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1 ncy, liver involvement, cerebral symptoms or pulmonary edema).
2 ng O2 sensing and preventing hypoxia-induced pulmonary edema.
3 ing pulmonary inflammation can contribute to pulmonary edema.
4 oxygen toxicity include vascular leakage and pulmonary edema.
5 itial fibrosis, left atrial hypertrophy, and pulmonary edema.
6 eal body weight could detect weaning-induced pulmonary edema.
7 tery catheter for diagnosing weaning-induced pulmonary edema.
8 lial cell surface, leading to persistence of pulmonary edema.
9 penia, and vascular leakage leading to acute pulmonary edema.
10 ult, halted LPS-induced vascular leakage and pulmonary edema.
11 hypoxemia, cardiopulmonary dysfunction, and pulmonary edema.
12 lung syndrome and sepsis, prime the lung for pulmonary edema.
13 ed with impaired wound repair and subsequent pulmonary edema.
14 ith intraluminal purulent exudate, BOOP, and pulmonary edema.
15 at causes leakage of protein-rich plasma and pulmonary edema.
16 e (LVSV) and aortic stiffness predict future pulmonary edema.
17 lial barrier function and the development of pulmonary edema.
18 s of respiratory mechanics, blood gases, and pulmonary edema.
19 t (n=2), and acute RV dysfunction with flash pulmonary edema.
20 attenuated VILI-induced albumin leakage and pulmonary edema.
21 ften present with cardiogenic shock or acute pulmonary edema.
22 nosine receptor ligands can be used to treat pulmonary edema.
23 stinguishing cardiogenic from noncardiogenic pulmonary edema.
24 with an important role in hyperoxic ALI and pulmonary edema.
25 MA), as a therapeutic strategy for treating pulmonary edema.
26 nt of plasma into the alveolar space causing pulmonary edema.
27 ma fluid is increased in adults with ALI and pulmonary edema.
28 tiating between hydrostatic and permeability pulmonary edema.
29 ive pulmonary disease, and acute cardiogenic pulmonary edema.
30 o maintain alveolar fluid homeostasis during pulmonary edema.
31 riction, lung inflammation, and protein-rich pulmonary edema.
32 ained from control patients with hydrostatic pulmonary edema.
33 osis surrounded by hemorrhagic effusions and pulmonary edema.
34 corpion venom causes respiratory failure and pulmonary edema.
35 oxia-treated mice die within days from acute pulmonary edema.
36 t may be valuable for diagnosing reperfusion pulmonary edema.
37 ockade has been shown to prevent and resolve pulmonary edema.
38 me overload in vivo pig model of hydrostatic pulmonary edema.
39 vacaftor is a novel therapeutic approach for pulmonary edema.
40 nfluent opacities, a finding consistent with pulmonary edema.
41 s confirm that SIPE is a form of hemodynamic pulmonary edema.
42 n, mortality, RRT, cardiovascular events, or pulmonary edema.
43 nt approach for inflammation-induced ALI and pulmonary edema.
44 olar fluid clearance, which in turn leads to pulmonary edema.
45 P had significantly enhanced lung damage and pulmonary edema.
46 spiratory distress syndrome from cardiogenic pulmonary edema.
47 rome and 15 patients (11.4%) had cardiogenic pulmonary edema.
48 SCs on both survival and the accumulation of pulmonary edema.
49 -/-) mice showed increased susceptibility to pulmonary edema.
50 linical signs associated with HPS, including pulmonary edema.
51 mmation with relevance for clinical study of pulmonary edema.
52 g systolic) treated with vasopressors (18%), pulmonary edema (14%), and hyponatremia<130 mmol/L (14%)
53 decrease in excess lung water, a measure of pulmonary edema (145 +/- 50 vs 87 +/- 20 microl; p < 0.0
54 ociated with lower incidences of cardiogenic pulmonary edema (22/155 [14.4%] vs. 43/155 [27.7%]; P =
56 pro-B-type natriuretic peptide, (2) clinical pulmonary edema, (3) radiologic pulmonary congestion or
57 ), 39% in 28 patients with acute cardiogenic pulmonary edema, 68% in nine patients with non-COPD hype
58 increased only in cases with weaning-induced pulmonary edema (9% +/- 3%, 9% +/- 4%, 21% +/- 23%, resp
59 When measured early after the onset of acute pulmonary edema, a BNP level of <250 pg/mL supports the
60 cell (EC) permeability and may culminate in pulmonary edema, a devastating complication of acute lun
61 decreased pulmonary gas exchange, increased pulmonary edema, abnormal lung compliance, and extensive
62 d the ability of Sph 1-P to prevent regional pulmonary edema accumulation in clinically relevant rode
63 e lung strategy to reduce the development of pulmonary edema, acute lung injury and pneumonia, and to
64 on cohort of consecutive patients with acute pulmonary edema admitted to three intensive care units.
