, Optics, image science, and vision, 19 8
E. Abbe (1873)
Beiträge zur Theorie des Mikroskops und der mikroskopischen WahrnehmungArchiv für mikroskopische Anatomie, 9
(1995)
Mouse hepatitisvirus type-3 infection provokes a decrease in the number of sinusoidal endothelial-cell fenestrae both in-vivo and in-vitro
Adish Dani, Bo Huang, J. Bergan, C. Dulac, X. Zhuang (2010)
Superresolution Imaging of Chemical Synapses in the BrainNeuron, 68
V. Cogger, D. Svistounov, A. Warren, S. Zykova, Richard Melvin, Samantha Solon-Biet, Jennifer O’Reilly, A. Mcmahon, J. Ballard, R. Cabo, D. Couteur, M. Lebel (2014)
Liver aging and pseudocapillarization in a Werner syndrome mouse model.The journals of gerontology. Series A, Biological sciences and medical sciences, 69 9
V. Mönkemöller, M. Schüttpelz, P. Mccourt, K. Sørensen, B. Smedsrød, T. Huser (2014)
Imaging fenestrations in liver sinusoidal endothelial cells by optical localization microscopy.Physical chemistry chemical physics : PCCP, 16 24
Peter Winter, Andrew York, D. Nogare, M. Ingaramo, Ryan Christensen, A. Chitnis, G. Patterson, H. Shroff (2014)
Two-photon instant structured illumination microscopy improves the depth penetration of super-resolution imaging in thick scattering samples.Optica, 1 3
Norman Brede, M. Lakadamyali (2012)
GraspJ: an open source, real-time analysis package for super-resolution imagingOptical Nanoscopy, 1
E. Betzig, G. Patterson, R. Sougrat, O. Lindwasser, S. Olenych, J. Bonifacino, M. Davidson, J. Lippincott-Schwartz, H. Hess (2006)
Imaging Intracellular Fluorescent Proteins at Nanometer ResolutionScience, 313
Russell Thompson, D. Larson, W. Webb (2002)
Precise nanometer localization analysis for individual fluorescent probes.Biophysical journal, 82 5
T. Klar, S. Jakobs, M. Dyba, A. Egner, S. Hell (2000)
Fluorescence microscopy with diffraction resolution barrier broken by stimulated emission.Proceedings of the National Academy of Sciences of the United States of America, 97 15
D. Baddeley, D. Crossman, S. Rossberger, J. Cheyne, J. Montgomery, Isuru Jayasinghe, C. Cremer, M. Cannell, C. Soeller (2011)
4D Super-Resolution Microscopy with Conventional Fluorophores and Single Wavelength Excitation in Optically Thick Cells and TissuesPLoS ONE, 6
Isuru Jayasinghe, M. Munro, D. Baddeley, B. Launikonis, C. Soeller (2014)
Observation of the molecular organization of calcium release sites in fast- and slow-twitch skeletal muscle with nanoscale imagingJournal of The Royal Society Interface, 11
H. Suleiman, Lei Zhang, Robyn Roth, J. Heuser, J. Miner, A. Shaw, Adish Dani (2013)
Nanoscale protein architecture of the kidney glomerular basement membraneeLife, 2
Mark Bates, Bo Huang, X. Zhuang (2008)
Super-resolution microscopy by nanoscale localization of photo-switchable fluorescent probes.Current opinion in chemical biology, 12 5
K. Sørensen, P. Mccourt, T. Berg, C. Crossley, David Couteur, K. Wake, B. Smedsrød (2012)
The scavenger endothelial cell: a new player in homeostasis and immunity.American journal of physiology. Regulatory, integrative and comparative physiology, 303 12
S. Linde, A. Löschberger, Teresa Klein, Meike Heidbreder, S. Wolter, M. Heilemann, M. Sauer (2011)
Direct stochastic optical reconstruction microscopy with standard fluorescent probesNature Protocols, 6
E. Wisse (1970)
