ライフサイエンスコーパス: flexural

1 ge, TEWL, and AD phenotype (flexural vs. non-flexural).

2 ouin scattering (SBS) mediated by long-lived flexural acoustic waves.

3 nally, magnetized water notably enhances the flexural and compressive strength of the cement grout st

4 ecific surface area, water permeability, and flexural and compressive strengths, were also evaluated

5 Flexural and tensile poly-lactic acid specimens are prin

6 At lower forces, smooth global flexural and torsional changes occur via even redistribu

7 At 0.075% BN, the 28-day compressive, flexural, and splitting tensile strengths increased by 4

8 gnificantly improved the 90-day compressive, flexural, and splitting tensile strengths of normal and

9 nd hyperkeratotic lichenified plaques in the flexural areas and extensor surfaces at later ages.

10 ve movement including on the face, genitals, flexural areas, and the palms and soles.

11 urrent vesicles, erosions, and maceration in flexural areas.

12 of a clamped-guided arch beam connected to a flexural beam and a T-shaped moveable mass.

13 On the other hand, cooling the heated flexural beams is used for helium (He) detection (therma

14 belt and suture zone, which rather indicate flexural bending of the southern margin of the Lhasa blo

15 We determined the flexural (bending) rigidities of actin and cofilactin fi

16 cimens failed predominantly due to torsional-flexural buckling mode.

17 M most likely are elevated by a non-thermal, flexural cantilever mechanism which is perhaps the most

18 a specific anharmonic connection between the flexural corrugation and longitudinal phonons whose fast

19 (PVDF)-based polymer ferroelectrics provide flexural, coupling-efficient, and multifunctional materi

20 ismic data to provide a synoptic view of the flexural deformation across the rift.

21 anowires bent by localized loading to couple flexural deformation and transverse piezoelectric respon

22 Identification of this flexural deformation has implications for early evolutio

23 specific strength in tension while allowing flexural deformation under bending or twisting.

24 etical model reveals that this unprecedented flexural deformation within the membrane is attributable

25 ggering their ordered rolling-up under rapid flexural deformation.

26 associated with specific phenotypes, such as flexural dermatitis (OR 8.4, 95% CI: 6.3-11.2), head and

27 however, the need for visual confirmation of flexural dermatitis by a trained investigator limits the

28 ngdom criteria and accurately report visible flexural dermatitis in their year old infants.

29 ' and investigator's observations of visible flexural dermatitis was high for all sites: kappa= 0.88-

30 mes (wheeze, urticaria, rhinitis and visible flexural dermatitis), and effect modification by Sm expo

31 and trained investigator's reports of visual flexural dermatitis.

32 ge, measured by standardized questions about flexural dermatitis.

33 elaxing bends, which are responsible for the flexural dynamics of DNA on a short time scale, t < or =

34 of asthma, bronchial hyperreactivity (BHR), flexural eczema (FE), allergic rhinitis, and sensitizati

35 SPT was positively related to flexural eczema and rhinoconjunctivitis, but not to whee

36 Atopic symptoms in the past year (flexural eczema and/or rhinoconjunctivitis) were reporte

37 In NHANES, flexural eczema in the past year was associated with sig

38 and mould was significantly associated with flexural eczema in the previous year, with a stronger as

39 However, the association with flexural eczema on examination was not significant (0.93

40 ns used the terminology 'childhood eczema', 'flexural eczema', 'infantile eczema', 'atopic neuroderma

41 the 60 vol.% Ap-SFRP remains ductile with 7% flexural elongation at lower temperatures (-50 degrees C

42 cooling rate and contraction mismatch on the flexural failure resistance of metal opaque-porcelain st

43 Flexural, fracture toughness, and indentation tests were

44 The mechanical (tensile, flexural, impact, hardness), dimensional stability, ther

45 n that incorporates displacements due to the flexural isostatic response of the lithosphere to loadin

46 es the tuning parameter for selection of the flexural leakage frequency, without affecting the main b

47 se score (SCORAD), involvement of the limbs, flexural lesion distribution at the age of 3 years, alle

48 ced from the residual stress and the applied flexural load was also determined for these specimens.

49 d subjected to either quasi-static or cyclic flexural loading to failure.

50 panded rib lath and tested under three-point flexural loading.

51 ger than unreinforced concrete (~4.5 MPa) in flexural loading.

52 0) failed at significantly lower (p < 0.05) flexural loads than did specimens with a positive therma

53 lks enhance the room-temperature tensile and flexural mechanical properties of the composite, whereas

54 ctive method for fabricating curvilinear and flexural microstructures.

