ライフサイエンスコーパス: annulus

1 l tunnel suture line and the tricuspid valve annulus.

2 with the enlarged but relatively normal FED annulus.

3 together and locked, plicating the posterior annulus.

4 similar torque capacity to pristine graphene annulus.

5 ontribute to the critical torque strength of annulus.

6 the papillary muscles, fascicles, and mitral annulus.

7 signal (bipolar voltage >/=1.5 mV) to the PV annulus.

8 o the tricuspid annulus, and 6 to the mitral annulus.

9 n also accurately measure the annular aortic annulus.

10 hofunctional abnormality of the mitral valve annulus.

11 aking multiple small incisions in the mitral annulus.

12 ventricular septal defect patch-to-tricuspid annulus.

13 unding negative collar, and a positive outer annulus.

14 d from the stress-strain relationship of the annulus.

15 arkers sewn equally spaced around the mitral annulus.

16 IPL thickness formed a horizontal elliptical annulus.

17 observed among patients with a small aortic annulus.

18 ucture with a three-dimensional saddle shape annulus.

19 left inferior pulmonary vein with the mitral annulus.

20 red with the SAPIEN 3 in patients with small annulus.

21 rect intraoperative assessment of the aortic annulus.

22 , circumpapillary images were derived for an annulus 100 microm in width, and the retinal nerve fiber

23 re higher in men than in women at the aortic annulus (13.1+/-1.7 versus 12.9+/-1.7 mm/m(2); P=0.007),

24 Patients (n = 120; aortic annulus 19 to 27 mm) considered by a multidisciplinary h

25 es included (1A) ventriculotomy-to-tricuspid annulus, (1B) ventriculotomy-to-ventricular septal defec

26 elastoma, 1; caseous calcification of mitral annulus, 3; and thrombus, 3.

27 efect patch, (2) ventriculotomy-to-pulmonary annulus, (3) pulmonary annulus-to-ventricular septal def

28 These mitral annulus abnormalities, together with auscultatory midsys

29 e left-sided pulmonary veins with the mitral annulus along the posterior base of the left atrial appe

30 vides comprehensive information about aortic annulus anatomy and geometry, supporting appropriate pat

31 e test, acquisition of information on aortic annulus anatomy, peripheral access sites, and evaluation

32 4 tachycardias were localized to the mitral annulus and 37 to the tricuspid annulus (including 9 par

33 ars, between scars, or between the tricuspid annulus and a scar.

34 ee-dimensional (3D) assessment of the aortic annulus and adjacent structures by multislice computed t

35 issural zone, and the boundary zone near the annulus and at the coaptation line, with reduced strain

36 area and areas determined by ventricle size (annulus and closure areas).

37 illar, with controllable extension above the annulus and into the surrounding solution.

38 is-patient mismatch between the small aortic annulus and LAA tertiles, but a higher rate of moderate-

39 tware, patient-specific models of the mitral annulus and leaflets were computed at mid- and end-systo

40 om prestage 1 3DE, spatial coordinates of TV annulus and leaflets were extracted; annulus size, leafl

41 ipheral vasculature, the aortic root and the annulus and optimal fluoroscopic positioning.

42 icular (LV) contraction displaces the aortic annulus and produces a force that stretches the ascendin

43 Aortic annulus and prosthesis diameter were not predictors of p

44 surrogate of the distance between the aortic annulus and the His bundle.

45 riate sizing of the dimensions of the aortic annulus and to choose not only the size but also the tra

46 chycardia, 3 were localized to the tricuspid annulus, and 6 to the mitral annulus.

47 with the highest strain at the commissures, annulus, and coaptation zones.

48 nificant injuries to the aorta, aortic valve annulus, and left ventricle require open surgical repair

49 plications involving the aorta, aortic valve annulus, and left ventricle.