An electron microscopic study of the fenestrated endothelial lining of rat liver sinusoids.Journal of ultrastructure research, 31 1
I. Rasnik, S. McKinney, T. Ha (2006)
Nonblinking and long-lasting single-molecule fluorescence imagingNature Methods, 3
B. Agnarsson, Saevar Ingthorsson, T. Gudjonsson, K. Leosson (2009)
Evanescent-wave fluorescence microscopy using symmetric planar waveguides.Optics express, 17 7
Michael Rust, Mark Bates, X. Zhuang (2006)
Sub-diffraction-limit imaging by stochastic optical reconstruction microscopy (STORM)Nature Methods, 3
(2013)
Video-rate nanoscopy using sCMOS camera-specific single-molecule localization algorithms
K. Sørensen, Jaione Simón-Santamaría, R. McCuskey, B. Smedsrød (2015)
Liver Sinusoidal Endothelial Cells.Comprehensive Physiology, 5 4
F. Braet, E. Wisse (2012)
AFM imaging of fenestrated liver sinusoidal endothelial cells.Micron, 43 12
Jun Ding, K. Takasaki, B. Sabatini (2009)
Supraresolution Imaging in Brain Slices using Stimulated-Emission Depletion Two-Photon Laser Scanning MicroscopyNeuron, 63
P. Parot, Y. Dufrêne, P. Hinterdorfer, C. Grimellec, D. Navajas, J. Pellequer, S. Scheuring (2007)
Past, present and future of atomic force microscopy in life sciences and medicineJournal of Molecular Recognition, 20
A. Benda, H. Aitken, D. Davies, R. Whan, C. Goldsbury (2016)
STED imaging of tau filaments in Alzheimer's disease cortical grey matter.Journal of structural biology, 195 3
S. Hell (2007)
Far-Field Optical NanoscopyScience, 316
V. Mönkemöller, C. Øie, W. Hübner, T. Huser, P. Mccourt (2015)
Multimodal super-resolution optical microscopy visualizes the close connection between membrane and the cytoskeleton in liver sinusoidal endothelial cell fenestrationsScientific Reports, 5
G. Moneron, S. Hell (2009)
Two-photon excitation STED microscopy.Optics express, 17 17
(1988)
Book-Review - Astrophysical and Laboratory Spectroscopy
K. Willig, H. Steffens, Carola Gregor, Alexander Herholt, M. Rossner, S. Hell (2014)
Nanoscopy of filamentous actin in cortical dendrites of a living mouse.Biophysical journal, 106 1
(2013)
Realtime analysis and visualization for single-molecule based super-resolution microscopy
A. Steffan, C. Pereira, A. Bingen, Michèle Valle, Jean‐Pierre Martin, F. Koehren, C. Royer, J. Gendrault, A. Kirn (1995)
Mouse hepatitis virus type 3 infection provokes a decrease in the number of sinusoidal endothelial cell fenestrae both in vivo and in vitroHepatology (Baltimore, Md.), 22
D. Couteur, A. Warren, V. Cogger, B. Smedsrød, K. Sørensen, R. Cabo, R. Fraser, R. McCuskey (2008)
Old Age and the Hepatic SinusoidThe Anatomical Record: Advances in Integrative Anatomy and Evolutionary Biology, 291
S. Holden, Stephan Uphoff, A. Kapanidis (2011)
DAOSTORM: an algorithm for high- density super-resolution microscopyNature Methods, 8
Michael Hofmann, C. Eggeling, S. Jakobs, S. Hell (2005)
Breaking the diffraction barrier in fluorescence microscopy at low light intensities by using reversibly photoswitchable proteins.Proceedings of the National Academy of Sciences of the United States of America, 102 49
K. Takasaki, Jun Ding, B. Sabatini (2013)
Live-cell superresolution imaging by pulsed STED two-photon excitation microscopy.Biophysical journal, 104 4
Jennifer O’Reilly, V. Cogger, D. Couteur (2010)
Biological : Full-length Old age is associated with ultrastructural changes in isolated rat liver sinusoidal endothelial cells
