1 Electron microscopic analyses demonstrate that lungs fro
2 nsive biochemical, biophysical, genetic, and
electron microscopic analyses of claudin-16 and -19 inte
3 Cryo-
electron microscopic analyses of EDF1 and its yeast homo
4 d magnetic resonance spectroscopy (MRS), and
electron microscopic analyses of leukocytes for granular
5 d by en face immunofluorescence and scanning
electron microscopic analyses of the fibrosa surface.
6 Electron microscopic analyses of these labeled neurons d
7 Immunofluorescence and
electron microscopic analyses reveal that the antigen pr
8 rganic carbon, and petrographic and scanning
electron microscopic analyses reveal that the phosphorit
9 Electron microscopic analyses revealed that CLDs adhere
10 Electron microscopic analyses revealed that in the absen
11 Electron microscopic analyses revealed unique ultrastruc
12 Moreover, biochemical and
electron microscopic analyses show that the WASH and WAV
13 Moreover,
electron microscopic analyses showed that integrin-depen
14 we performed proteomic, transcriptomic, and
electron microscopic analyses to demonstrate that mast c
15 Here, we used biochemical and
electron microscopic analyses to demonstrate that these
16 e bioinformatic, mutagenic, biochemical, and
electron microscopic analyses to unmask the structure an
17 gic, cellular, microcomputed tomography, and
electron microscopic analyses were performed to evaluate
18 Based on genetic, antigenic/immunologic, and
electron microscopic analyses, the Deltacaf mutant was d
19 By immunohistochemical and
electron microscopic analyses, we found that HDAC3 was l
20 By immunohistochemical and
electron microscopic analyses, we found that HDAC3 was l
21 sing histochemical, immunohistochemical, and
electron microscopic analyses.
22 vioral, biochemical, immunohistological, and
electron microscopic analyses.
23 Electron-microscopic analyses of kidneys fixed seconds t
24 meric structure was further characterized by
electron microscopic analysis (3), but the functional si
25 Histopathologic, immunohistochemical, and
electron microscopic analysis demonstrated features cons
26 Electron microscopic analysis demonstrated that, compare
27 Electron microscopic analysis further revealed hypertrop
28 Electron microscopic analysis further reveals that demye
29 Electron microscopic analysis in conjunction with GABA-i
30 Histological and
electron microscopic analysis indicated that Mfsd2a KO m
31 Consequently, we performed an
electron microscopic analysis of (1) the distribution of
32 Transmission
electron microscopic analysis of capillaries located in
33 However, cryo-
electron microscopic analysis of immature virions shows
34 Electron microscopic analysis of immunogold-labelled fre
35 Electron microscopic analysis of material processed for
36 Electron microscopic analysis of mutant and WT strains c
37 Single-particle
electron microscopic analysis of negatively stained Vps1
38 Correlative light
electron microscopic analysis of null mutant-infected ce
39 Electron microscopic analysis of polysome structures in
40 Electron microscopic analysis of sciatic nerves showed a
41 Electron microscopic analysis of the cerebral cortex rev
42 Furthermore,
electron microscopic analysis of the junctions showed in
43 High-resolution transmission
electron microscopic analysis of the nanoscale crosspoin
44 Field emission scanning
electron microscopic analysis of the treated and control
45 Electron microscopic analysis of the two Meissner affere
46 Electron microscopic analysis of two neuraminidase-antib
47 Electron microscopic analysis revealed that a large frac
48 Confocal and
electron microscopic analysis revealed that glial precur
49 In addition,
electron microscopic analysis revealed that post-entry o
50 Scanning
electron microscopic analysis revealed the presence of p
51 Electron microscopic analysis showed that crocin inhibit
52 Light and
electron microscopic analysis showed that HCN2 subunits
53 Transmission
electron microscopic analysis showed that podocytes of t
54 Electron microscopic analysis shows that partially degly
55 Serial
electron microscopic analysis shows that the Drosophila
56 III (ACIII), a marker of primary cilia, and
electron microscopic analysis to describe the developmen
57 A quantitative
electron microscopic analysis was performed on striatal
58 ncluded electroretinography (ERG), light and
electron microscopic analysis, and A2E quantification.
