ライフサイエンスコーパス: short axis

1 ed supraclavicular lymph nodes (> or =0.5 cm short axis).

2 mm in the long axis and > or = 10 mm in the short axis).

3 women/men was 7/9 mm (long axis) and 7/8 mm (short axis).

4 s divided along their experimentally imposed short axis.

5 de or with a lymph node greater than 5 mm in short axis.

6 terior wall penetration was internal jugular short axis 25%, internal jugular long axis 21%, subclavi

7 , internal jugular long axis 21%, subclavian short axis 64%, and subclavian long axis 39%.

8 ntry position tends to lie at one end of the short axis along which cleavage will pass.

9 teractions, in cinchonine it tilts along the short axis and bonds through the lone electron pair of t

10 al lymph nodes measuring 1 cm or more in the short axis and by recruiting centre.

11 greater in long axis and 5%-7% or greater in short axis and decreases of -6% to -10% or greater in lo

12 e imaged the LA and RA of all subjects using short axis and long axis slices by steady-state free pre

13 ocardial borders were traced manually from 2 short-axis and 2 apical views.

14 plane resolution approximately 1 mm(2)) of 5 short-axis and 2 long-axis slices of the heart were acqu

15 al synchrony measurements were made based on short-axis and 4-chamber steady-state free precession im

16 nsional echocardiograms were obtained in the short-axis and apical four-chamber views in 20 normal su

17 Short-axis and horizontal long-axis images were acquired

18 adient-echo (FGE) sequences were acquired in short-axis and horizontal long-axis orientations.

19 o significant difference in time between the short-axis and long-axis views at the internal jugular s

20 ions in the single crystalline disks, as the short axis, and both basal planes were terminated with C

21 nt views (parasternal long axis, parasternal short axis, apical 4-chamber [A4C], and subcostal).

22 hy views: parasternal long axis, parasternal short axis, apical four chamber, subcostal four chamber,

23 Residents used a short-axis approach for ultrasound guidance.

24 lic force during diastole is that the atrial short-axis area (ASA) is smaller than the ventricular sh

25 s area (ASA) is smaller than the ventricular short-axis area (VSA).

26 r in long axis and -6% to -12% or greater in short axis at CT can be considered true changes rather t

27 terior wall penetration of the long axis and short axis at each cannulation site.

28 ber of skin breaks between the long axis and short axis at the subclavian and internal jugular sites.

29 4.0 +/- 0.6 with long axis a = 112 A and the short axis b = 28 A, respectively.

30 001), TAPSE <17 mm (P=0.02), or right atrial short axis/BSA >/=25 mm/m(2) (P=0.04) at baseline.

31 Stretch across the short axis, but not in parallel with the MFs, suppressed

32 LVWT was assessed in parasternal long and short axis by 2-dimensional echocardiography and in shor

33 xis by 2-dimensional echocardiography and in short axis by CMR.

34 Semiautomated segmentation of short-axis cine images was used to create a three-dimens

35 Longitudinal and short-axis cine images were used to quantify left ventri

36 g data included steady-state free precession short-axis cine stack images, cine myocardial tagged ima

37 Short-axis cine steady-state free-precession and postcon

38 Short-axis CMR cines and full-volume 3DTTE data sets of

39 For ex vivo liver, the maximum short-axis coagulation diameter (7.6 cm +/- 0.2 [standar

40 er 8 minutes of treatment at 150 W, the mean short-axis coagulation diameter for in vivo liver was 5.

41 rast in defect region) using circumferential short-axis count profiles.

42 For anatomically matched left ventricular short-axis cross sections (n=46), infarct size measured

43 th filtered backprojection and resliced into short-axis cuts.

44 Pericardial inflammation was quantified on short-axis DHE sequences by contouring the pericardium,

45 er crystals in the left ventricle to measure short axis diameter, an ultrasonic flow meter to measure

46 he presence, size, and location of enlarged (short-axis diameter > 1 cm) abdominal lymph nodes.

