ライフサイエンスコーパス: femoral artery

1 the iliac artery and the lateral circumflex femoral artery.

2 agm-like and involved the lateral circumflex femoral artery.

3 e distal and middle parts of the superficial femoral artery.

4 the study, using a permanently catheterized femoral artery.

5 Mice were subjected to wire injury of the femoral artery.

6 attenuated the reflex in rats with a ligated femoral artery.

7 om rats exposed to surgical occlusion of the femoral artery.

8 e (SNP)-induced relaxation in denuded rabbit femoral artery.

9 in occlusion/15-min release of the left-hind femoral artery.

10 50 mL/min by means of catheterization of the femoral artery.

11 /without various inhibitors in intact rabbit femoral artery.

12 flow probes around an umbilical artery and a femoral artery.

13 and with a transit-time flow probe around a femoral artery.

14 tes after insertion of the catheter into the femoral artery.

15 microM for rabbit bladder and 0.3 microM for femoral artery.

16 el and a neointimal hyperplasia model of the femoral artery.

17 sorbable following implantation in a porcine femoral artery.

18 APP did not alter thrombus formation in the femoral artery.

19 paclitaxel-coated devices in the superficial femoral artery.

20 db/+ and db/db mice by ligation of the left femoral artery.

21 n and underwent a sham operation on the left femoral artery.

22 rmation and repair after acute injury to the femoral artery.

23 al hindlimb ischemia was induced by ligating femoral artery.

24 se pressor reflex found in rats with ligated femoral arteries.

25 exercise pressor reflex in rats with ligated femoral arteries.

26 vivo on isolated aortas, but also in vivo on femoral arteries.

27 on on the pressor reflex in rats with patent femoral arteries.

28 ygen species production in rats with ligated femoral arteries.

29 ovine model by implanting the scaffolds into femoral arteries.

30 47) in participants with completely occluded femoral arteries.

31 perficial external pudendal artery (2), deep femoral artery (1), lateral circumflex femoral artery (3

32 Lesion characteristics were 199 superficial femoral arteries, 110 popliteal, 218 tibials, and 52 mul

33 umflex femoral artery (3), medial circumflex femoral artery (2), articular branch of descending genic

34 descending genicular artery (1), perforating femoral arteries (3), posterior tibial recurrent artery

35 deep femoral artery (1), lateral circumflex femoral artery (3), medial circumflex femoral artery (2)

36 Plaques were most common in femoral arteries (54%), followed by coronary calcificati

37 DRG neurons isolated from rats with ligated femoral arteries (a model of PAD).

38 y densities and hindlimb perfusion following femoral artery ablation.

39 for TAVR in patients who were ineligible for femoral artery access and had high or prohibitive risk o

40 Common femoral artery access is the default strategy for large-

41 ual care in patients eligible for radial and femoral artery access.

42 zation may improve the process of care after femoral artery access.

43 C) and vascular smooth muscle cells of mouse femoral arteries after wire-induced endothelial denudati

44 Endothelial regeneration of the femoral artery after denuding wire injury was delayed in

45 -CO PET showed decreased blood volume in the femoral artery after the injury.

46 rats whereby microspheres injected into the femoral artery allowed a unilateral reduction in functio

47 nation revealed occlusion of the superficial femoral artery along its entire length, including previo

48 tal stump of one of the bilaterally occluded femoral arteries and the accompanying vein.

49 as the presence of any plaque in carotid or femoral arteries and/or CACS >/=1.

50 gt) mice also had reduced reperfusion of the femoral artery and angiogenesis.

51 Blood samples were obtained from one femoral artery and both femoral veins before and during

52 and false aneurysm of the right superficial femoral artery and femoral vein.

53 We sampled femoral artery and hepatic venous samples and measured t

54 The right femoral artery and its branches were ligated and excised

55 h rat underwent catheterization of the right femoral artery and left femoral vein.

56 S cell-derived EPC incorporated into injured femoral artery and reduced neointima formation in a mous

57 Six paired blood samples were taken from the femoral artery and the coronary sinus.

58 to their anatomic location, the superficial femoral artery and the popliteal artery are subject to v

59 Blood samples taken from femoral artery and vein allowed electrochemical measurem

60 Blood was frequently drawn from the femoral artery and vein during exercise and Q(m), a-(V(O

61 y artery are anastomosed peripherally to the femoral artery and vein of the recipient, respectively.