59 monoclonal antibodies, appears spherical by
electron microscopic analysis, and is not aggregated, al
60 proaches, primarily in combination with cryo-
electron microscopic analysis, generating the first stru
61 By confocal and
electron microscopic analysis, we have observed that the
62 Based on modeling and
electron microscopic analysis, we propose that LAP1 targ
63 as PLTs from peripheral blood determined by
electron microscopic analysis.
64 constructing the same neurons through serial
electron microscopic analysis.
65 ectroscopic, thermogravimetric, and scanning
electron microscopic analytical evidence for the structu
66 Scanning
electron microscopic and atomic force microscopic images
67 RNA synthesis, we used a hybrid approach of
electron microscopic and biochemical evaluation of both
68 ase and ligase activities as well as earlier
electron microscopic and biochemical studies implicating
69 Electron microscopic and electrophysiological data demon
70 Electron microscopic and glutaraldehyde cross-linking an
71 trephination and processed for transmission
electron microscopic and immunohistochemical analyses.
72 iagnosis is reliant on correlating clinical,
electron microscopic and immunohistological features wit
73 Transmission
electron microscopic and immunological analyses showed t
74 the respective high resolution transmission
electron microscopic and mass spectroscopic studies.
75 Here, we report crystallographic,
electron microscopic and small-angle X-ray scattering an
76 Detailed
electron microscopic and spectroscopic experiments coupl
77 Indeed, the synergism between cryogenic
electron microscopic and X-ray crystallographic structur
78 Here, using
electron-microscopic and spectroscopic approaches, we pr
79 Histological,
electron microscopic,
and biochemical analyses uncovered
80 X-ray, backscattered scanning
electron microscopic,
and histological analyses showed t
81 g a combination of calorimetric, scattering,
electron microscopic,
and in silico techniques, we demon
82 study was to determine the histological and
electron microscopic appearance of mesocolon, fascia, an
83 ELKS did not affect synapse numbers or their
electron microscopic appearance.
84 xo-spinous glutamatergic synapses using a 3D
electron microscopic approach in normal and MPTP-treated
85 o-photon imaging and glutamate uncaging, and
electron microscopic assays in acute brain slices showed
86 Finally, an
electron microscopic comparison of the organization of m
87 We have used
electron microscopic connectomics techniques, optimized
88 units are consistent with existing cryogenic
electron microscopic (
cryo-EM) maps, limit binding to in
89 e we present a 3.9- angstrom resolution cryo-
electron microscopic (
cryo-EM) structure of the human 55
90 We have determined the cryo-
electron microscopic (
cryo-EM) structures of two archaea
91 The method of cryo-
electron microscopic (
cryo-EM) tomography has elucidated
92 lexibility using single particle analysis of
electron microscopic data and identified interacting dom
93 Here we report quantitative
electron microscopic data demonstrating that ER-alpha is
94 t consistent with previous cellular and cryo-
electron microscopic data for full-length AMPA receptors
95 Now we provide novel
electron microscopic data from the rat hippocampus sugge
96 Biochemical and
electron microscopic data indicate that the DNA networks
97 Together with X-ray crystallographic and
electron microscopic data of the beta(2)AR-Gs complex (f
98 Electron microscopic data revealed that the bundles cons
99 c data with structural mass spectroscopy and
electron microscopic data to derive a detailed, experime
100 interaction using crystallographic and cryo-
electron microscopic data to identify contact points.
101 te mitochondria in serial blockface scanning
electron microscopic data.
