ライフサイエンスコーパス: atomic force microscope

1 a protein attached by flexible linkers to an atomic force microscope.

2 ndothelial cells by nanoindentation using an atomic force microscope.

3 graphene membranes by nanoindentation in an atomic force microscope.

4 4.8 by nanoindentation measurements with an atomic force microscope.

5 es by lateral indentation with the tip of an atomic force microscope.

6 indentation experiments carried out with an atomic force microscope.

7 e with a resolution comparable to that of an atomic force microscope.

8 appearance in the micrographs taken with the atomic force microscope.

9 hing single polysaccharide molecules with an atomic force microscope.

10 molecule force clamp adapted for use with an atomic force microscope.

11 the elongation of these molecules using the atomic force microscope.

12 le-molecule force-clamp measurements with an atomic force microscope.

13 rbon nanotubes on graphite surfaces using an atomic force microscope.

14 hment of antibodies is clearly visualized by atomic force microscope.

15 Ku protein to DNA was investigated using the atomic force microscope.

16 position on top of human platelets with the atomic force microscope.

17 in combination with a commercially available atomic force microscope.

18 ofiber is deflected by a cantilever under an atomic force microscope.

19 1) substrate by the tip of a low-temperature atomic force microscope.

20 unted onto the piezoelectric actuators of an atomic force microscope.

21 ed between 80-600 nm, which was confirmed by Atomic Force Microscope.

22 nd nanopillar, which we use as the tip of an atomic force microscope.

23 anotubes (MWNTs) by using manipulation by an atomic-force microscope.

24 silica spheres attached to cantilevers of an atomic-force microscope.

25 y interacting tips of scanning tunnelling or atomic force microscopes.

26 eyond the capabilities of typical commercial atomic force microscopes.

27 Using an atomic force microscope, a molecular mechanistic origin

28 The atomic force microscope, a relatively new tool for inves

29 boxypeptidase Y (CaY) was studied using both atomic force microscope (AFM) and quartz crystal microba

30 A combined atomic force microscope (AFM) and Raman spectrometer is

31 We demonstrate that the Atomic Force Microscope (AFM) can be used to immobilize

32 The tip of an atomic force microscope (AFM) can be used to indent soft

33 The Atomic Force Microscope (AFM) can map the heterogeneous

34 Force spectroscopy using the atomic force microscope (AFM) can yield important inform

35 Spring constant calibration of the atomic force microscope (AFM) cantilever is of fundament

36 s as they were dissociated from Coh using an atomic force microscope (AFM) cantilever.

37 olecules on a surface by using the tip of an atomic force microscope (AFM) coated with the desired mo

38 f PM2.5 airborne pollutants and, by means of atomic force microscope (AFM) combined with other charac

39 viability of molecules investigated with the atomic force microscope (AFM) continue to be limiting fa

40 le describes a new method for site-specific, atomic force microscope (AFM) fabrication of nanowire he

41 The atomic force microscope (AFM) has been used to apply suc

42 Phase imaging with a tapping mode atomic force microscope (AFM) has many advantages for im

43 We successfully applied atomic force microscope (AFM) imaging to visualize galDN

44 s ligands on solid support, was confirmed by atomic force microscope (AFM) imaging.

45 The atomic force microscope (AFM) in its force-measuring mod

46 d pairs have been directly measured with the Atomic Force Microscope (AFM) in several recent experime

47 The atomic force microscope (AFM) is a surface-sensitive ins

48 ween a conical tip and a flat surface in the atomic force microscope (AFM) is examined.

49 The atomic force microscope (AFM) is sensitive to electric d

50 The atomic force microscope (AFM) is widely used in material

51 termined as a function of erosion depth from atomic force microscope (AFM) measurements.

52 nd microtubules, have been measured using an atomic force microscope (AFM) operating in fluid tapping

53 ds based on single- or multiple-probes in an atomic force microscope (AFM) or a scanning electron mic

54 ngle molecule level; ChlD was attached to an atomic force microscope (AFM) probe in two different ori

55 Atomic force microscope (AFM) probe tips are structurall

56 the cytb6f complex using a Pc-functionalized atomic force microscope (AFM) probe to identify the posi

57 Using voltages applied by a conducting atomic force microscope (AFM) probe, the buried LaAlO3/S

58 le sweep of an ink-coated, biased conducting Atomic Force Microscope (AFM) probe-tip, an underlying t

59 ns of an ultrasensitive non-contact pendulum atomic force microscope (AFM) raised hopes that a wider

60 g L-alpha-phosphatidylcholine bilayers using atomic force microscope (AFM) spectroscopy.

