ライフサイエンスコーパス: arterial occlusion

1 plastic intimal lesions leading to segmental arterial occlusion.

2 pulmonary angiography failed to demonstrate arterial occlusion.

3 thrombolytic therapy in patients with acute arterial occlusion.

4 such as blindness and stroke are related to arterial occlusion.

5 nd surgery as the initial treatment of acute arterial occlusion.

6 ne, leading to vasospasm and, ultimately, to arterial occlusion.

7 use were relatively resistant to NMDA and to arterial occlusion.

8 onoclonal antibody injected 1 hour after the arterial occlusion.

9 botic agents to restore vessel patency after arterial occlusion.

10 t intervals ranging 12 to 96 hours after the arterial occlusion.

11 monophasic CT angiography ipsilateral to the arterial occlusion.

12 ent vision loss from progression to complete arterial occlusion.

13 imal desaturation, assessed during sustained arterial occlusion.

14 Three (11%) patients developed femoral arterial occlusion.

15 le treatment, although it is associated with arterial occlusion.

16 e woman developed clinical signs of an acute arterial occlusion.

17 eries that can restore circulation following arterial occlusion.

18 n anterior circulation proximal intracranial arterial occlusion.

19 Anterior circulation proximal intracranial arterial occlusion.

20 ly sufficient for adequate reperfusion after arterial occlusion.

21 cclusion plethysmography) after 5 minutes of arterial occlusion.

22 between parameters (p<0.0001); 40 (48%) had arterial occlusion.

23 fluorescence of human epidermal cells during arterial occlusion.

24 ygenation of hemoglobin within 30 s of renal arterial occlusion.

25 d (1 mg/kg intravenously) 1 h after onset of arterial occlusion.

26 the degree of tissue perfusion acutely after arterial occlusion.

27 k for infarction in patients with persistent arterial occlusion.

28 er of the brachial artery after 5 minutes of arterial occlusion.

29 emia is the increase in blood flow following arterial occlusion.

30 dent aggregation that may support thrombotic arterial occlusion.

31 ccurs when therapy is initiated 1 week after arterial occlusion.

32 cated by aneurysm formation, dissection, and arterial occlusions.

33 ections of N-methyl-D-aspartate (NMDA) or to arterial occlusions.

34 aemic stroke due to cervical and/or cerebral arterial occlusions.

35 Of 306, 282 (92%) had arterial occlusions.

36 the natural history of proximal intracranial arterial occlusions.

37 stabilize the developing plaques and prevent arterial occlusions.

38 c failure and 1 cardiac arrest, 1 mesenteric arterial occlusion, 1 seizure, and 1 sudden death).

39 ng retinal detachment (11%, 19/175), retinal arterial occlusion (2%, 3/175), and stroke (0.6%, 1/175)

40 s preferable to air breathing during retinal arterial occlusion, (2) hyperoxia during occlusion is be

41 rring diagnoses were isolated branch retinal arterial occlusion (5/16), combined central retinal vein

42 patients with PAMM caused by partial retinal arterial occlusion, a benign empirical approach, such as

43 During arterial occlusion, a decrease in oxyhemoglobin correspo

44 Mice that lack sema4D exhibit delayed arterial occlusion after vascular injury in vivo, and th

45 After 1-hour coronary arterial occlusion and 2-hour reperfusion, three groups

46 tive PI3Kgamma (PI3Kgamma KD) showed reduced arterial occlusion and accumulation of monocytes and T c

47 d flow and total hyperemia in the calf after arterial occlusion and also after isotonic ankle exercis

48 Arterial occlusion and baseline perfusion lesion extent

49 sion therapies re-establish blood flow after arterial occlusion and improve outcome for ischaemic str

50 pted atherosclerotic plaque initiates abrupt arterial occlusion and is the proximate event responsibl

51 earman-rank correlation coefficients between arterial occlusion and normalized perfusion values were

52 e regulated to avoid spontaneous bleeding or arterial occlusion and organ damage.

53 Correlation between arterial occlusion and perfusion indices was evaluated u

54 ith ischemic stroke with a proximal cerebral arterial occlusion and salvageable tissue on CT perfusio

55 ed that late secondary cerebral injury after arterial occlusion and subsequent recanalization may lim

56 udies with different modes of EVT, different arterial occlusions and different collateral grading met

57 ease (PAD) generates tissue ischemia through arterial occlusions and insufficient collateral vessel f

58 ion is beneficial in promoting recovery from arterial occlusion, and (3) hyperoxia has value even if

59 y Doppler/angiography) on the side of ocular arterial occlusion, and echocardiography.

60 nvestigator-determined cases of IOI, retinal arterial occlusion, and endophthalmitis.

