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1 e in the initial diagnosis of GCA giant cell arteritis .
2 lopathy affecting large arteries (giant cell arteritis).
3 attractive for arterial lesions of Takayasu arteritis.
4 nd lumen pathologies resulting from Takayasu arteritis.
5 revascularization in patients with Takayasu arteritis.
6 es of its main branches, indicating Takayasu arteritis.
7 red the gold standard in imaging of Takayasu arteritis.
8 s disease and the first GWAS of equine viral arteritis.
9 cute inflammatory illness marked by coronary arteritis.
10 tion, a response resembling clinical intimal arteritis.
11 tes in patients with panarteritic giant cell arteritis.
12 ic cells (DC) in the development of coronary arteritis.
13 and regulate the patterning of the emerging arteritis.
14 ells are required for LCCWE-induced coronary arteritis.
15 s in the pathological mechanisms of coronary arteritis.
16 ings relevant to the diagnosis of giant-cell arteritis.
17 diagnosis of challenging cases of giant-cell arteritis.
18 erning diagnosis and treatment of giant-cell arteritis.
19 dulating inflammation in atherosclerosis and arteritis.
20 r-alpha is present in arteries in giant cell arteritis.
21 ents with large-vessel disease in giant cell arteritis.
22 lesion described as endotheliitis or intimal arteritis.
23 nd devised a genetic risk score for Takayasu arteritis.
24 ar signaling in this mouse model of coronary arteritis.
25 chymal invasion and abscesses, and meningeal arteritis.
26 vation and granuloma formation in giant cell arteritis.
27 rom latent infection or induction of chronic arteritis.
28 the underlying pathomechanisms of giant cell arteritis.
29 s disease, multiple sclerosis and giant-cell arteritis.
30 , is the cause of gamma HV68-induced elastic arteritis.
31 during follow-up, with 1 caused by temporal arteritis.
32 olvement in elderly patients with giant cell arteritis.
33 re also diagnosed with giant cell (temporal) arteritis.
34 weanling mice exhibited milder large-vessel arteritis.
35 biopsy confirmed the diagnosis of giant cell arteritis.
36 idenced a worldwide distribution of Takayasu arteritis.
37 se in both giant cell arteritis and Takayasu arteritis.
38 condition or in association with giant cell arteritis.
39 d-free remission in patients with giant-cell arteritis.
40 ring was studied in patients with giant-cell arteritis.
41 and monocytes from patients with giant cell arteritis.
42 imicking polyarteritis nodosa and giant cell arteritis.
43 ils and monocytes that precipitates coronary arteritis.
44 individuals and in patients with giant cell arteritis.
45 A agonists may provide effective therapy for arteritis.
46 e age-related vasculitic syndrome giant cell arteritis.
47 s and tocilizumab) in patients with Takayasu arteritis.
48 omes are affected by the severity of intimal arteritis.
49 ains important in the management of Takayasu arteritis.
50 proach, prognosis, and treatment of brucella arteritis.
51 roles for monocytes and B cells in Takayasu arteritis.
52 ary embolism, transitory ischemic attacks to arteritis.
53 rimary sclerosing cholangitis and Takayasu's arteritis(3-6)-we identify that the causal gene, ETS2, i
54 cs and outcomes of 49 patients with Takayasu arteritis (80% female; median age, 42 years [20-55 years
56 s, such as Takayasu arteritis and giant cell arteritis, affect vital arteries and cause clinical comp
57 l and gene expression analyses of giant cell arteritis-affected temporal arteries revealed abundant e
59 equired for IL-1beta maturation) in coronary arteritis and evaluated the efficacy of IL-1 receptor an
60 r levels of chimerism, moderate CR including arteritis and fibrosis in the Peyer's patches and mesent
61 Large vessel vasculitides, such as Takayasu arteritis and giant cell arteritis, affect vital arterie
63 nd other recent investigations of giant cell arteritis and idiopathic intracranial hypertension is cl
64 A small number of patients with Takayasu arteritis and IgG4-related aortitis have also been succe
66 ecessary to regulate MCMV-associated elastic arteritis and latency in vivo and reactivation of a herp
67 a systemic lymphoplasmacytic and histiocytic arteritis and periarteritis in guinea pigs more than 2 m
68 enetic basis and pathophysiology of Takayasu arteritis and provides clues for potential new therapeut
70 ge vessel inflammatory disorders (giant cell arteritis and Takayasu arteritis) are the most common fo
71 nflamed arteries of patients with giant cell arteritis and Takayasu arteritis, and serum levels of th
72 ssel vasculitides, including both giant cell arteritis and Takayasu arteritis, and the aortitis of Co
73 tis, adult-onset Still's disease, giant cell arteritis and Takayasu arteritis, as well as other condi
75 ulitis, Wegener's granulomatosis, giant cell arteritis and Takayasu's arteritis in the US amounted to
76 y available tests: pentraxin-3 in giant cell arteritis and Takayasu's arteritis; von Willebrand facto
77 ce are protected from LCCWE-induced coronary arteritis and that this protection is mediated through t
79 cessful monitoring of patients with Takayasu arteritis and to plan possible interventional treatment.