62 The femoral artery and vein were cannulated and an extracorp

63 The common femoral artery and vein were catheterized for drug infus

64 city and oxygenation (SvO(2)) in superficial femoral artery and vein, respectively, along with artery

65 ascular cannulas that were inserted into the femoral artery and vein, respectively.

66 mb ischemic muscle one day after ligation of femoral artery and vein.

67 tured in vitro and then implanted around the femoral artery and veins before being transferred, as an

68 f Atherosclerotic Lesions in the Superficial Femoral Artery and/or Proximal Popliteal Artery [MDT-211

69 f Atherosclerotic Lesions in the Superficial Femoral Artery and/or Proximal Popliteal Artery Using th

70 tion of beta1 integrin attenuated FMD of the femoral artery, and blocking of beta1 integrin function

71 of the left external iliac artery and common femoral artery, and of the distal and middle parts of th

72 (n=58) underwent unilateral ligation of the femoral artery, and postoperative tissue ischemia was as

73 One-year outcomes of DES in the superficial femoral artery are promising, but longer-term benefits h

74 shear rate, flow, and radius in brachial and femoral arteries at rest and during post-occlusion hyper

75 lculate the endovascular distances from both femoral arteries at the level of the upper border of the

76 flow probes around an umbilical and a fetal femoral artery at 118+/-1 dGA (days of gestational age;

77 legged knee-extensor exercise, (2) step-wise femoral artery ATP infusion at rest, (3) passive exercis

78 afe and reduce luminal stenosis in a porcine femoral artery balloon angioplasty model.

79 cantly reduced luminal stenosis in a porcine femoral artery balloon angioplasty model.

80 Single-injury (40%-60% femoral artery balloon overstretch injury; n=2) and doub

81 n endothelial cells, which were collected by femoral artery biopsies, in 10 baboons before and after

82 Brachial and femoral artery blood flow (Q, ultrasound Doppler) at res

83 Fetal femoral artery blood flow decreased, and adrenal blood f

84 The maximum femoral artery blood flow response to hypoglycaemia occu

85 nderwent endothelial denudation of the right femoral artery by air desiccation to induce an atheroscl

86 Eighteen blood samples were taken from the femoral artery by the microfluidic blood sampler.

87 pumps, such as Impella((R)); left atrial to femoral artery bypass pumps, specifically the TandemHear

88 MI+unload; n=4), percutaneous left atrial-to-femoral artery bypass was initiated after 120 minutes of

89 ial pressure 30 mm Hg) and resuscitation via femoral artery cannulation followed by laparotomy (traum

90 Eight 50 kg Yorkshire swine with a femoral artery catheter for blood pressure measurement a

91 The approach included femoral artery catheterization to access the MCA and the

92 9091 consecutive patients (1.49%) undergoing femoral artery catheterization.

93 tery blood flow transducers, and uterine and femoral artery catheters.

94 ll stress with a percutaneous left atrial-to-femoral artery centrifugal bypass system while delaying

95 otic and uninjured nonatherosclerotic common femoral arteries (CFA) in cholesterol-fed New Zealand ra

96 s, such as middle cerebral artery occlusion, femoral artery clipping, and complete or incomplete cort

97 After wire injury of the femoral artery, Col8(-/-) mice had decreased vessel wall

98 Left femoral artery denudation in ApoE(-/-) mice on a hyperli

99 We use carotid ligation and femoral artery denudation models in mice with global or

100 mean blood velocity (Doppler ultrasound) and femoral artery diameter (edge-detection software) were m

101 At rest, the maximal decrease in femoral artery diameter (FAD) during AngII (9.0+/-0.2 to

102 sion imaging of hindlimb skeletal muscle and femoral artery diameter measurement were performed in no

103 Aortic and femoral artery diameters were measured by ultrasonograph

104 nfusion of autologous BMMNCs into the common femoral artery did not reduce major amputation rates in

105 x 0.6 and 1.3, respectively; P<0.05), as was femoral artery dilation.

106 Endovascular treatment of superficial femoral artery disease with nitinol self-expanding stent

107 estenosis prevention for de novo superficial femoral artery disease.