61 small infarct core, a proximal intracranial arterial occlusion, and moderate-to-good collateral circ

62 r infarct growth in patients with persistent arterial occlusion, and with a high incidence of asympto

63 y either a: (i) venous occlusion (VO); (ii); arterial occlusion (AO); or venous then arterial occlusi

64 d mixed model to determine the thresholds of arterial occlusion associated with perfusion derangement

65 sponse to a 10 min period of brachiocephalic arterial occlusion (BCO).

66 ulmonary hypertension (SAPH) associated with arterial occlusion by proliferating endothelial cells, a

67 ry hypertension associated with precapillary arterial occlusion by proliferating endothelial cells.

68 The prevention of arterial occlusion by the inhibition of clot formation o

69 scans generally indicate proximal pulmonary arterial occlusion by thromboemboli or, rarely, other pr

70 Arterial occlusion by thrombosis is the immediate cause

71 between the recruitment of capillaries after arterial occlusion (capillary density during postocclusi

72 terval of 64.32% to 70.05%) in a prospective arterial occlusion cardiac arrest simulation model.

73 When subjected to photothrombotic arterial occlusion, CD73(-/-) mice exhibited significant

74 ii); arterial occlusion (AO); or venous then arterial occlusion (COMBO).

75 with ASIC(3)-like currents is greater after arterial occlusion compared with control.

76 RATIONALE: Atherosclerotic-arterial occlusions decrease tissue perfusion causing is

77 ation and workup of a patient with a retinal arterial occlusion depends on many factors, including th

78 Arterial occlusion did not activate responsive units, su

79 during handgrip exercise and after transient arterial occlusion did not differ among the three treatm

80 For each arterial occlusion, DPCT data was analyzed using first-p

81 cales: Los Angeles Motor Scale (LAMS); Rapid Arterial Occlusion Evaluation (RACE); Cincinnati Stroke

82 ncing a large vessel occlusion stroke (Rapid Arterial Occlusion Evaluation Scale [RACE] score in the

83 bjected to 45 minutes of superior mesenteric arterial occlusion followed by 90 minutes of reperfusion

84 stion with recombinant DNase I all prevented arterial occlusions, GFR loss, and kidney infarction.

85 UWFA 4 of 24 (16.7%) SCD eyes had peripheral arterial occlusion (Goldberg I), and 20 of 24 eyes (83.3

86 , whereas the level of proximal intracranial arterial occlusion (ICA vs MCA-M1 vs MCA-M2) was not.

87 platelet responses with delay in the time of arterial occlusion in an in vivo model of thrombosis and

88 tant than the level of proximal intracranial arterial occlusion in determining outcomes.

89 Production of PDGF has a role in arterial occlusion in GCA.

90 established markedly reduced progression of arterial occlusion in mice.

91 severe angioproliferative PH associated with arterial occlusion in rats.

92 Eligible patients had a proximal arterial occlusion in the anterior cerebral circulation

93 ed unstable thrombus formation and prolonged arterial occlusion in the FeCl(3) in vivo thrombosis mod

94 ammation (IOI), endophthalmitis, and retinal arterial occlusion in the phase 3 HAWK and HARRIER trial

95 Microdialysis provided an early warning of arterial occlusion in transplanted grafts with delayed g

96 the stability of arterial thrombi and delays arterial occlusion in vivo.

97 matrigel) or hind-limb ischemia produced by arterial occlusion in wild-type or monocyte chemotactic

98 cur by somewhat different mechanisms than do arterial occlusions in older adults.

99 sed data for patients with complete proximal arterial occlusions in the anterior circulation who rece

100 Retinal arterial occlusions in the young typically occur by some

101 tiology and diagnostic evaluation of retinal arterial occlusions in young people as well as potential

102 In mice, 14E11 prevented arterial occlusion induced by FeCl(3) to a similar degre

103 lowing a 10-min episode of bilateral carotid arterial occlusion-induced forebrain ischemia.

104 peripheral blood were lower in animals with arterial occlusion injected with the monoclonal antibody

105 reperfusion, IPo consisted of three 1-minute arterial occlusions, interspersed with 1-minute reperfus

106 mic stroke caused by a proximal intracranial arterial occlusion, intraarterial treatment is highly ef

107 Adaptive neovascularization after arterial occlusion is an important compensatory mechanis

108 hypothesized that even if the site of major arterial occlusion is recanalized after stroke, microvas

109 Ischaemic stroke caused by arterial occlusion is responsible for the majority of st

110 ver, the anatomic extent and distribution of arterial occlusion is too severe to permit relief of pai

111 The natural history of proximal intracranial arterial occlusion is variable, with poor outcomes overa

112 rared spectroscopy (NIRS) using intermittent arterial occlusions, is associated with muscle oxidative

113 acute ischemic stroke caused by intracranial arterial occlusion leads to improved functional outcome

114 These complications are caused by thrombotic arterial occlusion localized at the site of high-risk at

115 d 72 h after permanent right middle cerebral arterial occlusion (MCAO) in adult male rats.