61 rmance, we carried out REM-US simulations of atomic force microscope (AFM) stretching and relaxing me

62 -dependent chromatin structure, we performed atomic force microscope (AFM) studies of fibers isolated

63 nylundecanethiol (FcC(11)SH) and a Pt-coated atomic force microscope (AFM) tip have been measured usi

64 An atomic force microscope (AFM) tip is used to write alkan

65 the direct transfer of an ink from a coated atomic force microscope (AFM) tip to a substrate of inte

66 polarizations focused onto a Au nanoparticle atomic force microscope (AFM) tip utilizing a backscatte

67 e multiwalled carbon nanotube attached to an atomic force microscope (AFM) tip was functionalized wit

68 ssembled monolayers (SAMs) with an Au-coated atomic force microscope (AFM) tip.

69 ile systems on a mica surface imaged with an atomic force microscope (AFM) to compile statistics of t

70 We applied atomic force microscope (AFM) to demonstrate directly th

71 We used an atomic force microscope (AFM) to examine the nanomechani

72 One recent experiment used the tip of an atomic force microscope (AFM) to manipulate multi-walled

73 streptavidin-biotin interaction by using the atomic force microscope (AFM) to measure the unbinding d

74 e single molecule force measurements with an atomic force microscope (AFM) to show that E-cadherin, a

75 An atomic force microscope (AFM) was employed to further ex

76 An atomic force microscope (AFM) was modified to detect and

77 The atomic force microscope (AFM) was used to assay the exte

78 An Atomic force microscope (AFM) was used to confirm the hy

79 A combined light fluorescence and atomic force microscope (AFM) was used to image the stru

80 Here, an atomic force microscope (AFM) was used to mechanically i

81 An atomic force microscope (AFM) was used to visualize CWAL

82 edge, for measuring traction forces using an atomic force microscope (AFM) with a cantilever that was

83 es the topographic imaging capability of the atomic force microscope (AFM) with a compositionally pat

84 ve nanomechanical instruments, including the atomic force microscope (AFM)(1-4) and optical and magne

85 riction mapped by directly imaging, with the atomic force microscope (AFM), a mutant EcoRI endonuclea

86 single molecule force spectroscopy using the atomic force microscope (AFM), and explain the two main

87 re characterized by cyclic voltammetry (CV), atomic force microscope (AFM), and X-ray photoelectron s

88 In an atomic force microscope (AFM), the probe tip can provide

89 the pristine membrane was detected using an atomic force microscope (AFM), whereas a repulsive force

90 By applying atomic force microscope (AFM)-based force spectroscopy t

91 We used an atomic force microscope (AFM)-based nanorobotic system t

92 the beta-peptide with the nonpolar tip of an atomic force microscope (AFM).

93 erized by 1% agarose gel electrophoresis and atomic force microscope (AFM).

94 lecular ring over each base in turn using an atomic force microscope (AFM).

95 nm were measured using the cantilever of an atomic force microscope (AFM).

96 rials onto a substrate using the probe of an atomic force microscope (AFM).

97 terol (chol) in a fluid environment using an atomic force microscope (AFM).

98 ucleotide AMP-PNP, have been imaged with the atomic force microscope (AFM).

99 OPG surface were located and imaged with the atomic force microscope (AFM).

100 quasi-static force-distance curves using the atomic force microscope (AFM).

101 a chemically modified graphite surface in an atomic force microscope (AFM).