47 Long-axis diameter (LAD), short-axis diameter (SAD), and volume were measured for

48 Specimens were serially sectioned, and short-axis diameter and length of each were measured.

49 he patient, prior diagnosis of cancer, nodal short-axis diameter and node location as determined by c

50 endobronchial ultrasonography; (3) a greater short-axis diameter of the mediastinal lymph node and hi

51 Short-axis diameter of these metastases was less than or

52 e longer at days 0, 2, and 28 (P < .05), but short-axis diameter was not different from that with RF

53 ons were as follows: Volume, sphericity, and short-axis diameter were 57.5 cm(3), 0.75, and 43.4 mm,

54 Coagulation volume, sphericity, and mean short-axis diameter were assessed, and mathematical func

55 Volume and short-axis diameter were determined by using a mathemati

56 Three parameters-short-axis diameter, long-axis diameter, and absence of

57 The mean +/- standard deviation of short-axis diameter, long-axis diameter, volume, and sph

58 Size (long-axis diameter, P=.005; short-axis diameter, P=.041) and attenuation (P=.0005) o

59 mferential strain (GCS), wall thickness, and short-axis diameter, was derived from an elliptical LV m

60 tumor deposits generally less than 1.5 cm in short-axis diameter.

61 ss-to-volume ratio (1.1+/-0.3) and geometry (short-axis diameter/length ratio=0.65+/-0.09) were norma

62 The increase in short axis (diameter) compensated for lower arteriolar l

63 poor survival (P </= .01), as were long- and short-axis diameters and number of distant lymph nodes f

64 nd </= .05, respectively), as were long- and short-axis diameters, number, and SUV(max) of distant ly

65 aunhofer MEVIS), we measured node volume and short-axis dimensions (SADs) and long-axis dimensions ba

66 lues of the relationship between the long-to-short axis displacement ratio and LV end-diastolic volum

67 that MA velocity, displacement, and long-to-short axis displacement ratio scale allometrically to he

68 LV short-axis echocardiographic images, LV stroke volume, a

69 /- 1.4 nm for long axis / 3.7 +/- 0.9 nm for short axis) embedded within the polymer matrix, whilst X

70 Reformatted short-axis end-systolic and end-diastolic CT data sets w

71 We assessed LV long-/short-axis function, torsion, volume, inflow dynamics, a

72 Patients with enlarged lymph nodes (short axis >/= 10 mm) on MRI were excluded.

73 Mean LVMT on short axis images at the mid-cavity level was 5.3 +/- 0.

74 e steady-state free precession cine long and short axis images in 300 consecutive participants free o

75 long axis images were 20% less than those on short axis images.

76 respectively) than measurements obtained on short axis images; apical LVMT values on long axis image

77 Short-axis images at the midventricular level were analy

78 e tracking applied to routine midventricular short-axis images calculated radial strain from multiple

79 ession and fast gradient echo cine long- and short-axis images in 2576 asymptomatic participants of M

80 phy used seven or eight spatially registered short-axis images to measure percent of endocardial surf

81 ECG-gated magnetic resonance imaging short-axis images were acquired 2 weeks after coronary l

82 For perfusion imaging, 3 short-axis images were acquired during every heartbeat w

83 frequency, 0.45-0.55 Nyquist; order, 7), and short-axis images were created.

84 nd 3 hours after reperfusion, midventricular short-axis images were digitized and segmented.

85 Midventricular short-axis images were obtained continuously for 40 minu

86 Reconstructed short-axis images were quantitated, and percentage varia

87 rable MRI and 201Tl basal and midventricular short-axis images were subdivided into 6 segments.

88 The short-axis images were transformed to the prolate sphero

89 Comparing findings from short-axis images with those at surgery, average accurac

90 On short-axis images, average bone elevation was 3.2 mm in

91 as measured from circumferential profiles of short-axis images.

92 ns (infarcted, noninfarcted and border) from short-axis images.

93 24.5%, and Hispanic 21.2%) using biplane and short-axis images.

94 rs of surgery) and 4 days later and included short-axis imaging at the midpapillary and apical levels

95 Short-axis imaging from apex to base was used to determi

96 Patients underwent breath-hold MR-tagged short-axis imaging on day 4+/-2 after MI at baseline and

97 Longitudinal and short-axis imaging readily disclosed each cardiac valve,

98 Selective inversion of magnetization in the short-axis imaging section along with all myocardium api

99 determined every other heartbeat in a single short-axis imaging slice.

