1 Time-lapse 3D confocal imaging of the NMBS demonstrates
2 Time-lapse 3D confocal microscopy showed that self-lysis
3 The high-resolution
time-lapse 3D images allow monitoring the progress of re
4 We used
time-lapse 3D imaging and mathematical modeling to asses
5 We used
time-lapse 3D imaging and quantitative image analysis to
6 Time-lapse AFM imaging, in solution, show that over time
7 Here, we use single-cell
time-lapse analyses to reveal that mycobacterial cell po
8 Time-lapse analysis of H. volcanii shows that divisome l
9 Moreover,
time-lapse analysis of Sup35 oligomer fibrillation on ce
10 Using
time-lapse and confocal microscopy to observe interactio
11 Using
time-lapse and correlative light-electron microscopy, we
12 Here we use wide-field
time-lapse and three-dimensional structured illumination
13 Using
time-lapse atomic force microscopy, we analyzed the morp
14 e proposed cascade was addressed by means of
time-lapse automated fluorescence microscopy, electron m
15 Here, we report a
time-lapse-
based bright-field imaging analysis system th
16 cross lifetime, age at presentation, and the
time lapse between surgery and the first AT episode vari
17 ough most astrocytes appeared dormant during
time-lapse calcium imaging, a subgroup displayed persist
18 Time-lapse confocal and superresolution microscopy revea
19 This protocol describes multichannel
time-lapse confocal imaging of anchor-cell invasion in l
20 Using
time-lapse confocal imaging of epithelial tissues in liv
21 Time-lapse confocal imaging showed that spine translocat
22 y using a membrane-permeant PI3P derivative,
time-lapse confocal imaging, electrophysiology, as well
23 By using
time-lapse confocal microscopy of HeLa cells co-expressi
24 We used multiphoton and
time-lapse confocal microscopy to monitor intracellular
25 ed glass surface was examined in vitro using
time-lapse confocal scanning laser microscopy.
26 This is consistent with
time-lapse crystallographic structures following inserti
27 Using kinetics and
time-lapse crystallography, we evaluated how a model DNA
28 nsfer order and implantation potential using
time-lapse data collected through expensive imaging hard
29 The
time-lapse data indicate that the same cells are differe
30 acquisition of synchronised 3D + time video
time-lapse datasets of the beating zebrafish heart.
31 segment and track neuronal morphodynamics in
time-lapse datasets.
32 We observed many isolates by
time-lapse,
differential interference contrast (DIC) mic
33 r ecosystems in Central Japan, where in situ
time-lapse digital images documenting sky and surface ve
34 This allows us to detect the
time-lapse dynamics of the lipid-lipid interactions duri
35 Time-lapse electrical resistivity imaging (ERI) was used
36 Time-lapse embryo imaging was performed to assess the ti
37 Here, using
time-lapse embryonic imaging, genetics, protein-interact
38 Viewed by
time-lapse epi-fluorescence microscopy, monocytes appear
39 Utilizing
time-lapse epifluorescence microscopy, we observed that
40 udy, we conducted both a clonal analysis and
time-lapse experiments to decipher the pattern and seque
41 During these
time-lapse experiments, dynamic data were collected on t
42 nterplay between optogenetic stimulation and
time lapse fast impedance assays in boosting the platfor
43 ficant improvement as demonstrated in the 13
time-lapse field surveys that included substantial repea
44 instrument with up to 0.5 frames per second
time-lapse FLIM measurements of cAMP levels using an Epa
45 al time fluorescent imaging (zone adjustable
time-lapse fluorescence image processor) and separation
46 Time-lapse fluorescence imaging of live cells at super-r
47 Typically, the approximate time frame for
time-lapse fluorescence imaging of mt-Keima is 20 h for
48 Unexpectedly, we find using
time-lapse fluorescence imaging that cdc-42 is not requi
49 ing in silico predictions, complemented with
time-lapse fluorescence imaging to study live interactio
50 its conversion into a product is followed by
time-lapse fluorescence microscopy at the single-cell le