50 -sectional area of the sinotubular junction, annulus, and LVOT, and the presence, location, and exten

51 mitral annulus, crista terminalis, tricuspid annulus, and right-sided PV via a posterior conduction o

52 EROA, RVol, annulus, and sinotubular junction should be routinely me

53 As a result, the graphane annulus anomalously has similar torque capacity to prist

54 Therefore, the beta-annulus appears not to be essential for particle assembl

55 ical outcomes in 246 patients with an aortic annulus area <400 mm(2) undergoing transcatheter aortic

56 Neoaortic annulus area (4.2 +/- 1.2 versus 4.9 +/- 1.2 cm(2)/m(2))

57 01), pulmonary arterial pressure (P</=0.001) annulus area (P=0.027), and apical displacement of the a

58 Pulmonary arterial pressure (r=0.66), annulus area (r=0.51), apical displacement of the anteri

59 rrelated to leaflet area (r=0.736; P<0.001), annulus area (r=0.651; P<0.001), right ventricular end-d

60 capillary area divided by the corresponding annulus area after subtraction of noncapillary blood ves

61 Median aortic annulus area and perimeter were 617 mm(2) (591-657) and

62 GE EchoPAC was used to measure annulus area and position of the PM tips.

63 uced >50% had a smaller preprocedural mitral annulus area compared with patients with </=50% reductio

64 analysis, LV end-systolic volume and mitral annulus area most strongly predicted MR (r(2)=0.82, P<0.

65 ing algorithm with an optimal goal of modest annulus area oversizing (5% to 10%).

66 The implementation of an MDCT annulus area sizing algorithm for TAVR reduces PAR.

67 2%, P=0.003) for the S3-THV, despite reduced annulus area to prosthesis oversizing (8.2+/-5.1 versus

68 striction angle (posterior leaflet to mitral annulus area) by 2-dimensional and 3-dimensional echocar

69 /- 0.6 cm; P < 0.0001), MV annulus areas (2D annulus area, 13.9 +/- 3.8 and 12.8 +/- 3.4 cm(2); P < 0

70 .8 and 12.8 +/- 3.4 cm(2); P < 0.0001 and 3D annulus area, 14.4 +/- 3.9 and 12.9 +/- 3.4 cm(2); P < 0

71 gitation fraction and vena contracta, mitral annulus area, and posterior leaflet restriction angle (p

72 Annulus area, perimeter, and orthogonal maximum and mini

73 +/- 0.6 and 3.6 +/- 0.6 cm; P < 0.0001), MV annulus areas (2D annulus area, 13.9 +/- 3.8 and 12.8 +/

74 eaflet (R(2)=0.97), closure (R(2)=0.89), and annulus areas (R(2)=0.84).

75 eaflet to closure areas and total leaflet to annulus areas when compared with patients without FMR (P

76 CT to measure MV total leaflet, closure, and annulus areas.

77 L) interface was quantified within a 0.70-mm annulus around Bruch's membrane opening after removal of

78 36) transduced ganglion cells within a dense annulus around the fovea center, whereas AAV2 containing

79 is who had both contrast MDCT and 3D-TEE for annulus assessment before balloon-expandable transcathet

80 ean perimeter-derived diameter of the aortic annulus at baseline with TAV (23.3+/-2.2 versus 23.6+/-1

81 ng (contrast CT and/or 3D-TEE) of the aortic annulus at baseline.

82 teria, the tubulin-like GTPase FtsZ forms an annulus at midcell (the Z-ring) which recruits the divis

83 correlated with destabilization of the beta-annulus at the icosahedral 3-fold axes.

84 4B/Snf7 concentration in a negatively curved annulus at the rim of the invagination.

85 epair in the presence of a dilated tricuspid annulus at the time of a left-sided valve surgical inter

86 th the densitometry values in the 0- to 2-mm annulus at total thickness (P = 0.014 and P = 0.022, res

87 rior quadrant 3D RNFL volume of the smallest annulus (AUROC value 0.977).

88 nding region at the quasi-6-fold at the beta-annulus axes remained intact.