116 Using the arterial occlusion method, we compared five literature-b

117 peripheral pulselessness (induced through an arterial occlusion model) manifest similarly to pulseles

118 ess into a disease mechanism that results in arterial occlusion, most frequently in atherosclerotic v

119 toimmune retinopathy (n = 3), branch retinal arterial occlusion (n = 3), branch retinal vein occlusio

120 In experiments terminated 12 hours after the arterial occlusion (n = 4), there were fewer necrotic ne

121 llowing arterial injuries at CT angiography: arterial occlusion (n = 7), arterial extravasation (n =

122 s preferable to air breathing during retinal arterial occlusion not only for maintaining b-wave ampli

123 Retinal arterial occlusions occur secondary to a multitude of me

124 rger (50-200-micron) particles reflected the arterial occlusion occurring more proximally.

125 space and that vascular remodeling following arterial occlusion occurs independently of myeloid speci

126 , MRA with ferumoxytol demonstrated complete arterial occlusion of an allograft.

127 18 years from the Netherlands) with proximal arterial occlusion of the anterior circulation, given in

128 hemic stroke caused by proximal intracranial arterial occlusion of the anterior circulation.

129 be an effective initial treatment for acute arterial occlusion of the legs.

130 lar cognitive impairment, caused by a sudden arterial occlusion or more subtle but protracted vascula

131 -up CTA and MRA were assessed for persistent arterial occlusion or recanalization.

132 des venous thrombosis (partial or complete), arterial occlusion, or aneurysm.

133 mice were completely resistant to thrombotic arterial occlusion (P<0.01).

134 Primary endpoint was arterial occlusion/patency.

135 ow (RHBF) responses to 10 minutes of forearm arterial occlusion (plethysmography), blood pressure, an

136 Mean arterial occlusion pressure (AOP) was 161 +/- 18 mmHg in

137 Pulmonary arterial occlusion pressure is not thought to reflect le

138 Pulmonary arterial occlusion pressure waveform analysis may identi

139 We postulated that pulmonary arterial occlusion pressure waveform analysis, a techniq

140 al venous, pulmonary arterial, and pulmonary arterial occlusion pressures, and cardiac index.

141 al venous, pulmonary arterial, and pulmonary arterial occlusion pressures; cardiac output; and quadri

142 Reduced cerebral perfusion resulting from arterial occlusion promotes the degradation of TAK1, a s

143 l velocity at rest (RBCV) and after 1-minute arterial occlusion (RBCVmax), and time taken to reach RB

144 Specifically, NF1 patients develop arterial occlusion resulting in tissue ischemia and sudd

145 1 patients develop renal artery stenosis and arterial occlusions resulting in cerebral and visceral i

146 Adaptive vascular remodeling in response to arterial occlusion takes the form of capillary growth (a

147 involves cardiovascular disorders, including arterial occlusions that result in cerebral and visceral

148 tive arterial extravasations, three isolated arterial occlusions, three cases of both arterial extrav

149 nalysis of the perfusion maps determined the arterial occlusion threshold for perfusion defects was 5

150 Based on the increased arterial occlusion time, tail bleeding time, and blood c

151 echanisms of cholesterol crystal (CC)-driven arterial occlusion, tissue infarction, and organ failure

152 from the early damaging events triggered by arterial occlusion to the late regenerative processes un

153 hat sequentially combines venous followed by arterial occlusions to determine muscle blood flow and O

154 ently inhibits thrombus formation and delays arterial occlusion upon vascular injury.

155 In MRP4-deficient mice, the arterial occlusion was delayed and the tail bleeding tim

156 ythmic handgrip exercise and after transient arterial occlusion was determined by strain gauge plethy

157 The presence of an arterial occlusion was inferred from the patient's sympt

158 after release of 1, 3 and 5 min of transient arterial occlusion was measured in the brachial artery w

159 odilation after release of 1, 3 and 5 min of arterial occlusion was significantly greater in patients

160 el of femoral artery thrombosis, the time to arterial occlusion was significantly prolonged in mice l

161 Confidence in identifying carotid arterial occlusions was also very high with this techniq

162 which also persists after complete proximal arterial occlusion) was also significantly greater at pl

163 phy signal (from ventricular fibrillation or arterial occlusion), we developed and validated a loss o

164 pairs of iliofemoral arteries of 24 rabbits; arterial occlusions were documented angiographically.

165 The timing and duration of arterial occlusions were manipulated to maintain tissue

166 Arterial occlusions were performed with a balloon-tipped

167 ize in a mouse stroke model (middle cerebral arterial occlusion) when injected (1 mg/kg intravenously

168 mic hypotension and bilateral common carotid arterial occlusion, which was followed by reperfusion.

169 t identifying subsets of patients with acute arterial occlusion who are most likely to benefit from t

170 We were able to document these transient arterial occlusions with fundus photography as well as f

171 ts with acute stroke (<6 hours) due to major arterial occlusion, without intracranial hemorrhage.