1 out influences from optical gradient forces (
optical trapping).
2 apillary electrophoresis, patch-clamping and
optical trapping.
3 in aqueous solution in a manner analogous to
optical trapping.
4 l structure of molecules complicates magneto-
optical trapping.
5 ing with 1-nm accuracy (FIONA) and dual-beam
optical trapping.
6 , as revealed by atomic force microscopy and
optical trapping.
7 ing dual-labeled gliding filament assays and
optical trapping.
8 oughout the near-infrared region favored for
optical trapping (
790-1064 nm).
9 With the use of
optical trapping,
a single vesicle that had attoliters (
10 Single-molecule
optical trapping allows ClpXP unfolding to be directly v
11 aman scattering from a single vesicle, while
optical trapping allows more than hour-long observations
12 Optical trapping allows noninvasive probing of piconewto
13 nts of various lengths using single-molecule
optical trapping and bulk fluorescence approaches in the
14 g cells, thereby extending cell viability in
optical trapping and cell manipulation applications.
15 Using an in vitro
optical trapping and fluorescence assay, we found that K
16 Optical trapping and levitation allow a particle to be m
17 Optical trapping and levitation also maintain optical al
18 t the single particle level using near-field
optical trapping and light-scattering techniques.
19 Noncontact
optical trapping and manipulation of micrometer- and nan
20 The techniques of
optical trapping and manipulation of neutral particles b
21 his paper describes a method, which combines
optical trapping and microfluidic-based droplet generati
22 hat are arranged by electrodynamic (that is,
optical trapping and optical binding) interactions.
23 ucidates the role of convection in plasmonic
optical trapping and particle assembly, and opens up new
24 Here we demonstrate simultaneous
optical trapping and rotation of a birefringent micropar
25 apable of simultaneous, spatially coincident
optical trapping and single-molecule fluorescence.
26 We use single-molecule
optical trapping and small-angle x-ray scattering, combi
27 We combine
optical trapping and surface-enhanced Raman scattering t
28 We show using single molecule
optical trapping and transient kinetics that the unusual
29 An ultrastable
optical trapping apparatus capable of base pair resoluti
30 Here, we used an automated
optical trapping apparatus in conjunction with a novel m
31 transcription elongation complexes, using an
optical trapping apparatus that allows for the detection
32 Here, by combining ultrastable
optical trapping apparatus with a novel two-bead assay t
33 Using a custom-modified
optical trapping apparatus, we used a tightly focused in
34 chniques currently available, those based on
optical trapping are promising.
35 The tight focus excitation requirements of
optical trapping are well suited to confocal Raman micro
36 rm the reader about recent progress in axial
optical trapping,
as well as the potential for these dev
37 ion, applied load, and temperature, using an
optical trapping assay capable of distinguishing pauses
38 We employ an
optical trapping assay to investigate the behaviors of t
39 We employed an
optical trapping assay to probe the motions of individua
40 ium of a DNA hairpin using a single-molecule
optical trapping assay, in which the unfolded state is c
41 Using a three-bead
optical trapping assay, we recorded NMIIB interactions w
42 With the use of an
optical-trapping assay based on in situ transcription by
43 sphate (ATP) (2-4 muM) was measured using an
optical-trapping assay featuring 1 base-pair (bp) precis
44 We developed an
optical-trapping assay to follow the cotranscriptional f
45 We employed an ultrastable
optical-trapping assay to follow the motion of individua
46 Here, we developed an
optical-trapping assay to monitor the translocation of i
47 Here, we describe a single-molecule
optical-trapping assay to study transcription initiation
48 Here, we used an
optical-trapping assay with high spatiotemporal resoluti
49 recision to the widely used, surface-coupled
optical-trapping assay.
50 the bead rotational fluctuations inherent in
optical trapping assays where beads are used to apply th
51 The most commonly used
optical-trapping assays are coupled to surfaces, yet suc
52 Such enhanced
optical-trapping assays are revealing the fundamental st
53 es, labeling with beads remains critical for
optical-trapping-
based investigations of molecular motor
54 ich are highly sought after in the fields of
optical trapping,
biological sensing and quantum informa
55 We show that
optical trapping can efficiently deform cell-cell interf
56 analyzed individually with a combination of
optical trapping,
capillary electrophoresis separation,
57 We demonstrate that
optical trapping combined with confocal Raman spectrosco
58 Optical-trapping confocal Raman microscopy is developed
59 ly 0.6 microm in size) have been acquired by
optical-trapping confocal Raman microscopy over the 900-
60 we develop an in silico model, supported by
optical trapping data, suggesting that the motors' diffu
61 Here, we report a new class of on-chip
optical trapping devices.
62 The
optical trapping enables capturing of individual bacteri
63 orough characterization of cell viability in
optical trapping environments was performed.
64 Optical trapping experiments indicate that dynein bound
65 Optical trapping experiments reveal details of molecular
66 to perform high-precision and high-bandwidth
optical trapping experiments to study motor regulation i
67 Optical trapping experiments were used to measure direct
68 ) = 6.2 s(-1)) determined in single molecule
optical trapping experiments, indicating that myosin 15-
69 Yet, as in previous
optical trapping experiments, the forces imposed on carg
70 In
optical trapping experiments, we found that increasing t
71 essive by using single molecule motility and
optical trapping experiments.