89 T) measurements for the assessment of aortic annulus before transcatheter aortic valve replacement.

90 fer cross-sectional assessment of the aortic annulus but its role for TAVR sizing has been poorly elu

91 at the sinuses of Valsalva and aortic valve annulus, but this difference is minor and clinically ins

92 Mitral annulus calcification (MAC) is a chronic, degenerative p

93 ted sinotubular junction and a normal aortic annulus can be treated with remodeling of the aortic roo

94 ntermediate-depth strata through failures of annulus cement, three to target production gases that se

95 P=0.036) and tended to have a smaller mitral annulus circumference (13.0+/-2.0 versus 14.8+/-4.1 cm,

96 erior/posterior leaflet projections onto the annulus, coaptation height, and mitral regurgitation jet

97 The automated 3D annulus commissure coronary ostia distances in normals s

98 s with ONHD had thicker retinae in the inner annulus compared with patients with ODE and controls (si

99 tinct structure in stage 3, a hyporeflective annulus consisting of deflected, degenerated or absent p

100 he intercommissural distance, 4 mm above the annulus, could be integrated in gray zones.

101 ht pulmonary vein (PV) in 3 patients, mitral annulus, crista terminalis, tricuspid annulus, and right

102 d by mild residual obstruction and pulmonary annulus diameter <0.5z.

103 In patients with an aortic annulus diameter <20 mm, severe PPM developed in 33.7% u

104 emic RV, NT-proBNP levels correlated with RV annulus diameter (r = 0.31, p = 0.024).

105 were divided in tertiles according to aortic annulus diameter (small aortic annulus tertile, medium a

106 underwent serial echocardiography, measuring annulus diameter and valve and right ventricular functio

107 The aortic annulus diameter in BAV patients was not significantly l

108 nterval, 3.5-21.0; P<0.001), tricuspid valve annulus diameter z-score (odds ratio, 1.3; 95% confidenc

109 rtic valve calcification density, and aortic annulus diameter, female sex was an independent risk fac

110 on (mean gradient, 24+/-13 mm Hg), pulmonary annulus diameters <0.5z, and unobstructed branch pulmona

111 urgitation fraction, 24.2+/-2.9%) and mitral annulus dilatation (P<0.01).

112 In contrast, annulus dilatation but not flattening occurred in nonpro

113 were also markedly abnormal with the mitral annulus dilating rapidly in early systole in response to

114 mputed tomography-based assessment of aortic annulus dimension in conjunction with adapted sizing gui

115 al 3D echocardiographic sizing of the aortic annulus dimension offers discrimination of post-TAVR par

116 and function, neo-aortic and tricuspid valve annulus dimensions and function, and aortic size and pat

117 Aortic annulus dimensions were quantified by multislice compute

118 prolapse, marked leaflet redundancy, mitral annulus disjunction (MAD), a larger left atrium and left

119 Mitral annulus disjunction (median: 4.8 versus 1.8 mm; P<0.001)

120 linear correlation was found between mitral annulus disjunction and curling (R=0.85).

121 of the mitral annulus showed a longer mitral annulus disjunction in 50 sudden death patients with MVP

122 Mitral annulus disjunction is a constant feature of arrhythmic

123 pillary muscles and inferobasal wall, mitral annulus disjunction, and systolic curling have been rece

124 work was the integrated product of force and annulus displacement during systole.

125 stimates of left ventricular mass and mitral annulus e' velocity (median absolute deviation of 16% an

126 ricular mass, left atrial volume, and mitral annulus e-prime) and disease (pulmonary arterial hyperte

127 E] to early diastolic velocity of the mitral annulus [E']; P = .003), impaired pulmonary function (di

128 oke volume, isovolumic relaxation, E' septal annulus, E/E' septal annulus, left ventricular diastolic

129 mean GCL+IPL thickness formed an elliptical annulus elongated by approximately 30% in the horizontal

130 33.6% +/- 3.98%, P = .034) at the innermost annulus (FAZ margin to 200 mum out).

