1 er acquisition and higher spatial detail via
super-resolution.
2 intracellular localization to be tracked at
super resolutions.
3 nd analyze the raw image data to reconstruct
super-resolution 3D data sets.
4 Here we apply
super-resolution 3D structured illumination microscopy (
5 source reconstruction algorithm to produce a
super-resolution 3D volume of the fetal thorax.
6 Using
super-resolution 3D-FISH and chromosome conformation cap
7 We present deep-learning-enabled
super-resolution across different fluorescence microscop
8 corporated into existing single-molecule and
super-resolution analysis packages to accurately locate
9 In this study, we use correlative
super resolution and electron microscopy to precisely de
10 Live-cell
super-resolution and electron microscopy analyses reveal
11 n-driven NE rupture by correlated live-cell,
super-resolution and electron microscopy.
12 e (both sexes) were analyzed using confocal,
super-resolution and EM in intact brain and acute brain
13 Using a combination of confocal,
super-resolution and EM, we defined DAT localization and
14 Using
super-resolution and expansion microscopy, we find that
15 Super-resolution and immunogold platinum replica electro
16 g picture of genome organization revealed by
super-resolution and live-cell imaging.
17 h of the three IP3R isoforms and an array of
super-resolution and ultrastructural approaches we demon
18 omic force and optical microscopy (including
super resolution),
and some have been reported to affect
19 Using confocal, expansion,
super-resolution,
and electron microscopy, we determined
20 As a proof of concept for
super-resolution applications, we use nanographenes in S
21 Using 3D-SIM, a
super resolution approach, we found that RUSH VSVG trans
22 -contrast and nanoscale resolution using the
super-resolution approach of DNA-PAINT.
23 However,
super-resolution approaches are limited, for numerous re
24 dimensions) that is superior to the current
super-resolution by fluorescence light microscopy.
25 Thus, our
super-resolution compatible labeling probes allow visual
26 a competition-enabled imaging technique with
super-resolution (
COMPEITS) that enables quantitative su
27 ed nephrocyte functional assays, carried out
super-resolution confocal microscopy of slit diaphragm p
28 To demonstrate the potential of this
super-resolution correlator, we visualize the distributi
29 r relatively high laser intensities, current
super-resolution cryo-CLEM methods require cryo-protecta
30 o the problem of specimen devitrification in
super-resolution cryo-CLEM.
31 elation analyses of high-content multiplexed
super-resolution data.
32 ese are contained within densely distributed
super-resolution data.
33 lpha- and beta-tubulin in microtubules using
super-resolution detection.
34 Through a
super-resolution-
driven approach, here we characterize t
35 However, current co-localization analysis of
super-resolution fluorescence imaging is prone to false
36 Using
super-resolution fluorescence imaging, we show that unde
37 tial application in optical data storage and
super-resolution fluorescence microscopies.
38 ed imaging of spatially correlated far-field
super-resolution fluorescence microscopy and atomic forc
39 Here, using
super-resolution fluorescence microscopy and spectroscop
40 Super-resolution fluorescence microscopy has enabled imp
41 Super-resolution fluorescence microscopy is a powerful t
42 Here, using
super-resolution fluorescence microscopy, we report that
43 e widespread application of nanographenes in
super-resolution fluorescence microscopy.
44 tum dots, as a new class of fluorophores for
super-resolution fluorescence microscopy.
45 of DiB-splits for wide-field, confocal, and
super-resolution fluorescence microscopy.
46 Potential label-free alternatives to
super-resolution fluorescence techniques have been the f
47 , which generates a longitudinally-polarized
super-resolution focal point.
48 dynamics in hard-to-transfect cell lines by
super-resolution for over an order of magnitude longer t
49 This deep learning-based
super-resolution framework can be broadly applied to enh
50 ydrogenase 1-mutated human glioma by using a
super-resolution framework to upsample three-dimensional
51 ers of overlapping emitter images in the raw
super-resolution image data.
