ライフサイエンスコーパス: spoiled gradient

1 al segmentation of an MR image acquired with spoiled gradients and fat suppression.

2 udy examining coronally oriented 124-section spoiled gradient echo images acquired on 3 magnetic reso

3 contrast-enhanced MRI using radio frequency spoiled gradient echo imaging sequence after injection o

4 ntrast enhancement-T1-weighted 3-dimensional spoiled gradient echo LAVA (liver acquisition with volum

5 -1) days of gestation were imaged using a 3D Spoiled Gradient Echo method at 9.4 T using two contrast

6 dimensional (2D) inversion recovery-prepared spoiled gradient echo sequence at a temporal resolution

7 g for meniscal scoring and axial and coronal spoiled gradient echo sequences with water excitation fo

8 uppression, T2-weighted fast SE imaging, and spoiled gradient-echo (GRE) imaging before and after inj

9 P), fat-suppressed bSSFP, and fat-suppressed spoiled gradient-echo (GRE) sequences for 3.0-T magnetic

10 gittal fat-suppressed three-dimensional (3D) spoiled gradient-echo (SPGR) (60/5, 40 degrees flip angl

11 tagging compared with that of radiofrequency spoiled gradient-echo (SPGR) MR imaging with tagging.

12 on oxide (SPIO)-enhanced and double-enhanced spoiled gradient-echo (SPGR) sequences between 2001 and

13 [PD]-weighted FSE, two-dimensional [2D] fast spoiled gradient-echo [FSPGR], three-dimensional [3D] FS

14 -weighted fast spin-echo [SE] sequence and a spoiled gradient-echo [GRE] sequence) were optimized for

15 inium was used to trigger three-dimensional, spoiled gradient-echo abdominal MR angiography in 50 adu

16 fat-suppressed transverse three-dimensional spoiled gradient-echo acquisitions (3.6-4.5/1.5-1.9 [rep

17 -enhanced MR imaging with serial breath-hold spoiled gradient-echo acquisitions.

18 Spoiled gradient-echo and single-shot rapid acquisition

19 In addition to conventional T1-weighted spoiled gradient-echo and T2-weighted fast spin-echo seq

20 ho and three-dimensional gadolinium-enhanced spoiled gradient-echo and three-dimensional phase-contra

21 MR angiography by using a three-dimensional spoiled gradient-echo breath-hold technique during the a

22 ans of subtraction of three-dimensional fast spoiled gradient-echo images obtained before contrast ma

23 Three-dimensional spoiled gradient-echo imaging (3.8-4.2/1.3-1.7 [repetiti

24 Fifty patients underwent 3D spoiled gradient-echo imaging (4.2/1.8 [repetition time

25 A 3D spoiled gradient-echo imaging technique was used to imag

26 went dynamic gadolinium-enhanced breath-hold spoiled gradient-echo imaging.

27 Spoiled gradient-echo in vivo images of the femur, humer

28 ce [28 women, 31 men]) underwent T1-weighted spoiled gradient-echo inversion recovery magnetic resona

29 nium-enhanced, ultrafast, three-dimensional, spoiled gradient-echo modality and the findings confirme

30 A series of fast or spoiled gradient-echo MR images were obtained during the

31 T2-weighted MR images and three-dimensional spoiled gradient-echo MR images.

32 gnal intensity changes in the magnitude fast spoiled gradient-echo MR images.

33 Gadolinium-enhanced spoiled gradient-echo MR imaging depicts residual tumor

34 nium-enhanced, ultrafast, three-dimensional, spoiled gradient-echo MRA with surgical findings in 15 l

35 times on the order of 800 msec with use of a spoiled gradient-echo pulse sequence (repetition time, 1

36 MR imaging at 1.5 T with a three-dimensional spoiled gradient-echo pulse sequence before and after ad

37 rformed by using a 1.5-T MR unit with a fast spoiled gradient-echo pulse sequence, short repetition a

38 n interpolated three-dimensional T1-weighted spoiled gradient-echo sequence (3.4-6.8/1.2-2.3 [repetit

39 dynamic contrast-enhanced three-dimensional spoiled gradient-echo sequence at 3 T.

40 um-enhanced subtraction MR venography with a spoiled gradient-echo sequence before and at multiple ti

41 ated, high-resolution three-dimensional (3D) spoiled gradient-echo sequence that uses magnitude and f

42 A spoiled gradient-echo sequence with seven echo times alt

43 ed from the same three-dimensional multiecho spoiled gradient-echo sequence.