102 h to be directly imaged in the buffer in the atomic force microscope (AFM, also known as scanning for

103 Studies using atomic force microscopes (AFMs) have shown that mammalia

104 Force spectroscopy using the atomic force microscope allows the behaviour of single p

105 le-molecule force-clamp spectroscopy with an atomic force microscope along with molecular dynamics an

106 ncrease in vesicle height as measured by the atomic force microscope and a similar increase in vesicl

107 s of force with mechanical probes (e.g., the atomic force microscope and biomembrane force probe), P-

108 ed-coil tail fragments were acquired with an atomic force microscope and displayed characteristic tri

109 Recent technical advances, primarily the atomic force microscope and laser tweezers, enable us to

110 multistage entropic spring has been shown in atomic force microscope and optical tweezer experiments

111 the arrival of new technologies, such as the atomic force microscope and related techniques, a new er

112 We have constructed a combined TappingMode atomic force microscope and scanning ion conductance mic

113 ns syntaxin 1A and synaptobrevin 2, using an atomic force microscope and the Jarzynski equality of no

114 od relies on the imaging capabilities of the atomic force microscope and the reduction in size of the

115 terizing the nanoelectrode geometry with the atomic force microscope and using water with a very low

116 are the stretching experiments performed by atomic force microscopes and laser tweezers.

117 Atomic force microscopes and optical tweezers are widely

118 The fibers were stretched with the atomic force microscope, and stress-versus-strain data w

119 k phosphorus is demonstrated with conductive atomic-force-microscope anodic oxidation.

120 Laser tweezers and atomic force microscopes are increasingly used to probe

121 xperiments performed in the fluid cell of an atomic force microscope at room temperature and pH value

122 Atomic force microscope-based phase imaging in air is ca

123 Using scanning tunneling and atomic force microscope break-junction techniques, the c

124 o the glass substrate and to the probe of an atomic force microscope by water-soluble linkers to faci

125 Here, we show that an atomic force microscope can be used to image and three-d

126 The atomic force microscope can detect the mechanical finger

127 e stress gradient generated by the tip of an atomic force microscope can mechanically switch the pola

128 Here we show that an atomic force microscope can obtain a range of surface an

129 chanical forces exerted by laser tweezers or atomic force microscopes can be used to drive rare trans

130 ial equation to describe the dithering of an atomic force microscope cantilever and a single molecule

131 s Strep-Tactin to specifically attach to the atomic force microscope cantilever and form a consistent

132 to a controlled applied force, e.g., via an atomic force microscope cantilever.

133 ls as they spread on a fibronectin-patterned atomic-force microscope cantilever and coverslip.

134 gions inside a protein complex, and T-shaped atomic force microscope cantilevers functionalized with

135 Additionally, active optical feedback of atomic force microscope cantilevers has been used to mod

136 sing functionalized bead arrays assembled on atomic-force-microscope cantilevers.

137 The counter surface was the tip of an atomic force microscope coated with conductive titanium

138 black inside an etched nanocavity under the atomic force microscope control.

139 sion high pressure liquid chromatography and atomic force microscope data.

140 In this report, we systematically analyzed atomic force microscope-derived phase images of mica, gl

141 perature, at the nanometer scale by using an atomic force microscope equipped with a flow-through cel

142 n rate constants were measured in situ by an atomic force microscope equipped with a flow-through cel

143 i myosin II rod domain images collected from atomic force microscope experiments.

144 e consisting of the sharp metallic tip of an atomic force microscope; finite element simulations reve

145 The rupture forces measured by atomic force microscope force spectroscopy also indicate

146 single molecule force spectroscopy using an atomic force microscope has been a useful tool to invest

147 Direct imaging with the atomic force microscope has been used to identify specif

148 The atomic force microscope has enabled us to observe plasma

149 The atomic force microscope has recently been the subject of

150 Using an atomic force microscope high-resolution modulus maps of

151 Taken together, the atomic force microscope images and DNA binding assays pr

152 Atomic force microscope images were concomitantly record

153 inct morphologies in electron microscope and atomic force microscope images, often within a single im

154 This report describes force measurements and atomic force microscope imaging of lipid-protein interac

155 Atomic force microscope imaging showed that the etching

156 tilevers have traditionally found utility in atomic force microscope imaging.

157 hysically mapping large DNA clones by direct atomic force microscope imaging.

158 molecules, we used the cantilever tip of an atomic force microscope in a pulling setup.

159 Using an atomic force microscope in combination with confocal mic

160 voltage pulses when scanned by a conductive atomic force microscope in contact mode.