51 Using
time-lapse fluorescence microscopy in budding yeast, we
52 Here, using
time-lapse fluorescence microscopy to examine PhoP-depen
53 In addition, we used
time-lapse fluorescence microscopy to image dynamic type
54 ometry of Reaction Rate Constant (CRRC) uses
time-lapse fluorescence microscopy to measure a rate con
55 Time-lapse fluorescence microscopy was used to assess ch
56 Using
time-lapse fluorescence microscopy we observed that symm
57 tubule dynamics and used high-resolution and
time-lapse fluorescence microscopy, revealing that mitoc
58 this problem, we used long-term quantitative
time-lapse fluorescence microscopy, transmission electro
59 -cell transcriptomics, we define a molecular
time-lapse from pre-DC fate specification through DC nic
60 Here, we applied
time-lapse high-speed atomic force microscopy to visuali
61 nowledge, this device is the first to enable
time-lapsed,
high-throughput live imaging of cnidarian l
62 We used
time-lapse holotomographic microscopy to observe cholest
63 experimental and modeling approach that uses
time-lapse imagery to directly relate burrow formation t
64 Applying treeHFM to
time lapse images of hematopoietic progenitor cell diffe
65 y system, which allowed gathering underwater
time-lapse images every 30 minutes consecutively over 3
66 By studying
time-lapse images of a seismic reflector between two wat
67 , as demonstrated by kymographs derived from
time-lapse images of FtsZ ladder formation.
68 et up and has the potential to generalize to
time-lapse images of other organisms or different experi
69 yed in vivo two-photon microscopy to produce
time-lapse images of serotonin axons in the neocortex of
70 mensional confocal microscopy and two-photon
time-lapse images of T cell-dendritic cell interactions
71 To address this question, we analyzed
time-lapse images of the mouse epidermis taken over 1 we
72 The iPALM
time-lapse images show significant lattice dynamics with
73 The analysis of
time-lapse images showing cells dividing to produce clon
74 Time-lapse images were acquired to record events due to
75 Combined with
time lapse imaging of development in culture, we demonst
76 llumination Microscopy (SPIM) revolutionized
time lapse imaging of live cells and organisms due to it
77 Here, we used 3D and
time lapse imaging on young leaves at different stages o
78 Using
time-lapse imaging accompanied by immunostaining and mol
79 Localization and
time-lapse imaging analysis reveals that MAP7 is enriche
80 Time-lapse imaging and fate mapping demonstrate that the
81 Time-lapse imaging and genetic cell-lineage tracing were
82 Here, we use in vivo
time-lapse imaging and genetic manipulation in Drosophil
83 successful application of reporter lines for
time-lapse imaging and mouse transplantation experiments
84 Time-lapse imaging and scanning electron microscopy reve
85 Here, we use
time-lapse imaging and single cell RNA-seq to measure ac
86 ng the archaeal cells to enable quantitative
time-lapse imaging and single-cell analysis, which would
87 The software enabled
time-lapse imaging and the use of temporally varying cha
88 Here, we use
time-lapse imaging and transgenesis in zebrafish to visu
89 ich timescales are most accessible using the
time-lapse imaging approach and explore uncertainties in
90 Time-lapse imaging assays also revealed the essential ro
91 In vivo
time-lapse imaging demonstrated that local TH first incr
92 In single cell
time-lapse imaging experiments, VHA(B) -eGFP localizatio
93 Despite the introduction of
time-lapse imaging improvements in IVF success rates hav
94 itu genotyping of a library of strains after
time-lapse imaging in a microfluidic device overcomes th
95 Confocal
time-lapse imaging in acute slices reveals that groups o
96 Using
time-lapse imaging in an obstetrical brachial plexus inj
97 Using
time-lapse imaging in primary mouse neurons, we found th
98 al contributions, we use lineage tracing and
time-lapse imaging in zebrafish to identify an endoderma
99 into the dorsal root entry zone (DREZ) with
time-lapse imaging in zebrafish.
