ライフサイエンスコーパス: static magnetic field

1 on potential of coupled phonons with applied static magnetic field.

2 e tunable over a wide frequency range by the static magnetic field.

3 ringing were related to the strength of the static magnetic field.

4 absorption spectroscopy in the presence of a static magnetic field.

5 entation of the bicelles with respect to the static magnetic field.

6 d no adverse effects from embryo exposure to static magnetic field.

7 low relaxation of magnetization in a 3000 Oe static magnetic field.

8 of electrical currents in the presence of a static magnetic field.

9 he molecular orientation with respect to the static magnetic field.

10 perconductivity, acting in a way opposite to static magnetic fields.

11 ent nitroxide radical cosolutes, at multiple static magnetic fields.

12 fference in spectral density J(0) at the two static magnetic fields.

13 igher-resolution machines with high-strength static magnetic fields.

14 ups of the Ile, Leu, and Val residues at two static magnetic fields.

15 of Xenopus embryos were oriented in strong, static magnetic fields.

16 he pulsing rate in the CPMG sequence, at two static magnetic fields, 11.7 and 14.1 T, and three tempe

17 e we show that transcranial application of a static magnetic field (120-200 mT at 2-3 cm from the mag

18 In this analogy, the static magnetic field acts as the DC voltage, while the

19 of plasma-ferrite metamaterials via external static magnetic field and other structure parameters pro

20 Both static magnetic fields and convective flow can induce th

21 eristics of these radical pairs at different static magnetic fields and ionic strengths.

22 the bound state observed at 14.1 and 23.5 T static magnetic fields, and the small determined R2bound

23 nicated with focused ultrasound in different static magnetic fields (approximately 0, 1.5, 3.0, and 4

24 For geometries in which the capillary and static magnetic field are not parallel, the electrophore

25 determine whether the behavioral effects of static magnetic fields are dependent on field strength,

26 High strength static magnetic fields are known to induce vertigo, beli

27 Static magnetic fields as high as 7.0 T did not have a s

28 generated by nuclear spins that precess in a static magnetic field B0 in the presence of magnetic fie

29 Radiofrequency and static magnetic field calculations are used alongside th

30 Recent experiments have shown that intense static magnetic fields can alter the geometry of the ear

31 However, a demonstration that static magnetic fields can influence human brain activit

32 (NMR) region, corresponding to the strongest static magnetic fields currently available.

33 er pulsed EPR spectroscopy up to the highest static magnetic fields currently available.

34 Conclusion Static magnetic fields dampened microbubble cavitation a

35 We show that a static magnetic field drives an oscillating intervalley

36 is observation provides a clear example of a static magnetic-field effect on a fundamental cellular p

37 nsitivity independent of the strength of the static magnetic field, extending the applicability of ma

38 20 years, yielding MR systems with stronger static magnetic fields, faster and stronger gradient mag

39 Image acquisition involves the use of static magnetic fields, field gradients and radiofrequen

40 However, the impact of the static magnetic field generated by an MRI scanner on the

41 However, the static magnetic field generated by the cellular telephon

42 es of Paramecium caudatum align with intense static magnetic fields >3 Tesla.

43 generating GigaGauss level, solenoidal quasi-static magnetic fields in under-dense plasma using screw

44 imaging is susceptible to distortions due to static magnetic field inhomogeneities.

45 is currently lacking, despite evidence that static magnetic fields interfere with neuronal function

46 frequency pulses in the presence of a strong static magnetic field is identical between solution and

47 amental limits in circumstances in which the static magnetic field is not sufficiently strong to trun

48 The control of quasi-static magnetic fields is of considerable interest in ap

49 The shielding of static or quasi-static magnetic fields is typically accomplished through

50 ed nonferromagnetic aneurysm clips to strong static magnetic fields is unlikely to result in any clin

51 ely applied parallel or perpendicular to the static magnetic field, is a valuable technique for study

52 Here we have employed the effects of weak static magnetic fields (not exceeding 46 mT) on radical

53 d magnetic resonance imaging scanners with a static magnetic field of 3 Tesla or higher are becoming

54 a robust nystagmus while simply lying in the static magnetic field of an MRI machine.

55 The static magnetic field of an MRI scanner decreased BBB op

56 Purpose To determine the relationship of the static magnetic field of an MRI scanner on focused ultra

57 The static magnetic field of MRI scanners can induce a magne

58 r and even in the absence of any motion, the static magnetic field of MRI scanners induces a magneto-

59 The static magnetic field of the MR imaging device affects t

60 otein-containing bicelles are aligned in the static magnetic field of the NMR spectrometer.

61 shifted reversibly at room temperature in a static magnetic field of up to 2 T.

62 the transmembrane domain with respect to the static magnetic field, of 21 +/- 2 degrees and, at the s

63 oride in a manner similar to that of a quasi-static magnetic field on the order of 1 tesla.

64 Static magnetic field, or B0, and combined transmit and

65 T) schemes utilize very low frequency, quasi-static, magnetic fields; power transfer occurs via magne

66 H}-15N NOE data collected at 500 and 700 MHz static magnetic fields showed that the internal motions

67 In contrast, the effects of a homogeneous, static magnetic field (SMF) on Central Nervous System (C

68 udy aims to examine the influence of a 0.5 T static magnetic field (SMF) on yeast and human embryonic

69 ng hit by ferromagnetic objects attracted by static magnetic field (SMF) produced by scanner magnet -

70 modulated radiofrequency (PRF) signal, and a static magnetic field (SMF), applied independently, incr

71 or efficient BBB crossing under the external static magnetic field (SMF).

72 d, modulation frequencies and the background static magnetic field (SMF).

73 15 mT intensity of static magnetic fields (SMFs) applied on the aeration re

74 We demonstrate that transcranial static magnetic field stimulation (tSMS) over the somato

75 Transcranial static magnetic field stimulation (tSMS) was recently in

76 Here, we combine transcranial static magnetic field stimulation (tSMS) with resting-st

77 er a temperature range of 290-320 K and at a static magnetic field strength of 14.1 T.

78 ation is static (continuous, proportional to static magnetic field strength, requiring neither head m

79 elmi coils are compatible with MR imaging at static magnetic field strengths of 1.5 T or less.

80 ame relaxation data acquired at 310 K and at static magnetic field strengths of 11.7, 14.1 and 18.8 T

81 netic resonance imaging systems operating at static magnetic fields strengths of 7 Tesla or higher ha

82 it explores the application of a transverse static magnetic field to a ternary hybrid nanofluid coat

83 ed electrons in the diffraction peaks with a static magnetic field to obtain the time-dependent diffr

84 lysis of k(CR) in the presence of an applied static magnetic field was used to extract the singlet an

85 ) measurements for in-plane and out-of-plane static magnetic field were utilized to determine both th

86 Static magnetic fields were not found to have a signific

87 ucture but align differently relative to the static magnetic field when dissolved in a liquid crystal

88 ty in n-type-doped magneto-optic InAs with a static magnetic field where light coupling is mediated b

89 e of alignment of nuclear spins with applied static magnetic field, which is called nuclear spin pola

90 ation within 3D images in a 1D inhomogeneous static magnetic field with a matched rf field gradient.

91 cells exposed during 72 h to a 0.5 T uniform static magnetic field with those of unexposed cells.