ライフサイエンスコーパス: Weber

1 Weber's law can be explained either by a compressive sca

2 f the extent of inbreeding, which Broman and Weber suggest may be quite common.

3 oth the difference limen (DL; threshold) and Weber ratio (WR; discriminatory sensitivity, independent

4 nd its implications, proportional timing and Weber's law, temporal dynamics and linear waiting, and t

5 Bruno Kisch and Professor Arthur Weber.

6 he relative differences (a behavior known as Weber's law), or follow more complex rules.

7 hen both are specified in the same units (as Weber fractions), Vernier acuities are closely predicted

8 t up to the visual resolution limit (average Weber fractions of 0.13 at 50 c/deg).

9 In this issue of Blood, Weber and colleagues demonstrate that in the first 10 da

10 nce efficiency for all sites first stated by Weber and Daniel in 1966.

11 lds for luminance-defined targets, comparing Weber contrast sensitivity (CSw).

12 psychophysical data, accounting for constant Weber fractions over a large range of intermediate speed

13 In this issue of Genes & Development, Weber and colleagues (pp.

14 The frequency DL/Weber fraction was determined for each subject under the

15 uency discrimination threshold (frequency DL/Weber fraction).

16 he relative difference in frequencies (i.e., Weber fraction) and discrimination accuracy (i.e., corre

17 94%, p < 0.0001), a finding seen across each Weber class.

18 d are classified in three main subtypes: EBS Weber-Cockayne (EBS-WC), EBS Kobner (EBS-K), and EBS Dow

19 The circuits exhibit Weber's law behaviour as in natural biological systems,

20 Human speed discrimination thresholds follow Weber's law over a large range of reference (i.e., pedes

21 f it is linear on expected outcome) followed Weber's Law.

22 cognitive representation of outcomes follows Weber's Law, namely that the spread of the distribution

23 ng how psychophysical thresholds depart from Weber's law at slow speeds.

24 te speeds as well as a marked departure from Weber's law at slow speeds.

25 Over 150 years ago, E.H. Weber declared that experience showed that tactile acuit

26 gnitive abilities of bat pollinators, invoke Weber's law inappropriately, and cannot predict observed

27 In this issue, Weber and coworkers report that DNA-demethylating drugs

28 Using the Marshfield Weber 9 marker panel, we performed a genomewide linkage

29 In this issue of Cell Host & Microbe, Weber et al. (2015), along with recent work by Sato et a

30 In this issue of Cell Host & Microbe, Weber et al. show that incoming nucleocapsid-bound genom

31 iming: the scalar property, a strong form of Weber's law, and ratio comparison mechanisms.

32 Genotyping of Weber Screening Set 9 (387 short tandem-repeat polymorph

33 eptor system reveals the molecular origin of Weber's law in bacterial chemotaxis.

34 enomenon is achieved for a specific range of Weber numbers (We >40) and droplet Froude numbers during

35 f colliding droplets are delineated based on Weber number and impact number.

36 perceived lightness from luminance ratios or Weber contrast.

37 gic telangiectasia (HHT; also known as Osler-Weber-Rendu disease).

38 y hemorrhagic telangiectasia, or Rendu-Osler-Weber disease, is an autosomal dominant disorder charact

39 rrhagic telangiectasia (HHT), or Rendu-Osler-Weber disease, is an autosomal dominant disorder of loca

40 orrhagic telangiectasia (HHT, or Rendu-Osler-Weber syndrome), clinical evaluations and genetic studie

41 l being timed, so as to preserve the overall Weber law of interval timing.

42 A Parkes Weber syndrome was diagnosed based on the clinical pictu

43 ry radiographic lymphangiography in a Parkes-Weber syndrome (PKWS) patient with suspected RASA1 mutat

44 xperience, we revaluate the phenomenological Weber's law and its generalizations to the Weber-Fechner

45 haemorrhagic telangiectasia, or Osler-Rendu-Weber (ORW) syndrome, is an autosomal dominant vascular

46 rt that prefrontal cells use the same scale (Weber's Law) used by sensory neurons to code stimulus in

47 e 391 SSTRPs in the CHLC Human Screening Set/Weber Version 6 (Research Genetics, Inc., Huntsville, AL

48 oatomic system interacting with a Stillinger-Weber potential with variable tetrahedrality.