102 Autophagy was evaluated using
electron microscopic detection of autophagosomes and by
103 We examined the
electron microscopic dual immunolabeling of M2Rs and the
104 and basolateral amygdala (BLA), we examined
electron microscopic dual immunolabeling of these recept
105 ddressed this question using ROS imaging and
electron microscopic dual labeling for vasopressin and p
106 We therefore comparatively examined
electron microscopic dual labeling of D2R and parvalbumi
107 ral amygdalar nucleus (BLa) of the rat using
electron microscopic dual-labeling immunocytochemistry.
108 Electron microscopic (
EM) and molecular analyses reveal
109 Using automated reconstruction of a volume
electron microscopic (
EM) image of the female brain, we
110 At the
electron microscopic (
EM) level, in cortical layers IV-V
111 and double immunocytochemical methods at the
electron microscopic (
EM) level.
112 ht that myosin VIIA is a dimeric myosin, our
electron microscopic (
EM) observations revealed that ful
113 g, triple immunofluorescent labeling, and 3D
electron microscopic (
EM) reconstruction of rat CA3 pyra
114 BARs) on CA1 pyramidal cells, as assessed by
electron microscopic (
EM) techniques, compared with estr
115 Electron microscopic (
EM) tomography independently showe
116 synaptic assays of exocytosis, together with
electron microscopic estimates of single vesicle capacit
117 Immunohistochemical and
electron microscopic evaluations established that there
118 d upregulation of mitophagy was confirmed by
electron microscopic evidence of increased autophagic va
119 We also report
electron microscopic evidence of previously unidentified
120 Recent biochemical and
electron microscopic evidence suggests that these channe
121 In addition, confocal and scanning
electron microscopic examination demonstrated that chito
122 sly unreported pedigree with PACD, light and
electron microscopic examination of an excised corneal b
123 Electron microscopic examination of isolated tau filamen
124 cussed speculum by scanning and transmission
electron microscopic examination of its ultrastructure,
125 Conventional transmission
electron microscopic examination of murine embryonic fib
126 Electron microscopic examination of primary tissues reve
127 Electron microscopic examination of rat brain sections c
128 Electron microscopic examination of retinas at postnatal
129 the satellite cell was first identified when
electron microscopic examination of skeletal muscle demo
130 n tissue distribution; immunofluorescent and
electron microscopic examination of subcellular localiza
131 Electron microscopic examination revealed severe structu
132 Transmission and scanning
electron microscopic examination reveals the nanofiber n
133 Electron microscopic examination showed that the mutant
134 l organization and structure during scanning
electron microscopic examination, (e) distorted posterio
135 d was studied with high-resolution light and
electron microscopic examination.
136 ted prior to their brains being prepared for
electron microscopic examination.
137 Systematic analysis of
electron microscopic findings reveals clusters of findin
138 rfism syndrome (BADS) was investigated using
electron microscopic,
genetic, and virological studies,
139 sults from the use of expensive Transmission
Electron Microscopic images and Dynamic Light Scattering
140 ible as interruptions in the bilayer in cryo-
electron microscopic images and tomographic reconstructi
141 Electron microscopic images of extended tetrameric struc
142 Electron microscopic images of fly ashes showed a wide r
143 h high precision from single high resolution
electron microscopic images of graphene that show dynami
144 agen fibril diameters obtained from scanning
electron microscopic images of normal rat thoracic aorta
145 morphometric evaluations obtained in static
electron microscopic images of podocyte processes.
146 Electron microscopic images of smMLCK cross-linked to F-
147 Comparisons of single particle
electron microscopic images of the full-length BphP dime
148 stallite size established by diffraction and
electron microscopic images of the material; the crystal
149 Electron microscopic images of the purified particles sh
150 stal structure agree perfectly with previous
electron microscopic images of VWF dimeric bouquets with
151 pressure flow hypothesis was challenged when
electron microscopic images suggested that sieve tubes c
152 ticle reconstruction from negatively stained
electron microscopic images were used to verify the Yfh1
153 lls (SACs) and bipolar cells (BCs) in serial
electron microscopic images with help from EyeWire, an o
154 s were comparable to data reconstructed from
electron microscopic images.