55 ant cantilevers vibrating in an out-of-plane flexural mode has to date been limited by the considerab

56 of short-time scale ballistic motion in the flexural mode of a nanomembrane cantilever, driven by th

57 perties of the LN allow to activate multiple flexural mode of vibration with only top electrodes.

58 antilevers, thermally excited in an in-plane flexural mode, are investigated and applied as sensors f

59 thermomechanical vibrations, up to the ninth flexural mode, with displacement sensitivities of ~7-14

60 theorem and Maxwell-Boltzmann statistics for flexural modes and can be used in fast thermometry and m

61 unding fluid was extended to consider higher flexural modes vibrating at high Reynolds numbers.

62 ilational and shearing modes to out-of-plane flexural modes, a paradigm that we refer to as "omnimoda

63 interface and strong interface-scattering of flexural modes, which make a large contribution to kappa

64 was observed in the viscosity data at higher flexural modes, which vibrate at elevated frequencies.

65 g in their in-plane rather than out-of-plane flexural modes.

66 The tensile and flexural moduli improved with the addition of biocarbon,

67 Three-point flexural moduli of a flowable, luting, and hybrid compos

68 ctrolytes (0.13%) and a much larger ultimate flexural modulus (7.8 GPa) than pure polymer electrolyte

69 The flexural strength (FS) and flexural modulus (FM) were not significantly different (

70 Flexural modulus decreased for the 20 wt% group, due to

71 Notably, the flexural modulus of the materials was not compromised, a

72 ibit significantly higher flexural strength, flexural modulus, and hardness and lower volumetric shri

73 resins exhibit the higher flexural strength, flexural modulus, hardness, and hydrophobicity and lower

74 A model for the sequence-dependent internal flexural motion of duplex DNA, which casts the mean squa

75 the coupling effects of the longitudinal and flexural motion of these resonators, we create narrow tr

76 Inertial swimmers use flexural movements to push water and generate thrust.

77 e-tethered filaments can grow while exerting flexural or tensile force on the motile surface.

78 Flexural oscillations of freestanding films, nanomembran

79 ls, this work suggests that tunable electron-flexural phonon couping can provide a handle to control

80 bonded graphene film by recovering the long flexural phonon lifetime.

81 Thermally-activated flexural phonon modes should generate dynamic changes in

82 in the out-of-plane direction due to dynamic flexural phonons and static wrinkling.

83 practices of neglecting the contributions of flexural phonons to transport in two-dimensional materia

84 projected mass density increase endowing the flexural phonons, as they move with their group velocity

85 stic electron coupling with an odd number of flexural phonons, contributing to the increase of the Lo

86 cantilever, driven by thermal fluctuation of flexural phonons, including measurements of ballistic ve

87 shows that the phoretic force is due to the flexural phonons, whose flow is known to be ballistic an

88 kling, with only a small contribution due to flexural phonons.

89 ing peaks, as observed with a polymer-coated flexural plate wave sensor.

90 rption method and detected downstream with a flexural plate wave vapor sensor.

91 The flexural-plate-wave (FPW) sensor, a type of ultrasonic s

92 ity, curing kinetics, surface microhardness, flexural properties, and dimensional accuracy were evalu

93 of the TiO(2) nanoparticles in enhancing the flexural properties.

94 The recently discovered flexural pulse wave, which is naturally generated by hea

95 rovides an opportunity to follow the natural flexural pulse waves.

96 tal atopy, FLG status, or report of an itchy flexural rash at 2 months.

97 by parental report of a typical itchy and/or flexural rash.

98 Lesions typically developed at flexural regions, genitalia, and the scalp, especially t

99 , we create narrow transmission bands at the flexural resonances of the beams inside the wide frequen

100 heir in-plane rather than their out-of-plane flexural resonant mode have been fabricated and shown to

101 cene emerged marine terraces associated with flexural rift-flank uplift.

102 diamond nanomembranes with thinning-reduced flexural rigidities can be shaped into various 3D mesost

103 rtebrate and yeast cofilactin scale with the flexural rigidities determined from analysis of shape fl

104 of the axoneme depends on both the intrinsic flexural rigidity (EI) and the elastic resistance to int

105 nized myosin-driven contraction by providing flexural rigidity and enhanced connectivity to actin net

106 We estimated the average intrinsic flexural rigidity and interdoublet shear stiffness of wi

107 nvestigated two major mechanical parameters, flexural rigidity and interdoublet shear stiffness, of t

108 Due to their high flexural rigidity and persistence length of the order of

109 ent-specific persistence length, an index of flexural rigidity directly proportional to Young's modul

110 ess to the canalicular wall and their finite flexural rigidity EI.

