ライフサイエンスコーパス: radiant

1 ne tumors (NET) compared with placebo in the RADIANT-3 study.

2 a on the impact of biomarkers on OS from the RADIANT-3 study.

3 ed in the everolimus and placebo arms of the RADIANT-3 study.

4 al among patients with pNET in the phase III RADIANT-3 study.

5 In view of the previous RADIANT-4 findings of longer progression-free survival w

6 RADIANT-4 is a multicentre, randomised, double-blind, pl

7 d, double-blind, placebo-controlled, phase 3 RADIANT-4 trial, adult patients (aged >/=18 years) with

8 In the phase 3 RADIANT-4 trial, everolimus increased progression-free s

9 Enrolment for RADIANT-4 was completed on Aug 23, 2013, but the trial i

10 001 In Advanced Neuroendocrine Tumors study (RADIANT-4).

11 s to kidNey Transplantation Community Study (RaDIANT), a randomized, dialysis facility-based, control

12 Recent solutions include the use of coupled radiant and sub-radiant modes yielding narrow asymmetric

13 diffuser diverged white-light spot covers a radiant angle up to 120(o) with CIE coordinates of (0.34

14 contradicts other studies reporting that the radiant blue in Hypolimnas butterflies is caused by comp

15 xcised tumors views and confirmed by optical radiant efficiency measurement, Hey-A8 or OVCAR3 tumors

16 d NIR optical imaging (3.86-fold increase in radiant efficiency), magnetic resonance imaging (1.41-fo

17 One important criterion is that the radiant energy added by human activities should not exce

18 tonic organisms revealed that the balance of radiant energy and available nutrients regulated herbivo

19 Even if GHG emissions peak in 2015, the radiant energy barrier will be exceeded by 100%, requiri

20 he understanding of the pathophysiology of a radiant energy or chemical injury as well as advancement

21 ce data from the NASA Clouds and the Earth's Radiant Energy System (CERES) with a PV performance mode

22 f radiative flux from the clouds and earth's radiant energy system instrument aboard Terra satellite,

23 ed a uniform disk of continuous wave thermal radiant energy to the exposed corneal stromal surface wi

24 e masking effect of cooling aerosols be made radiant energy-neutral by reductions in black carbon and

25 has reported that the spectral emission and radiant exitance beam profiles from LCUs can be highly i

26 measured at the light tip, it describes the radiant exitance from the surface of the light tip, and

27 ak compressive stress and its variation with radiant exposure are consistent with a model that consid

28 stress transients generated at the threshold radiant exposure for ablation indicates that the onset o

29 of retinal damage was investigated by using radiant exposure levels that are 2 to 150 times those us

30 to free ICG at 808 nm laser irradiation with radiant exposure of 6 W/cm(2).

31 The radiant exposure required at the SGNs to evoke compound

32 , including light wavelength, irradiance and radiant exposure, as well as cell culture conditions (e.

33 9 mJ/cm(2)) and 60 (224 mJ/cm(2)) seconds of radiant exposure.

34 Radiant exposures measured at CAP threshold are similar

35 rsibly inhibit small-diameter axons at lower radiant exposures than large-diameter axons.

36 For radiant exposures that do not produce material removal,

37 an detect the presence of single-digit pW of radiant flux intensity.

38 stable near-infrared emission with a maximum radiant flux of 1.7 W m(-2) at an external quantum effic

39 erratic blinking and substantial dark (never radiant) fractions that occur in all available qdots may

40 easuring the latency of tail withdrawal from radiant heat (the tail-flick test).

41 sed the impact of tailshock on reactivity to radiant heat applied to the foot.

42 ve effect of the kappa agonist U50,488 using radiant heat applied to the ipsilateral hindpaw, and we

43 Finally, using a low-intensity radiant heat assay capable of detecting hyperalgesic res

44 ts (12 studies [n = 562]; high consistency), radiant heat dressings (4 studies [n = 160]; moderate co

45 air-fluidized beds, protein supplementation, radiant heat dressings, and electrical stimulation.

46 n decreased the latency of paw withdrawal to radiant heat in mice, indicative of thermal hyperalgesia

47 Radiant heat is often used for studying thermal nocicept

48 aseline foot withdrawal responses to noxious radiant heat mediated by Adelta and C fibers were simila

49 ithdrawal threshold in response to a noxious radiant heat or pressure stimulus.