52 To acquire three dimensional (3D)
super-resolution images of DNA, we combined binding acti
53 we use nanographenes in SMLM to generate 3D
super-resolution images of silica nanocracks.
54 a we previously generated can be extended to
super-resolution images taken under different experiment
55 approach to extract protein copy number from
super-resolution images.
56 sis packages have been developed to generate
super-resolution images.
57 aphase based on single-particle averaging of
super-resolution images.
58 nclude photon counting (PC), chromatography,
super resolution imaging, fluorescence imaging, and mass
59 d analysis of proteome (MAP) method for cell
super-resolution imaging (Cell-MAP) which preserves cell
60 Here, we describe a rapid, accessible
super-resolution imaging and analysis workflow-SEQUIN-th
61 d developed a software package for real-time
super-resolution imaging and crosslinking control.
62 ccessible chromatin with visualization, PALM
super-resolution imaging and lattice light-sheet microsc
63 man scattering, surface enhances absorption,
super-resolution imaging and others.
64 and-induced DDR1 clustering by widefield and
super-resolution imaging and provide evidence for a mech
65 We demonstrate
super-resolution imaging at depths of up to 66 um for ce
66 Super-resolution imaging based on single molecule locali
67 Super-resolution imaging confirmed the presence of simil
68 on, analysis of beta1 integrin clustering by
super-resolution imaging demonstrates that CD82 expressi
69 At the same time, quality of
super-resolution imaging depends on high label specifici
70 is still challenging to perform large volume
super-resolution imaging for entire animal organs.
71 We develop a quantitative assay based on
super-resolution imaging in fixed cells and light sheet
72 Using
super-resolution imaging in single bacterial cells, we s
73 Super-resolution imaging of individual cells is required
74 e foundation for accelerated single-molecule
super-resolution imaging of large swaths of, if not enti
75 ategy was further demonstrated by multicolor
super-resolution imaging of lipid droplets and proteins
76 Using
super-resolution imaging of live cells, we show here tha
77 Using
super-resolution imaging of living cells, we find that P
78 uorescent flipper probes for single-molecule
super-resolution imaging of membrane tension in living c
79 olution (COMPEITS) that enables quantitative
super-resolution imaging of non-fluorescent processes.
80 Here we show by
super-resolution imaging of ORAI1, STIM1, and septin 4 i
81 e, highly photostable probe allows live-cell
super-resolution imaging of tubulin localization and mot
82 Expansion microscopy (ExM) allows
super-resolution imaging on conventional fluorescence mi
83 der high (de)excitation light intensities of
super-resolution imaging or in single-molecule applicati
84 traightforwardly integrated in a multiplexed
super-resolution imaging protocol and benefits from adva
85 By contrast, optical
super-resolution imaging provides information about mole
86 Single-molecule and
super-resolution imaging relies on successful, sensitive
87 the behavior and health of the cell, and our
super-resolution imaging results indicate that aggresome
88 Biochemical synaptic preparations and
super-resolution imaging revealed increased levels and a
89 fluctuation imaging (cryo-SOFI), a low-dose
super-resolution imaging scheme based on the SOFI princi
90 Super-resolution imaging shows that whereas the MT cytos
91 Super-resolution imaging suggested nanometer proximity b
92 algorithm, when paired with next-generation
super-resolution imaging systems, could be used to acces
93 Here, we introduce a
super-resolution imaging technique with an acquisition r
94 Various
super-resolution imaging techniques have been developed
95 turation, transport and fusion in vitro with
super-resolution imaging techniques, and two-photon micr
96 Super-resolution imaging using assay for transposase-acc
97 Super-resolution imaging using structured illumination r
98 capable of serving as an ideal candidate for
super-resolution imaging with extremely low luminescence
99 tructures and achieve multi-color, live-cell
super-resolution imaging with greatly reduced photobleac
100 Using high- and
super-resolution imaging with ovastacin(mCherry) as a fl
101 Confocal and
super-resolution imaging within the cell interior reveal
102 loaking(8,9), biochemical sensing(10,11) and
super-resolution imaging(12,13).