108 new options for the treatment of superficial femoral artery disease; however, the comparative efficac

109 stenoses, one dissection), one in the common femoral artery (dissection), and 14 in the deep femoral

110 endothelial nitric oxide synthase within the femoral artery during reactive hyperemia yielded substan

111 The average blood loss from the treated femoral artery during the first minute after injury was

112 ed neointimal expansion in response to acute femoral artery endothelial denudation injury compared wi

113 In this study, mice made ischemic by femoral artery excision were injected with the DIs MS275

114 ochemistry in murine ischemic hindlimb after femoral artery excision.

115 outer diameter of surgically exposed, intact femoral artery (FA) of anaesthetized mice.

116 like lesions induced by air desiccation of a femoral artery, followed by balloon overstretch of the d

117 The potential value of femoral arteries for improving the predictive capacity o

118 emic preconditioning induced by clamping the femoral artery for 5 min followed by 5 min of reperfusio

119 In some, we simulated PAD by ligating a femoral artery for 72 h before the experiment.

120 Ligating the femoral artery for 72 h in decerebrated rats exaggerates

121 tting analysis revealed that ligation of the femoral artery for 72 h increased the EP4 receptor prote

122 nd dilator function in mesenteric and caudal femoral arteries from 180-day-old offspring of dams fed

123 In contrast, femoral arteries from HA fetuses showed decreased contra

124 on the endothelium of a biopsy specimen of a femoral artery from an APS patient.

125 graphy with a 6 French sheath via the common femoral artery from April 2011 through May 2014 in 4 cen

126 Insulin action in endothelial cells and femoral artery from Tg(Prkcb)apoE-/- mice was impaired b

127 The rabbits were euthanized, and the injured femoral artery (IF) and sham-operated femoral artery (SF

128 t in the aorta in 28 (20%) mummies, iliac or femoral arteries in 25 (18%), popliteal or tibial arteri

129 intimal hyperplasia after wire injury of the femoral artery in a murine model (OA-NO(2) treatment res

130 methyl-L -arginine (L -NMMA) into the common femoral artery in both the supine and upright-seated pos

131 ogenesis in vivo, using excision of the left femoral artery in both TSP2-null and wild-type mice, rev

132 Permanent ligation of the femoral artery in C57BL/6 J mice enlarged pre-existing c

133 hyperplastic response to wire injury of the femoral artery in comparison to their littermate control

134 Ligating a femoral artery in rats results in blood flow patterns to

135 following acute unilateral occlusion of the femoral artery in rats.

136 es and relaxant response to acetylcholine of femoral artery in vivo.

137 e hundred nineteen patients with superficial femoral artery in-stent restenosis and chronic limb isch

138 DCBA for superficial femoral artery in-stent restenosis is associated with le

139 (300 mU . m(-2) . min(-1)) alone and during femoral artery infusion of BQ123 (an antagonist of type

140 The arterial lesions following femoral artery injury in LZ/ApoE((-/-)) mice were suppre

141 factor-1 (SDF-1) levels were observed after femoral artery injury in p21+/+ and p21-/- mice, althoug

142 n pediatric cardiac interventions and avoids femoral artery injury in small infants.

143 ce of this receptor expression, we applied a femoral artery injury model to A2bAR knockout (KO) mice

144 hibition of neointimal hyperplasia following femoral artery injury was abolished in HO-1(-/-) mice (O

145 sive failure to rebleeding in a rat model of femoral artery injury, and identified mechanisms that co

146 Following femoral artery injury, CRP2 expression persisted in the

147 he mechanism of B-myb-mediated resistance to femoral artery injury.

148 68% reduction in intimal/medial ratio after femoral artery injury.

149 vein graft, carotid, renal, and superficial femoral artery interventions.

150 erization through the arterial tree from the femoral artery into the ophthalmic artery.