44 ent, breath holding, and a three-dimensional spoiled gradient-echo sequence.

45 been performed with spin-echo sequences and spoiled gradient-echo sequences.

46 roximately every second for 2 minutes with a spoiled gradient-echo T1 transverse section through the

47 in 205 patients at 1.5 T with use of a fast spoiled gradient-echo technique (repetition time, 9-12 m

48 tetate dimeglumine were combined with a fast spoiled-gradient-echo magnetic resonance (MR) sequence t

49 All had three-dimensional fast spoiled gradient recall (3D FSPGR), T(1)-weighted pre- a

50 A spoiled gradient recall acquisition in the steady-state

51 sessment and a scan using three-dimensional, spoiled gradient recall acquisition volumetric magnetic

52 sion segmentations of three-dimensional fast spoiled gradient recall scans acquired during the same s

53 d six women) by using a high-resolution thin spoiled-gradient recall acquisition in the steady-state

54 mensional, inversion recovery prepared, fast spoiled gradient/recall in the steady state scan of the

55 They had 3D inversion-prepared fast spoiled gradient recalled (FSPGR), dual-echo and triple-

56 during stimulation using a gated multislice, spoiled gradient recalled (SPGR) imaging protocol in a 4

57 scanner with a three-dimensional T1-weighted spoiled gradient recalled pulse sequence.

58 2-weighted sequences and an ultra-low-SAR 3D spoiled gradient-recalled acquisition in the steady stat

59 by using a gadodiamide-enhanced T1-weighted spoiled gradient-recalled acquisition in the steady stat

60 st-to-noise ratio (CNRE) for a fat-saturated spoiled gradient-recalled acquisition in the steady stat

61 ctuating equilibrium, three-dimensional (3D) spoiled gradient-recalled acquisition in the steady stat

62 Fast transverse spoiled gradient-recalled acquisition in the steady stat

63 400/0.15), fat-suppressed three-dimensional spoiled gradient-recalled acquisition in the steady stat

64 Dynamic gadolinium-enhanced fast multiplanar spoiled gradient-recalled acquisition in the steady stat

65 n-echo (oblique axial) and three-dimensional spoiled gradient-recalled acquisition in the steady stat

66 High-resolution spoiled gradient-recalled acquisition magnetic resonance

67 ed by using phase-sensitive T1-weighted fast spoiled gradient-recalled acquisition, T1-weighted contr

68 s on three-dimensional, Fourier-transformed, spoiled gradient-recalled and T2-weighted MRI sequences.

69 Fat-saturated spoiled gradient-recalled images enabled reconstruction

70 sis of dynamic T1-weighted three-dimensional spoiled gradient-recalled imaging data with a two-compar

71 pin-echo imaging and axial three-dimensional spoiled gradient-recalled imaging were performed with ea

72 ate-, and T2-weighted, and three-dimensional spoiled gradient-recalled MR imaging at 3, 6, 12, 24, an

73 ed with a fat-suppressed, three-dimensional, spoiled gradient-recalled sequence.

74 a from the adductor canal to the feet and 3D spoiled gradient-recalled-echo bolus chase MR angiograms

75 9-80 years) underwent fast three-dimensional spoiled gradient-recalled-echo imaging with the keyhole

76 patients were imaged with three-dimensional spoiled gradient-recalled-echo magnetic resonance (MR) a

77 inium-enhanced, T1-weighted, fat suppressed, spoiled gradient-recalled-echo MR images and T2-weighted

78 Fat-suppressed, spoiled gradient-recalled-echo MR images demonstrated hy

79 Sagittal, fat-suppressed, 3D, spoiled gradient-recalled-echo MR imaging of two bovine

80 Fast gradient-echo and spoiled gradient-recalled-echo MR imaging sequences were

81 precession sequence with a three-dimensional spoiled gradient-recalled-echo sequence for MR evaluatio

82 ired with a three-dimensional radiofrequency spoiled gradient-recalled-echo sequence.

83 hat the steady-state sequence is superior to spoiled gradient-recalled-echo sequences for MR evaluati

84 ted, intermediate-weighted, T2-weighted, and spoiled gradient-recalled-echo T1-weighted images.

85 weighted, fast spin-echo; three-dimensional, spoiled gradient-recalled-echo; and fluid-attenuated inv