155 w on the revolutionary strategies toward the
electron microscopic imaging of beam-sensitive materials
156 e fact that ultrastructural analyses require
electron microscopic imaging of fixed tissue.
157 ovide material for scanning and transmission
electron microscopic imaging of these magnetic particles
158 Electron microscopic imaging of vps23Delta yeast reveale
159 Electron microscopic imaging revealed the lack of tombus
160 Transmission
electron microscopic imaging shows that LptE can disrupt
161 y at cryogenic temperatures and transmission
electron microscopic imaging techniques to chemically ch
162 Here, we used biochemistry and
electron microscopic imaging to demonstrate that the mul
163 With fluorescence and
electron microscopic imaging we demonstrated massive mov
164 Automated transmission
electron microscopic imaging, molecular tagging, tracing
165 Advances in optical and
electron microscopic imaging, structural biology and mol
166 mulations with protein array experiments and
electron microscopic imaging, to arrive at a structural
167 -ActFP is observed via cellular transmission
electron microscopic imaging.
168 modeling, confocal fluorescence imaging, and
electron microscopic imaging.
169 generated through serial block face scanning
electron microscopic imaging.
170 Previous
electron-microscopic imaging has shown high RNA polymera
171 Combining light and
electron microscopic immunochemistry in the rat spinal t
172 projections gate OPN activity, postembedding
electron microscopic immunochemistry was performed on an
173 To address this question we examined the
electron microscopic immunocytochemical localization of
174 Both synaptosomal uptake studies and
electron microscopic immunocytochemistry demonstrated kn
175 Electron microscopic immunocytochemistry of the rat brai
176 Here, we used
electron microscopic immunocytochemistry to assess direc
177 We employed
electron microscopic immunocytochemistry to evaluate alt
178 Then,
electron microscopic immunocytochemistry was performed t
179 Serial section
electron microscopic immunocytochemistry was then perfor
180 ited surround light responses, and light and
electron microscopic immunocytochemistry, we show in the
181 ions, we performed high-resolution light and
electron microscopic immunocytochemistry.
182 elta subunit localization at pubertal onset,
electron microscopic-
immunocytochemistry (EM-ICC) was em
183 Electron microscopic immunogold data further suggest tha
184 il, Lymnaea stagnalis L., applying light and
electron microscopic immunohistochemistry and biochemica
185 m2 receptor in correlation with synapses by
electron microscopic immunohistochemistry in the mouse t
186 We used light and
electron microscopic immunohistochemistry to demonstrate
187 By using light and
electron microscopic immunohistochemistry, we demonstrat
188 apses from amacrine cells were identified in
electron microscopic immunolabeling experiments.
189 Electron microscopic immunolabeling in the PL-PFC of adu
190 Cell fractionation and
electron-microscopic immunolabeling studies demonstrated
191 the Banff g score correlated with light and
electron microscopic indexes of chronic microvascular da
192 Electron microscopic investigations of Merkel endings an
193 Light and
electron microscopic investigations revealed a structura
194 Confocal laser and
electron microscopic investigations showed that PRiMA im
195 med pharmacological manipulations, light and
electron microscopic investigations to show that, althou
196 nprecedented performance allows expansion of
electron microscopic investigations with atomic resoluti
197 Electron microscopic level analysis of Sox11 RNAi-inject
198 At the
electron microscopic level MGV and MGD terminals are non
199 nvestigation used immunocytochemistry at the
electron microscopic level to determine which structures
200 nt investigation, immunocytochemistry at the
electron microscopic level was used to determine which s
201 At the
electron microscopic level, GluD1-IR was preferentially
202 At the
electron microscopic level, opsin labeling was confined
203 At the
electron microscopic level, SG and V2M terminals 1) are
204 At the
electron microscopic level, striatal A(2A) R labeling wa
205 xpression has yet to be characterized at the
electron microscopic level.
