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1 (smoking, diabetes mellitus, and peripheral arterial disease).
2 he limbs of certain patients with peripheral arterial disease.
3 ossible matches), 95% of whom had peripheral arterial disease.
4 ts with stable coronary artery or peripheral arterial disease.
5 ypic switching, an important pathobiology in arterial disease.
6 se risks can adversely affect progression of arterial disease.
7 disease and monitoring therapy in peripheral arterial disease.
8 stable coronary artery disease or peripheral arterial disease.
9 en, and patients with diabetes or peripheral arterial disease.
10 e most efficacious treatments for peripheral arterial disease.
11 walking performance developed for peripheral arterial disease.
12 CHD), cerebrovascular disease and peripheral arterial disease.
13 -induced angiogenesis, such as in peripheral arterial disease.
14 on remains unclear in patients with manifest arterial disease.
15 d be extended to patients without peripheral arterial disease.
16 Q can be used in patients without peripheral arterial disease.
17 ith T2D that are related to early markers of arterial disease.
18 s, tobacco use, heart failure, or peripheral arterial disease.
19 d their receptors, adipokines, and miRNAs to arterial disease.
20 ty and mortality in patients with peripheral arterial disease.
21 nt hypertension, preeclampsia, or peripheral arterial disease.
22 pathy, ischemic heart disease and peripheral arterial disease.
23 age rates in patients with severe peripheral arterial disease.
24 artery of diabetic patients with peripheral arterial disease.
25 validated therapy for symptomatic peripheral arterial disease.
26 A for treatment of infrapopliteal peripheral arterial disease.
27 in patients with symptomatic infrapopliteal arterial disease.
28 sease, heart failure, stroke, and peripheral arterial disease.
29 ase, cerebrovascular disease, and peripheral arterial disease.
30 , coronary revascularisation, and peripheral arterial disease.
31 on is tissue- and life-saving in obstructive arterial disease.
32 unctional decline in persons with peripheral arterial disease.
33 ctional decline among people with peripheral arterial disease.
34 clinical imaging in patients with peripheral arterial disease.
35 art disease, ischaemic stroke, or peripheral arterial disease.
36 carotid dissection, and, rarely, peripheral arterial disease.
37 e in persons with lower-extremity peripheral arterial disease.
38 r than revascularization for lower-extremity arterial disease.
39 ssion worsens vascular outcome in peripheral arterial disease.
40 Mac-1-deficiency did not prevent late graft arterial disease.
41 care of patients with symptomatic peripheral arterial disease.
42 and leukocyte recruitment in lower-extremity arterial disease.
43 impaired in elderly patients with peripheral arterial disease.
44 between [Formula: see text] and subclinical arterial disease.
45 coronary artery disease, and lower extremity arterial disease.
46 d CHD, stroke, heart failure, and peripheral arterial disease.
47 nd surgical revascularization for peripheral arterial disease.
48 hemic heart disease implying a role in human arterial disease.
49 on differences in the location and extent of arterial disease.
50 life-threatening complication of peripheral arterial disease.
51 ons in patients with asymptomatic peripheral arterial disease.
52 increased risks of venous thromboembolic and arterial disease.
53 on of kidney disease, stroke, and peripheral arterial disease.
54 art disease, ischemic stroke, and peripheral arterial disease.
55 ach in patients with advanced below-the-knee arterial disease.
56 ith chronic coronary syndromes or peripheral arterial disease.
57 hemia represents the end stage of peripheral arterial disease.
58 al immunoprivilege or medial inflammation in arterial diseases.
59 articipation of inflammation and immunity in arterial diseases.
60 beneficial against bone demineralization and arterial diseases.