131 lure of midline fusion within the developing annulus fibrosis of the intervertebral discs and increas

132 (IVD) herniation involves disruption of the annulus fibrosus (AF) caused by ageing or excessive mech

133 tenance of healthy nucleus pulposus (NP) and annulus fibrosus (AF) have not been fully elucidated.

134 Efficacious annulus fibrosus (AF) repair strategy that delivers cell

135 The annulus fibrosus (AF) represents a complex, multilamella

136 n growth plate (GP), cartilage endplate (EP) annulus fibrosus (AF), and nucleus pulposus (NP) with va

137 ounded by a multi-layered fibrocartilagenous annulus fibrosus (AF).

138 model involving degenerative inflamed human annulus fibrosus (hAF) cells was established in vitro an

139 lts for both nucleus pulposus (R = 0.92) and annulus fibrosus (R = 0.83) regions.

140 ained samples resolved the nucleus pulposus, annulus fibrosus and constituent lamellae, and finer str

141 d reporter and immunohistochemical staining, annulus fibrosus and nucleus pulposus cells of young-adu

142 placement of intervertebral disk structures (annulus fibrosus and nucleus pulposus) by cartilage and

143 Healthy bovine annulus fibrosus cells, however, demonstrated a protecti

144 12.5 kPa +/- 1.3; grade 5, 16.5 kPa +/- 2.1; annulus fibrosus grade 1, 90.4 kPa +/- 9.3; grade 5, 120

145 By using puncture surgery of the annulus fibrosus in rabbits, ex vivo puncture experiment

146 7.5 revealed an abnormal organization of the annulus fibrosus in the dKOs, with chondrocyte-like cell

147 ficant increase in both nucleus pulposus and annulus fibrosus MR elastography-derived shear stiffness

148 shear stiffness of the nucleus pulposus and annulus fibrosus regions of all lumbar IVDs were assesse

149 bute to the mesenchyme of the AV sulcus, the annulus fibrosus, and the parietal leaflets of the AV va

150 the contribution of EPDCs to the AV sulcus, annulus fibrosus, and the parietal leaflets of the AV va

151 ell and nucleus in meniscus, tendon, and the annulus fibrosus, as well as in stem cell-seeded scaffol

152 ller AV sulcus and a severely underdeveloped annulus fibrosus.

153 rtebral disc generate prestrain in the outer annulus fibrosus.

154 chordal rupture increased progressively with annulus flattening (7% versus 24% versus 42% for AHCWR >

155 ive value of multiple measures of the aortic annulus for post-TAVR paravalvular (PV) regurgitation an

156 be a novel zinc binding site within the beta annulus formed by the N termini of the three C subunits

157 on at common non-PV AF trigger sites (mitral annulus, fossa ovalis, eustachian ridge, crista terminal

158 The aortic annulus, generally elliptic, assumes a more round shape

159 without differences compared with the large annulus group.

160 hose with mild to moderate TR with a dilated annulus (>/=40 or >/=21 mm(2), Class IIa).

161 ng to the presence of RV dilation (tricuspid annulus>=40 mm) and RV systolic dysfunction (tricuspid a

162 arkedly disordered, suggesting that the beta-annulus had been disrupted and that this could destabili

163 s sizes for global RNFL volume, the smallest annulus had the best AUROC values (P values: .0317 to .0

164 degeneration were pre-operative large aortic annulus (hazard ratio: 1.1; p = 0.01), pre-operative aor

165 atients versus 4 of 6 controls and tricuspid annulus in 5 of 18 ARVD patients versus 2 of 6 controls

166 e maximal excursion of the leaflets from the annulus in diastole.

167 owed greater TV tethering volume and flatter annulus in group B.

168 valence, and clinical impact of small aortic annulus in patients with aortic stenosis, and evaluate t

169 tion prostheses similarly reshape the aortic annulus in TAV and BAV.