100 Two-photon
time-lapse imaging indicated that microglia depletion re
101 Time-lapse imaging is a fundamental tool for studying ce
102 cell-cell interactions from high-throughput
time-lapse imaging microscopy data of cells in nanowell
103 It further provides a novel tool for in vivo
time-lapse imaging of adult fish for non-cardiac studies
104 This allows P-IID to be used in
time-lapse imaging of apoptosis using confocal laser sca
105 Time-lapse imaging of autophagosomes and ATP/ADP levels
106 uorescence microscopy have made snapshot and
time-lapse imaging of bacterial cells commonplace, yet f
107 Time-lapse imaging of BAX recruitment and mitochondrial
108 e performed long-term, non-invasive, in vivo
time-lapse imaging of c1vpda embryonic and larval morpho
109 strategy for in vivo longitudinal and rapid
time-lapse imaging of CC presynaptic terminal developmen
110 Time-lapse imaging of cells expressing the K1646R mutant
111 esolution microscopy, photostable cQDs allow
time-lapse imaging of chromatin and nucleoli during cell
112 We carried out in vivo
time-lapse imaging of Drosophila adult sensory neuron di
113 With
time-lapse imaging of ECM micro-fiber morphology, the lo
114 nascent synapses, we performed simultaneous
time-lapse imaging of fluorescently-tagged ribbons in re
115 We used confocal fluorescence
time-lapse imaging of FOXO1-GFP in adult isolated living
116 Furthermore,
time-lapse imaging of herpes simplex virus 1 infected ep
117 We performed
time-lapse imaging of individual ipsilaterally projectin
118 cilium; its lumenal space is rich in Ca(2+)
Time-lapse imaging of isolated hPSCs reveals that the ap
119 spin-down, and turbidity assays, as well as
time-lapse imaging of liquid droplet formation.
120 at HySP enables unmixing of seven signals in
time-lapse imaging of living zebrafish embryos.
121 Time-lapse imaging of multiple labels is challenging for
122 eet microscopy to perform three-dimensional,
time-lapse imaging of neutrophil-like HL-60 cells crawli
123 e show live alveologenesis, using long-term,
time-lapse imaging of precision-cut lung slices.
124 Using live
time-lapse imaging of primary resected tumors, we discov
125 ge N") and long-term operations ("large T"),
time-lapse imaging of shear-wave velocity (V S ) structu
126 Indeed, using 2-photon
time-lapse imaging of SP-transgenic granule cells in mou
127 Three-dimensional fluorescence
time-lapse imaging of the beating heart is extremely cha
128 d human corneal epithelial cell sheets using
time-lapse imaging of the cell culture process every 20
129 We performed
time-lapse imaging of the mitochondrial inner membrane o
130 We developed a novel method for
time-lapse imaging of the rapid dynamics of miRNA activi
131 3D
time-lapse imaging of this biosensor in embryos revealed
132 As a case study, we present super-resolution
time-lapse imaging of wild-type Bacillus subtilis spores
133 Time-lapse imaging revealed disruption of the initial st
134 Time-lapse imaging revealed dynamic changes in the metab
135 In vivo
time-lapse imaging revealed that LT-HSCs at steady-state
136 Time-lapse imaging revealed that MSCs recruited MRL.Fas(
137 Time-lapse imaging reveals a nuanced role for p21 in can
138 Time-lapse imaging reveals rapid pulsatile level changes
139 Time-lapse imaging reveals that alpha-actinin-1 puncta w
140 Time-lapse imaging reveals that branching events are syn
141 Time-lapse imaging reveals that the distinct myelinating
142 lysis of cellular dynamics from high-content
time-lapse imaging screens with little prior knowledge a
143 cells appeared to be partially inhibited and
time-lapse imaging showed a possible role for host macro
144 Time-lapse imaging showed that hepatic-specified endoder
145 Time-lapse imaging shows that non-motile bacteria 'hitch
146 ens up exciting new opportunities for direct
time-lapse imaging studies over a 24-hour time course, t
147 l microscopic assessment or more recently by
time-lapse imaging systems.