103 t applications such as image restoration and
super-resolution imaging, and discuss how the latest dee
104 tricular cardiomyocytes via a combination of
super-resolution imaging, biophysical, and genomic appro
105 us attractive applications in optics such as
super-resolution imaging, enhanced spontaneous emission,
106 With the use of live cell single-molecule
super-resolution imaging, Forster resonance energy trans
107 In single molecule localization-based
super-resolution imaging, high labeling density or the d
108 r its applications in optical communication,
super-resolution imaging, high-dimensional entangled sou
109 Combined with
super-resolution imaging, HiPR-FISH shows the diverse st
110 of light such as tracking protein movement,
super-resolution imaging, identification of circulating
111 Using single-molecule
super-resolution imaging, we characterized the dynamics
112 Using
super-resolution imaging, we demonstrate that inter-mito
113 domain-specific BioID proximity labeling and
super-resolution imaging, we identify CEP112 as a basal
114 Using
super-resolution imaging, we observed that G protein-cou
115 ovides a convenient and versatile method for
super-resolution imaging, which may be routinely used fo
116 -caged fluorophores promising candidates for
super-resolution imaging, which was realized by photoact
117 meter search, and could serve to democratize
super-resolution imaging.
118 e tracking of protein-RNA tethering, and for
super-resolution imaging.
119 ited state quenchers for single-molecule and
super-resolution imaging.
120 molecule fluorescence and localization-based
super-resolution imaging.
121 d a dinuclear platinum complex (Pt(2) L) for
super-resolution imaging.
122 d (U-DNA-Seq) that was combined with in situ
super-resolution imaging.
123 CNNs), a form of DL, were trained to perform
super resolution in image space by using synthetically g
124 Here, to achieve
super-resolution in all three dimensions, we applied Arr
125 erative adversarial network (GAN) to perform
super-resolution in coherent imaging systems.
126 challenging to obtain three-dimensional (3D)
super-resolution information of structures and dynamic p
127 We then benchmarked our
super-resolution labelling method on synthetic DNA nanos
128 maging in nanoscale topography) strategy for
super-resolution labelling upon visualization on single
129 rse biologically relevant information at the
super-resolution level.
130 Using
super resolution live imaging and correlative light and
131 cent proteins (pcFPs) are powerful tools for
super-resolution localization microscopy and protein tag
132 bolic labeling, bioorthogonal chemistry, and
super-resolution localization microscopy to image two co
133 ol and benefits from advantages of DNA-based
super-resolution localization microscopy, such as high s
134 by a full octave and show that the predicted
super-resolution manifests in a critical intensity and f
135 Our results underscore the power of
super-resolution mapping of ecologically relevant traits
136 to a voxel size of 1.7 x 1.7 x 3 mm using a
super-resolution method that combined weighted total var
137 We use this temporal
super-resolution method to resolve fast voltage and glut
138 RNAs with 20 nm resolution by combining the
super-resolution method, DNA-based points accumulation i
139 Exploiting
super-resolution methods for cryo-FM is advantageous, as
140 lls through a synergy of single-molecule and
super-resolution methods.
141 scope design shows promise for future use in
super-resolution micro-endoscopes and in vivo neural ima
142 We present a 4Pi single-molecule switching
super-resolution microscope that enables ratiometric mul
143 g-diodes, lasers, single-molecular tracking,
super-resolution microscope, and advanced quantum light
144 Super-resolution microscopic analyses in various organis
145 Yet, despite the widespread adoption of
super-resolution microscopies, single-molecule data proc
146 Using chemical genetics,
super resolution microscopy, and live-cell imaging we di
147 Super-resolution microscopy (SRM) bypasses the diffracti
148 Super-resolution microscopy allows imaging of cellular s
149 Optical
super-resolution microscopy allows nanoscale imaging of
150 omolecular interactions within biofilms, and
super-resolution microscopy analysis of biofilm developm
151 By combining
super-resolution microscopy and chromatin fiber analyses
152 combination of imaging approaches including
super-resolution microscopy and electron microscopy we i
153 Importantly,
super-resolution microscopy and quantitative image analy
154 Lastly, we provide an outlook for
super-resolution microscopy and single-molecule tracking
155 Using
super-resolution microscopy and single-particle analysis
156 orescent proteins (PCFPs) are widely used in
super-resolution microscopy and studies of cellular dyna
157 ll-molecule fluorescent probes for live-cell
super-resolution microscopy and the challenges that need
158 all-molecule fluorescent probes in live-cell
super-resolution microscopy are given.