65 ay prove valuable for diagnosing reperfusion pulmonary edema after pulmonary endarterectomy and had p
66 hydrostatic (TACO) and permeability (TRALI) pulmonary edema after transfusion is difficult, in part
67 spiratory distress syndrome from cardiogenic pulmonary edema alone or no edema (area under the receiv
68 ity of USA300 to cause severe lung necrosis, pulmonary edema, alveolar hemorrhage, hemoptysis, and de
70 ted to the respiratory tract and resulted in pulmonary edema and acute lung injury with hyaline membr
74 thelium that leads to impaired resolution of pulmonary edema and also facilitates accumulation of pro
75 with respiratory failure due to cardiogenic pulmonary edema and chronic obstructive pulmonary diseas
76 lung water (EVLW) correlate to the degree of pulmonary edema and have substantial prognostic informat
77 bronchiolitis, diffuse alveolar damage with pulmonary edema and hemorrhage, and interstitial and air
79 ndings included diffuse alveolar damage with pulmonary edema and hyaline membrane formation associate
81 type in Ent2(-/-) mice, including attenuated pulmonary edema and improved gas exchange during ALI in
82 WASP knockdown attenuated the development of pulmonary edema and improved survival in a mouse model o
83 cellular adenosine generation show increased pulmonary edema and inflammation after ventilator-induce
89 mplicated HIF1A-stabilization in attenuating pulmonary edema and lung inflammation during ALI in vivo
91 nants of systemic anaphylaxis and associated pulmonary edema and might be beneficial targets for anap
92 e proinflammatory cytokine TNF, showing both pulmonary edema and mortality at subthreshold S1P doses.
93 Anxa2(+/+) controls, Anxa2(-/-) mice develop pulmonary edema and neutrophil infiltration in the lung
95 this setting is essential for resolution of pulmonary edema and recovery of left ventricular functio
96 ensation typified by increased heart weight, pulmonary edema and reduced function compared to control
98 uggested that naloxone attenuates neurogenic pulmonary edema and reverses hypoxemia after brain death
100 potential therapeutic approach for reducing pulmonary edema and the severity of HPS following ANDV i
101 ardiac dysfunction as the principal cause of pulmonary edema and therefore help in the diagnosis of a
103 oleic acid acted synergistically to increase pulmonary edema and to worsen gas exchange and hemodynam
104 accompanying brain death leads to neurogenic pulmonary edema and triggers development of systemic and
105 ology of the lung tissues revealed extensive pulmonary edema and vascular damage following infection,
106 virus 71-induced brainstem encephalitis with pulmonary edema and/or neurogenic shock (stage 3B) is as
107 e 1-week mortality of enterovirus 71-induced pulmonary edema and/or neurogenic shock without adverse
110 mpact on outcome and treatment of neurogenic pulmonary edema, and considerations for organ donation.
111 vascular permeability, interleukin-2-induced pulmonary edema, and delayed-type hypersensitivity (DTH)
112 tion of P326TAT attenuated vascular leakage, pulmonary edema, and endothelial apoptosis in the lungs
116 sfunction, cardiac hypertrophy and fibrosis, pulmonary edema, and impaired mitochondrial function.
117 y disease exacerbations or acute cardiogenic pulmonary edema, and in immunocompromised patients, as w
118 gas exchange and lung compliance, increased pulmonary edema, and inflammatory indices, such as inter
119 attenuates cardiac hypertrophic remodeling, pulmonary edema, and interstitial fibrosis and prevents
121 y of proinflammatory cytokines, high-protein pulmonary edema, and neutrophilic lung inflammation.
123 ications (respiratory failure, reintubation, pulmonary edema, and pneumonia) within 3 days of surgery
127 tantially less lung injury and inflammation, pulmonary edema, and tissue bacterial burden than did in
128 es a new PCV2 disease syndrome, called acute pulmonary edema (APE), which, unlike other PCVAD syndrom
129 dicted development of clinically significant pulmonary edema (area under the receiver-operating chara
130 impaired carotid body O2 sensing and develop pulmonary edema as a consequence of poor ventilatory ada
131 4 as a potential target for the treatment of pulmonary edema associated with heart failure generated
133 ute respiratory distress syndrome (ARDS) and pulmonary edema associated with the accumulation of neut
134 controls and patients with acute cardiogenic pulmonary edema, baseline protein-C levels were low and
135 et: severe hyperkalemia, metabolic acidosis, pulmonary edema, blood urea nitrogen level higher than 1
136 Fio2 ratios from 6 to 24 hrs, p < .01 each), pulmonary edema (bloodless wet-to-dry-weight ratio; p =
137 ty in DNI patients with COPD and cardiogenic pulmonary edema but not in patients with post-extubation
139 elium, including enhancing the resolution of pulmonary edema by up-regulating sodium-dependent alveol
141 resolution of alveolar edema in cardiogenic pulmonary edema can be rapid, the rate of edema resoluti
143 t outcomes (death, congestive heart failure, pulmonary edema, cardiogenic shock, stroke, myocardial i
144 gressing abruptly to cardiac dysfunction and pulmonary edema causes rapid death within several hours.
