ライフサイエンスコーパス: brain scan

1 in the immersion program at the time of the brain scan.

2 Of the 27 children, 25 (92.6%) required a brain scan.

3 etric T1-weighted magnetic resonance imaging brain scan.

4 fiber integrity at all pairs of points in a brain scan.

5 imb based solely on a T1-weighted structural brain scan.

6 ther was administered 111 MBq of 201Tl for a brain scan.

7 hizophrenia that are detectable with in vivo brain scans.

8 nderstood, despite decades of research using brain scans.

9 T2-weighted magnetic resonance imaging (MRI) brain scans.

10 measuring neck muscle CSA on T1-weighted MR brain scans.

11 tracking motion-correction methods for human brain scans.

12 ho also underwent high-resolution structural brain scans.

13 hemisphere lesions) underwent MRI anatomical brain scans.

14 em to predict variable rewards while we made brain scans.

15 t high-resolution magnetic resonance imaging brain scans.

16 scence, and more than half have abnormal MRI brain scans.

17 l pulvinar high signal on magnetic resonance brain scanning.

18 0.67) for weekend/holiday admissions; early brain scan 1.30 (0.87 to 1.94) and 1.43 (0.95 to 2.18);

19 went serial magnetic resonance imaging (MRI) brain scans 3.5 years apart.

20 ld consequences, it is critical to interpret brain scans accurately, because decisions based on neura

21 Thus, using over 1,000 brain scans, across three independent samples, we link s

22 ulated functional magnetic resonance imaging brain scans, ad libitum dinner, and evening snacking.

23 The 3 HABs underwent a repeated brain scan after TSPO blockade with XBD173 (N-benzyl-N-e

24 pants underwent a magnetic resonance imaging brain scan and completed a selection of personality meas

25 our analysis technique with high-resolution brain scanning and high-frequency motion correction to c

26 were obtained in 6 subjects; 2 subjects had brain scans and 5 subjects had scans of the thorax or ab

27 ceived structural magnetic resonance imaging brain scans and completed the Dementia Rating Scale-2, a

28 pathology--on T2-weighted magnetic resonance brain scans and neuropsychological test findings in elde

29 Brain scans and postmortem data showed that affected ind

30 nges are often readily visible in individual brain scans, and AN may be a valuable model disorder to

31 extracted from abundance of existing medical brain scans, and could potentially provide a characteris

32 domen), and magnetic resonance imaging (MRI; brain) scans as a part of staging requirements for immun

33 tests and a magnetic resonance imaging (MRI) brain scan at approximate yearly intervals for the first

34 for age and gender underwent structural MRI brain scans at baseline and 6-9 months after commencing

35 H(2)(15)O positron emission tomography (PET) brain scans before a randomized, placebo-controlled, 3-w

36 g of patients, but this requires specialized brain scans beyond routine clinical data, making it less

37 Many studies include a MR brain scan but no peripheral measure of muscle mass.

38 l subjects, using magnetic resonance imaging brain scan data and automated analysis techniques.

39 as they can make accurate predictions about brain scan data from individual subjects.

40 swallow screen on day of admission (day 0), brain scan (day 0 or 1), aspirin (day 0 or 1), admission

41 All analyses of brain scans done with statistical parametric mapping wer

42 cross-sectional area (CSA) on volumetric MR brain scans enabling brain and muscle size to be measure

43 e use 376 longitudinally acquired structural brain scans from 108 typically developing adolescents to

44 Using magnetic resonance imaging brain scans from 11 primate species, we measured gray, w

45 quired structural magnetic resonance imaging brain scans from 618 typically developing males and fema

46 pplying SBM in >1250 longitudinally acquired brain scans from 647 healthy individuals aged 3-30 years

47 or MRI had annual proton density/T2-weighted brain scans from which total lesion volume was measured

48 obtained from an magnetic resonance imaging brain scan in a sample of subjects (n = 707) who have un

49 ain patients (n = 56) underwent pretreatment brain scans in two clinical trials.

50 Three-Tesla magnetic resonance imaging brain scans (including brain-substructure volumetrics) w

51 Serial fetal brain scans indicate that the immediate response of a fe

52 NMO brain scan lesions compared to controls were large (> 2

53 months from clinical onset, and a follow-up brain scan obtained less than 12 months from CIS onset.

54 SPECT brain scans obtained 3 h after injection were evaluated

55 olution parcellation were created to analyze brain scans of 1189 youths collected as part of the Phil

56 rating systems were used to compare the MRI brain scans of 48 elderly patients with depression diagn

57 and posterior aspects of cerebellum from MRI brain scans of 53 chimpanzees (Pan troglodytes).

58 Clinical brain scans of 83 patients with brain lesions (67 in the

59 xyglucose positron emission tomography (PET) brain scans on 25 subjects with OCD, 25 with MDD, and 16

60 ts in the repeatability study had had two MR brain scans on three different scanners.

61 ormed not later than 2 weeks after a routine brain scan positive for at least one area of gadolinium

62 eir IQs were estimated (without awareness of brain-scan results).

63 ons, experimental brain phantom, and patient brain scans showed improved quality with this collimator

64 Resting-state brain scans showed increased activity for the meditation

65 A few small functional brain-scanning studies suggest that, in healthy individu

66 digital subtraction of serially acquired MR brain scans to allow determination of rates of global an

67 bject naming skills and acquiring structural brain scans twice.

68 This is a preliminary study of SPECT brain scan using dipyridamole as a stress agent to asses

69 Finally, a patient brain scan was obtained with a combination of HCB and fa

70 To investigate this, structural brain scans were acquired at two time points (mean scan

71 photon emission computed tomographic (SPECT) brain scans were acquired for 15 drug-free depressed pat

72 Anatomic brain scans were acquired with a 1.5-T magnetic resonanc

73 Pre- and post-surgical T1-weighted MRI brain scans were analysed to extract hippocampal and res

74 Forty-nine PET/MRI brain scans were included: brain tumor studies using (18

75 FDG PET brain scans were obtained and visually graded by an expe

76 Brain scans were obtained at 4-week intervals to the end

77 Whole-body scans and brain scans were obtained at various times after injecti

78 Subsequently, pairs of dynamic brain scans were obtained for 11 healthy men to identify

79 Magnetic resonance imaging brain scans were obtained from 243 subjects, comprising

80 By using magnetic resonance imaging, brain scans were obtained from 27 patients with major de

81 Brain scans were obtained using a PET scanner.

82 Brain scans were reviewed by a neuroradiologist (unaware

83 All participants underwent 1.5T MRI brain scanning with subsequent automatic measurement of

84 healthy volunteers (n = 46) underwent SPECT brain scans with (99m)Tc-TRODAT-1, a radiolabeled tropan

85 al sites analysed structural T1-weighted MRI brain scans with harmonised protocols of individuals wit

86 rience in these examinations, not limited to brain scans, with the use of an incubator equipped not o

87 ttern (thrombolysis, brain scan within 12 h, brain scan within 1 h, dysphagia screening), a day of th

88 variation: a diurnal pattern (thrombolysis, brain scan within 12 h, brain scan within 1 h, dysphagia

89 A computed tomography brain scan within 18 h of stroke onset identified the pr