159 Recent advances in fluorescence
super-resolution microscopy are providing important insi
160 ng, and highlights the power of quantitative
super-resolution microscopy as a tool to bridge the gap
161 Here, using electron- and
super-resolution microscopy at the Drosophila neuromuscu
162 Super-resolution microscopy demonstrated that CD40L is p
163 Super-resolution microscopy encompasses a diverse set of
164 Our results highlight the power of
super-resolution microscopy for the study of gamma-secre
165 ncement expands the routine applicability of
super-resolution microscopy from selected cellular targe
166 Single-molecule
super-resolution microscopy has developed from a special
167 g cytoskeleton at nanoscale resolution using
super-resolution microscopy has enabled many insights in
168 Multicolor single-molecule localization
super-resolution microscopy has enabled visualization of
169 In this context,
super-resolution microscopy has gained considerable inte
170 However, the combination of ICCS with
super-resolution microscopy has not been explored yet.
171 Super-resolution microscopy has spatial resolution beyon
172 Different physical approaches to
super-resolution microscopy have been introduced over th
173 Recent developments in multiplexed,
super-resolution microscopy have enabled an unprecedente
174 Recent advances in localization-based
super-resolution microscopy have enabled researchers to
175 Recent advances in gene engineering and
super-resolution microscopy have underscored the spatiot
176 egistration and visualization of correlative
super-resolution microscopy images from different micros
177 report stimulated emission depletion (STED)
super-resolution microscopy images of aptamer-based, flu
178 ent tagging of gamma-secretase subunits with
super-resolution microscopy in fibroblasts.
179 The use of
super-resolution microscopy in recent years has revealed
180 interested researchers to establish 4Pi-SMS
super-resolution microscopy in their laboratories.
181 r demonstrate by in vitro binding assays and
super-resolution microscopy in vivo that the mechanism b
182 Super-resolution microscopy is broadening our in-depth u
183 gress, the full potential of single-molecule
super-resolution microscopy is yet to be realized, which
184 omosome conformation capture experiments and
super-resolution microscopy measurements.
185 Super-resolution microscopy of GFP-labelled receptors an
186 est this model, we carried out 3D, two-color
super-resolution microscopy of histones and DNA with and
187 Super-resolution microscopy of MCF-7 cells treated with
188 Super-resolution microscopy offers a significant gain in
189 Single-molecule-based
super-resolution microscopy offers researchers a unique
190 In contrast to most other 3D
super-resolution microscopy or 3D particle-tracking micr
191 This renders
super-resolution microscopy particularly valuable, and a
192 erein, we introduce a new design concept for
super-resolution microscopy probes that combines specifi
193 Super-resolution microscopy revealed that AQP4 rAbs with
194 Stochastic optical reconstruction microscopy
super-resolution microscopy revealed that coexpressed IK
195 versus inaccessible chromatin states, while
super-resolution microscopy reveals a continuum of chrom
196 Super-resolution microscopy reveals distinct functions o
197 Super-resolution microscopy reveals extra, short-A-bands
198 Proximity-labeling and
super-resolution microscopy show that Nup188 is vicinal
199 but both immunogold electron microscopy and
super-resolution microscopy showed that ITPR3 in CCA cel
200 Finally, correlative live-cell and
super-resolution microscopy showed that lysosomes intera
201 Proximity-PAINT (pPAINT), a variation of the
super-resolution microscopy technique DNA-PAINT.