151 ercise pressor reflex in rats with a ligated femoral artery is attenuated by blockade of the acid sen

152 Atherosclerosis in the superficial femoral artery is common in patients suffering from peri

153 st determined in the nonstenotic superficial femoral artery is sufficient to prevent ischemic symptom

154 After surgical excision of the femoral artery, laser Doppler perfusion imaging demonstr

155 Local drug delivery for superficial femoral artery lesions has been investigated with the in

156 peripheral arterial disease, and superficial femoral artery lesions requiring implantation of stents>

157 endovascular treatment of short superficial femoral artery lesions revealed excellent results, effic

158 Treatment of de novo superficial femoral artery lesions with PEB angioplasty and stenting

159 guidelines for the treatment of superficial femoral artery lesions, eliminate unnecessary procedures

160 y-four patients, with 90 stented superficial femoral artery lesions, were randomly assigned to post-d

161 ing stent (DES) in patients with superficial femoral artery lesions.

162 iety Consensus (TASC II) B and C superficial femoral artery lesions.

163 trong reduction of blood flow recovery after femoral artery ligation (arteriogenesis) dependent on th

164 althy tissue and collateral remodeling after femoral artery ligation (FAL) in wild-type and eNOS-knoc

165 as not apparent in mice treated with DMOG or femoral artery ligation alone.

166 pe mice, whereas recovery of perfusion after femoral artery ligation and endothelial sprouting from a

167 Mice underwent unilateral femoral artery ligation and excision.

168 nd White rabbits (n=56) underwent unilateral femoral artery ligation and excision.

169 ly improved the neovascularization following femoral artery ligation and recovery of perfusion of the

170 Femoral artery ligation and resection were used as an in

171 iments in preclinical PAD models (unilateral femoral artery ligation and resection) were conducted to

172 erived NPY accelerates the early response to femoral artery ligation by promoting collateral conducta

173 ery was fully restored in 2 to 3 weeks after femoral artery ligation in all groups of mice fed a norm

174 , and reduces collateral vessel growth after femoral artery ligation in CD8(-/-) mice.

175 ed impaired blood flow recovery after common femoral artery ligation in synectin null mice.

176 Ischemia was induced by right femoral artery ligation in wild-type and CHOP-10(-/-) mi

177 e compared the effects of DMOG treatment and femoral artery ligation individually or in combination o

178 Blood flow recovery after femoral artery ligation is significantly improved in Glr

179 od flow and failure to recover in the murine femoral artery ligation model of hindlimb ischemia.

180 Here we used a femoral artery ligation model to demonstrate that TNFR1-

181 nd restored the impaired angiogenesis in the femoral artery ligation model.

182 aseline, 6 h, and 1, 3, 7, and 14 days after femoral artery ligation or sham operation.

183 nonatherosclerotic conditions, we performed femoral artery ligation surgery in mice lacking the 9p21

184 lost following genetic deletion of FOXC2 or femoral artery ligation to reduce venous flow in mice, a

185 and the time course of arteriogenesis after femoral artery ligation was evaluated in HCE and strain-

186 METHODS AND Recovery of blood flow after femoral artery ligation was impaired (>80%) in AMPKalpha

187 Recovery of blood flow after femoral artery ligation was impaired (>80%) in AMPKalpha

188 Unilateral femoral artery ligation was performed in diabetic (db(-)

189 and ischemic muscle neovascularization after femoral artery ligation were impaired in the conditional

190 Vascular responses to femoral artery ligation were similar in Clic1(-/-) and w

191 -/-) mice exhibited attenuated angiogenesis (femoral artery ligation) and PEG-catalase treatment in c

192 In a mouse model of arteriogenesis (femoral artery ligation), we found that endothelial cell

193 ting of normal arteriogenesis in response to femoral artery ligation, and thereby serve as a model fo

194 Following femoral artery ligation, animals were either kept sedent

195 After femoral artery ligation, CD8+ T cells infiltrate the sit

196 After femoral artery ligation, MbTg(+) mice were characterized

197 After common femoral artery ligation, mu-CT imaging demonstrated form

198 infused into CD8(-/-) mice immediately after femoral artery ligation, selectively homed to the ischem

199 After femoral artery ligation, serial laser Doppler imaging de

200 infused into CD8(-/-) mice immediately after femoral artery ligation, they selectively homed to the i

201 Femoral artery ligation-induced ischaemia in mice increa

202 b/db) mice subjected to permanent unilateral femoral artery ligation.

203 ring neovascularization in mice after single femoral artery ligation.

204 covery of perfusion (83%) and function after femoral artery ligation.

205 ecific Phd2 knockout (kPhd2KO) and performed femoral artery ligation.