49 duplication (1), polymicrogyria (1), Sturge-Weber syndrome (1), and tuberous sclerosis (1).

50 ed in patients with sporadic PWSs and Sturge-Weber syndrome.

51 isorders, joining McCune-Albright and Sturge-Weber syndromes.

52 romise for preventing brain injury in Sturge-Weber syndrome.

53 tribute to the neurologic declines in Sturge-Weber syndrome.

54 sights into the neurologic aspects of Sturge-Weber syndrome and are summarized here.

55 be useful for the early diagnosis of Sturge-Weber syndrome and perfusion magnetic resonance imaging,

56 the participants (23 of 26) with the Sturge-Weber syndrome and from 92% of the participants (12 of 1

57 The Sturge-Weber syndrome and port-wine stains are caused by a soma

58 g vascular development cause both the Sturge-Weber syndrome and port-wine stains, and the severity an

59 The Sturge-Weber syndrome is a sporadic congenital neurocutaneous d

60 n 97 samples from 50 persons with the Sturge-Weber syndrome, a port-wine stain, or neither (controls)

61 normal tissue from 3 persons with the Sturge-Weber syndrome.

62 ren (four Rasmussen encephalitis, two Sturge-Weber syndrome).

63 rmed on three pediatric patients with Sturge-Weber syndrome (SWS).

64 Case Alex, with Sturge-Weber Syndrome affecting the left hemisphere, failed to

65 choroidal thickness in patients with Sturge-Weber syndrome and detect abnormalities that are not vis

66 at least 1 eye in 12 individuals with Sturge-Weber syndrome using enhanced depth imaging SD-OCT.

67 ch as those found in individuals with Sturge-Weber syndrome.

68 umented by Freiburg Acuity Contrast Testing (Weber index: %W) who subsequently experienced PVD, as co

69 R) and CS (Freiburg acuity contrast testing: Weber index, %W).

70 in this issue of Molecular Cell suggest that Weber's law of sensory perception may apply to a number

71 s) for their structural flexibility, (2) the Weber-Fechner law of human sensing that sensation is pro

72 T predicts well-timed peak responses and the Weber law property, like that observed in interval timin

73 netics and isotherms were collected, and the Weber-Morris intraparticle diffusion model and Freundlic

74 numerical information, as postulated by the Weber-Fechner law or Stevens' law for psychophysical/sen

75 numerical information, as postulated by the Weber-Fechner law.

76 Mean-dependent gain control followed the Weber-Fechner relation and occurred primarily at odor tr

77 perm adapted their sensitivity following the Weber-Fechner law.

78 ntly labeled microsatellite markers from the Weber 9a human screening set (Research Genetics, Huntsvi

79 xhibited logarithmic compression obeying the Weber-Fechner law for magnitudes.

80 strated a temporal pattern suggestive of the Weber effect (a transient increase in adverse event repo

81 l Weber's law and its generalizations to the Weber-Fechner law and fold-change detection.

82 adapted in background light according to the Weber-Fechner relation, well known to describe the adapt

83 This Weber-like law for perceptual learning demonstrates that

84 sitivity declined approximately according to Weber's Law, with a 10-fold reduction occurring at an in

85 Analogous to Weber's Law in sensory physiology, some gene transcripti

86 tive to the background, a feature related to Weber's Law.

87 up)--proteasome degradation system in vitro, Weber-Ban and colleagues elucidate its mechanism and des

88 n metal substrates is concluded to be Volmer-Weber (VW) mode.

89 through either Stranski-Krastanov or Volmer-Weber island growth.

90 ovide a complete reformulation of the Volmer-Weber 3D island growth mechanism, which has always been

91 rd amplitude yielded results consistent with Weber's Law and changing the modulation rate yielded res

92 with numerosity in a manner consistent with Weber's law.