ライフサイエンスコーパス: compressive

1 Our compressive algorithms will speed-up many tasks, such as

2 fall from considerable height that produced compressive and hinge (greenstick) fractures in multiple

3 The films showed in-plane compressive and out-of-plane tensile strains.

4 ring the pancreaticojejunostomy, creation of compressive and shear forces during suture placement and

5 arvesting ambient mechanical energy via both compressive and stretching modes.

6 n their localization, MAPs may be exposed to compressive and tensile forces.

7 t-in safety mechanism for ensuring that both compressive and tensile loads are managed well.

8 oidal gels are able to withstand substantial compressive and tensile loads, and exhibit a remarkable

9 rom wurtzite and NiAs structure, by applying compressive and tensile strain along the symmetry axis,

10 bmicron distributions of displacements, with compressive and tensile strain patterns approaching a fi

11 Wavy structure, of which compressive and tensile strain periodically varied along

12 Our findings on the self-tuning of the compressive and tensile strained domain ratio along the

13 A model of coexistent compressive and tensile strained domains is proposed to

14 t is further improved by 890% and 940% under compressive and tensile strains, respectively.

15 ographic directions ([110] and [-110]) under compressive and tensile strains.

16 durable as bare steel and highly tolerant to compressive and tensile stresses due to chemical bonding

17 Myosin motors generate both compressive and tensile stresses on F-actin and conseque

18 filament models and evaluate the effects of compressive and twisting loads on strain energy distribu

19 We find that this compressive approach performs as well as other compressi

20 uate the effect of shell stiffness and Tg on compressive behavior and compression set in siloxane mat

21 We study the uniaxial compressive behavior of disordered colloidal free-standi

22 he mycelium which reproduces the tensile and compressive behavior of the material.

23 ures, electrical, and magnetic properties of compressive BiFeO3 films under electric-field and pressu

24 eld-induced strain up 10% is achieved in the compressive BiFeO3 films.

25 f helical microcoils formed by deterministic compressive buckling establish the basis for systems tha

26 Paradoxically, such local compressive buckling should not occur given the tensile

27 o/nanostructures into extended 3D layouts by compressive buckling.

28 ion in confined spaces, we conducted dynamic compressive cycle tests on living animals.

29 hanical properties after more than 1 x 10(6) compressive cycles, and its original shape can be recove

30 Distally, compressive deformation of intramyocardial blood vessels

31 wn to be very brittle and can sustain little compressive deformation.

32 Given the prevalence of compressive deformations in most blunt head trauma, this

33 The cell-cell force can be either tensile or compressive depending on the cell-microenvironment inter

34 The developed compressive device is also useful for studying a variety

35 conversion of compressive displacements to torsional ones, was also pr

36 el shows that interfacial viscous forces and compressive dissipation in nanoconfined water can decrea

37 deduced from the percolation theory that the compressive ductility, ec, can reach the maximum value a

38 polarization characterizing the AP, altering compressive electrostatic forces across the membrane.

39 significantly increased sheet thickness and compressive equilibrium modulus, and enabled more unifor

40 local curvature is introduced to assess the compressive failure load of human femur with simulated l

41 ate compressive strengths (over 2 GPa), high compressive failure strain (over 20%), and superior micr

42 damage process, we build a formal analogy of compressive failure with the depinning transition of an

43 Here we focus on compressive failure, which concerns a wide range of geop

44 e eutectic varying from 25 to 40% exhibiting compressive flow strengths ranging from 500 to 900 MPa h

45 Mechanistic primary outcomes: knee joint compressive force and plasma IL-6 levels; secondary clin

46 A compressive force introduced by a ramp/flat fault was su

47 tions confirm that a biologically attainable compressive force of 25 pN sustains the toroid and yield

48 -ray diffraction the consequence of applying compressive force on a stack of membranes against the hy

49 which base-pairing interactions generated a compressive force on sub-persistence length segments of

50 he diet group had greater reductions in knee compressive force than those in the exercise group.

