ライフサイエンスコーパス: single molecule imaging

1 ear x-ray optics and high field physics, and single molecule imaging.

2 ral organization of EqtII in living cells by single molecule imaging.

3 es both challenges and dramatically improves single-molecule imaging.

4 r unamplified nucleic acids that is based on single-molecule imaging.

5 from routine gel electrophoresis to advanced single-molecule imaging.

6 by cosedimentation, electron microscopy, and single-molecule imaging.

7 ques and access to a microscope equipped for single-molecule imaging.

8 ecovery after photobleaching experiments and single-molecule imaging.

9 Single-molecule imaging analysis shows that cholesterol

10 lastically coupled reactions is proposed for single molecule imaging and rotor manipulation experimen

11 e of ~100 mum are essential for simultaneous single molecule imaging and single ion-channel electrica

12 We address this issue by single molecule imaging and tracking in fibroblast peric

13 Here we present a single-molecule imaging and analysis platform using scie

14 DNA by integrating fluorescence measurement, single-molecule imaging and computational modeling.

15 Combining single-molecule imaging and deep sequencing, we show tha

16 single-cell sequencing data, as well as from single-molecule imaging and electron micrographs of fixe

17 ecules by the dye YOYO-1 using complementary single-molecule imaging and gel electrophoresis-based da

18 Single-molecule imaging and manipulation of biochemical

19 ly well suited for applications in live-cell single-molecule imaging and multiplexed cellular labelin

20 ange of localization applications, including single-molecule imaging and particle tracking, in fields

21 Recently, single-molecule imaging and photocontrol have enabled su

22 such heterogeneity, we used a combination of single-molecule imaging and reversed-phase liquid chroma

23 e and a combination of techniques, including single-molecule imaging and single-particle electron mic

24 is hand-in-hand with the new development of single-molecule imaging and spectroscopic technology and

25 For this study, we used single-molecule imaging and ssDNA curtains to examine th

26 chers need to have substantial experience in single-molecule imaging and statistical analysis to cond

27 , we present a method combining high-density single-molecule imaging and statistical inference to sep

28 We used single-molecule imaging and stepwise photobleaching in X

29 d photostability, phototoxicity in live-cell single-molecule imaging, and use of new labels for nanos

30 cribe new approaches of subunit labeling for single-molecule imaging, applied to determine the TERT c

31 We have developed a single-molecule imaging approach for investigating the f

32 orescence in situ hybridization (MERFISH), a single-molecule imaging approach that allows the copy nu

33 discussion is given on the extension of the single-molecule imaging approach to catalysis that does

34 We use a single-molecule imaging approach to visualize the intera

35 Single molecule imaging approaches like dSTORM and PALM

36 more recently developed single-filament and single-molecule imaging approaches.

37 Here, we describe a single-molecule imaging assay that 1) utilizes compariso

38 index can act as lenses that are capable of single-molecule imaging at 70 degrees C when placed in i

39 ing monomer pool to achieve fast, continuous single-molecule imaging at optimal densities with signal

40 Using a combination of single-molecule imaging, biochemistry and electrophysiol

41 used three-dimensional electron microscopy, single-molecule imaging, biochemistry, and in vivo assay

42 Here, we use single molecule imaging by atomic force microscopy (AFM)

43 Single-molecule imaging by means of atomic force microsc

44 We demonstrated two-color single-molecule imaging by observing the spatiotemporal

45 are applied for the first time to high-speed single-molecule imaging by tracking their lateral mobili

46 Our real-time single-molecule imaging data demonstrate that TFIID alon

47 several techniques (polarization microscopy, single-molecule imaging, emission time dependence, energ

48 We have established a single-molecule imaging experimental platform called "DN

49 The number of reports per year on single-molecule imaging experiments has grown roughly ex

50 Single-molecule imaging experiments have shed new light

51 e relevant for the interpretation of in vivo single-molecule imaging experiments, bacterial photosynt

52 suggesting that UCNPs are ideally suited for single-molecule imaging experiments.