170 tometry values, especially in the 0- to 2-mm annulus in the anterior layer (r = 0.419; P = 0.001), wh

171 o the mitral annulus and 37 to the tricuspid annulus (including 9 para-Hisian), and all were adenosin

172 ensional, noncircular geometry of the aortic annulus is important for transcatheter heart valve (THV)

173 Caseous calcification of mitral annulus is rather rare echocardiographic finding with pr

174 s (4 weeks) and, later, cells in the leaflet/annulus junction mesenchyme expressing inactive NFATC1 (

175 At this leaflet/annulus junction, CD44(+) cells clustered during elongat

176 , which subsequently ascend from the leaflet/annulus junction.

177 e 1 tethering is related to having larger TV annulus, larger leaflet area, larger right ventricular s

178 c relaxation, E' septal annulus, E/E' septal annulus, left ventricular diastolic volume).

179 These patients had larger annulus, lower cover-index; more often had transfemoral

180 ed that D-shaped versus saddle-shaped mitral annulus (MA) segmentation is more biomechanically approp

181 ion affects the zinc binding and/or the beta-annulus, making it more fragile under neutral/basic pH c

182 The mean diameter of the prostheses at the annulus matched the mean perimeter-derived diameter of t

183 The smallest-size annulus may have the best diagnostic potential, partly o

184 This study compares annulus measurements from 3D-TEE using off-label use of

185 Annulus measurements from both modalities predict mild o

186 Annulus measurements using a new method for analyzing 3D

187 er diagnostic performance than the larger RT annulus OCA3.

188 f lipid bilayer rendered water-soluble by an annulus of "membrane scaffold protein." Disc-enclosed bi

189 cisions were made along the posterior mitral annulus of a pressurized left ventricle.

190 ivision machine that directs an invaginating annulus of cell wall peptidoglycan.

191 e inferior quadrant of outer circumpapillary annulus of circular grid (OCA) 1 (0.959, 0.939), inferio

192 nitially, to which is then added an external annulus of dendrites only in sublamina b whose origin is

193 long-range nature, extending beyond a single annulus of next-neighbor boundary lipids.

194 tion would propel the DNA towards the narrow annulus of NurA, leading to duplex melting and nucleolyt

195 contained in sublamina b, thereby forming an annulus of secondary ON dendrites in sublamina b.

196 ith aortic insufficiency or a dilated aortic annulus or ascending aorta were at greater risk for rein

197 vena cava, superior vena cava, or tricuspid annulus or by ablating focally in the lateral RA.

198 g aortic root dimensions at the aortic valve annulus or sinus of Valsalva in elite athletes (n=5580).

199 n vena cavae and right atrium; the tricuspid annulus; or between TV leaflets, improving coaptation.

200 roups, the MR+ group had more dilated mitral annulus (P<0.0001), a reduced annular height to commissu

201 ing femoral delivery (P=0.04), larger aortic annulus (P=0.0004), and smaller prosthesis diameter (P=0

202 tolic short-/long-axis ratio <0.6, tricuspid annulus peak systolic velocity >/= 8 cm/s, and peak syst

203 ic short-/long-axis ratio >/= 0.6, tricuspid annulus peak systolic velocity <8 cm/s, and peak systoli

204 and long-axis/length-area ratios, tricuspid annulus peak systolic velocity, RV peak longitudinal glo

205 DAR) was also calculated based on the native annulus perimeter and perimeter of the selected THV.

206 Aortic annulus perimeter appears therefore ideally suited for a

207 type of upper bulge stem cells, the vascular annulus persisted in surgically denervated mouse skin.

208 n in controls, both measured using tricuspid annulus plane systolic excursion (stress, 25.0 mm +/- 5.

209 V fractional area change (FAC) and tricuspid annulus plane systolic excursion (TAPSE) for the predict

210 Tricuspid annulus plane systolic excursion decreased and the perce

211 High Z(va) and low tricuspid annulus plane systolic excursion were associated with wo

212 treatment arm, high Z(va) and low tricuspid annulus plane systolic excursion, but not moderate to se

213 The aortic annulus plane was reconstructed in 10% increments over t

214 The presence of a small aortic annulus poses a considerable challenge in the management

215 boptimal placement of the prosthesis, and/or annulus-prosthesis-size mismatch due to malsizing can co

216 oups, the post-operative anterior MV leaflet-annulus ratio was 17% greater and tenting area 24% small

217 ior leaflet and posterior part of the mitral annulus, reducing posterior leaflet mobility.

