ライフサイエンスコーパス: flexural

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

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

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

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

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

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

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

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

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

10 Identification of this flexural deformation has implications for early evolutio

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

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

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

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

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

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

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

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

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

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

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

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

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

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

25 Flexural, fracture toughness, and indentation tests were

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

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

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

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

30 ctive method for fabricating curvilinear and flexural microstructures.

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

70 The flexural rigidity of microtubules was measured by applyi

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

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

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

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

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

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

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

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

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

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

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

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

83 may stabilize microtubule growth by reducing flexural rigidity.

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

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

86 The flexural stiffness of the tropomyosins was quantified an

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

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

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

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

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

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

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

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

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

96 Flexural strength and modulus, toughness, and fracture t

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

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

99 The flexural strength first increased, then plateaued with i

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

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

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

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

104 The flexural strength of hydrated OWC samples was increased

105 The flexural strength of the aluminas was determined with th

106 Flexural strength of the compact is not only determined

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

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

123 ce flaws does not significantly increase the flexural strength.

124 Flexural strength/modulus increased significantly for bo

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

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

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

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

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

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

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

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

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

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

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