J. Martin, J. Heerden (1980)
Surgery of the liver, biliary tract, and pancreas.Mayo Clinic proceedings, 55 5
F. Braet, J. Riches, Willie Geerts, Kristina Jahn, E. Wisse, P. Frederik (2009)
Three‐dimensional organization of fenestrae labyrinths in liver sinusoidal endothelial cellsLiver International, 29
M. Gustafsson (2005)
Nonlinear structured-illumination microscopy: wide-field fluorescence imaging with theoretically unlimited resolution.Proceedings of the National Academy of Sciences of the United States of America, 102 37
D. Couteur, V. Cogger, Astrid Markus, P. Harvey, Z. Yin, A. Ansselin, A. Mclean (2001)
Pseudocapillarization and associated energy limitation in the aged rat liverHepatology, 33
S. Wolter, M. Schüttpelz, M. Tscherepanow, S. Linde, M. Heilemann, M. Sauer (2010)
Real‐time computation of subdiffraction‐resolution fluorescence imagesJournal of Microscopy, 237
Christian Kempf, T. Staudt, P. Bingen, H. Horstmann, J. Engelhardt, S. Hell, T. Kuner (2013)
Tissue Multicolor STED Nanoscopy of Presynaptic Proteins in the Calyx of HeldPLoS ONE, 8
P. Bethge, Ronan Chéreau, E. Avignone, G. Marsicano, U. Nägerl (2013)
Two-photon excitation STED microscopy in two colors in acute brain slices.Biophysical journal, 104 4
M. Gustafsson, L. Shao, P. Carlton, C. Wang, I. Golubovskaya, W. Cande, D. Agard, D. Agard, J. Sedat (2008)
Three-dimensional resolution doubling in wide-field fluorescence microscopy by structured illumination.Biophysical journal, 94 12
Gerrit Best, Roman Amberger, D. Baddeley, T. Ach, S. Dithmar, R. Heintzmann, C. Cremer (2011)
Structured illumination microscopy of autofluorescent aggregations in human tissue.Micron, 42 4
Peter Ilgen, S. Stoldt, L. Conradi, C. Wurm, Josef Schoff, B. Ghadimi, T. Liersch, S. Jakobs, A. Lo, H. Kong (2014)
STED Super-Resolution Microscopy of Clinical Paraffin-Embedded Human Rectal Cancer TissuePLoS ONE, 9
E. Rego, L. Shao, J. Macklin, Lukman Winoto, G. Johansson, Nicholas Kamps-Hughes, M. Davidson, M. Gustafsson (2011)
Nonlinear structured-illumination microscopy with a photoswitchable protein reveals cellular structures at 50-nm resolutionProceedings of the National Academy of Sciences, 109
M. Ovesný, P. Krízek, J. Borkovec, Z. Svindrych, G. Hagen (2014)
ThunderSTORM: a comprehensive ImageJ plug-in for PALM and STORM data analysis and super-resolution imagingBioinformatics, 30
T. Gould, Daniel Burke, J. Bewersdorf, M. Booth (2012)
Adaptive optics enables 3D STED microscopy in aberrating specimens.Optics express, 20 19
F. Braet, R. Zanger, S. Kämmer, E. Wisse (1997)
Noncontact versus contact imaging: An atomic force microscopic study on hepatic endothelial cells in vitroInternational Journal of Imaging Systems and Technology, 8
(1873)
Beiträge zur Theorie des Mikroskops und der mikrosko - pischen Wahrnehmung
A. Matsuda, L. Shao, J. Boulanger, C. Kervrann, P. Carlton, P. Kner, D. Agard, J. Sedat (2010)
Condensed Mitotic Chromosome Structure at Nanometer Resolution Using PALM and EGFP- HistonesPLoS ONE, 5
A. Mclean, V. Cogger, G. Chong, A. Warren, Astrid Markus, J. Dahlstrom, D. Couteur (2003)
Age‐related pseudocapillarization of the human liverThe Journal of Pathology, 200
Yufeng Hou, Isuru Jayasinghe, D. Crossman, D. Baddeley, C. Soeller (2015)