51 hile compression wood of gymnosperms creates compressive force to push stems upward.

52 erent types of mechanical stimuli, including compressive force, tensile force, and shear force as wel

53 of an endothelial cell subjected to a local, compressive force.

54 h its (in)elastic mechanical response to the compressive force.

55 s in cells under varying levels of shear and compressive force.

56 rod-like shapes in several generations after compressive forces are removed.

57 he mechanotransduction channels are gated by compressive forces conveyed via two rows of microtubules

58 the migrating border cell cluster to resist compressive forces from nurse cells.

59 d breakage in isolated small molecules using compressive forces may present opportunities for the dev

60 t tube and mesentery, thereby regulating the compressive forces that buckle the gut tube into loops.

61 Here, we demonstrate that by applying compressive forces to growing E. coli, cells no longer r

62 discrepancy in cell response between direct compressive forces using AFM and those within flow field

63 After 18 months, knee compressive forces were lower in diet participants (mean

64 on have largely been performed under applied compressive forces, but such studies are poor predictors

65 ed cell death provides an outlet for lateral compressive forces, thereby promoting vertical mechanica

66 hich allows MT filaments to bear much larger compressive forces.

67 deformation and fragmentation in response to compressive forces.

68 slender morphology and must elongate against compressive forces.

69 and display adaptive behavior in response to compressive forces.

70 can reinforce actin networks in response to compressive forces.

71 ither pharmacological or physical removal of compressive forces.

72 ximum compression, with linearization of the compressive function for input sound levels between 50 a

73 ave metamaterial aperture is used to perform compressive image reconstruction at 10 frames per second

74 By leveraging metamaterials and compressive imaging, a low-profile aperture capable of m

75 provide a 'speed limit' constraint on major compressive impacts that is inconsistent with recent mod

76 how that the lithiation is suppressed by the compressive interfacial strain.

77 Buckling events, which occur due to compressive intracellular forces and cross-talk between

78 ymerized actin does not actively support the compressive load, it is required for sodium efflux.

79 ABSTRACT: Massage, in the form of cyclic compressive loading (CCL), is associated with multiple h

80 ttle bulk amorphous alloy by simple uniaxial compressive loading at room temperature.

81 nucleation of ripples under both tensile and compressive loading conditions.

82 enhanced with massage in the form of cyclic compressive loading during regrowth after atrophy.

83 the hypothesis that TRPV4 transduces dynamic compressive loading in articular chondrocytes.

84 Massage in the form of cyclic compressive loading is a potential anabolic intervention

85 a bulk metallic glass matrix subjected to a compressive loading-unloading cycle.

86 over the traditional helicoidal design under compressive loading.

87 radiographs with as little as 100 N of axial compressive loading.

88 erability for strains up to 20% under normal compressive loading.

89 g on responses of these complex solids under compressive loads and kinetic impact experiments.

90 toskeletal filaments do not actively support compressive loads in breast, ovarian, and prostate cance

91 ract in transverse directions under uniaxial compressive loads leading to auxeticity.

92 racellular MTs carry a large fraction of the compressive loads sensed by the cell and therefore, like

93 t) enhances matrix synthesis and tensile and compressive mechanical properties.

94 arious gold architectures are formed through compressive mesoscale coalescences of spherical gold nan

95 Our results suggest new compressive modalities as a foundation for massive scali

96 er 100%, tensile stiffness by over 300%, and compressive moduli by over 140%, compared with High dens

97 he anteroposterior direction, both shear and compressive moduli experienced a significant decrease fr

98 Generally, the compressive moduli increased, the time to gelation decre

99 density of the beads to 1.3g/cm(3) and the compressive modulus by two orders of magnitude, they rem

100 o steady state, while the posterior region's compressive modulus decreased approximately 5%, and no s

101 The constructs showed a compressive modulus of 499.18 +/- 86.45 kPa.

102 The compressive modulus of the cartilage-hydrogel constructs

103 stable, and by switching between states, the compressive modulus of the overall structure can be rati

104 perimental evidence that supports a role for compressive motion and the additional insight gained fro

105 ce is the direct demonstration of a role for compressive motions and the ability to understand in ato

106 ns invoking a role for fast 'promoting' (or 'compressive') motions that, in principle, can aid hydrog

107 d adults under attentional load shows strong compressive nonlinearities, thought to reflect intrinsic

108 a significant role in the amplification and compressive nonlinearity of the cochlea.