148 Using
time-lapse imaging to follow divisions and fates of basa
149 We show that DeSOS can be used in
time-lapse imaging to generate super-resolution movies i
150 We use quantitative microscopy and
time-lapse imaging to observe pulses in the activity of
151 murine lung-on-chip infection model and use
time-lapse imaging to reveal the dynamics of host-Mycoba
152 We combined single-cell laser axotomy with
time-lapse imaging to study the dynamics of phosphatidyl
153 reverse genetics and multivariate long-term
time-lapse imaging to test current cell shape control mo
154 l assessments of cellular rearrangements and
time-lapse imaging to visualize cochlear remodeling in m
155 Time-lapse imaging was used to evaluate mechanisms of ce
156 over 28 days and processed for quantitative
time-lapse imaging with dynamic histomorphometry.
157 By combining
time-lapse imaging with genetics, we here identify the l
158 Using long-term
time-lapse imaging with intact Drosophila larvae, we fou
159 Extended
time-lapse imaging with less than one virion per cell al
160 By combining
time-lapse imaging with scDNA-seq, we determined that mu
161 Through a combination of
time-lapse imaging, and chemical and mechanical perturba
162 tion of approaches, including FACS analysis,
time-lapse imaging, immunofluorescence microscopy, and c
163 Using a rat primary neuron model,
time-lapse imaging, immunohistochemistry, and confocal m
164 induced pluripotent stem cells (iPSCs) using
time-lapse imaging, immunostaining, and single-cell RNA
165 eneration with single-axon laser axotomy and
time-lapse imaging, monitoring the initial changes in tr
166 Through
time-lapse imaging, optical highlighting, and combined g
167 applications, including cellular isolation,
time-lapse imaging, protocol optimization, and lineage-t
168 roduce SIFT, single-cell isolation following
time-lapse imaging, to address these limitations.
169 characterized cell-cycle delay identified by
time-lapse imaging, was used to clarify the relationship
170 Using
time-lapse imaging, we find that mesenchymal cell conden
171 Using three-dimensional (3D)
time-lapse imaging, we found that stomatal pore formatio
172 calcium signaling throughout RV infection by
time-lapse imaging.
173 spots, turning on and off, are confirmed by
time-lapse imaging.
174 e utility of the method in vivo in mice with
time-lapse imaging.
175 e study their mobility characteristics using
time-lapse imaging.
176 -tracing and transcriptomics approaches with
time-lapse imaging.
177 within an intact microvascular network using
time-lapse imaging.
178 matrix (ECM) protein surfaces was studied by
time-lapse imaging.
179 Time-lapsed imaging of GFP-laced rodlets in human cells
180 trate that 1) rapid, quantitative 3D and 4D (
time lapse)
imaging of cellular and subcellular processe
181 Time-lapse impedance measurements are used to reveal cel
182 Here, we performed
time lapse in vivo two photon imaging in somatosensory c
183 We here developed tiv-AFM, combining
time-lapse in vivo atomic force microscopy with upright
184 By means of
time-lapse in vivo calcium imaging and neural activity m
185 Using a combination of
time-lapse in vivo single-cell analysis and Caenorhabdit
186 Time-lapse in vivo two-photon imaging showed that OVX-as
187 r Vigilance Test (PVT-B), with long response
times (lapses)
indicating reduced alertness.
188 Using 3D,
time-lapse intravital imaging for direct visualization o
189 In this study, using
time-lapse intravital imaging of the spleen, we identify
190 her use our localization data to reconstruct
time-lapse iPALM images of the Gag-Dendra2 lattice withi
191 n both localization correlation analysis and
time-lapse iPALM.
192 Time-lapse live cell imaging revealed active migration o
193 ic probability theory, computer simulations,
time-lapse live cell microscopy, and single-cell analysi
194 This method, combined with
time-lapse live imaging and glutamate uncaging, could de
195 We used
time-lapse live-cell imaging of Neurospora crassa in mic
196 This conclusion was validated by long-term
time-lapse live-imaging experiments.