202 ging by rapid beam oscillation (nSPIRO) is a
super-resolution microscopy technique that was originall
203 Super-resolution microscopy techniques enable optical im
204 dered actin bundles of even fibroblasts with
super-resolution microscopy techniques.
205 ation, sRNA-FISH signals can be imaged using
super-resolution microscopy to examine the subcellular l
206 provide an overview of recent studies using
super-resolution microscopy to investigate mitochondria,
207 e applied a single-cell measure coupled with
super-resolution microscopy to investigate the integrate
208 In this work we employed
super-resolution microscopy to reveal the nanometric-sca
209 Here we use
super-resolution microscopy to show that 53BP1 and RIF1
210 Here, we used
super-resolution microscopy to study meiotic centromere
211 filtration slit density, as assessed by STED
super-resolution microscopy upon tissue clearing.
212 Using
super-resolution microscopy we detect no change in dendr
213 ce imaging and stimulated emission depletion
super-resolution microscopy were performed in prkar1 kno
214 and emerging opportunities in optogenetics,
super-resolution microscopy, and photoactive molecular d
215 Despite progress in
super-resolution microscopy, discriminating and quantify
216 Here, we used
super-resolution microscopy, electron microscopy, live-c
217 ss the boundary of the spinal cord and, with
super-resolution microscopy, is positioned with synaptic
218 es in vitro and in cells; when combined with
super-resolution microscopy, it unveiled details of ultr
219 ere, we combine single-molecule tracking and
super-resolution microscopy, light-induced subcellular l
220 Combined with standard and
super-resolution microscopy, photostable cQDs allow time
221 Using
super-resolution microscopy, we analyzed the localizatio
222 Using
super-resolution microscopy, we demonstrate that neurexi
223 Using nanoscale
super-resolution microscopy, we found that TRPML1 channe
224 e microscopy, and 3D-structured illumination
super-resolution microscopy, we identified a new trypano
225 Using site-specific fluorescent labeling and
super-resolution microscopy, we show that HA and NA are
226 al labelling of a microneme protein MIC2 and
super-resolution microscopy, we show that micronemes are
227 Using
super-resolution microscopy, we show that only a small s
228 Using a
super-resolution microscopy, we show that surprisingly,
229 Using
super-resolution microscopy, we then screened for regula
230 using up to twelve rounds of Exchange-PAINT
super-resolution microscopy.
231 or Cy-thiol adduct formation, necessary for
super-resolution microscopy.
232 cation of molecular complexes in multiplexed
super-resolution microscopy.
233 dily compatible with structured illumination
super-resolution microscopy.
234 f photoswitchable GFPs as improved tools for
super-resolution microscopy.
235 onal synapses using multiplexed confocal and
super-resolution microscopy.
236 a unique periciliary localization defined by
super-resolution microscopy.
237 c densities (PSDs) using high-resolution and
super-resolution microscopy.
238 nexplored protein family as novel probes for
super-resolution microscopy.
239 eripheral region of the nucleus, as shown by
super-resolution microscopy.
240 essible to cell population analysis by using
super-resolution microscopy.
241 an be used in time-lapse imaging to generate
super-resolution movies in zebrafish.
242 seven men) were prospectively recruited for
super-resolution MRI.
243 Super-resolution nanoscopy and dynamic channel tracking
244 t can be used to monitor LDs evolution under
super-resolution nanoscopy.
245 Here, we introduce cryogenic
super-resolution optical fluctuation imaging (cryo-SOFI)
246 lity-make it attractive for observation with
super-resolution optical microscopy.
247 Super-resolution PAINT imaging of the same targets is pe
248 Super-resolution Photo-Activatable Localization Microsco
249 ctly in the bloodstream as the basis for new
super-resolution photoacoustic flow cytometry in vivo.