Nanoscale analysis of ryanodine receptor clusters in dyadic couplings of rat cardiac myocytes.Journal of molecular and cellular cardiology, 80
S. Wolter, A. Löschberger, Thorge Holm, S. Aufmkolk, M. Dabauvalle, S. Linde, M. Sauer (2012)
rapidSTORM: accurate, fast open-source software for localization microscopyNature Methods, 9
S. Tompsett (1963)
Medical BiochemistryNature, 199
M. Heilemann, S. Linde, M. Schüttpelz, R. Kasper, B. Seefeldt, Anindita Mukherjee, P. Tinnefeld, M. Sauer (2008)
Subdiffraction-resolution fluorescence imaging with conventional fluorescent probes.Angewandte Chemie, 47 33
Dong Li, E. Betzig (2016)
Response to Comment on “Extended-resolution structured illumination imaging of endocytic and cytoskeletal dynamics”Science, 352
A. Warren, P. Bertolino, V. Benseler, R. Fraser, G. McCaughan, D. Couteur (2007)
Marked changes of the hepatic sinusoid in a transgenic mouse model of acute immune-mediated hepatitis.Journal of hepatology, 46 2
Barna Dudok, L. Barna, M. Ledri, S. Szabó, Eszter Szabadits, B. Pintér, S. Woodhams, C. Henstridge, Gyula Balla, Rita Nyilas, Csaba Varga, Sang-Hun Lee, M. Matolcsi, J. Cervenak, I. Kacskovics, Masahiko Watanabe, C. Sagheddu, M. Melis, M. Pistis, I. Soltesz, I. Katona (2014)
Cell-specific STORM superresolution imaging reveals nanoscale organization of cannabinoid signalingNature neuroscience, 18
S. Sahl, F. Balzarotti, Jan Keller-Findeisen, M. Leutenegger, V. Westphal, A. Egner, Flavie Lavoie-Cardinal, Andriy Chmyrov, T. Grotjohann, S. Jakobs (2016)
Comment on “Extended-resolution structured illumination imaging of endocytic and cytoskeletal dynamics”Science, 352
Thorge Holm, Teresa Klein, A. Löschberger, T. Klamp, G. Wiebusch, S. Linde, M. Sauer (2014)
A blueprint for cost-efficient localization microscopy.Chemphyschem : a European journal of chemical physics and physical chemistry, 15 4
M. Ingaramo, Andrew York, Peter Wawrzusin, Oleg Milberg, Amy Hong, R. Weigert, H. Shroff, G. Patterson (2014)
Two-photon excitation improves multifocal structured illumination microscopy in thick scattering tissueProceedings of the National Academy of Sciences, 111
Robin Diekmann, Ø. Helle, C. Øie, P. Mccourt, T. Huser, M. Schüttpelz, B. Ahluwalia (2017)
Chip-based wide field-of-view nanoscopyNature Photonics, 11
Haiyang Yu, H. Suleiman, A. Kim, J. Miner, Adish Dani, A. Shaw, S. Akilesh (2013)
Rac1 Activation in Podocytes Induces Rapid Foot Process Effacement and ProteinuriaMolecular and Cellular Biology, 33
R. Crang, K. Klomparens (1988)
Artifacts in biological electron microscopy
F. Braet, E. Wisse (2002)
Structural and functional aspects of liver sinusoidal endothelial cell fenestrae: a reviewComparative Hepatology, 1
P. Laissue, R. Alghamdi, P. Tomančák, E. Reynaud, H. Shroff (2017)
Assessing phototoxicity in live fluorescence imagingNature Methods, 14
B. Zapotoczny, K. Owczarczyk, K. Szafranska, E. Kuś, Stefan Chlopicki, Stefan Chlopicki, Marek Szymoński (2017)
Morphology and force probing of primary murine liver sinusoidal endothelial cellsJournal of Molecular Recognition, 30
Carlas Smith, Nikolai Joseph, B. Rieger, K. Lidke (2010)
Fast, single-molecule localization that achieves theoretically minimum uncertaintyNature methods, 7
E. Betzig (1995)
Proposed method for molecular optical imaging.Optics letters, 20 3