111 anics theory to derive an effective, average flexural rigidity for the arms.

112 However, how MT flexural rigidity in cells is regulated remains poorly u

113 In the two mutant strains, the flexural rigidity is not significantly different from wi

114 filaments is 9.8 microm, corresponding to a flexural rigidity of 0.040 pN microm(2).

115 onstrate that DAP substitution increases the flexural rigidity of dsDNA yet also facilitates conforma

116 hs suggest that for [MgATP] >/= 0.25 mM, the flexural rigidity of heavy meromyosin (HMM)-propelled ac

117 vature and moment equation, we find that the flexural rigidity of microtubules depends on their lengt

118 The flexural rigidity of microtubules was measured by applyi

119 eoretical modeling suggests a 30-40% lowered flexural rigidity of the actin filaments at [MgATP] </=

120 Moreover, due to lower flexural rigidity of the actin filaments, smaller featur

121 ent models, we demonstrate that the apparent flexural rigidity of the axoneme depends on both the int

122 n the myosin II class may be to modulate the flexural rigidity of the light chain binding domain to m

123 ovement demonstrates that the differences in flexural rigidity of the two myosin lever arms is suffic

124 These values in conjunction with the large flexural rigidity of tubulin protofilaments obtained (18

125 in experiment, which instead measures either flexural rigidity or response to radial deformation.

126 rotubules, their diamagnetic anisotropy, and flexural rigidity predict the required field strength fo

127 ld to a value of 2.2 microm and the filament flexural rigidity to 0.0091 pN microm(2).

128 like structures comprising the matrix have a flexural rigidity, EI, that is sufficiently stiff to ser

129 a anglica showed an increase in diameter and flexural rigidity, while Young's bending modulus and bre

130 ein-C (cMyBP-C) to thick-filament length and flexural rigidity.

131 ding their charge density, viscous drag, and flexural rigidity.

132 may stabilize microtubule growth by reducing flexural rigidity.

133 e (FRC) prostheses is dependent, in part, on flexural rigidity.

134 angle normal faults, plutonic intrusions and flexural rotation of initially high-angle normal faults.

135 Geometrically-biased flexural shear wave speed was 1.9 0.1 m/s, corresponding

136 atric eczema develops quickly after birth at flexural sites subjected to continuous mechanical constr

137 Mechanical properties such as flexural, splitting tensile and compressive strengths al

138 rbon fibre content, the quasi-static tensile/flexural stiffness and strength increases following the

139 Under all conditions, stalk flexural stiffness followed a biphasic trajectory, chara

140 This study measured stalk flexural stiffness in maize inbred genotypes across mult

141 envelope may cause a spatial distribution of flexural stiffness in the same nucleus.

142 nvelope mechanics have assumed values of the flexural stiffness of the envelope based on simple scali

143 The flexural stiffness of the tropomyosins was quantified an

144 f the envelope to bending, quantified by the flexural stiffness, helps determine the microtubule-depe

145 sing a computational wing model with varying flexural stiffness.

146 Bending tests also revealed over 8% flexural strain.

147 ith the coated nanoparticles showed improved flexural strength (10% to 30% higher) and work of fractu

148 Large particles at 2 wt% yielded the highest flexural strength (134.03 +/- 4.65 MPa) and Vickers hard

149 The highest flexural strength (195+/-8 MPa) and fracture toughness (

150 lly matched glass would increase the biaxial flexural strength (BFS).

151 The flexural strength (FS) and flexural modulus (FM) were no

152 a-analysis aimed to evaluate and compare the flexural strength (FS), surface hardness, fracture tough

153 These optimal loadings were tested for flexural strength (FS), water sorption (WS) and solubili

154 illed denture bases demonstrated the highest flexural strength (MD = -1.11, 95% CI [-1.29, -0.93], p

155 ite with a filler mass fraction of 55% had a flexural strength (mean +/- SD; n = 6) of 196+/-10 MPa,

156 The flexural strength (mean+/-SD; n = 10) was 86+/-20 MPa fo

157 re characterized by evaluating their 3-point flexural strength (n = 6), modulus of elasticity (n = 6)

158 Dentin beams were used for 3-point flexural strength (sigma) test.

159 g with enhanced fracture toughness (KIC) and flexural strength (sigmaf) of the composites by ~75% (5.