161 To address this issue, we used the atomic force microscope in force spectroscopy mode to sh

162 We use an atomic force microscope in force-clamp mode to apply mec

163 We use an atomic force microscope in force-clamp mode to apply mec

164 force to single isolated FimH bonds with an atomic force microscope in order to test this directly.

165 We use the atomic force microscope in situ, during the crystallizat

166 e nanofibers were also investigated using an atomic force microscope in tapping mode.

167 bone to recover its toughness as measured by atomic force microscope indentation testing.

168 1 nN) to the N-cadherin-coated beads via an atomic force microscope induced a localized mechanical r

169 Electrons are injected from the tip of an atomic force microscope into a thin film of lead-zircona

170 The atomic force microscope is broadly used to study the mor

171 ensity maps of biological surfaces using the atomic force microscope is presented.

172 Control of this confinement using an atomic force microscope lithography technique enabled us

173 nanoscale resolution, for example, using an atomic force microscope, magnetic tip, or super-resoluti

174 cosidic oxygen atoms O1 and O4 determined by atomic force microscope manipulations is corroborated by

175 Atomic force microscope manipulations of single polysacc

176 Our atomic force microscope measurements indicated that one

177 Atomic force microscope measurements of fusion forces un

178 cell adhesion molecules were determined from atomic force microscope measurements of the forced disso

179 This report describes atomic force microscope measurements of the strengths an

180 this artefact when conical tips are used for atomic force microscope measurements of thin samples.

181 Atomic force microscope measurements were analyzed by la

182 hods that use a quartz crystal microbalance, atomic force microscope, microcantilever, or other tools

183 Using the force sensor of an atomic force microscope, motor forces of the human immun

184 Using a custom-built atomic force microscope, myofibrils were first placed in

185 Using a combined fluorescence/atomic force microscope nanomanipulation system, we stre

186 Here we report in situ atomic force microscope observations and molecular model

187 mples in liquids, obtained with a commercial atomic force microscope operated dynamically with small-

188 acterial cell death using a novel high-speed atomic force microscope optimized for imaging live cells

189 thogens, via external pressure applied by an atomic force microscope, or via cell migration across un

190 at results from the interactions between the atomic force microscope probe and the hydrophobic domain

191 n and visualize these forces, using a chiral atomic force microscope probe coupled to a plasmonic opt

192 on substrates and gold-coated microspherical atomic force microscope probe tips (end radius R approxi

193 We have used a DNA-aptamer tethered to an atomic force microscope probe to carry out recognition i

194 ic tethers to attach biotin molecules to the atomic force microscope probe.

195 contain molecules that, when stretched in an atomic force microscope, produce a force spectrum charac

196 Using an atomic force microscope protocol that quantified single-

197 o the main subjects and the invention of the atomic force microscope provided new ways to manipulate

198 ith experimentally determined values with an atomic force microscope, providing further support to th

199 olynucleotide adsorption are consistent with atomic force microscope results.

200 Goniometry measurements performed with an atomic force microscope reveal that the (001)(YN) plane

201 phosphatidylcholine lipid membranes with the atomic force microscope reveals a repulsive force betwee

202 A combined scanning electrochemical-atomic force microscope (SECM-AFM) has been used to prob

203 he tip of a combined scanning tunnelling and atomic force microscope (STM/AFM) was used to dehydrogen

204 Past atomic force microscope studies of the interaction of th

205 rication tools, both scanning tunnelling and atomic force microscopes suffer from a loading deficienc

206 Using an atomic force microscope, supported bilayers of saturated

207 We used a combined fluorescence/atomic force microscope system to determine that sheets

208 Here we report an atomic force microscope technique that can measure mecha

209 dge gap, we used a combined fluorescence and atomic force microscope technique to determine the stiff

210 Here, using single-molecule atomic-force microscope techniques, we show how the vari

211 orn apart between a quartz-tuning-fork-based atomic force microscope (TF-AFM) and a nanomanipulator,

212 nt coupled to the microcantilever probe from atomic force microscope thus providing reliable micromec

213 amined by measuring the forces arising as an Atomic Force Microscope tip (diameter 20 nm) - simulatin

214 er with coupled leaflets, penetration of the atomic force microscope tip always occurred in a single

215 ering the antibody and MUC1 molecules to the atomic force microscope tip and sample surface with flex

216 gold contact was pressed on by a conducting atomic force microscope tip at constant force.