109 Compressive nonlinearity, harmonic distortion, and DC sh

110 onsisting of spatial summation followed by a compressive nonlinearity, this model accurately predicts

111 mputations: temporal summation followed by a compressive nonlinearity.

112 operations: temporal summation followed by a compressive nonlinearity.

113 t-in strains ranging from 1% tensile to 0.2% compressive on substrates with different thermal coeffic

114 In our study, isquemic and compressive optic neuropathies were the ones that most o

115 gnoses were ischemic optic neuropathy (25%), compressive optic neuropathy (18.7%) and hereditary opti

116 ed on axial scans, was equally predictive of compressive optic neuropathy as the more involved volume

117 Patients with compressive optic neuropathy at the time of presentation

118 At an average of 3.2 years follow-up, compressive optic neuropathy had developed in 17% (25/14

119 the most important quantifiable predictor of compressive optic neuropathy in patients with optic neur

120 nificant volumetric univariate predictors of compressive optic neuropathy included medial rectus volu

121 Compressive optic neuropathy is associated with signific

122 The rate of compressive optic neuropathy was significantly lower and

123 t disease progression and the development of compressive optic neuropathy.

124 imary outcome measure was the development of compressive optic neuropathy.

125 multaneously enrich or deplete either in the compressive or in the tensile strain fields around the d

126 h exhibit reversible resistance changes upon compressive or tensile deflections.

127 can be precisely controlled to induce either compressive or tensile strain on supported catalysts.

128 the microcantilever bends due to the induced compressive or tensile stresses, which result from the s

129 is easily applied, and gives improvements in compressive plasticity.

130 The treatment restores the inferior compressive properties of osteoarthritic cartilage to th

131 eased type I/II collagen ratio, and enhanced compressive properties.

132 the astral microtubules buckle as they exert compressive, pushing forces.

133 The rupture turned twice into the compressive quadrant, against the preferred branching di

134 t alternating direction method algorithm for compressive quantum state estimation that can handle bot

135 microdamage occurred in both the tensile and compressive regions.

136 The compressive, rheological, and degradation properties of

137 In saliency-based compressive sampling (CS) for remote sensing image signa

138 , through a tinted screen, whilst performing compressive sampling and recovering high-resolution deta

139 Furthermore, by using a compressive sampling strategy, we demonstrate continuous

140 Weber's law can be explained either by a compressive scaling of sensory response with stimulus ma

141 Compressive sensing (CS) is a technique to sample a spar

142 Compressive sensing (CS) theory demonstrates that by usi

143 ial way to improve the imaging speed is with compressive sensing (CS), a technique that allows for a

144 Compressive sensing allows signals to be efficiently cap

145 range of quantum states, thus demonstrating compressive sensing as an effective technique for measur

146 For any node, compressive sensing enables accurate reconstruction of t

147 nt developments in sparse approximations and compressive sensing have demonstrated that useful inform

148 This paper presents an implementation of compressive sensing in fluorescence microscopy and its a

149 bust state reconstruction algorithm based on compressive sensing is developed.

150 ctronic structure and the recently developed compressive sensing lattice dynamics (CSLD).