62 tion, 1.78 (95% CI 1.53-2.07) for peripheral arterial disease, 1.32 (95% CI 1.15-1.50) for cerebrovas
63 rior stroke/transient ischemic attack, 6.5%; arterial disease, 15.9%; all CHADS-VASc risk factors wer
64 on, of which the most common were peripheral arterial disease (16.2%, n=992) and heart failure (14.1%
65 with stent occlusion or stenoses, peripheral arterial disease (ABI <1.0), symptomatic cardiac disease
66 rongly positively associated with peripheral arterial disease (adjusted cause-specific hazard ratio 2
67 ars old with VTE had 3.3-fold higher risk of arterial disease (adjusted hazard ratio, 3.28; 95% confi
68 es was positively associated with peripheral arterial disease (adjusted HR 2.98 [95% CI 2.76-3.22]),
69 udy examined parenchymal rejection and graft arterial disease after total allomismatched cardiac tran
70 isease mortality and one study on peripheral arterial disease).All but one study reported positive as
71 on second exertion in patients with coronary arterial disease, also known as the warm-up angina pheno
72 m selenium with the prevalence of peripheral arterial disease among 2,062 US men and women 40 years o
73 m and lower limbs is a common consequence of arterial disease and a major source of morbidity and mor
77 cal for blood flow restoration in peripheral arterial disease and is triggered by increasing fluid sh
78 LI) is the most advanced stage of peripheral arterial disease and is usually treated with bypass surg
79 a range of conditions, including peripheral arterial disease and myocardial infarction, where it has
80 disease, the use of paclitaxel in peripheral arterial disease and other conditions, the harm signal n
81 al arterial revascularization for peripheral arterial disease and to assess whether readmission risk
83 ADA HbA1c clinical categories for peripheral arterial disease, and 0.683 for ADA fasting glucose conc
84 the absence of beta-blocker use, peripheral arterial disease, and a deeper prosthesis insertion are
85 with preserved ejection fraction, peripheral arterial disease, and abdominal aortic aneurysms, are al
86 disease, cerebrovascular disease, peripheral arterial disease, and all-cause cardiovascular disease,
87 disease, cardiovascular disease, peripheral arterial disease, and all-cause mortality than did fasti
88 med in patients with diabetes and peripheral arterial disease, and at least 25% require subsequent re
90 including coronary heart disease, peripheral arterial disease, and cerebrovascular disease, in an eld
91 ertension, myocardial infarction, peripheral arterial disease, and impaired renal function were signi
93 infections-male sex, hypertension, coronary arterial disease, and serogroup C1 infections-were each
95 ed diabetes mellitus, symptomatic peripheral arterial disease, and superficial femoral artery lesions
96 n, previous heart failure, MI, or peripheral arterial disease; and who received coronary artery bypas
98 the treatment of lower extremity peripheral arterial disease are typified with diminished patency.
100 lae and smooth muscle cells (SMCs), and many arterial diseases are characterized by defective lamella
102 ss (IMT) is a noninvasive marker of systemic arterial disease, associated with atherosclerosis, abnor
103 ary heart disease, heart failure, peripheral arterial disease, asthma, chronic kidney disease, diabet
104 ary heart disease, heart failure, peripheral arterial disease, asthma, chronic kidney disease, diabet
105 s (ie, risk factors, coronary and peripheral arterial disease, asymptomatic carotid stenosis, and 10-
106 ment of patients with symptomatic peripheral arterial disease because they are associated with simila
108 flow in an experimental model of peripheral arterial disease, by exploiting fluorescence in the NIR-
109 al artery revascularization, lower-extremity arterial disease, carotid endarterectomy or angioplasty,
110 ic medial arterial calcification (MAC) is an arterial disease commonly referred as Monckeberg's scler
111 he fully adjusted odds ratios for peripheral arterial disease comparing selenium quartiles 2, 3, and
113 disease, cerebrovascular disease, peripheral arterial disease, congestive heart failure, malignant ve
116 , and race-adjusted prevalence of peripheral arterial disease decreased with increasing serum seleniu
119 c heart disease, aortic aneurysm, peripheral arterial disease, endocarditis, and all other cardiovasc
121 ase, acute myocardial infarction, peripheral arterial disease, epilepsy, substance abuse, heart failu
122 disease, diabetes mellitus, known peripheral arterial disease, evaluation by a vascular specialist, a
124 d 13 patients suspected of having peripheral arterial disease (five men; mean age, 67 years; age rang
125 sease (coronary artery disease or peripheral arterial disease) followed from 1997 to 2009, AF status
126 ysplasia (FMD) is a rare, nonatherosclerotic arterial disease for which the molecular basis is unknow
127 The SMART score (Second Manifestations of Arterial Disease) for 10-year risk of myocardial infarct
129 field of cell-based therapies for peripheral arterial disease has been in a state of continuous evolu
130 ease, including HTN, HF, CHD, and peripheral arterial disease, have a better prognosis compared with
131 r stable angina, ischemic stroke, peripheral arterial disease, heart failure, and cardiac arrest, to
132 rs include advanced age, smoking, peripheral arterial disease, high blood pressure, coronary artery d
133 .77; 95% CI, 0.62-0.94; P = .01), peripheral arterial disease (HR, 0.65; 95% CI, 0.49-0.87; P = .004)
135 s noted for fractures (HR, 1.80), peripheral arterial disease (HR, 2.25), venous thromboembolism (HR,
136 nce interval [CI]: 1.82 to 2.29), peripheral arterial disease (HR: 1.95; 95% CI: 1.72 to 2.21), unher
138 disease, coronary artery disease, peripheral arterial disease, hypertension, pulmonary hypertension,
139 l injury and dysfunction precede accelerated arterial disease in allograft vasculopathy and systemic
140 dothelial dysfunction and the progression of arterial disease in the general population is unknown.