100 gradient-echo MR tagging was performed with short-axis imaging spanning the LV.

101 ven when the first cleavage occurs along the short axis imposed by this experimental treatment, the p

102 he LV lead location was classified along the short axis into an anterior, lateral, or posterior posit

103 We acquired basal and apical short-axis left ventricular (LV) images in 15 patients t

104 ction, such as cavity shape and the ratio of short-axis left ventricular muscle to cavity area, may p

105 tion was significantly greater at the apical short-axis level in all wall regions than in other short

106 y greater at the lateral wall, regardless of short-axis level, whereas E(1) "radial thinning" strains

107 displacement, and E(1) and E(2) strains at 3 short-axis levels (significance was defined as P<0.05).

108 the atrioventricular valve (AVV) and apical short-axis levels and in 4 anatomic wall regions.

109 C) were computed at both LV base- and mid-LV short-axis levels remote from the site of anteroapical S

110 of the LV were acquired at apical and basal short-axis levels to assess LV torsion.

111 Look-Locker images were acquired at four short-axis levels to measure myocardial and blood longit

112 nt differences in radial wall motion between short-axis levels were noted.

113 axis level in all wall regions than in other short-axis levels, and it was clockwise.

114 At all short-axis levels, septal radial motion was significantl

115 ains were similar in all wall regions at all short-axis levels.

116 n or in endocardial/epicardial strain at all short-axis levels.

117 adolinium-diethylenetriaminepentacetate at 3 short-axis locations using a saturation recovery interle

118 Short-axis magnetic resonance tagging was performed span

119 Short-axis maps were generated using an OsiriX plug-in t

120 Both the long and short axis measurements were significantly higher in Gro

121 ing lesion size; 95% limits of agreement for short-axis measurements were -11.6% to 6.7% for lesions

122 For long- and short-axis measurements, respectively, overall intraobse

123 An abnormal bone contour identified on a short-axis MR image at the femoral head-neck junction co

124 f myocardial perfusion data on four parallel short-axis MR image sections at every heartbeat.

125 surgery, the alpha angle was normal but the short-axis MR image showed abnormal bone contour.

126 Short-axis MR images of the femoral head-neck junction w

127 0 patients, 3D dual cardiac phase data sets, short-axis multisection breath-hold images, and through-

128 LV size, short-axis muscle (mass) area (LVMA), and function were

129 ensitivity analysis determined that a 1.5-cm short axis nodal measurement distinguished patients with

130 distribution of signal intensity across the short axis of any rod-shaped object.

131 fluorescent protein distribution across the short axis of rod-shaped bacteria.

132 c fields, yielding divisions parallel to the short axis of the cell and the compressive tensor.

133 of the peptidoglycan network parallel to the short axis of the cell, with distinct architectural feat

134 long, reflecting greater restriction in the short axis of the cell.

135 sition during metaphase was only 0.5% of the short axis of the cell.

136 eviation, was only 1.5% of the length of the short axis of the cell.

137 he early AP axis are first aligned along the short axis of the elliptical egg cylinder.

138 t, even modest degrees of stretch across the short axis of the MFs suppressed total contractile prote

139 ls treated with ISO and stretched across the short axis of the MFs.

140 round the center of the forespore across the short axis of the sporangium.

141 strated FDG-avid lymph nodes up to 1.5 cm in short axis on PET/CT, which did not represent active lym

142 Myocardial contrast echocardiography in a short-axis (open-chest) or modified four-chamber view (c

143 rwent real-time and cine MRI in the standard short-axis orientation with a 1.5T MRI scanner.

144 e measured in each of 20 sectors per LGE-CMR short-axis plane.

145 perfusion images at rest were acquired in 3 short-axis planes by use of a T1-weighted turboFLASH seq

146 1.5-T clinical scanner to acquire contiguous short-axis planes from the apex to the mitral valve plan

147 dolinium-enhanced cardiac magnetic resonance short-axis planes.