218 RNFL microcirculation was measured within an annulus region centered at the optic nerve head divided

219 lacement >2 versus </=2 mm beyond the mitral annulus, respectively.

220 smallest inflow, left AVV color diameter at annulus, right AVV overriding left atrium, and LV width.

221 ice success (100% vs 92.8%; P=0.37), risk of annulus rupture (0% vs 1.4%; P=1.00), or valve migration

222 ally life-threatening complications, such as annulus rupture or aortic dissection, remained stable ov

223 s the composite of in-hospital death, aortic annulus rupture, and severe PAR.

224 ere constructed by the self-assembly of beta-annulus-S-peptide and the interaction between S-peptide

225 The beta-annulus-S-peptide was synthesized by native chemical lig

226 thesized by native chemical ligation of beta-annulus-SBz peptide with Cys-containing S-peptide that s

227 omain OCT corresponded to the hyporeflective annulus seen by AOSLO.

228 Preoperative MDCT measurements of the aortic annulus served as basis for assignment to a theoretical

229 ith virus particles in tailor-made disk- and annulus-shaped microchambers, that strong confinement of

230 Previously, we used an annulus-shaped PET transmission source inside the field

231 sion, a transmission-based technique with an annulus-shaped transmission source will be more accurate

232 Histology of the mitral annulus showed a longer mitral annulus disjunction in 50

233 ed the thickest retina and RNFL in the outer annulus (significant in the inferior segment compared wi

234 pe (n=10, with coaptation height >40% of the annulus similar to posterior MVP); plus 138 healthy refe

235 a larger prosthesis with increasing indexed annulus size ( P<0.001), while there was no difference i

236 /- 1.03 mm vs. 8.55 +/- 1.34 mm, p < 0.001), annulus size (20.9 +/- 1.4 vs. 22.9 +/- 1.7 mm, p < 0.00

237 of AVC load, absolute and relative to aortic annulus size (AVCdensity), on overall mortality in patie

238 osthesis-patient mismatch (PPM), considering annulus size and body size of patients.

239 and left ventricle (LV) may alter tricuspid annulus size and papillary muscle (PM) positions leading

240 ry can lead to TR by altering both tricuspid annulus size and PM position.

241 ltidetector computed tomography-based aortic annulus size consisted of the perimeter-derived diameter

242 after TAVR versus SAVR in the large indexed annulus size group (2.5% versus 0%; P=0.01) but without

243 Aortic annulus size had a major impact on valve hemodynamics an

244 hlights the importance of considering aortic annulus size in the evaluation of high-risk patients who

245 ective was to evaluate the effects of aortic annulus size on valve hemodynamics and clinical outcomes

246 Indexed annulus size was an independent predictor of PPM after T

247 s of TV annulus and leaflets were extracted; annulus size, leaflet area, prolapse volume, tethering v

248 than after SAVR across all groups of indexed annulus size, reflecting better hemodynamic performance

249 (>14-18 mm/m(2)) group according to indexed annulus size.

250 , especially in patients with a small native annulus size.

251 d by body surface area to produce an indexed annulus size.

252 bal 2D RNFL thickness AUROC values for all 4 annulus sizes (P values: .0593 to .6866).

253 When comparing the 4 annulus sizes for global RNFL volume, the smallest annul

254 ( P<0.001) and declined with larger indexed annulus sizes with both TAVR ( P=0.04) and SAVR ( P=0.03

255 ent frame at the level of the virtual aortic annulus, stent frame underexpansion due to heavily calci

256 By birth, a vascular annulus stereotypically surrounded the keratin 15 negati

257 ypically exhibit pressure in their outermost annulus (surface casing pressure, SfCP) due to gas accum

258 0 mm) and RV systolic dysfunction (tricuspid annulus systolic excursion plane<17 mm): pattern 1, norm

259 ranscatheter device to plicate the tricuspid annulus (TA) and reduce tricuspid regurgitation (TR).