250 Super-resolution reconstruction is a method typically us
251 Here, we present a
super-resolution reconstruction method for LA-ICP-MS ima
252 Quantitative
super-resolution reconstruction, combined with Gaussian
253 -lapse fluorescence imaging of live cells at
super-resolution remains a challenge, especially when th
254 To achieve
super-resolution scanning electrochemical microscopy (SE
255 Using
super-resolution sequencing, we explore the Y Chromosome
256 Super-resolution SERS images at different focal planes s
257 Our work demonstrates
super-resolution SERS imaging to probe membrane receptor
258 ion in the number of raw images required for
super-resolution SIM, and generate images under extreme
259 Using live-cell high-speed
super-resolution single-molecule microscopy we could dis
260 Correlative
super-resolution (
SR) fluorescence and electron microsco
261 Super-resolution (
SR) microscopy has been used to observ
262 Three-dimensional
super-resolution (
SR) US has shown potential to noninvas
263 Ultrathin sections scanned with
super-resolution STED microscopy allowed the detection o
264 nal labeling strategy that enables two-color
super-resolution (
STED) and 3D confocal imaging of two o
265 t spatial scales, FCS has been combined with
super-resolution stimulated emission depletion (STED) mi
266 bining genetic engineering with quantitative
super-resolution stimulated emission depletion (STED) mi
267 Super-resolution stimulated emission depletion (STED) mi
268 other super-resolution techniques, including
super-resolution stimulated emission depletion (STED), p
269 Instead, as shown by
super-resolution stimulated emission depletion microscop
270 e displacement/diffusivity mapping (SMdM), a
super-resolution strategy that enables the nanoscale map
271 to-3D transformation is applied to obtain 3D
super-resolution structural and dynamic information.
272 Confocal,
super resolution structured illumination microscopy, tot
273 ecting sample-induced optical aberrations in
super-resolution structured illumination microscopy (SIM
274 We detected maize miR2275 by
super-resolution structured illumination microscopy and
275 ve imaging of cells in vitreous ice by using
super-resolution structured illumination microscopy in c
276 Using
super-resolution structured illumination microscopy, we
277 We conclude with a
super-resolution study of renewable energy resources bas
278 In this work, we present a
super-resolution surface-enhanced Raman scattering (SERS
279 ate the veracity of this deep learning-based
super-resolution technique by inferring unresolved featu
280 y U test was used to check that the proposed
super-resolution technique yields the highest peak signa
281 Conventionally, label-based microscopy and
super-resolution techniques are employed.
282 this Feature, we discuss efforts to develop
super-resolution techniques based on vibrational spectro
283 Current
super-resolution techniques require either the use of sp
284 STED microscopy achieves among various other
super-resolution techniques the best temporal resolution
285 The emergence of other
super-resolution techniques, including super-resolution
286 enables a straightforward implementation of
super-resolution techniques.
287 rs immobilized on a surface and located with
super-resolution techniques; the small-molecule L-Tym an
288 s, microfluidics, and improved approaches to
super-resolution,
thousands to hundreds of thousands of
289 Purpose To develop and evaluate a
super-resolution three-dimensional (3D) MR spectroscopic
290 As a case study, we present
super-resolution time-lapse imaging of wild-type Bacillu
291 sion microscopy to enable rapid, multiplexed
super-resolution tissue imaging.
292 o track the platinum drugs in real time with
super-resolution to elucidate their mechanism of action,
293 these momentum combs in spectroscopy enables
super-resolution tomography of key band-structure detail
294 cements of >10(6) probe molecules to achieve
super-resolution topography and diffusivity mapping.
295 We also demonstrate cross-modality
super-resolution,
transforming confocal microscopy image
296 Super-resolution ultrasound localization microscopy (ULM
297 Super-resolution upsampling improved peak signal-to-nois
298 Conclusion Three-dimensional
super-resolution US imaging using microbubbles allows no
299 the probes were applied to realize specific
super-resolution visualization of the intracellular LDs
300 l and functional microvasculature details at
super-resolution within a short acquisition time (severa