217 growth using dip-pen nanolithography and an atomic force microscope tip coated with poly-dl-lysine h

218 nd low-frequency (40-240 Hz) dithering of an atomic force microscope tip excited by a sine wave volta

219 aligned NWs are deflected with a conductive atomic force microscope tip in contact mode.

220 cell is formed by bringing a Pt/TiO2-coated atomic force microscope tip into contact with a flat sub

221 e by a local electric field created using an atomic force microscope tip is also demonstrated.

222 We demonstrate this by sliding a conductive-atomic force microscope tip on a thin film of molybdenum

223 llagen-related peptides immobilized onto the atomic force microscope tip showed that the specific int

224 ned by specific attachment of a gold-covered atomic force microscope tip to engineered Cys residues c

225 Here, we use an atomic force microscope tip to reversibly 'sketch' singl

226 -deformation of a nanobelt/nanowire using an atomic force microscope tip under different contact forc

227 Furthermore, by modifying the atomic force microscope tip we developed a method for de

228 zation of membrane proteins by the indenting atomic force microscope tip, consistent with the glycopr

229 local thermal reduction of GO with a heated atomic force microscope tip.

230 l-field enhancement around the region of the atomic force microscope tip.

231 ng crystallization of the thin film using an atomic force microscope tip.

232 Glass micropipettes, atomic force microscope tips and nanoneedles can be used

233 ynuclein molecules at their C-termini at the atomic force microscope tips and substrate surfaces, and

234 Chemical force microscopy performed with atomic force microscope tips decorated with functional g

235 Atomic force microscope tips terminated with spore cells

236 solution of approximately 100 nm by using an atomic force microscope to both redistribute lithium ion

237 Here we use an atomic force microscope to calibrate the distance-depend

238 Here we have used a high bandwidth atomic force microscope to demonstrate that these light-

239 We overcome this problem by using an atomic force microscope to deposit and image in situ the

240 Here we have used the atomic force microscope to directly observe changes in t

241 Here we confirm these predictions using the atomic force microscope to dynamically follow the moveme

242 Using the atomic force microscope to locally probe the cell membra

243 We use a feedback-controlled atomic force microscope to measure and modulate forces a

244 We used an atomic force microscope to measure changes in the mechan

245 We used an atomic force microscope to measure force distance curves

246 Herein, we use an atomic force microscope to measure the length of gold na

247 We used an atomic force microscope to measure the vertical and late

248 In this work, we used the atomic force microscope to perform single-molecule force

249 Using a modified atomic force microscope to probe dendritic actin network

250 We use a modified conducting atomic force microscope to simultaneously probe the cond

251 We have used an atomic force microscope to study the mechanical properti

252 formed nano-indentation experiments using an atomic force microscope to track capsid swelling and mea

253 opographic and recognition (TREC) mode of an atomic force microscope to visualize UCP1 reconstituted

254 Adhesive forces measured with an atomic force microscope under ambient conditions are gen

255 The atomic force microscope uses a force-sensing cantilever

256 An atomic force microscope was used to image the structure

257 An atomic force microscope was used to study single-electro

258 nd immunity protein 9 (Im9) complex using an atomic force microscope we show that application of low

259 Using the atomic force microscope, we have been able to image and

260 ty; by compressing a DNA tetrahedron with an atomic force microscope, we have measured the axial comp

261 Using an atomic force microscope, we have studied three-dimension

262 lls to dynamic stiffness conditions using an atomic force microscope, we observe a seconds-timescale

263 the wear volume in atomistic simulations and atomic force microscope wear experiments.

264 The surface forces apparatus and atomic force microscope were used to study the effects o

265 ess three problems that limit the use of the atomic force microscope when measuring elastic moduli of

266 A novel atomic force microscope with a magnetically oscillated t

267 of individual antibodies was imaged using an atomic force microscope with a probe modified with lecti

268 the surfaces of the probe and sample of the atomic force microscope with flexible polymer tethers, a

269 e that integrates a custom-built, horizontal atomic force microscope with micropipette manipulation.

270 dly through large angles using the tip of an atomic force microscope, without undergoing catastrophic