197 HMSiR, that assemble in situ and enable long
time-lapse,
live-cell nanoscopy of discrete cellular str
198 Here we present 9 years of
time-lapse mapping of an active submarine channel along
199 torized stage of a microscope for conducting
time-lapse microphotography of multiple observations in
200 The microfluidic device enabled quantitative
time-lapse microphotography reported here should be suit
201 ction was further verified experimentally by
time-lapse microscopic examinations of the snf1Delta str
202 employ temporal variance analysis of a short
time-lapse microscopic image series to capture the motio
203 Time-lapse microscopic-photography allows in-depth pheno
204 Time lapse microscopy showed that isogenic cells express
205 Time-lapse microscopy and computer simulations suggest t
206 Time-lapse microscopy and electron microscopy confirmed
207 ied the mobilities of labeled glycolipids by
time-lapse microscopy and fluorescence recovery after ph
208 Here, we used
time-lapse microscopy and fluorescent reporters of DNA r
209 Using
time-lapse microscopy and quantitative image analysis, w
210 fied at cellular and whole tissue levels via
time-lapse microscopy and quantitative PCR.
211 h widely used assays such as flow cytometry,
time-lapse microscopy and single-molecule RNA Fluorescen
212 Moreover, by pairing smFISH with
time-lapse microscopy and the analysis of pedigrees, we
213 Moreover, it can correct temporal drift in
time-lapse microscopy data and thus improve continuous s
214 In live-cell
time-lapse microscopy experiments, we could not detect a
215 Time-lapse microscopy imaging provides direct access to
216 Here, we used
time-lapse microscopy in combination with microfluidics
217 Here, we used electron, confocal and
time-lapse microscopy in combination with pharmacologica
218 Here we use single-cell
time-lapse microscopy of Cyclin-Dependent Kinase 2 (CDK2
219 Next, from single-cell, single-RNA level
time-lapse microscopy of independent lineages of Escheri
220 We performed high-resolution
time-lapse microscopy of mouse and human neutrophils and
221 ulation process is monitored by using either
time-lapse microscopy or fluorescence-activated cell sor
222 Time-lapse microscopy revealed that a stiff 3D niche sig
223 Time-lapse microscopy reveals catastrophic and highly he
224 ltarhsB mutants do not kill target bacteria,
time-lapse microscopy reveals that they assemble and fir
225 h respect to the entire cell population in a
time-lapse microscopy sequence.
226 Our
time-lapse microscopy showed most exchange was from Fibs
227 Time-lapse microscopy showed that HuR was required for t
228 Time-lapse microscopy shows that NDK-1 is expressed on p
229 We used
time-lapse microscopy to analyze the dynamic effects of
230 We used high-precision
time-lapse microscopy to characterize the maturation kin
231 Here, we used knockout mouse models and
time-lapse microscopy to elucidate Galpha and Gbeta subu
232 Using
time-lapse microscopy to monitor Escherichia coli popula
233 is This method is based on automated digital
time-lapse microscopy to observe the growth and morpholo
234 We later utilised
time-lapse microscopy to show that internalised mitochon
235 ime, called EAST, which is live-monitored by
time-lapse microscopy video.
236 he sorted groups by proliferation assays and
time-lapse microscopy which confirmed the proliferative
237 napshots with known cell ages as recorded in
time-lapse microscopy, and (iii) snapshots with unknown
238 In this study, we combine microfluidics,
time-lapse microscopy, and computational modeling to inv
239 fluorescence in situ hybridization (smFISH),
time-lapse microscopy, and mathematical modeling in sing
240 were followed at the single-cell level using
time-lapse microscopy, and showed two distinct, albeit d
241 high-content screening, super-resolution and
time-lapse microscopy, digital pathology, public genetic
242 Here, we examined this question using
time-lapse microscopy, genetic perturbation, bioinformat
243 and gain-of-function experiments followed by
time-lapse microscopy, in vivo imaging, and whole-mount
244 toxicity in chronic settings, sophisticated
time-lapse microscopy, or bulky/expensive chemo-stat ins
245 Here, utilizing long-term, quantitative
time-lapse microscopy, we identified two oppositely orie
246 Using
time-lapse microscopy, we observed oscillations of cell-
247 Using microfluidics and
time-lapse microscopy, we quantitatively analyzed how th
248 uation of Living Arrays of Mycobacterium), a
time-lapse microscopy-based method that observes individ
249 llowed CHH fibroblasts by pulse-labeling and
time-lapse microscopy.