160 amic content, leading to a trade-off between flexural strength (varying from 89 to 800 MPa) and fract

161 day water-aging, NACP+QADM nanocomposite had flexural strength and elastic modulus matching those of

162 (2)-decorated densified bamboo exhibits high flexural strength and elastic stiffness, with both prope

163 than ChNC resulted in the greatest improved flexural strength and fracture energy by 24% and 28%.

164 bon nanotubes (CNTs) (3DP GC) with both high flexural strength and hierarchical porous structure is r

165 exhibited significantly enhanced tensile and flexural strength and moduli.

166 es were tested for CHX release and recharge, flexural strength and modulus (at 24 hr and 1 mo), surfa

167 y scanning electron microscopy, ISO standard flexural strength and modulus measurements, contact angl

168 Flexural strength and modulus, toughness, and fracture t

169 e stabilization of cubic leucite reduced the flexural strength and the number of crack deflections in

170 Degree of conversion (DC), flexural strength and Vickers hardness were evaluated to

171 compromised, although a slight reduction in flexural strength associated with the nanogel-modified i

172 ne conditions, and increased compressive and flexural strength at 28 and 56 days compared to the cont

173 atrix increased the compressive strength and flexural strength by 65%, and 74%, respectively, after 2

174 critical role of the 1D CNTs in the enhanced flexural strength by increasing the friction and adhesio

175 s exhibited a significantly lower (p < 0.05) flexural strength compared with rapidly cooled specimens

176 The flexural strength first increased, then plateaued with i

177 The mean biaxial flexural strength for the group corresponding to 22.2 wt

178 ive strength from 46.36 MPa to 49.81 MPa and flexural strength from 10.5 MPa to 11.47 MPa, indicating

179 The flexural strength in MPa (mean +/- SD; n = 10) was 86 +/

180 hisker composite with 70% filler level had a flexural strength in MPa (mean +/- SD; n = 6) of 248 +/-

181 hermally reduced Gr-rGO-reinforced GFRPs the flexural strength increased by 15.7% and 14.4%, tensile

182 ronmental, and electronic systems where high flexural strength is preferred.

183 e validation experiments yielded the maximum flexural strength of 78.52 MPa, the maximum ultimate ten

184 crostructure, crack deflection patterns, and flexural strength of a leucite-reinforced porcelain.

185 ved carbon nanomaterial, the compressive and flexural strength of cement samples are enhanced by 24%

186 gs of 0.02 to 0.06 wt.%, the compressive and flexural strength of concrete composites increases by 28

187 The flexural strength of hydrated OWC samples was increased

188 ent distribution, apatite/collagen ratio and flexural strength of mineralized dentin treated with GA

189 PEI) binder for silica sand that doubled the flexural strength of parts to 6.28 MPa compared with tha

190 ughness, DeltaE, surface micro-hardness, and flexural strength of the 3D printed dentures were measur

191 The flexural strength of the aluminas was determined with th

192 Flexural strength of the compact is not only determined

193 with the control ones, the reduction of the flexural strength of the heat-treated, impregnation/heat

194 crostructure, crack deflection patterns, and flexural strength of the material.

195 The mean flexural strength of the rubidium-exchanged material was

196 2.4% of increase in compressive strength and flexural strength respectively, due to fiber-paste inter

197 Plots of flexural strength S versus indentation load P show a ste

198 after 7 days and 61.90% after 56 days, while flexural strength showed a 66.17% increase after 7 days

199 es a simple and effective method to evaluate flexural strength sigma(F) and fracture toughness K(C).

200 d at 1150 degrees C exhibited a mean biaxial flexural strength significantly higher than that of all

201 ough compressive strength, split-tensile and flexural strength tests.

202 al symmetric unit cells showed 13-35% higher flexural strength than octet cell cored counterpart.

203 istinct advantages: i) an intrinsically high flexural strength that enables their large-scale applica

204 ry infiltration, resulting in an increase in flexural strength to 52.7 MPa.

205 The particle size, mechanical and flexural strength was also determined.

206 such as Young's modulus, shear modulus, and flexural strength were calculated for selected complexes

207 litting tensile strength, bond strength, and flexural strength with a maximum increase of 34.5%, 35%,

208 asured shear stress concentration factor and flexural strength with the fracture toughness of concret

209 undred resin), with enhancements of 13.4% in flexural strength, 25% in tensile strength, and 21.5% in

210 strength (50.1 MPa tensile strength, 6.7 MPa flexural strength, and 26.7 MPa compressive strength), h

211 dental porcelain, evaluate its effect on the flexural strength, and characterize its microstructure.

212 ed mineralized trabecular bone volume, lower flexural strength, and histologic evidence of osteomalac

213 ensile strength, tensile modulus, ductility, flexural strength, and Izod impact energy.