53 The development of probes for single-molecule imaging has dramatically facilitated the

54 tobleach recovery, fluorescence correlation, single-molecule imaging) have been adapted to measure mo

55 Our technology thus paves the way toward single molecule imaging in cells and living animals, all

56 Most assays and single molecule imaging in live hippocampal neurons reve

57 us, by combining direct genetic labeling and single molecule imaging in vivo, our work establishes an

58 Here, we use single-molecule imaging in a vertebrate cell-free extrac

59 ce light-sheet microscopy to perform in vivo single-molecule imaging in early Drosophila melanogaster

60 Single-molecule imaging in live cells has illuminated th

61 Using single-molecule imaging in live cells, we directly visua

62 ng and unbinding events in space and time by single-molecule imaging in live primary T cells for a ra

63 It can also be used for single-molecule imaging in the presence of high concentr

64 Single-molecule imaging in this thick polysaccharide mat

65 Using three-color single-molecule imaging in vitro we revealed how the dyn

66 Single-molecule imaging is used for the first time to st

67 dies emphasize the importance of controls in single-molecule imaging measurements, and indicate that

68 We report a high-resolution, single-molecule imaging method to probe CI-mediated DNA

69 Using single cell and single molecule imaging methods (fluorescence resonance

70 ments of complex stoichiometry than existing single-molecule imaging methods.

71 Using single molecule imaging of a fluorescent phospholipid, t

72 onjugation to streptavidin for high-affinity single molecule imaging of biotinylated receptors on liv

73 Single molecule imaging of eGFP-PspA and its amphipathic

74 Single molecule imaging of motility in cell extracts dem

75 Moreover, single-molecule imaging of a Cy3-labeled agonist, [Lys(7

76 tly visualized in dendrites and spines using single-molecule imaging of a diffusion-restricted Venus-

77 Single-molecule imaging of biological macromolecules has

78 We carried out single-molecule imaging of CHD4 in live mouse embryonic

79 Single-molecule imaging of endosomal trafficking will si

80 Single-molecule imaging of fluorescently labeled biomole

81 In sum, real-time single-molecule imaging of fluorescently labeled Ebola V

82 Moreover, single-molecule imaging of green fluorescent protein (GF

83 g currently available XFELs and suggest that single-molecule imaging of individual biomolecules could

84 Here, we report single-molecule imaging of nascent peptides (SINAPS) to

85 lso compares favorably to what we measure by single-molecule imaging of nonspecifically bound fluores

86 chnology has wide applications for real-time single-molecule imaging of protein-nucleic acid interact

87 Using live-cell confocal and single-molecule imaging of rat hippocampal neurons cultu

88 Quantitative single-molecule imaging of receptor assembly in the plas

89 y; 2) far-Western blotting; and 3) live cell single-molecule imaging of SH2 membrane recruitment.

90 so demonstrate the possibility of dual-color single-molecule imaging of SNAP-tag fusion proteins.

91 selection of optimal dyes and conditions for single-molecule imaging of SNAP-tagged fusion proteins i

92 Single-molecule imaging of translation in individual gra

93 such as UCNPs with exceptional brightness at single molecule imaging powers.

94 specific adsorption on the interpretation of single-molecule imaging results.

95 Single-molecule imaging revealed that unlike WASP/N-WASP

96 Single molecule imaging reveals that motors pause and fr

97 Single-molecule imaging reveals that signaling is initia

98 Solution assays and single-molecule imaging show that CAH3 binds CP already

99 Single-molecule imaging shows that this step lowers tran

100 l/noise in other techniques such as in vitro single-molecule imaging, stochastic optical reconstructi

101 (CaHydA), we now report electrochemical and single-molecule imaging studies carried out on a catalyt

102 of time-dependent conformation, all previous single-molecule imaging studies of polymer transport inv

103 Using a high-throughput single molecule imaging system and Lagrangian coordinate

104 bound to a glass surface and detected with a single-molecule imaging system.