M. Mohamad, S. Mitchell, Lindsay Wu, Melanie White, S. Cordwell, J. Mach, Samantha Solon-Biet, D. Boyer, Dawn Nines, Abhirup Das, Shi‐Yun Li, A. Warren, S. Hilmer, R. Fraser, D. Sinclair, S. Simpson, R. Cabo, D. Couteur, V. Cogger (2016)
Ultrastructure of the liver microcirculation influences hepatic and systemic insulin activity and provides a mechanism for age‐related insulin resistanceAging Cell, 15
Meng-Tsen Ke, Yasuhiro Nakai, S. Fujimoto, Rie Takayama, Shuhei Yoshida, T. Kitajima, Makoto Sato, Takeshi Imai (2016)
Super-Resolution Mapping of Neuronal Circuitry With an Index-Optimized Clearing Agent.Cell reports, 14 11
E. Wisse, R. Zanger, K. Charels, P. Smissen, R. McCuskey (1985)
The liver sieve: Considerations concerning the structure and function of endothelial fenestrae, the sinusoidal wall and the space of disseHepatology, 5
V. Hamel, P. Guichard, Mathias Fournier, R. Guiet, Isabelle Flückiger, A. Seitz, P. Gönczy (2014)
Correlative multicolor 3D SIM and STORM microscopy.Biomedical optics express, 5 10
R. Fraser, V. Cogger, B. Dobbs, H. Jamieson, A. Warren, S. Hilmer, D. Couteur (2012)
The liver sieve and atherosclerosisPathology, 44
S. Rossberger, T. Ach, Gerrit Best, C. Cremer, R. Heintzmann, S. Dithmar (2013)
High-resolution imaging of autofluorescent particles within drusen using structured illumination microscopyBritish Journal of Ophthalmology, 97
S. Hell, Jan Wichmann (1994)
Breaking the diffraction resolution limit by stimulated emission: stimulated-emission-depletion fluorescence microscopy.Optics letters, 19 11
G. Ball, Justin Demmerle, R. Kaufmann, Ilan Davis, I. Dobbie, L. Schermelleh (2015)
SIMcheck: a Toolbox for Successful Super-resolution Structured Illumination MicroscopyScientific Reports, 5
K. Chu, P. McMillan, Zachary Smith, Jie Yin, J. Atkins, P. Goodwin, S. Wachsmann-Hogiu, S. Lane (2014)
Image reconstruction for structured-illumination microscopy with low signal level.Optics express, 22 7
Adel Kechkar, Deepak Nair, M. Heilemann, D. Choquet, J. Sibarita (2013)
Real-Time Analysis and Visualization for Single-Molecule Based Super-Resolution MicroscopyPLoS ONE, 8
V. Cogger, A. Warren, R. Fraser, M. Ngu, A. Mclean, D. Couteur (2003)
Hepatic sinusoidal pseudocapillarization with aging in the non-human primateExperimental Gerontology, 38
V. Cogger, G. McNerney, Tun Nyunt, L. DeLeve, P. Mccourt, B. Smedsrød, D. Couteur, T. Huser (2010)
Three-dimensional structured illumination microscopy of liver sinusoidal endothelial cell fenestrations.Journal of structural biology, 171 3
K. Wake (1980)
Perisinusoidal stellate cells (fat-storing cells, interstitial cells, lipocytes), their related structure in and around the liver sinusoids, and vitamin A-storing cells in extrahepatic organs.International review of cytology, 66
L. Bouwens, E. Wisse (1985)
Proliferation, Kinetics, and Fate of Monocytes in Rat Liver During a Zymosan‐ Induced InflammationJournal of Leukocyte Biology, 37
T. Mori, T. Okanoue, Y. Sawa, N. Hori, M. Ohta, K. Kagawa (1993)
Defenestration of the sinusoidal endothelial cell in a rat model of cirrhosisHepatology, 17
P. Macphee, E. Schmidt, A. Groom (1995)
Intermittence of blood flow in liver sinusoids, studied by high-resolution in vivo microscopy.The American journal of physiology, 269 5 Pt 1
S. Hilmer, V. Cogger, R. Fraser, A. Mclean, D. Sullivan, D. Couteur (2005)
Age‐related changes in the hepatic sinusoidal endothelium impede lipoprotein transfer in the ratHepatology, 42