214 ties of PCC, including compressive strength, flexural strength, and splitting tensile strength, play

215 WPA) on the flow time, compressive strength, flexural strength, and thermal conductivity of mortars.

216 ute to its high mechanical tensile strength, flexural strength, and toughness.

217 splays a three-fold elevation in tensile and flexural strength, as compared to pure epoxy resin, with

218 The composite flexural strength, elastic modulus, hardness, and degree

219 ased composites exhibit significantly higher flexural strength, flexural modulus, and hardness and lo

220 The NPUA-based resins exhibit the higher flexural strength, flexural modulus, hardness, and hydro

221 0.3% GO-MMt demonstrated superior values of flexural strength, followed by RBC + 0.5% GO-MMt (p < 0.

222 nocomposites, including water-aging effects, flexural strength, fracture toughness, and three-body we

223 The flexural strength, modulus, and resilience were signific

224 particulate-filled compounds (p < 0.001) for flexural strength, modulus, work of fracture, strain at

225 lts showed that at 0.50% JF and 10% CCA, the flexural strength, splitting tensile strength and compre

226 ctate and powder:liquid ratio (p < 0.001) on flexural strength, strain-at-peak-load, work-of-fracture

227 hane to the commercial cement led to similar flexural strength, toughness, and conversion at 72h comp

228 xy) phenyl]-propane (BisGMA) were tested for flexural strength, viscosity, and water sorption.

229 Flexural strength, work-of-fracture, and fracture toughn

230 owever, lower correlations were observed for flexural strength-toughness and flexural toughness-MOR w

231 ce flaws does not significantly increase the flexural strength.

232 ystalline C-S-H, renowned for its remarkable flexural strength.

233 healing, resulting in a 27.8% improvement in flexural strength.

234 ns due to their esthetic appearance and high flexural strength.

235 Flexural strength/modulus increased significantly for bo

236 e toughness of common glasses, while keeping flexural strengths comparable to transparent polymers, s

237 The flexural strengths in MPa (mean +/- SD; n = 6) of DCPA-w

238 The nanocomposites had flexural strengths of 70-120 MPa, after 84-day immersion

239 thalate (PET) to enhance the compressive and flexural strengths of these mortars.

240 ths, similar tensile strengths, and superior flexural strengths to those of NAC after 90 days.

241 powder, as evidenced by its compressive and flexural strengths, respectively.

242 n enhance resistance to both compressive and flexural strengths.

243 However, the tensile strength, flexural stress, hardness and impact load were improved

244 atous skin lesions sparing warm regions (eg, flexural surfaces and skinfolds) were identified in 4 pa

245 cterized by multiple skin webs affecting the flexural surfaces often accompanied by craniofacial anom

246 Methods included a 3-point flexural test, quantification of hydroxyproline (collage

247 d through compression, indirect tension, and flexural tests.

248 ss and average crack growth resistance using flexural tests.

249 veyor belt's elasticity into the aerodynamic flexural-torsional flutter treatment of the belt, with t

250 vior with 1% and 1.5% fiber content, and the flexural toughness increases remarkably from 2.2 to 47.1

251 fiber volumes for compressive toughness and flexural toughness were 0.5% and 1%, respectively.

252 observed for flexural strength-toughness and flexural toughness-MOR with similar R(2) = 0.75.

253 sults suggest that long-term and late-summer flexural uplift of the Coast Ranges reduce the effective

254 e drums, we demonstrate that the macroscopic flexural vibrations of graphene induce dynamical optical

255 G mutation carriage, TEWL, and AD phenotype (flexural vs. non-flexural).

256 antage of the unique capabilities of SLL for flexural wave focusing and collimation, we develop a str

257 operly, both the quality and quantity of the flexural wave measurement data can be significantly incr

258 The meta-layer is described by a flexural wave polarizability tensor, which captures inde

259 han two orders of magnitude amplification of flexural wave signals to overcome the detection limit.

260 lation of amplitude and frequency spectra of flexural wave temporal refraction and reflection through

261 emonstration of refraction and reflection of flexural waves across a temporal boundary in a continuum

262 testing of an elastic invisibility cloak for flexural waves in a mechanical lattice.

263 e numerically investigate the propagation of flexural waves in a thin reticulated plate augmented wit

264 transmission and reflection coefficients of flexural waves in both amplitude and phase and nonrecipr

265 at "swims" on land by propagating retrograde flexural waves.

266 g time, mechanical strength (compressive and flexural), workability, water absorption and microstruct