151 mpressive approach performs as well as other compressive sensing techniques with greatly simplified p

152 Using a modified version of compressive sensing that incorporates the principles of

153 Compressive sensing, a procedure for solving inverse pro

154 h advanced undersampling techniques, such as compressive sensing, we can acquire information at rates

155 By exploiting acoustic metamaterials and compressive sensing, we present here a single-sensor lis

156 a method for network reconstruction based on compressive sensing, which takes advantage of the networ

157 ue motivated from the mathematical theory of compressive sensing.

158 We constructed a compressive-sensing approach to pseudo-randomly acquire

159 We develop a completely data-driven, compressive-sensing based method to address this issue b

160 sation could largely be accounted for by the compressive shape of the modulation input-output functio

161 of wurtzite CdSe cores, producing asymmetric compressive shells that create built-in biaxial strain,

162 (SRM) shows great potential in an ultrafast compressive single pixel camera.

163 Elevated compressive solid stress in the interior of the tumor is

164 lls modulate their tonicity to survive under compressive solid stress.

165 the second stage involves novel computations-compressive spatial summation (a form of normalization)

166 ation directly parallels earlier findings of compressive spatial summation in visual cortex describin

167 plex geometrical structures, with an average compressive stiffness of O(1) kPa (0.49 +/- 0.04 kPa str

168 alone, fibrin gels engineered with increased compressive stiffness simultaneously increased the osteo

169 An ultrafast release of the compressive strain along the surface-normal direction is

170 in a barrier height increase with increasing compressive strain and decrease with increasing tensile

171 Tc is enhanced due to the nanoscale compressive strain and proximity effect, whereas Jc is d

172 mesocrystal experiences higher out-of-plane compressive strain and shows a stronger magnetic anisotr

173 ory shows that up to [Formula: see text]3.5% compressive strain can be induced in an InSb quantum wel

174 Compressive strain can turn the trivial monolayer into a

175 Uniquely, we found that compressive strain could significantly enhance both reac

176 Here we investigate tensile and compressive strain effects on the WF of rubrene single c

177 ed ORR activity can be explained by means of compressive strain effects.

178 lemental platinum results exclusively from a compressive strain exerted on the platinum surface atoms

179 ti-year-long accelerated aging studies under compressive strain followed by a time-temperature-superp

180 arity applied across the substrate generates compressive strain in a nanomagnet and switches its magn

181 uted to the severely distorted structure and compressive strain in the LDH nanosheets, which signific

182 The piezo-phototronic effect under compressive strain increases the internal electric field

183 n of hydrogen evolution, which occurs due to compressive strain induced by the formation of a CuAg su

184 HOR activity of Pt/CuNWs likely by providing compressive strain on Pt; surface Cu further aids in hyd

185 sites arising from the ligand effect and the compressive strain on the Pd surface owing to the smalle

186 but it becomes more favourable under a small compressive strain or at high temperatures.

187 In contrast, increasing compressive strain over time shows a greater role for vi

188 l motion driven by electric field, while the compressive strain results in the opposite behaviors.

189 tensile strain side, Ge, Si, and GaP on the compressive strain side.

190 ffect can be introduced by applying a -0.45% compressive strain to greatly enhance the PD's response

191 In contrast, films that are under a large compressive strain typically remain metallic at all temp

192 mission through the PC, predicting decreased compressive strain with proximity to the receptor's core

193 of O(1) kPa (0.49 +/- 0.04 kPa stress at 30% compressive strain) and therefore mimics the mechanical

194 and exhibit supercompressibility (up to 90% compressive strain).

195 r compounds, under a broad range of in-plane compressive strain, could be materials in nature realizi

196 energy shows that the scaling of the energy, compressive strain, shear strain, system size, pressure,

197 30 mW cm(-2) UV illumination and at a -0.45% compressive strain, the PD's photocurrent is dramaticall

198 and Pd, finite size effects introduce local compressive strain, which alters the chemisorption prope

199 ns, which reveal regions of both tensile and compressive strain.

200 ers evolve into a corrugated structure under compressive strain.

201 tough hydrogels capable of withstanding >90% compressive strain.