Marcel Müller, V. Mönkemöller, Simon Hennig, W. Hübner, T. Huser (2016)
Open-source image reconstruction of super-resolution structured illumination microscopy data in ImageJNature Communications, 7
A. Warren, P. Bertolino, V. Cogger, A. Mclean, R. Fraser, D. Couteur (2005)
Hepatic pseudocapillarization in aged miceExperimental Gerontology, 40
R. Ando, H. Mizuno, A. Miyawaki (2004)
Regulated Fast Nucleocytoplasmic Shuttling Observed by Reversible Protein HighlightingScience, 306
D. Unnersjö-Jess, L. Scott, H. Blom, H. Brismar (2016)
Super-resolution stimulated emission depletion imaging of slit diaphragm proteins in optically cleared kidney tissue.Kidney international, 89 1
D. Sage, H. Kirshner, T. Pengo, N. Stuurman, Junhong Min, S. Manley, M. Unser (2015)
Quantitative evaluation of software packages for single-molecule localization microscopyNature Methods, 12
A. Warren, V. Cogger, R. Fraser, L. DeLeve, R. McCuskey, D. Couteur (2011)
The Effects of Old Age on Hepatic Stellate CellsCurrent Gerontology and Geriatrics Research, 2011
W. Treem, Ronald Sokol (1998)
Disorders of the MitochondriaSeminars in Liver Disease, 18
M. Schürmann, N. Frese, A. Beyer, P. Heimann, D. Widera, V. Mönkemöller, T. Huser, B. Kaltschmidt, C. Kaltschmidt, A. Gölzhäuser (2015)
Helium Ion Microscopy Visualizes Lipid Nanodomains in Mammalian Cells.Small, 11 43
D. Crossman, P. Ruygrok, Yufeng Hou, C. Soeller (2015)
Next-generation endomyocardial biopsy: the potential of confocal and super-resolution microscopyHeart Failure Reviews, 20
L. DeLeve (2015)
Liver sinusoidal endothelial cells in hepatic fibrosisHepatology, 61
C. Specht, I. Izeddin, Pamela Rodriguez, M. Beheiry, P. Rostaing, X. Darzacq, M. Dahan, A. Triller (2013)
Quantitative Nanoscopy of Inhibitory Synapses: Counting Gephyrin Molecules and Receptor Binding SitesNeuron, 79
Simon Hennig, V. Mönkemöller, Carolin Böger, Marcel Müller, T. Huser (2015)
Nanoparticles as Nonfluorescent Analogues of Fluorophores for Optical Nanoscopy.ACS nano, 9 6
L. Barna, Barna Dudok, Vivien Miczán, A. Horváth, Zsófia László, I. Katona (2015)
Correlated confocal and super-resolution imaging by VividSTORMNature Protocols, 11
C. Eggeling, C. Ringemann, R. Medda, G. Schwarzmann, K. Sandhoff, S. Polyakova, V. Belov, B. Hein, C. Middendorff, A. Schönle, S. Hell (2009)
Direct observation of the nanoscale dynamics of membrane lipids in a living cellNature, 457
Z. Kmieć (2001)
Cooperation of Liver Cells in Health and DiseaseAdvances in anatomy, embryology, and cell biology, 161
Eddie Wisse, De Rb, R. Jacobs, McCuskey Rs (1983)
Scanning electron microscope observations on the structure of portal veins, sinusoids and central veins in rat liver.Scanning electron microscopy, Pt 3
V. Mönkemöller (2016)
Optical super-resolution microscopy of the structure and dynamics of cellular nanopores
D. Couteur, R. Fraser, V. Cogger, A. Mclean (2002)
Hepatic pseudocapillarisation and atherosclerosis in ageingThe Lancet, 359
F. Braet, E. Wisse, P. Bomans, P. Frederik, Willie Geerts, A. Koster, L. Soon, S. Ringer (2007)
Contribution of high‐resolution correlative imaging techniques in the study of the liver sieve in three‐dimensionsMicroscopy Research and Technique, 70
Kjetil Elvevold, B. Smedsrød, I. Martinez (2008)