206 lta-1 in DRG neurons, both at the light- and
electron-microscopic level.
207 tribution pattern as determined by light-and
electron-microscopic-
level immunocytochemistry indicates
208 re evident at both the light microscopic and
electron microscopic levels.
209 tex, amygdala and striatum, at the light and
electron microscopic levels.
210 he RegIIIalpha crystal structure into a cryo-
electron microscopic map of the pore complex, and show t
211 n situ small/wide-angle X-ray scattering and
electron microscopic measurements showed that the HNC-SL
212 y crystallographic, NMR, and single-particle
electron microscopic methods from a remarkably diverse a
213 Here, we used light and
electron microscopic methods to examine the GABAergic in
214 tric organ discharge (EOD) and the light and
electron microscopic morphology as the fish mature from
215 using RNA sequencing analysis, quantitative
electron microscopic morphometry, Western blotting, and
216 microscopy of isolated muscle fibers and by
electron microscopic observation of muscle tissue fixed
217 Electron microscopic observation of these territories re
218 Electron microscopic observation revealed endoplasmic re
219 temporal neocortex or perirhinal cortex, and
electron microscopic observations of anterogradely label
220 Light and
electron microscopic observations of the relations betwe
221 Electron microscopic observations revealed septal bouton
222 Scanning electron and transmission
electron microscopic observations showed that the compou
223 Our combined confocal and quantitative
electron-microscopic observations indicated that POR pro
224 Here we report direct
electron-microscopic observations of deposition growth o
225 Here, we present detailed light and
electron microscopic pathology examination of the kidney
226 l RNA sequencing and fluorescence as well as
electron microscopic phenotyping.
227 tive against strong biofilm producers, whose
electron microscopic picture was quite similar to that o
228 Based on this
electron microscopic picture, we propose that the light-
229 Here we present novel
electron microscopic postembedding immunogold data from
230 g immunohistochemical Golgi cell markers and
electron microscopic profiles of granule cells, indicati
231 We examined Dm8 neurons in these circuits by
electron microscopic reconstruction and expansion micros
232 Tet(O)-bound 70S ribosome based on our cryo-
electron microscopic reconstruction at 9.6-A resolution.
233 Serial
electron microscopic reconstruction confirms that LT11 r
234 Our
electron microscopic reconstruction of the anterior phar
235 The 8-A cryo-
electron microscopic reconstruction of the filament reve
236 Site-directed mutagenesis,
electron microscopic reconstruction, and chemical cross-
237 The results of
electron microscopic reconstruction, which are in a good
238 s hypothesis was tested using serial section
electron microscopic reconstructions of thalamocortical
239 We determined three distinct negative-stain
electron microscopic reconstructions of the CS1 pilus an
240 Serial
electron microscopic reconstructions revealed that M5 ce
241 A model based on
electron-microscopic reconstructions of the mouse retina
242 characteristics were achieved using scanning
electron microscopic (
SEM) and Energy Dispersive X-Ray A
243 deformation, which was confirmed by scanning
electron microscopic (
SEM) examination.