206 b, miR-494, and miR-495, 1 day before double femoral artery ligation.

207 ted from endothelial cells were subjected to femoral artery ligation.

208 out (KO) and wild-type littermates underwent femoral artery ligation.

209 n, and limb salvage in old mice subjected to femoral artery ligation.

210 betic db/+ mice were subjected to unilateral femoral artery ligation.

211 plants and hind limb revascularization after femoral artery ligation.

212 limb ischemia was followed for 21 days after femoral artery ligation.

213 ty, and recovery of limb perfusion following femoral artery ligation.

214 of ischemic mouse gastrocnemius muscle after femoral artery ligation.

215 n recovery and increased tissue injury after femoral artery ligation.

216 deficient mice with limb ischemia induced by femoral artery ligation/transection.

217 In response to femoral artery mechanical injury, mice with homozygous d

218 had no effect on the EPR in rats with patent femoral arteries (n = 9).

219 stigate whether post-dilation of superficial femoral artery nitinol self-expanding stents using a cry

220 ntrol mice (n=9) or mice with surgical right femoral artery occlusion (n=29) were injected with NC100

221 is and muscle perfusion were evaluated after femoral artery occlusion in a porcine model using single

222 n the modulation of neovascularization after femoral artery occlusion in mice.

223 ble immunofluorescence experiments show that femoral artery occlusion mainly augments ASIC(3) express

224 nt of TASC B, C and D lesions in superficial femoral artery occlusive disease; ISRCTN48164244).

225 on Scientific, MA) after implantation in the femoral arteries of 18 familial hypercholesterolemic swi

226 The left femoral arteries of DDAH1 TG mice and wild-type (WT) mic

227 KEY POINTS: Ligating the femoral artery of a rat for 72 h, a model for peripheral

228 xpanding stents implanted in the superficial femoral artery of diabetic patients with peripheral arte

229 oral artery (dissection), and 14 in the deep femoral artery (one thrombosis, 13 stenoses).

230 limb muscle survival and stroke volume after femoral artery or middle cerebral artery ligation, respe

231 valuate Treatment of Obstructive Superficial Femoral Artery or Popliteal Lesions With A Novel Paclita

232 We used right femoral artery or radial artery access to catheterize th

233 as administered intraarterially (ipsilateral femoral artery) or systemically to 8 CD IGS rats just be

234 tients, balloon occlusion of the superficial femoral artery over 5 minutes was painless under resting

235 measured by PATD and simultaneously with two femoral artery PCCO catheters.

236 ue resistance (P < 0.001), despite preserved femoral artery perfusion.

237 s from rats with freely perfused and ligated femoral arteries: peripheral artery disease (PAD) model.

238 Key words were: "superficial femoral artery," "popliteal artery," "angioplasty," "dru

239 nol self-expanding stents in the superficial femoral artery, post-dilation with cryoplasty balloon re

240 Resting IOP was 12.1 +/- 2.8 mmHg and mean femoral artery pressure was 97.6 +/- 10.7 mmHg.

241 Thus, occlusion of the femoral artery promulgated vascular adaptations, even in

242 A <1.73 m(2); OR 7.1, p = 0.008), and higher femoral artery puncture (OR 5.3, p = 0.013).

243 Female gender, low BSA, and higher femoral artery puncture are significant risk factors for

244 Central (carotid-femoral artery PWV, PWV(CF) ) and peripheral (carotid-ra

245 Femoral artery reactivity was determined by wire myograp

246 s in S100A1 knockout (SKO) mice subjected to femoral artery resection unveiled insufficient perfusion

247 genesis and salvaged limbs in SKO mice after femoral artery resection.

248 e, n = 3) imaged before and 1 and 4 wk after femoral artery resection.

249 nd 97.9% of CT scans from the right and left femoral arteries, respectively.

250 In vivo, PKCalpha transduction in rat femoral arteries resulted in a significant increase in t

251 ting has been shown to improve patency after femoral artery revascularization compared with balloon a

252 methyl-l-arginine acetate (l-NMMA) into both femoral arteries reversed the insulin-stimulated increas

253 in phasic (rabbit bladder (Rbl)) and tonic (femoral artery (Rfa)) smooth muscle were determined by m

254 njured femoral artery (IF) and sham-operated femoral artery (SF) were collected for immunohistochemis

255 loons (DEB) for the treatment of superficial femoral artery (SFA) in-stent restenosis (ISR).