80 There were 87,794 patients with giant cell arteritis and/or polymyalgia rheumatica (n = 25,581), in
82 2 of 203 (1.0%) for treatment of giant cell arteritis, and 1 of 193 (0.5%) for the pathophysiologic
86 ZV) vasculopathy produces stroke, giant cell arteritis, and granulomatous aortitis, and it develops a
87 ulomatosis, polyarteritis nodosa, giant-cell arteritis, and hypersensitivity vasculitis on the basis
88 teritis, in 1 of 1 cases of nongranulomatous arteritis, and in 5 of 18 control aortas (28%) obtained
90 vasculitides (Takayasu arteritis, giant cell arteritis, and polyarteritis nodosa) to atherosclerosis,
91 ients with giant cell arteritis and Takayasu arteritis, and serum levels of this cytokine mirror dise
92 uding both giant cell arteritis and Takayasu arteritis, and the aortitis of Cogan syndrome and relaps
94 ndents (5.1%; 95% CI, 2.2%-8.0%), giant cell arteritis; and 10 of 218 respondents (4.6%; 95% CI, 1.8%
95 is, polymyalgia rheumatica (PMR), giant cell arteritis, ankylosing spondylitis, and Sjogren's syndrom
99 ntracerebral VZV vasculopathy and giant cell arteritis are strongly associated with productive VZV in
101 disorders (giant cell arteritis and Takayasu arteritis) are the most common form of systemic vasculit
102 the category of acute rejection with intimal arteritis (ARV) is relevant to short- and long-term clin
103 Giant cell arteritis has supplanted temporal arteritis as the preferred term for chronic granulomatou
104 s disease, giant cell arteritis and Takayasu arteritis, as well as other conditions such as Castleman
105 e, our data demonstrate that in the coronary arteritis associated with KD, TGF-beta suppresses elasti
107 patients with A-AION secondary to giant cell arteritis (biopsy-proven), 20 patients with NA-AION, and
108 dy-mediated rejection ("mixed") activity and arteritis but little hyalinosis, whereas TCMR2 had less
109 be effective for the treatment of Takayasu's arteritis, but their role in the treatment of other form
110 metropolitan hospital and having giant cell arteritis, carotid artery disease, atrial fibrillation,
111 or RAO in cardiac surgery include giant cell arteritis, carotid stenosis, stroke, hypercoagulable sta
113 lammatory vascular disease, such as Takayasu arteritis, chemotherapy- or radiation-induced vascular i
114 c rejection grade, endotheliitis, transplant arteritis, coagulation necrosis, acute pancreatitis, pre
116 We performed a genetic study in Takayasu arteritis comprising 6,670 individuals (1,226 affected i
118 rtic involvement in patients with giant cell arteritis correlates with the significant detection of V
119 In temporal arteries affected by giant cell arteritis, DCs are highly enriched and activated and hav
120 multiple myeloma; acute leukemia; giant cell arteritis; dialysis; esophageal, stomach, pancreas, lung
121 ystemic granulomatous vasculitis, giant cell arteritis, diverse connective tissue disorders; viral, s
122 (EAV) is the causative agent of equine viral arteritis (EVA), a reproductive and respiratory disease
123 ustry as the causative agent of equine viral arteritis (EVA), a respiratory, systemic, and reproducti
124 T cells in vasculitic lesions of giant cell arteritis express several markers that identify them as
125 with such unusual manifestations of temporal arteritis facilitates early diagnosis and treatment, the
126 ontrol group, with significant reductions of arteritis, fibrosis, and cellular infiltration, includin
127 e provides a clinical overview of giant cell arteritis, focusing on diagnosis, treatment, and practic
128 thologic studies proposing an acute coronary arteritis followed by healing fail to account for the co
131 her an association exists between giant cell arteritis (GCA) and the presence of varicella-zoster vir
132 Polymyalgia rheumatica (PMR) and giant cell arteritis (GCA) are related inflammatory disorders occur
134 ticle aims to provide a review of giant cell arteritis (GCA) clinical features, differential diagnosi
142 Glucocorticoid (GC) therapy for giant cell arteritis (GCA) is effective but requires prolonged admi
149 that extracranial involvement of giant cell arteritis (GCA) may be more extensive than previously ap
150 a large-scale genetic analysis on giant cell arteritis (GCA), a polygenic immune-mediated vasculitis.