202 dges for cation migration, are stabilized by compressive strain.

203 n optimized structure can sustain beyond 50% compressive strain.

204 up to 117 MHz in a blue LED chip under 0.14% compressive strain.

205 reases) significantly with in-plane tensile (compressive) strain, which agrees qualitatively with den

206 No-bonding outcomes (i) during the uniaxial compressive straining of films (a near-hydrostatic setti

207 strate that alternating in-plane tensile and compressive strains (less than 0.01%) can be used to pro

208 al mitral annular segment, all rings induced compressive strains along the entire annulus, with great

209 is inferred that TAI in CC may be related to compressive strains and that in Py may be related to ten

210 with conductive interface, whereas in-plane compressive strains extended deeper within the substrate

211 ease in response to physiologically relevant compressive strains in a 3-dimensional chondrocyte cultu

212 y rings (COS, RSA, PHY, ETL, and GEO) induce compressive strains that are predominate in the lateral

213 onductance is increased by 165% under -1.78% compressive strains, and reduced by 48% under 1.78% tens

214 type magnetic orderings are observed at high compressive strains, suggesting that it may be possible

215 f LED array is enhanced by 120% under -0.05% compressive strains.

216 nsile strains while others were dominated by compressive strains.

217 ductivity within a wide range of tensile and compressive strains.

218 ahedra exclude hydrogen from regions of high compressive strains.

219 In this study development of a high compressive strength (~13 MPa hydrated state) polymeric

220 The optimum compressive strength and fracture toughness reached 48.6

221 The quantitative mechanical data (brittle compressive strength and friction coefficient) obtained

222 t the critical point itself cerium lacks any compressive strength but offers resistance to shear.

223 recipitation and, thus, the influence on the compressive strength development of the waste material.

224 heir failure to address critical issues like compressive strength for load-bearing bone grafts.

225 to 56 days showed a significant increase in compressive strength greater than 50%.

226 The results of compressive strength in mortars made up to 56 days showe

227 xide derivative with exceptional and tunable compressive strength is reported.

228 These structures achieve a compressive strength that is 10 times higher than the yi

229 cant plastic deformation with a reduction in compressive strength when they are subjected to cyclic s

230 allows for an increase of density as well as compressive strength while reducing the compressibility

231 ) is valorized to produce compacts with high compressive strength without the use of a hydraulic bind

232 great axial strength, they have weak radial compressive strength, and do not bond well to one anothe

233 nt in a compact fiber composite with tunable compressive strength, surface roughness, and porosity ba

234 ascals, equivalent to >2 megapascal uniaxial compressive strength.

235 ply of structural components to increase its compressive strength.

236 posites (MINCs), which exhibit high ultimate compressive strengths (over 2 GPa), high compressive fai

237 ociated cation produces materials of various compressive strengths and elasticity.

238 imate tensile strains of approximately 325%, compressive strengths of approximately 26 MPa, and fract

239 other transition metal borides, and ultimate compressive strengths up to 1940 +/- 103 MPa were measur

240 resented artificial cellular materials reach compressive strengths up to 280 MPa with densities well

241 teoblasts and MC3T3-E1 cells were exposed to compressive stress (0, 1, 2, 3, 4, and 5 g/cm(2)) in 3D

242 Our results suggest that compressive stress accumulated during tumor growth can e

243 similar, and that vimentin protects against compressive stress and preserves mechanical integrity by

244 d, where the steeply down-dip orientation of compressive stress axes at approximately 600 km arises f

245 s in subduction zones finds that the maximum compressive stress axis plunges systematically trenchwar

246 At compressive stress below 2 GPa, relatively small amounts

247 On timescales of minutes, we show that a compressive stress causes a reduction of the MCS volume,

248 technique so that the creation of shear and compressive stress could be minimized.