256 Angioplasty for the Treatment of Superficial Femoral Artery [SFA] and Proximal Popliteal Artery [PPA]

257 al vessels only, n = 15; tibial and superior femoral artery [SFA] and/or popliteal vessels, n = 22).

258 f Atherosclerotic Lesions in the Superficial Femoral Artery [SFA] and/or Proximal Popliteal Artery [P

259 e, the hindlimb muscles of rats with ligated femoral arteries show increased levels of reactive oxyge

260 Injured femoral arteries showed a 20% increase in neointimal hyp

261 endothelial denudation injury to the murine femoral artery significantly upregulates mDia1 mRNA tran

262 s of zotarolimus uptake into excised porcine femoral artery specimens immersed in radiolabeled drug s

263 All deep femoral artery stenoses were diaphragm-like and involved

264 al artery disease due to de novo superficial femoral artery stenotic or occlusive lesions were random

265 osclerosis with risk factors was stronger in femoral arteries than carotid or coronary arteries.

266 muscle contractions are greater in rats with femoral arteries that were previously ligated (24-72 h e

267 ured above (caudal artery) and below (distal femoral artery) the collateral circuit.

268 Acute) or 3 weeks following occlusion of the femoral artery; the 3-week animals were in turn limited

269 Femoral artery thrombosis was documented in 6 (9%) infan

270 riovenous fistula, retroperitoneal hematoma, femoral artery thrombosis, surgical vascular repair, acc

271 Moreover, in an in vivo model of femoral artery thrombosis, the time to arterial occlusio

272 eceptor (AR) in the calcified media of human femoral artery tissue and calcified human valves.

273 15) underwent surgical ligation of the right femoral artery to induce unilateral hindlimb ischemia.

274 Serial blood samples were collected from the femoral artery to measure (18)F-FDG and glucose concentr

275 e instrumented with vascular catheters and a femoral artery Transonic flow probe for chronic recordin

276 n leg vascular conductance) was evaluated by femoral artery tyramine infusion.

277 Femoral blood flow (FBF, femoral artery ultrasound Doppler) and femoral vascular

278 etized and implanted in porcine coronary and femoral arteries using standard interventional equipment

279 15 serial blood samples were taken from the femoral artery via a surgically inserted catheter during

280 Flow-mediated dilation of the brachial and femoral arteries was performed with the use of ultrasoun

281 hind-limb surgery with excision of the left femoral artery was conducted.

282 dovascular occlusion of the left superficial femoral artery was induced in 14 New Zealand white rabbi

283 After 12 weeks of an HFD, the femoral artery was ligated and blood flow recovery was m

284 action of the hindlimb muscles of rats whose femoral artery was ligated evoked a larger reflex presso

285 Percent wall volume in the superficial femoral artery was measured with black blood MRI.

286 ure values in mm Hg) of the left superficial femoral artery was obtained in patients undergoing elect

287 ommon iliac (CIA), external iliac (EIA), and femoral arteries were classified into five types, known

288 n and maximum TBR in the carotid, iliac, and femoral arteries were highly reproducible.

289 ater in DRG neurons isolated from rats whose femoral arteries were ligated for 72 h.

290 pressure waveforms, from ascending aorta to femoral artery, were transduced and archived digitally u

291 f blood velocity in both normal and ischemic femoral arteries, which are beyond the capabilities of u

292 ns was noted in high-fat diet fed mice after femoral artery wire denudation injury.

293 In a mouse femoral artery wire injury model, antibody targeting of

294 otes neointimal VSMC hyperplasia in a murine femoral artery wire injury model.

295 Endothelial regeneration after femoral artery wire injury was also quantified after APC

296 Femoral artery wire injury was performed in SMC-conditio

297 After femoral artery wire injury, MRP-14(-/-) mice had signifi

298 On femoral artery wire injury, PRCP(gt/gt) mice had increas

299 ndent dilatation (EDD) was lower in isolated femoral arteries with ageing (P < 0.001).

300 (90.6%) and dissection (5.2%) of the common femoral artery with high rates of primary treatment succ