151 ge arteries is well-documented in giant-cell arteritis (GCA), but the risk for cardiovascular events
153 n rheumatology care and age, sex, giant cell arteritis (GCA), PMR relapses, corticosteroid complicati
163 ies, ranging from the vasculitides (Takayasu arteritis, giant cell arteritis, and polyarteritis nodos
164 avian or axillary vessels; aortic giant-cell arteritis; giant-cell arteritis presenting as an intense
165 is characterizes the pathology of giant cell arteritis, granulomatous aortitis, and intracerebral var
168 ), performed for the diagnosis of giant cell arteritis, has a low reported rate of complications.
169 , and some patients with refractory Takayasu arteritis have responded to the immunomodulator leflunom
172 ted during the 1984 outbreak of equine viral arteritis in central Kentucky subsequently became long-t
176 iption of a premortum diagnosis of pulmonary arteritis in PAN in which the patient had a response to
179 matosis, giant cell arteritis and Takayasu's arteritis in the US amounted to $150 million per year.
180 tion of LCCWE produced severe focal coronary arteritis in TLR4(-/-) and C57BL/6 control mice but not
181 s with pathologically verified granulomatous arteritis, in 1 of 1 cases of nongranulomatous arteritis
182 to autoimmune vasculitis, such as giant cell arteritis, in which CD8+ Treg cells fail to contain CD4+
184 f some of these conditions, such as Takayasu arteritis, includes a very long period of low level symp
185 urvival, parenchymal rejection, or occlusive arteritis, indicating that these processes are IFN-gamma
186 lammation of the arterial wall in giant cell arteritis induces a series of structural changes, includ
196 We show here that LCCWE-induced coronary arteritis is dependent on intact TLR2 and MyD88 signalin
197 ysm formation in association with giant cell arteritis is discussed, along with the implications of r
198 general, the clinical outcome of giant-cell arteritis is excellent, and efforts must now concentrate
200 In other vascular territories, giant-cell arteritis is most commonly diagnosed by vascular imaging
201 The clinical presentation of giant cell arteritis is occasionally nonspecific; patients can have
204 nt cell arteritis (GCA, also called temporal arteritis) is a rare and Takayasu arteritis (TA) is an e
206 mes of 79 consecutive patients with Takayasu arteritis (median age, 39 years; interquartile range [IQ
207 ary arteries: acute self-limited necrotizing arteritis (NA), subacute/chronic (SA/C) vasculitis, and
208 results than in patients with GCA giant cell arteritis -negative results ( TAB temporal artery biopsy
211 ssociated with increased RAO were giant cell arteritis (odds ratio [OR], 7.73; CI, 2.78-21.52; P < 0.
212 were more likely to have had rejection with arteritis, odds ratio (OR): 4.83 (1.47-15.87), p = 0.009
213 -documented classic PAN was found to have an arteritis of medium-sized muscular pulmonary arteries.