250 enous electrical stimulation and single-cell
time-lapse microscopy.
251 ion inserted into ribosomal DNA (rDNA) using
time-lapse microscopy.
252 uorescent images are acquired with automated
time-lapse microscopy.
253 for rapid and accurate stitching of large 2D
time-lapse mosaics.
254 Finally, we generate
time-lapse movies of complex neural arborization through
255 Our analysis focuses on
time-lapse movies of Escherichia coli cells trapped in a
256 d to quantify individual cell divisions from
time-lapse movies of explanted Drosophila larval brains,
257 ng resources, which can process terabytes of
time-lapse multi-channel mosaics 15 to 100 times faster
258 Its exquisite sensitivity enables
time-lapse optical biopsies that capture minute changes
259 s system is compatible with high-resolution,
time-lapse optical microscopy.
260 Time-lapse photography was used to reconstruct the wheat
261 Furthermore, using confocal imaging and
time-lapse recordings, we demonstrated "intracellular cr
262 t is well constrained by the data, we obtain
time-lapse repeatability of about 2% in the model domain
263 Time-lapse SAFIRe imaging can be performed for an extend
264 Here, using
time-lapsed scanning tunnelling microscopy and density f
265 Time-lapse SECM imaging revealed a suitable window of 30
266 olymer networks from fluorescence microscopy
time-lapse sequences facilitates such quantitative studi
267 to quantify growth cone morphodynamics from
time-lapse sequences imaged both in vitro and in vivo, b
268 erved by tracking single CPR molecules using
time-lapse single-molecule fluorescence imaging and subs
269 Time-lapse single-molecule fluorescence imaging can part
270 Time-lapse SPECT imaging results illustrated both local
271 Time lapse studies of E. coli cells treated with LL-37 s
272 It also enables
time-lapse studies of entire cell cultures in multiple i
273 h conventional computed tomography (CT) in a
time-lapse study.
274 tures and organelles in living cells by long
time-lapse super-resolution microscopy is challenging, a
275 Using
time-lapse superresolution microscopy in brain slices, w
276 A novel
time-lapse synchrotron deep-UV microscopy methodology wa
277 For the first time,
time-lapse synchrotron X-ray phase contrast computed tom
278 rest and oxygen stress challenge, attaining
time-lapse three-dimensional oxygenation maps across ent
279 Using single molecule fluorescence,
time-lapse TIRF microscopy and AFM imaging we characteri
280 Time-lapse total internal reflection fluorescence (TIRF)
281 , we used simultaneous electrophysiology and
time-lapse two photon imaging to examine how spines chan
282 We used
time-lapse two-photon imaging of dendritic spine motilit
283 ctural changes in axonal boutons imaged with
time-lapse two-photon laser scanning microscopy (2PLSM).
284 Time-lapse two-photon microscopy in adult slices was use
285 Here we report the first end-to-end study of
time-lapse V S imaging that uses traffic noise continuou
286 Using
time-lapse video imaging and mice infection, we observed
287 Time-lapse video imaging compiled from the optical scree
288 olarity are investigated by multidimensional
time-lapse video microscopy and immunocytochemistry.
289 Time-lapse video microscopy confirmed that delivery occu
290 Time-lapse video microscopy revealed that deposition of
291 As shown by
time-lapse video microscopy, ATIP3 depletion exacerbates
292 A smartphone was used to record, via
time-lapse video, the times at which color appeared as a
293 s are now overcome, using phase contrast and
time-lapse videography to reveal the dynamic behavior of
294 As shown by
time-lapse videomicroscopy of in vitro produced embryos
295 ical vein endothelial cells (HUVEC) and used
time-lapse videomicrosopy and quantitative image analysi
296 e virtual reality, but not after exposure to
time-lapse videos.
297 sive virtual reality relative to exposure to
time-lapse videos.
298 Here we report
time-lapse X-ray crystallography snapshots of catalytic
299 Here the authors use
time-lapse X-ray crystallography to capture the states o
300 n atomic level, we employed a combination of
time-lapse X-ray crystallography, molecular dynamics sim