105 A high-speed high-throughput single-molecule imaging technique for identifying molecu

106 These results suggest that the single-molecule imaging technique provides a powerful to

107 We have developed a single-molecule imaging technique that uses quantum-dot-

108 vity were measured using bulk solution and a single-molecule imaging technique to investigate the oli

109 In the present study, we have used single molecule imaging techniques to demonstrate that T

110 In this work, we use single-molecule imaging techniques to examine the initia

111 MERFISH extends single-molecule imaging techniques to profile the copy n

112 Here, we report the use of single-molecule imaging techniques to study the interact

113 a better exploitation of currently available single-molecule imaging techniques, provides an avenue t

114 Using single-molecule imaging techniques, we provide evidence

115 Here we present an ultrasensitive single-molecule imaging technology capable of detecting

116 Using in vitro single-molecule imaging technology, we directly observed

117 wards the ultimate goal of atomic resolution single-molecule imaging that is a prominent justificatio

118 We used single molecule imaging to measure tubulin turnover in s

119 e employ genetics, cell lineage tracing, and single molecule imaging to show that mutations in lin-22

120 Here we use single-molecule imaging to count the number of RNA molec

121 We applied high-throughput single-molecule imaging to decode combinatorial modifica

122 We used single-molecule imaging to demonstrate that Saccharomyce

123 We use single-molecule imaging to detect individual damage site

124 Here, we use real-time single-molecule imaging to determine how the ATP-depende

125 Here, we use single-molecule imaging to directly visualize Saccharomy

126 To elucidate this coordination, we used single-molecule imaging to follow the behaviours of the

127 ral mechanistic question, this study employs single-molecule imaging to investigate PI3K activation i

128 Here we used single-molecule imaging to investigate the effects of te

129 To address this discrepancy, we applied single-molecule imaging to locate and track type 1 IP3Rs

130 facilitated dissociation (FD), we have used single-molecule imaging to measure dissociation kinetics

131 approach is presented for the application of single-molecule imaging to membrane receptors through th

132 tal internal reflection (TIR) microscopy and single-molecule imaging to monitor interactions between

133 Ticau et al. use single-molecule imaging to reveal how ORC, Cdc6, and Cdt

134 Here, we used single-molecule imaging to show that cohesin can diffuse

135 We used single-molecule imaging to track quantum dot-labeled P2X

136 Here, we use CRISPR genome editing and single-molecule imaging to track telomerase trafficking

137 Here, we use single-molecule imaging to visualize Cascade and Cas3 bi

138 locases act in crowded environments, we used single-molecule imaging to visualize FtsK in real time a

139 Here, we use single-molecule imaging to visualize Rad51 as it aligns

140 Here, we use single-molecule imaging to visualize the interplay betwe

141 We use single-molecule imaging to visualize the movement of ind

142 Here we have used multiple single molecule imaging tools to determine that the prot

143 Here, we combine in vivo and in vitro single-molecule imaging, transcription factor (TF) mutag

144 However, using single-molecule imaging we find that CTCF binds chromati

145 Using two-colour, single-molecule imaging we visualize interactions betwee

146 To achieve a signal/noise ratio conducive to single-molecule imaging, we adapted reflected light-shee

147 Using single-molecule imaging, we found that bacterial RecA an

148 Here, using single-molecule imaging, we measured the spatial distrib

149 imple coculture experimental model and using single-molecule imaging, we provide quantitative data sh

150 Using single-molecule imaging, we show that TubRC complexes we

151 Using microfluidics with single-molecule imaging, we simultaneously monitored rev

152 e we demonstrate the concept of submolecular single-molecule imaging with DNA chains assembled from D

153 Here we used single-molecule imaging with simultaneous whole-cell vol