72 Single-molecule
optical-trapping experiments are now resolving the small
73 gyroscopic directional stabilization and the
optical trapping field.
74 hered microsphere from equilibrium using the
optical trapping force, the tensions of individual stran
75 The nuclei of cells were exposed to
optical trapping forces at various wavelengths, power de
76 ams in these fluids can generate anisotropic
optical trapping forces, even for particles larger than
77 Here by using a DNA-tethered
optical trapping geometry, we find that the force-genera
78 tal advances are complemented by insights in
optical-trapping geometry and single-molecule motility a
79 While
optical trapping has been the most explored method of le
80 e bio-chemical detection, reflective filter,
optical trapping,
hot-electron generation, and heat-assi
81 Optical trapping immobilizes the particle while maintain
82 We describe the exciting advances of using
optical trapping in the field of analytical biotechnolog
83 al calibrations, results in a more versatile
optical trapping instrument that is accurately calibrate
84 We constructed a next-generation
optical trapping instrument to study the motility of sin
85 Using a high-resolution
optical trapping instrument, we directly observed the pr
86 Optical trapping is a powerful manipulation and measurem
87 Plasmon-enhanced
optical trapping is being actively studied to provide ef
88 Optical trapping is potentially a powerful technique in
89 e of processive myosin motors as measured by
optical trapping is similarly uncertain.
90 We propose and demonstrate a new
optical trapping method for single cells that utilizes m
91 Using a modified
optical-trapping method, we examined the group function
92 We report on
optical trapping methodology capable of making precise i
93 in molecules in real time using magnetic and
optical trapping micromanipulation techniques.
94 assay in conjunction with a high-resolution
optical trapping microscope, we have examined the behavi
95 We tested this proposal by comparing
optical trapping motility measurements of cover strand m
96 Here, we use
optical-trapping nanometry to probe the mechanics of enz
97 ere we demonstrate three-dimensional magneto-
optical trapping of a diatomic molecule, strontium monof
98 The energy and forces involved in
optical trapping of lipid vesicles were derived in terms
99 Optical trapping of liposomes is a useful tool for manip
100 Successful
optical trapping of magnetic beads was found to be depen
101 Magneto-
optical trapping of molecules could provide a similarly
102 The results are consistent with the
optical trapping of particles at or near the excitation
103 arming motility assays, video microscopy and
optical trapping of single cells.
104 Optical trapping of single molecules in three-bead assay
105 Optical trapping of small structures is a powerful tool
106 Detection involves the
optical trapping of solitary, fluorescently tagged dsDNA
107 ic device may find potential applications in
optical trapping,
optical data storage and many other re
108 ic field enhancement in the plasmon-assisted
optical trapping process.
109 xciton confinement layer, and a conventional
optical trapping scheme, we show a peak external quantum
110 Single-molecule analysis of myosin by
optical trapping showed a comparable 2-fold reduction in
111 The model reproduces key signatures found in
optical trapping studies of structurally defined complex
112 s work, we improved the spatial precision of
optical trapping studies of transcription to approximate
113 e probability of multiple-motor transport in
optical trapping studies.
114 A new
optical trapping study shows that the stepsize of cytopl
115 We present a single-molecule
optical-trapping study of the interactions of RNAPII wit
116 e present the development of an ultra-stable
optical trapping system with angstrom-level resolution,
117 accuracy is crucial for force calibration of
optical trapping systems.
118 In this study, we established the
optical trapping technique for determining membrane mech
119 A novel
optical trapping technique is described that combines an
120 Here, we use our recently developed
optical trapping technique to characterize the swimming
121 e under tension and torque using the angular
optical trapping technique.
122 Here we employ
optical trapping techniques to investigate the structure
123 anscription elongation using single-molecule
optical trapping techniques.
124 Using single-molecule
optical-trapping techniques, we examined the force-induc
125 Using single molecule
optical-trapping techniques, we found that betaCM has a
126 Here, we use single-molecule
optical trapping to determine the mechanochemistry of tw
127 Here, we used
optical trapping to determine the unitary and ensemble f
128 ngle-molecule gold nanoparticle tracking and
optical trapping to examine the mechanism of coordinatio
129 ce (flow cell) used in conjunction with dual
optical trapping to manipulate DNA dumbbells and to visu
130 Using dual
optical trapping to manipulate DNA, and single-molecule
131 erties of microtubule cross-links we applied
optical trapping to mitotic asters that form in mammalia
132 d confocal Raman microscope is combined with
optical trapping to probe and analyze bacterial spores i
133 We used high-resolution
optical trapping to study individual RecBCD molecules mo
134 cal and ensemble-level experiments involving
optical trapping using a photonic force microscope and p
135 ith a fluorophore at high efficiency, and 3)
optical trapping virometry to measure the number of gp12
136 (CHO) cells was conducted after exposure to
optical trapping wavelengths using Nd:YAG (1064 nm) and
137 Using
optical trapping,
we observed myosin VI stepping against
138 Combined
optical trapping with single-molecule fluorescence imagi
139 Here, we combine
optical trapping with TIRF-based microscopy to measure t
140 s and experimental protocols best suited for
optical trapping work.