50 sured by either reactivity to high-intensity radiant heat or reactivity to electric shock, and produc

51 Intense radiant heat pulses concomitantly activate Adelta- and C

52 reduced the latency of paw withdrawal from a radiant heat source in a dose-dependent manner (EC(50) =

53 Animals were slowly heated with a radiant heat source to 43 degrees C and then maintained

54 293 cells or paw withdrawal latencies from a radiant heat source, and there was no evidence of sponta

55 s to lick front and back paws in response to radiant heat stimuli compared to vehicle administration

56 Nociception in rats was measured using a radiant heat stimulus and the effect of intrathecal admi

57 the paw withdrawal latency in response to a radiant heat stimulus in normal rats.

58 indpaw, but not the forepaw, measured with a radiant heat stimulus.

59 increase in the paw withdrawal latency to a radiant heat stimulus.

60 region of the amygdala (BLA) suppresses the radiant heat tail flick (TF) reflex in anesthetized rats

61 t shock while measuring nociception with the radiant heat tail flick (TF) test.

62 Radiant heat tail flick latency, as a measure of behavio

63 ed in the hot plate, high- and low-intensity radiant heat tail flick, and von Frey hair assays.

64 and fentanyl were markedly diminished in the radiant heat tail-flick and hot-plate assays.

65 Thermal antinociception was measured using a radiant heat tail-flick assay; mechanical sensitivity wa

66 NSAIDs are inactive in the radiant heat tail-flick test, an assay of moderate to se

67 ribogaine) was investigated in rats with the radiant heat tail-flick test.

68 oids are effective topical analgesics in the radiant heat tailflick assay and display synergistic int

69 d greater potency than morphine in the mouse radiant heat tailflick assay and similar to the active m

70 ith our prior studies showing synergy in the radiant heat tailflick assay.

71 third day and nociceptive testing using the radiant heat tailflick method was carried out 4 h later.

72 y leave the public vulnerable to explosions, radiant heat, toxic gas clouds, and air pollution from h

73 mmunicative modality, infrared radiation or "radiant heat," which capitalizes on the infrared sensory

74 gion of the amygdala persistently suppressed radiant heat-evoked tail flick reflexes of anesthetized

75 f anandamide altered withdrawal responses to radiant heat.

76 produced antinociception or hyperalgesia to radiant heat.

77 nhibit a spinal reflex, tail withdrawal from radiant heat.

78 as measured by reactivity to lower-intensity radiant heat.

79 tion of the tail flick (TF) reflex evoked by radiant heat.

80 ture; WBH was administered with an Aquatherm radiant-heat device (patent pending; Cancer Research Ins

81 l, uninflamed hindpaws was determined by the radiant-heat paw withdrawal test.

82 Antinociception studies using a radiant-heat tail flick analgesia method demonstrated th

83 ias consequent to the use of long-wavelength radiant heating (i.e. CO(2) laser) as stimulation proced

84 and the foot withdrawal responses to noxious radiant heating in lightly anesthetized rats.

85 awal and the tail-flick responses to noxious radiant heating in lightly anesthetized rats.

86 frared signals through a mechanism involving radiant heating of the pit organ, rather than photochemi

87 ed psychophysical and EEG brain responses to radiant (laser-evoked potentials, LEPs) and contact heat

88 tral super-massive black hole generates vast radiant luminosities through the gravitational accretion

89 xperimental evidence of the collective super-radiant mode in Bragg structure containing 60 InAs monol

90 The super-radiant mode is not manifested in the case if only a sma

91 reveal an appearance of the additional super-radiant mode, originated from coherent collective intera

92 s include the use of coupled radiant and sub-radiant modes yielding narrow asymmetric Fano resonances

93 status in relation to BMI for seven SNPs in Radiant (P<0.0057), with PsyCoLaus giving supportive evi

94 e Goldstone and Higgs modes inside the super-radiant phase and their corresponding spectral weights b

95 e advantages are the RL light source's lower radiant power and the corresponding longer data acquisit

96 roughout the exposure cycle and the spectral radiant power as a function of wavelength, 2) analysis o

97 The spectral radiant power can be very different between different br

98 e 370 spectra was multiplied by the spectral radiant power distribution of D65 light so that the fina

99 owing information about the curing light: 1) radiant power output throughout the exposure cycle and t

100 ssive group but not the control group in the Radiant sample.

101 etween the cavity field and the atomic super-radiant state enable ultra-fast transfer of photonic fre

102 d sample of 2442 MDD cases and 809 controls (Radiant Study).

103 y filaments and latency of withdrawal from a radiant thermal source.

104 We used radiant thermal stimulation to deliver purely thermal st

105 en PET total glycolytic volume and CLI total radiant volume (r(2) = 0.99) and various PET and CLI ana

106 e per injected dose (radiance/ID), and total radiant volume.