145 eeded to treat=16, with survival improved in pulmonary edema, chronic obstructive pulmonary disease e
146 r performance, reduced fibrosis, and reduced pulmonary edema comparable to or better than metoprolol
148 e wet-to-dry lung weight ratio, a measure of pulmonary edema, compared with mice that received LPS al
150 predictive markers of clinically significant pulmonary edema (defined as acute respiratory distress s
152 ollapse, acute left ventricular failure with pulmonary edema, disseminated intravascular coagulation,
153 "pulmonary edema," "experimental neurogenic pulmonary edema," "donor brain death," and "donor lung i
156 l, 26 patients (84%) experienced reperfusion pulmonary edema during the first 72 hours after pulmonar
158 ng conditions such as severe hyperkalemia or pulmonary edema) during severe AKI allowed many patients
160 rms "neurogenic" with "pulmonary oedema" or "pulmonary edema," "experimental neurogenic pulmonary ede
162 oxygenase-2 mRNA and PGE2-inducing factor in pulmonary edema fluid and accounts for the differential
163 ations of surfactant proteins A and D in the pulmonary edema fluid and higher concentrations in the p
166 human alveolar type II cells exposed to ALI pulmonary edema fluid compared with plasma (0.02 +/- 0.0
168 In this study, we tested the hypothesis that pulmonary edema fluid from patients with ALI might reduc
171 e have reported that IL-1beta is elevated in pulmonary edema fluid in those with ALI and mediates an
172 nsistent with the experimental results, high pulmonary edema fluid levels of IL-8 (>4000 pg/ml) were
175 to identify fibroblast mitogenic factors in pulmonary edema fluid, and second to examine the human l
178 almeterol 10 (-6) M attenuated the degree of pulmonary edema following acid-induced lung injury.
181 d increase in lung vascular permeability and pulmonary edema following transient overexpression of th
183 nockout mice had increased vascular leak and pulmonary edema formation after endotracheal LPS, and in
184 We evaluated the role of TNF signaling in pulmonary edema formation in a clinically relevant mouse
185 ce, Sphk1(-/-) mice showed markedly enhanced pulmonary edema formation in response to lipopolysacchar
186 ung injury through enhanced PMN recruitment, pulmonary edema formation, and endothelial and myeloid c
187 ess ET increases lung VEGF levels, promoting pulmonary edema formation, and that hypoxia exaggerates
191 itially seen with acute flaccid paralysis or pulmonary edema had significantly greater frequencies of
192 al parameters in patients with high-altitude pulmonary edema (HAPE) and high-altitude pulmonary hyper
193 om eleven unbiased studies for high altitude pulmonary edema (HAPE) and respiratory distress syndrome
196 roxidase activity, endothelial permeability (pulmonary edema), immune cell infiltrate (histological a
197 583 treatment was associated with attenuated pulmonary edema, improved histologic lung injury, and da
198 mplicated 19.4% of ongoing pregnancies, with pulmonary edema in 16.7% and sustained arrhythmias in 2.
199 kness occurred in 314 (23.7%), high-altitude pulmonary edema in 22 (1.7%), and high-altitude cerebral
201 luid clearance in normal lungs and b) reduce pulmonary edema in acid aspiration-induced lung injury b
202 F plays a central role in the development of pulmonary edema in ALI through activation of p55-mediate
203 o patients, pericardial effusion in one, and pulmonary edema in another; in the group that underwent
205 l mechanisms that regulate the resolution of pulmonary edema in both the normal and the injured lung.
206 injection, providing >60% protection against pulmonary edema in endotoxin-challenged mice (vs <6% pro
208 tion of circulating histamine and associated pulmonary edema in mice, were significantly attenuated b
209 VR, considering the risk of life-threatening pulmonary edema in PVOD, if treated by conventional pulm
210 anging from respiratory tract irritation and pulmonary edema in severe cases to constrictive bronchio
213 (neutrophil infiltration) and wet-dry ratio (pulmonary edema) in the lungs of animals subjected to Gr
214 on of proinflammatory cytokines, more severe pulmonary edema, increased neutrophil extracellular trap
215 agnosis between hydrostatic and permeability pulmonary edema, invasive techniques such as right heart
216 e alveolar epithelium to prevent and resolve pulmonary edema is a crucial determinant of morbidity an
224 y dynamic strain (VT 825+/-424 mL) developed pulmonary edema (lung weight from 334+/-38 to 658+/-99 g
225 y contribute to the development of hyperoxic pulmonary edema, lung injury, and respiratory failure.