148 us to evaluate aortic valve area directly by short axis planimetry.

149 The third used basal, middle and apical short-axis plus apical four- and two-chamber views compa

150 e same increase was not observed in the long/short axis ratio.

151 lation coefficient, rs = 0.161 and P = .049; short axis: rs = 0.128 and P = .163).

152 A short-axis saturation-recovery gradient-echo section was

153 , and empty fractions (EFs) were provided by short axis (SAX) and area-length methods.

154 frame, 13 frames per section position, nine short-axis section positions per breath hold).

155 Twelve contiguous short-axis sections and six four-chamber sections that c

156 o peak Ecc were measured in 12 segments from short-axis sections.

157 steady-state free precession 4-chamber and 3 short axis sequences and regions of interest were drawn

158 Eight myocardial sectors were analyzed per short axis slice and myocardial blood flow calculated wi

159 surements were performed at a midventricular short axis slice before (ie, native T1 times) and after

160 pressed as a percent of the left ventricular short axis slice) decreased over the course of six weeks

161 T1 mapping was performed in single short-axis slice before and after 15 minutes of gadolini

162 size index was generated from the number of short-axis slices and average radius of each slice, and

163 Circumferential profiles of the short-axis slices and the contrast of the inserts were u

164 re measured in six to eight left ventricular short-axis slices of equal thickness using technetium-99

165 Five- to 10-microm contiguous short-axis slices of explanted hearts from 3 patients wi

166 The homogeneity of count distribution in short-axis slices of the normal phantom was analyzed as

167 resonance imaging LVESV from summated serial short-axis slices was significantly greater than LVESV a

168 Matching short-axis slices were acquired for cine, T1 mapping, an

169 Five representative short-axis slices were analyzed to determine defect size

170 SPECT short-axis slices were projected to create reprojected i

171 Myocardial function, scar, perfusion (2-3 short-axis slices), and oxygenation were assessed.

172 Two short-axis slices, 1 basal and 1 apical were analyzed.

173 With the LV viewed in equidistant short-axis slices, the region of dysfunction was demarca

174 owest ratio of minimal/maximum counts from 5 short-axis slices.

175 arrhythmia-specific 757-segment analysis of short-axis SPECT images was performed in all datasets.

176 ection fraction, myocardial edema (multiecho short-axis spin-echo acquisition), and myocardial fibros

177 evaluated by biplane and volumetric (cardiac short-axis stack) cine MRI and by biplane and volumetric

178 o measure LV function and volume from serial short-axis summation.

179 with a noncompaction ratio of >/=2 underwent short axis systolic and diastolic LVNC ratio measurement

180 Midventricular short-axis T1 maps were acquired in the same examination

181 Short-axis tagged magnetic resonance images were acquire

182 med manually for 60 degrees samples of 11-13 short-axis tomograms spanning the entire heart, from whi

183 Short-axis two-dimensional echocardiography demonstrated

184 PVR areas seen on a short-axis view were measured immediately after deployme

185 internal jugular was more efficient than the short-axis view with fewer redirections.

186 l circumferential S and SRs from parasternal short-axis view with speckle tracking software (Velocity

187 ormal function from the parasternal long- or short-axis view.

188 igher than those of nonisotropic images with short-axis views (median, 4 vs 3 [25th and 75th percenti

189 c global circumferential strain (GCS) from 2 short-axis views and global longitudinal strain (GLS) fr

190 dial (Err) systolic strains were measured on short-axis views at basal, mid, and apical left ventricu

191 uman torso mannequin using the long-axis and short-axis views at each site.

192 g-axis views and circumferential strain from short-axis views were measured on 2-dimensional echocard

193 t 1.5 T on basal, midventricular, and apical short-axis views.

194 of the LV (basal, midventricular, and apical short axis) was applied in 31 patients with nonischemic

195 Gated end-systolic images in short axis were acquired in harmonic mode and digitized

196 tinal nodes measuring 1 cm or greater in the short axis were considered positive.

197 M-mode tracing of the left ventricular (LV) short-axis were recorded.