The liver sinusoidal endothelial cell: a cell type of controversial and confusing identity.American journal of physiology. Gastrointestinal and liver physiology, 294 2
N. Olivier, Debora Keller, Vinoth Rajan, P. Gönczy, S. Manley (2013)
Simple buffers for 3D STORM microscopyBiomedical Optics Express, 4
M. Heilemann, S. Linde, Anindita Mukherjee, M. Sauer (2009)
Super-resolution imaging with small organic fluorophores.Angewandte Chemie, 48 37
遠山 正彌, 高辻 功一, 木山 博資 (2010)
人体の解剖生理学 = Human anatomy & physiology
S. Shim, C. Xia, Guisheng Zhong, H. Babcock, J. Vaughan, Bo Huang, Xun Wang, Cheng Xu, G. Bi, X. Zhuang (2012)
Super-resolution fluorescence imaging of organelles in live cells with photoswitchable membrane probesProceedings of the National Academy of Sciences, 109
B. Dobbs, G. Rogers, H. Xing, R. Fraser (2008)
Endotoxin-induced defenestration of the hepatic sinusoidal endothelium: a factor in the pathogenesis of cirrhosis?Liver, 14 5
G. Farrell, Narci Teoh, R. McCuskey (2008)
Hepatic Microcirculation in Fatty Liver DiseaseThe Anatomical Record: Advances in Integrative Anatomy and Evolutionary Biology, 291
J. Pullman, J. Nylk, Elaine Campbell, F. Gunn-Moore, M. Prystowsky, K. Dholakia (2016)
Visualization of podocyte substructure with structured illumination microscopy (SIM): a new approach to nephrotic disease.Biomedical optics express, 7 2
S. Hess, T. Girirajan, Michael Mason (2006)
Ultra-high resolution imaging by fluorescence photoactivation localization microscopy.Biophysical journal, 91 11
AbstractSuper-resolution fluorescence microscopy, also known as nanoscopy, has provided us with a glimpse of future impacts on cell biology. Far-field optical nanoscopy allows, for the first time, the study of sub-cellular nanoscale biological structures in living cells, which in the past was limited to electron microscopy (EM) (in fixed/dehydrated) cells or tissues. Nanoscopy has particular utility in the study of “fenestrations” – phospholipid transmembrane nanopores of 50–150 nm in diameter through liver sinusoidal endothelial cells (LSECs) that facilitate the passage of plasma, but (usually) not blood cells, to and from the surrounding hepatocytes. Previously, these fenestrations were only discernible with EM, but now they can be visualized in fixed and living cells using structured illumination microscopy (SIM) and in fixed cells using single molecule localization microscopy (SMLM) techniques such as direct stochastic optical reconstruction microscopy. Importantly, both methods use wet samples, avoiding dehydration artifacts. The use of nanoscopy can be extended to the in vitro study of fenestration dynamics, to address questions such as the following: are they actually dynamic structures, and how do they respond to endogenous and exogenous agents? A logical further extension of these methodologies to liver research (including the liver endothelium) will be their application to liver tissue sections from animal models with different pathological manifestations and ultimately to patient biopsies. This review will cover the current state of the art of the use of nanoscopy in the study of liver endothelium and the liver in general. Potential future applications in cell biology and the clinical implications will be discussed.
Nanophotonics – de Gruyter
Published: Feb 23, 2018
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.