244 A scanning
electron microscopic (
SEM) image of the Au NBs revealed
245 cidobacterium thermophilum" and subjected to
electron microscopic,
spectroscopic, and biochemical ana
246 erone) responses were followed together with
electron microscopic stereologic analysis of excitatory
247 Here we use microarray gene profiling and
electron microscopic stereology to reveal lower expressi
248 The cryo-
electron microscopic structure of cMed bound to a core i
249 We present cryo-
electron microscopic structure of full-length human Plex
250 Here, we have determined a cryogenic
electron microscopic structure of Sec13/31 together with
251 The cryo-
electron microscopic structure of the expressome reveals
252 aks within chromatin, we determined the cryo-
electron-microscopic structure of human PARP2-HPF1 bound
253 Here we report cryo-
electron microscopic structures of the helical filaments
254 Here we report cryo-
electron microscopic structures of the human mitochondri
255 Here, we present crystallographic and cryo-
electron microscopic structures of the icosahedral MCPyV
256 We have determined cryo-
electron microscopic structures of the PoTC.RRF complex,
257 Here we present crystallographic and
electron microscopic structures of the SDA complex coupl
258 Here we report two cryo-
electron-microscopic structures of human FACT in complex
259 d myocardium as detected by histological and
electron microscopic studies and an impaired diastolic f
260 Although previous
electron microscopic studies determined some of the post
261 Additionally, dual label light and
electron microscopic studies in select brain areas demon
262 Light and
electron microscopic studies indicate that the inclusion
263 Second, light and
electron microscopic studies indicated that estradiol in
264 Western blot and
electron microscopic studies indicated that repeated soc
265 performed unbiased quantitative morphometric
electron microscopic studies of biopsied kidney samples
266 Electron microscopic studies of hagfish tissues demonstr
267 gold can be used as markers in quantitative
electron microscopic studies of protein distributions in
268 We describe cryo-
electron microscopic studies of the interaction between
269 The high resolution transmission
electron microscopic studies of the nanocomposite reveal
270 ceptors comes from several sources including
electron microscopic studies of the nicotinic acetylchol
271 pharmacobehavioral, electrophysiologic, and
electron microscopic studies on ADF and n-cofilin single
272 Electron microscopic studies performed in mice fed with
273 valent ions and at low temperature, previous
electron microscopic studies showed that ICP8 will form
274 Moreover,
electron microscopic studies showed that Pentobra had ro
275 Furthermore,
electron microscopic studies showed that supernatants de
276 Virus growth was confirmed by detailed
electron microscopic studies that revealed intranuclear
277 iverse original observations with subsequent
electron microscopic studies, and recent work on the sig
278 ands, this review summarizes five decades of
electron microscopic studies.
279 these questions, we undertook an immunogold
electron microscopic study of Tg(PG14) mice.
280 6-7B26/3 turbofan engine were analyzed in an
electron microscopic study, down to the nanoscale, for a
281 od, and is verified by X-ray diffraction and
electron microscopic techniques coupled with density fun
282 Electron microscopic techniques demonstrate that, at ele
283 been investigated using optical and scanning
electron microscopic techniques.
284 g a combination of genetic, biochemical, and
electron microscopic techniques.
285 was identified on cholangiocytes in vitro by
electron microscopic techniques.
286 of the nanoparticles was investigated using
electron microscopic techniques.
287 Our previous transmission
electron microscopic (
TEM) analysis showed that ectopic
288 o prepare Drosophila larvae for transmission
electron microscopic (
TEM) analysis.
289 mic Force Microscopic (AFM) and Transmission
Electron Microscopic (
TEM) images support the presence o
290 through cosettling experiment, transmission
electron microscopic (
TEM) observation, and Derjaguin-La
291 the liquid state of sodium for transmission
electron microscopic (
TEM) observation.
292 hesized nMgO were determined by transmission
electron microscopic (
TEM) studies.
293 well as reciprocal space, using transmission
electron microscopic (
TEM) techniques.
294 combining electrophysiology and transmission
electron microscopic (
TEM) tomography imaging to analyze
295 d Ndc80 and Ska complexes on microtubules by
electron microscopic tomography to identify the structur
296 es, including immuno-electron microscopy and
electron microscopic tomography, demonstrate that these
297 ssion of Runx2 disrupts acini formation, and
electron microscopic ultrastructural analysis revealed t
298 Miller chromatin spreads were used for
electron microscopic visualization of rDNA genes in an s
299 segmentation of mitochondria contained in 3D
electron microscopic volumes generated through serial bl
300 e principal insights obtained from cryogenic
electron microscopic,
X-ray crystallographic, and smFRET