260 left-heart valve surgery when the tricuspid annulus (TA) is dilated but methodology for the measurem

261 ium aortic annulus tertile, and large aortic annulus tertile [LAA], respectively) as measured by tran

262 d trial cohort, patients in the small aortic annulus tertile who underwent transcatheter aortic valve

263 tertile, P=0.035 for LAA versus small aortic annulus tertile).

264 (small aortic annulus tertile, medium aortic annulus tertile, and large aortic annulus tertile [LAA],

265 ing to aortic annulus diameter (small aortic annulus tertile, medium aortic annulus tertile, and larg

266 alysis (P=0.048 for LAA versus medium aortic annulus tertile, P=0.035 for LAA versus small aortic ann

267 population by visual flicker, limited to an annulus that constricts content complexity to simple mov

268 m no HFPEF were 0.823 for E/E' at the medial annulus, the best TDE parameter; 0.816 for bPP; and 0.86

269 Through-the-annulus threading of calix[5]arene penta-O-ethers by dia

270 A complete study of the through-the-annulus threading of the larger calix[8]arene macrocycle

271 ]arene macroring cannot give the through-the-annulus threading with them because of its small dimensi

272 omplexation to occur or to allow through-the-annulus threading?

273 in vivo mechanical properties of the aortic annulus throughout the cardiac cycle.

274 ume measurement from the level of the aortic annulus to the aortic bifurcation.

275 Despite the anatomic proximity of the aortic annulus to the LM, TAVR plus LM PCI is safe and technica

276 culotomy-to-pulmonary annulus, (3) pulmonary annulus-to-ventricular septal defect patch, and (4) vent

277 successfully implanted in 22 (88%) patients (annulus too large and extreme horizontal aorta in 2 and

278 ion of neural networks forming a functional "annulus-type" central nervous system with three subsets

279 ing characteristics in hydrogenated graphene annulus under circular shearing at the inner edge.

280 offer the opportunity to measure the aortic annulus under direct vision during the procedure.

281 s measured by increasing the intensity of an annulus until it veiled a central target.

282 incisions in the atrial aspect of the mitral annulus using a cardioport video-assisted imaging system

283 whereas aortic root size at the aortic valve annulus was 1.6 mm (P=0.04) greater in athletes than in

284 ional spatio-temporal representation of each annulus was generated through a best fit using 16 piecew

285 ent with RP, mfERG amplitude for each circle/annulus was highly correlated with corresponding layer t

286 icornavirales, no intra-pentamer stabilizing annulus was seen, instead the intra-pentamer stability c

287 y and dimensions of sinotubular junction and annulus were associated with progression (all p <= 0.007

288 ntrol to ring state at end-systole along the annulus were calculated.

289 solute AVC to cross-sectional area of aortic annulus) were measured, and severe AVC was separately de

290 he percentage of the detected vessels in the annulus) were measured.

291 rated smaller responses from the surrounding annulus when it was contiguous compared with when it was

292 e and was localized adjacent to the vascular annulus, which comprised post-capillary venules.

293 g cells at the perimeter to express an OCT4+ annulus, which is coincident with a region of higher cel

294 ography was used to visualize and tag the PV annulus, which was then integrated with 3-dimensional vo

295 able to SAVR in patients with a small aortic annulus who are susceptible to PPM to avoid its adverse

296 , each with a nanoscale separation gap (coax annulus width).

297 induced compressive strains along the entire annulus, with greatest values occurring at the lateral m

298 ocalized in the posterior part of the mitral annulus, with markedly calcified margins, and no signifi

299 severe paravalvular leak) in the extra-large annulus, without differences compared with the large ann

300 ariate analysis, a preoperative aortic valve annulus z score of </=-2.5 was associated with reinterve