226 li pneumonia with a significant reduction in pulmonary edema, lung vascular permeability, and bactere
227 omparable levels of physiological injury and pulmonary edema, measured by respiratory system mechanic
228 ents with HF are severely ill as a result of pulmonary edema, myocardial ischemia, or cardiogenic sho
230 respectively, for patients with cardiogenic pulmonary edema (n = 97), acute exacerbation of chronic
233 thmia, heart, liver or renal dysfunction, or pulmonary edema, occurred in both groups to a similar ex
234 ctomy is closely associated with reperfusion pulmonary edema occurrence in the next 48 hours (area un
236 lmonary rales, cardiomegaly, interstitial or pulmonary edema on chest radiograph, S(3) heart sound, t
238 .008), as well as increased diuretic use and pulmonary edema on first chest x-ray, which resolved wit
239 art rate, arterial oxygenation, evidence for pulmonary edema on initial chest x-ray, or rearrest.
240 airway inflammation and rapid development of pulmonary edema on thoracic images, coronary artery aneu
241 case report, we described fast resolution of pulmonary edema on treatment with the tyrosine kinase in
242 resent a degree of subclinical high-altitude pulmonary edema or a functional limitation in pulmonary
243 one or more of the following complications: pulmonary edema or embolism, myocardial infarction, stro
245 3 per quintile; 95% CI, 1.0 to 1.7; P=0.03), pulmonary edema (OR, 2.1 per quintile; 95% CI, 1.6 to 2.
247 Severe presentation (cardiogenic shock, pulmonary edema, or cardiac arrest) was noted in 91% pre
248 estigator-reported congestive heart failure, pulmonary edema, or cardiac failure (hazard ratio for th
250 no weight loss, hypoxemia, lung dysfunction, pulmonary edema, or pulmonary inflammation over a 6-day
251 isk for clinically significant postoperative pulmonary edema, particularly resulting from the acute r
253 rate is a risk factor for ventilator-induced pulmonary edema, possibly because it amplifies lung visc
254 l O2 saturation (hypoxemia), lung pathology, pulmonary edema, reduced lung compliance, increased basa
255 erapeutic intervention for the prevention of pulmonary edema related to inflammatory injury and incre
256 due to an inflammatory and high permeability pulmonary edema secondary to direct or indirect lung ins
259 et a therapeutic option for the treatment of pulmonary edema, several experimental studies have repor
261 S is characterized by increased permeability pulmonary edema, severe arterial hypoxemia, and impaired
263 fatal myocardial infarction, cardiac events, pulmonary edema, stroke, thromboembolism, renal failure,
264 es virus (ANDV) causes a highly lethal acute pulmonary edema termed hantavirus pulmonary syndrome (HP
266 ung injury (TRALI), a form of noncardiogenic pulmonary edema that develops during or within 6 h after
268 e of PLY, a mediator of pneumococcal-induced pulmonary edema, this binding stabilizes the ENaC-PIP2-M
269 aeruginosa-induced vascular permeability and pulmonary edema through the modulation of actin cytoskel
271 inflammatory and hypersensitivity disorders, pulmonary edema, traumatic lung injury, cerebral edema r
272 ide, TRALI causes hypoxia and noncardiogenic pulmonary edema, typically within 6 hours of transfusion
274 lish-language articles concerning neurogenic pulmonary edema using the search terms "neurogenic" with
275 respiratory distress syndrome or cardiogenic pulmonary edema) using area under the receiver-operating
276 eta1-mediated acute lung injury by promoting pulmonary edema via regulation of actin cytoskeleton dyn
287 acteristics curves to detect weaning-induced pulmonary edema were 0.89 (95% CI, 0.78-0.99) for extrav
289 mechanisms responsible for the formation of pulmonary edema were identified by 1980, the mechanisms
290 he mechanisms that explain the resolution of pulmonary edema were not well understood at that time.
291 nic obstructive pulmonary disease, and acute pulmonary edema), whereas others were observed only in C
292 syndrome are characterized by noncardiogenic pulmonary edema, which can be assessed by measurement of
293 right ventricular strain and noncardiogenic pulmonary edema, which may potentially alter concentrati
294 an or equal to 14% diagnosed weaning-induced pulmonary edema with a sensitivity of 67% (95% CI, 43-85
297 otoxin into the distal airspaces resulted in pulmonary edema with the loss of alveolar epithelial flu
300 ermore, we hypothesized that the I/R-induced pulmonary edema would be significantly attenuated in rat