249 tween the ends of myofilaments, resulting in compressive stress exerted to single actin filaments, ca

250 On the other hand, the compressive stress generated by the cells at the onset o

251 e inhibited Poisson contraction results in a compressive stress in the direction transverse to the te

252 visiae We used this system to determine that compressive stress is partly sensed through a module con

253 liquid interface culture were subjected to a compressive stress of 30 cm H(2)O; this is comparable to

254 mined the effect of multiple applications of compressive stress on both mechanophore activity and the

255 iomechanical sequence caused by a controlled compressive stress on multicellular spheroids (MCSs) use

256 rs are under tension and impart an intrinsic compressive stress on the collagen.

257 o enable the investigation of the effects of compressive stress on the growth of the genetically trac

258 increased exponentially with either applied compressive stress or temperature, consistent with a the

259 This study suggested that compressive stress regulates osteoblastic and osteoclast

260 Here we show that compressive stress stimulates migration of mammary carci

261 arities in the nuclear response to shear and compressive stress suggest that the nucleus is a mechano

262 umor to grow, it must be able to support the compressive stress that is generated as it presses again

263 Results showed that compressive stress within 5.0 g/cm(2) did not influence

264 wth in a confined space generates mechanical compressive stress within tumors, but little is known ab

265 pathways are deleted, cells fail to adapt to compressive stress, and all cells lyse at relatively low

266 alline materials have shown the formation of compressive stress, which can increase the density of ma

267 ay contributes to the response to mechanical compressive stress.

268 h assumes that wrinkles completely relax the compressive stress.

269 ts, which scales with the amount of shear or compressive stress.

270 on cell microorganization and is enhanced by compressive stress.

271 n a confined environment build up mechanical compressive stress.

272 adaptive response of osteoblasts exposed to compressive stress.

273 gonal-rhombohedral (T-R) phase transition by compressive stress.

274 ccurs at a well-defined value of the applied compressive stress.

275 Gigapascal-level compressive stresses are measured within pure silicon so

276 situ SEM and in situ TEM studies reveal that compressive stresses change the reaction kinetics so tha

277 ompletely analytical, it is based on biaxial compressive stresses due to differential growth between

278 ence interval, 0.96-0.99; P=0.006) and large compressive stresses during balloon deflation (odds rati

279 simulations to estimate the magnitude of the compressive stresses exerted on endothelial cells during

280 role of the nonlinear response of F-actin to compressive stresses in potentiating both myosin-mediate

281 rticles were annealed and quenched to induce compressive stresses in the alumina passivation shell su

282 ature ~300 nm are prone to severing and thus compressive stresses mechanically coordinate contractili

283 The resultant hydrogels display compressive stresses of 14-15 MPa at 98% compression wit

284 ess uses coherent nanoprecipitates to induce compressive stresses on the host matrix, functionally re

285 growing endoderm and mesenchyme, generating compressive stresses that lead to their buckling and fol

286 ay be reversibly manipulated between 0-8 GPa compressive stresses to enable systematic and reversible

287 in breaking the symmetry between tensile and compressive stresses to facilitate mesoscale network con

288 sk of fracture because of exposure to cyclic compressive stresses.

289 Our new temporal compressive summation model captures (1) subadditive tem

290 Compressive surface strains have been necessary to boost

291 oach to limit surgery to those patients with compressive symptoms or uncertain diagnosis.

292 In uncertain cases or with lack of compressive symptoms, a trial of steroids is worthwhile.

293 Moreover, pituitary enlargement may lead to compressive symptoms, which necessitates urgent surgical

294 ace topography where the ratio of horizontal compressive tectonic stresses to near-surface gravitatio

295 Importantly, compressive temporal summation directly parallels earlie

296 are tuned using a piezotronic effect when a compressive/tensile strain is applied on the GaN NB.

297 Differing from the conventional compressive testing results, such a delaying process is

298 The critical value of compressive traction stress at the transition from a pro

299 At low 3D compressive traction stresses, cells utilize bleb format

300 lging in the brain cortex in vivo after mild compressive trauma.