141 The age-adjusted prevalence of peripheral arterial disease in the US population has been estimated
142 The age-adjusted prevalence of peripheral arterial disease in the US population was estimated to a
143 epair, bypass for lower extremity peripheral arterial disease - in Ontario, Canada, between 2004 and
144 Surgical treatment options for peripheral arterial disease include angioplasty, endarterectomy, an
145 linical consequences of occlusive peripheral arterial disease include intermittent claudication, that
146 linical consequences of occlusive peripheral arterial disease include pain on walking (claudication),
147 s was previously found to be associated with arterial diseases, including intracranial aneurysm.
148 the Treatment of SFA and Proximal Popliteal Arterial Disease [INPACT SFA I], NCT01175850; IN.PACT Ad
149 ation, cardiac revascularization, peripheral arterial disease intervention, or cardiovascular death.
150 nstay for the treatment of acute and chronic arterial disease involving the coronary and peripheral b
157 te coronary syndrome, stroke, and peripheral arterial diseases, is a chronic progressive inflammatory
159 ular accident, heart failure, and peripheral arterial disease), kidney disease (a composite of ESKD o
160 quality of life similarly compared to other arterial disease level groups, they underwent revascular
167 mouse hindlimb ischemia model of peripheral arterial disease, MITCH-PEG co-delivery of hiPSC-ECs and
168 tive sample size [n(e)] = 9,396); peripheral arterial disease (n(e) = 5,215); abdominal aortic aneury
170 -enhanced MR angiography revealed peripheral arterial disease not recognized with duplex US and was m
171 [CI], 0.31-0.45; P=5.5*10(-26)], peripheral arterial disease (odds ratio 0.42; 95% CI, 0.26-0.68; P=
172 lysis revealed that patients with peripheral arterial disease of the lower extremities are at higher
173 ease, cerebrovascular disease, or peripheral arterial disease or with multiple risk factors for ather
174 coronary, cerebrovascular, and/or peripheral arterial) disease or multiple atherothrombotic risk fact
175 (OR, 0.58; 95% CI, 0.43-0.78) and peripheral arterial disease (OR, 0.43; 95% CI, 0.22-0.85) were less
176 se (OR, 0.12; 95% CI, 0.03-0.45), peripheral arterial disease (OR, 6.36; 95% CI, 1.56-25.87), and pro
177 ociations between the CAD-GRS and peripheral arterial disease (OR: 1.28; 95% CI: 1.23 to 1.32), abdom
179 patients with renal dysfunction, peripheral arterial disease, or following a brief P2Y12-receptor an
181 nts with diabetes, heart failure, peripheral arterial disease, or tobacco use had the largest predict
182 ated with progression of preclinical carotid arterial disease over a 6-year period and was more close
186 respond poorly to treatments for peripheral arterial disease (PAD) and are more likely to present wi
188 differences in the prevalence of peripheral arterial disease (PAD) and its associations with cardiov
191 ulate angiogenesis are altered in peripheral arterial disease (PAD) and whether these factors are ass
194 nvestigate the pathophysiology of peripheral arterial disease (PAD) by examining magnetic resonance i
198 rtance: Patients with concomitant peripheral arterial disease (PAD) experience worse cardiovascular o
200 en and women with lower extremity peripheral arterial disease (PAD) have higher levels of inflammator
203 Cadmium has been associated with peripheral arterial disease (PAD) in cross-sectional studies, but p
205 ; weight (kg)/height (m)(2)) with peripheral arterial disease (PAD) in prior studies may reflect lowe
215 mmation in the pathophysiology of peripheral arterial disease (PAD) is well established, the contribu
217 an important role in determining peripheral arterial disease (PAD) pathology, which causes a spectru
218 0.1, mean age 30 +/- 7 years); 2) peripheral arterial disease (PAD) patients (n = 12; mean ABI 0.6 +/
222 ntially increases the severity of peripheral arterial disease (PAD) symptomology, however, the biolog
224 urine cadmium concentrations with peripheral arterial disease (PAD) were evaluated by using data from
225 tion of progressive versus stable peripheral arterial disease (PAD) with the risk of future cardiovas
226 rength training for patients with peripheral arterial disease (PAD) without intermittent claudication
227 d that women with lower extremity peripheral arterial disease (PAD) would have greater mobility loss
228 ystem, but their association with peripheral arterial disease (PAD), a high-prevalence vascular illne
229 ma-based factors as predictors of peripheral arterial disease (PAD), and comparative data between ind
230 risk factors for atherosclerotic peripheral arterial disease (PAD), such as dyslipidemia, diabetes m