214 ) Systemic vasculitis disorders (necrotizing arteritis of the polyarteritis type, hypersensitivity va
216 were associated with allograft loss, whereas arteritis (OR=0.5, 95% CI=0.2-1.2, P=0.11) and glomeruli
217 yndrome, polyarteritis nodosa, or giant-cell arteritis) or a hematologic condition (myelodysplastic s
218 eral blood mononuclear cells from giant cell arteritis patients into immunodeficient NSG mice engraft
219 scription in temporal arteries of giant cell arteritis patients with and without up-regulated neoangi
220 sfer experiments, CCR6(+) T cells produce an arteritis pattern with media-invasive T cells damaging v
221 aled discrete, superficial, white retinitis; arteritis; phlebitis; and retinal hemorrhages with or wi
222 (PET Imaging of Giant Cell and Takayasu Arteritis [PITA], NCT04071691; Residual Inflammation and
223 antly higher in patients with GCA giant cell arteritis -positive results than in patients with GCA gi
224 els; aortic giant-cell arteritis; giant-cell arteritis presenting as an intense systemic inflammatory
227 t virus replication is necessary for chronic arteritis, since antiviral therapy of mice with establis
228 and radiographic manifestations of Takayasu arteritis (TA) in a cohort from the US, evaluate the res
229 d temporal arteritis) is a rare and Takayasu arteritis (TA) is an even rarer autoimmune disease (AID)
230 nflammation is a typical feature of Takayasu arteritis (TA), and tumor necrosis factor (TNF) is impor
231 ng been the standard for diagnosing temporal arteritis (TA), but in practice this test is less than 1
233 ust be able to confidently diagnose temporal arteritis (TA), since failure to make a correct diagnosi
236 clinical and laboratory features of Takayasu arteritis (TAK) and explore the risk factors that associ
237 Giant cell arteritis (GCA) and Takayasu's arteritis (TAK) are major forms of large-vessel vasculit
240 Most frequently encountered are giant cell arteritis (temporal arteritis) and vasculitis secondary
241 regulation of neoangiogenesis in giant cell arteritis, temporal arteries were examined for the exten
242 ei (LCCWE) into mice causes a focal coronary arteritis that histopathologically mimics the coronary l
243 tract (LCCWE), mice develop a focal coronary arteritis that histopathologically resembles Kawasaki di
246 Although much less common than giant cell arteritis, the different forms of antineutrophil cytopla
247 a for a positive biopsy result in giant cell arteritis, the imaging characteristics of primary angiit
249 imilar to the lesions observed in Takayasu's arteritis, the nongranulomatous variant of temporal arte
250 for polymyalgia rheumatica and/or giant cell arteritis to 2.82 for systemic lupus erythematosus).
251 ve highlighted etiologies such as giant cell arteritis, trauma, neuro-syphilis and demyelination seco
252 ymyalgia rheumatica, 228,000 have giant cell arteritis, up to 3.0 million have had self-reported gout
253 AMR: T cell-mediated rejection with intimal arteritis (v) lesion (TCMRV; n = 78), total antibody-med
254 cording to the Banff classification, intimal arteritis (v-lesion) contributes to diagnosing T cell-me
256 arteries (TAs) from patients with giant cell arteritis, varicella zoster virus (VZV) is seen in perin
259 ved in all known arteriviruses except equine arteritis virus (EAV) and wobbly possum disease virus (W
260 espiratory syndrome virus (PRRSV) and equine arteritis virus (EAV) are economically important veterin
261 apted virulent Bucyrus (VB) strain of equine arteritis virus (EAV) established persistent infection i
263 eptibility of CD3(+) T lymphocytes to equine arteritis virus (EAV) infection and establishment of per
265 f the virulent Bucyrus (VB) strain of equine arteritis virus (EAV) to produce the modified live virus
266 is the critical natural reservoir of equine arteritis virus (EAV), as venereal infection of mares fr
267 jor envelope proteins (G(L) and M) of equine arteritis virus (EAV), both individually and in heterodi
271 e determined the crystal structure of equine arteritis virus PLP2 in complex with ubiquitin (1.45 A).
273 xin-3 in giant cell arteritis and Takayasu's arteritis; von Willebrand factor antigen in childhood ce
282 licted the immunosuppressed patients whereas arteritis was restricted to the immunocompetent ones.
284 , a significantly milder rejection with less arteritis was seen in the allografts of the recipient ma
285 maurosis in whom the diagnosis of giant cell arteritis was suggested by perineural enhancement on orb
286 s casei wall extract (LCWE) induces coronary arteritis, we show that LCWE increased TGF-beta signalin
287 ematosus (SLE), systemic sclerosis, Takayasu arteritis, Wegener granulomatosis, Behcet syndrome, and
288 tery specimens from patients with giant cell arteritis were analyzed bu two-color immunohistochemistr
289 ghty-eight percent of patients with Takayasu arteritis were inadequately controlled with or were into
290 patients suspected of having GCA giant cell arteritis were included in a prospective three-universit
291 ant role in the pathogenesis of equine viral arteritis when horses are infected with the virulent str
292 one of the RAG1(-/-) mice developed coronary arteritis, whereas 70% of WT and 100% of B cell(null) mi
293 the temporal arteries, mimicking giant cell arteritis, while, to our knowledge, the association betw
295 pes can be distinguished: cranial giant-cell arteritis with ischemic complications in the eye, the fa
297 tral nervous system; large-vessel giant-cell arteritis with occlusions in the subclavian or axillary
298 t advances in medical management of Takayasu arteritis, with a special focus on the rationale and evi
300 ihood of stroke or visual loss in giant-cell arteritis without increasing bleeding complications.