232 hy for suspected or known chronic peripheral arterial disease (PAD), with contrast material-enhanced
245 ysiological angiogenesis to treat peripheral arterial diseases (PAD) by increasing the vascular endot
246 e impact of polyvascular disease (peripheral arterial disease [PAD] and cerebrovascular disease [CVD]
247 The study population included 203 peripheral arterial disease participants who underwent vertical acc
250 important for the large number of peripheral arterial disease persons without access to supervised wa
251 ery disease, limb ischemia due to peripheral arterial disease, pressure-overload heart failure, wound
252 In spline regression models, peripheral arterial disease prevalence decreased with increasing se
254 including hypertension, diabetes, peripheral arterial disease, previous myocardial infarction, angina
255 mellitus, hypertension, smoking, peripheral arterial disease, previous stroke, previous coronary byp
258 ween adiposity, metabolic abnormalities, and arterial disease progression in children and adolescents
260 re patients who underwent a major peripheral arterial disease-related amputation during the period be
262 on, the most common of which were peripheral arterial disease (reported in 992 [16.2%] of 6137 patien
265 y treatment for patients with infrapopliteal arterial disease reveal suboptimal procedural and 1-year
266 , atrial fibrillation, aortic and peripheral arterial disease, rheumatic heart disease, and endocardi
267 ascular risk score (Second Manifestations of Arterial Disease risk score) (RR, 1.01; 95% CI: 1.00, 1.
268 tions to prevent mobility loss in peripheral arterial disease should focus on reversing pathophysiolo
269 alth (REACH) and Secondary Manifestations of Arterial Disease (SMART) risk scores (area under the cur
270 ic obstructive pulmonary disease, peripheral arterial disease, smoking, diabetes, renal failure, hype
271 96%; LR, 3.1 [95% CI, 2.0-4.7]), peripheral arterial disease (specificity, 97%; LR, 2.7 [95% CI, 1.5
272 o-option" patients suffering from peripheral arterial diseases, such as critical limb ischemia (CLI).
273 cal limb ischemia have severe below-the-knee arterial disease that limits the use of bypass surgery o
275 of non-atherosclerotic and non-inflammatory arterial diseases that primarily involves the renal and
276 prior coronary artery disease or peripheral arterial disease the COMPASS (Cardiovascular Outcomes fo
277 surgical therapy for coronary and peripheral arterial disease, the burden of these illnesses remains
278 m reviewed the natural history of peripheral arterial disease, the use of paclitaxel in peripheral ar
279 ended for secondary prevention in peripheral arterial disease, their effectiveness in CLI is uncertai
280 valent condition for coronary and peripheral arterial diseases, these findings create a paradox where
281 res is increased in patients with peripheral arterial disease, thus increasing the incidence of repor
282 l infarction, ischemic stroke, or peripheral arterial disease to receive vorapaxar (2.5 mg daily) or
283 hundred seventy participants with peripheral arterial disease underwent baseline measurement of calf
286 nium levels and the prevalence of peripheral arterial disease was not statistically significant, alth
287 tive tobacco use, and other risk factors for arterial disease were analyzed by using a multivariate C
288 dy, 141 patients with symptomatic peripheral arterial disease were assigned to treatment with heparin
289 coronary artery bypass graft, and peripheral arterial disease were associated with prescription of as
290 bstructive pulmonary disease, and peripheral arterial disease were less likely to improve (P<0.05 for
291 ial, 76 patients with symptomatic peripheral arterial disease were randomized 2:1 to receive a helica
292 cular ejection fraction <20%, and peripheral arterial disease were significant predictors of mortalit
293 ptions for diabetic patients with peripheral arterial disease when revascularization is not possible
294 ngina, myocardial infarction, and peripheral arterial disease, whereas raised diastolic blood pressur
295 ronic coronary, intracranial, and peripheral arterial diseases, which together account for the leadin
296 hospitalizations of patients with peripheral arterial disease who had peripheral arterial revasculari
297 More than 1 in 6 patients with peripheral arterial disease who undergo peripheral arterial revascu
298 rial in symptomatic patients with peripheral arterial disease who underwent endovascular treatment fo
299 hospitalizations of patients with peripheral arterial disease who were discharged alive after periphe
300 e traditional focus of immunopathogenesis of arterial disease, with the goal of integrating the playe