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1 pathway plays a critical role in intestinal cell injury.
2 ntrols were analyzed in an in vitro model of cell injury.
3 rodent models of neurodegeneration or nerve cell injury.
4 (HMGB1, histones) confirmed coagulopathy and cell injury.
5 ion only at concentrations that cause acinar cell injury.
6 about the direct role of TGFbeta in tubular cell injury.
7 ene expression, and it is a key mechanism of cell injury.
8 th the magnitude of complement-induced lytic cell injury.
9 trations (500 mum) that were associated with cell injury.
10 M) abrogated TLCS-induced Ca(2+) signals and cell injury.
11 y study epithelial closure in the absence of cell injury.
12 cted based on those found to decrease acinar cell injury.
13 uption of neural processes and biomarkers of cell injury.
14 tion, vascular inflammation, and endothelial cell injury.
15 hibitor did not protect against APAP-induced cell injury.
16 rane attack complex (MAC) as the effector of cell injury.
17 the presence of proinflammatory signals and cell injury.
18 eates vulnerability in both compartments for cell injury.
19 of the OGD and simulated reperfusion-induced cell injury.
20 on zymogen activation, amylase secretion, or cell injury.
21 a-acinar cell zymogen activation, and acinar cell injury.
22 hogens, as well as danger signals related to cell injury.
23 for Src inhibitors as an approach to reduce cell injury.
24 sting did not alter the severity of regional cell injury.
25 ikely to have implications in other types of cell injury.
26 id accumulation, foam cells, and endothelial cell injury.
27 h are characterized by prominent endothelial cell injury.
28 ment of chronic inflammation and endothelial cell injury.
29 Ngb expression and exacerbated H2O2-induced cell injury.
30 ment of chronic inflammation and endothelial cell injury.
31 viral gene expression cascade and limit host cell injury.
32 the form of cytoplasmic increases, leads to cell injury.
33 mice after streptozotocin (STZ)-induced beta-cell injury.
34 s that female sex steroids protect from beta-cell injury.
35 and STAT3 in hyperoxic lung and endothelial cell injury.
36 und to confer protection against endothelial cell injury.
37 -ethylhexyl)phthalate (MEHP)-induced Sertoli cell injury.
38 d lipid peroxidation and hepatic endothelial cell injury.
39 in NSAID-induced gastric mucosal and gastric cell injury.
40 otecting macrophages from adriamycin-induced cell injury.
41 nerated oxidant stress, synergize to promote cell injury.
42 rate can be accompanied by progressive beta-cell injury.
43 locker amiloride attenuated acidosis-induced cell injury.
44 factors in APOL1 renal risk variant-mediated cell injury.
45 lar mechanism(s) underlying toxicant-induced cell injury.
46 face of hypercytokinemia and potential islet cell injury.
47 had evidence for alveolar epithelial type 1 cell injury.
48 sanoid species that promote inflammation and cell injury.
49 species (ROS) that must be removed to avoid cell injury.
50 use rather than a consequence of parenchymal cell injury.
51 st complement-mediated glomerular epithelial cell injury.
52 under conditions of inflammatory stress and cell injury.
53 Sertoli cells could rescue the PFOS-induced cell injury.
54 biting GAPDH phosphorylation should decrease cell injury.
55 stimulation, pathogen infection, or sterile cell injury.
56 oxidative- and nutrient-deprivation-induced cell injury.
57 ng vascular remodeling following endothelial cell injury.
58 lular processes that underlie virus-mediated cell injury.
59 tected cells from proteotoxic stress-induced cell injury.
60 e increased which is an indication of neuron cell injury.
61 prevented activation of NF-kappaB and acinar cell injury.
62 he zebrafish and mammalian responses to hair cell injury.
63 axis protected against the oxidant-mediated cell injury.
64 d possibly other conditions that result from cell injuries.
65 ent that has been implicated in a variety of cell injuries.
66 sed by germ cells after MEHP-induced Sertoli cell injury acts upon Sertoli cell TNFR1 and activates N
67 nd in which steatogenesis, inflammation, and cell injury aggravate ER stress seems to be at play.
68 tion reflected the severity of an individual cell injury, allowing to discriminate between minor and
69 gations defining the mechanism of epithelial cell injury, alternative macrophage activation and effer
70 numbers is due to losses in cell viability, cell injury and a subsequent inability to be detected by
71 s a potential early marker of ischemic renal cell injury and a therapeutic target.Methods Differentia
72 IPF is characterized by alveolar epithelial cell injury and activation with interstitial inflammatio
73 blation with liposomal doxorubicin increases cell injury and apoptosis in the zone of increased coagu
76 ion of human GST A4-4 (hGSTA4-4) to vascular cell injury and consequent transplant arteriosclerosis i
78 hways involved in the development of tubular cell injury and death before and after transplantation.
80 hat activation of PKC-delta promotes tubular cell injury and death during albuminuria, broadening our
81 rstitial inflammation, fibrosis, and tubular cell injury and death, but the mechanisms underlying the
82 overexpression stimulated, independently of cell injury and death, release of numerous chemokines an
83 n disease (PD) and the molecular pathways of cell injury and death, we remain without therapies that
86 ation of polymorphisms related to epithelial cell injury and dysfunction and abnormal wound healing,
87 t EPA and DHA prevent DON-induced intestinal cell injury and enhance barrier function, which is assoc
89 zing radiation (IR) as a model of adult stem cell injury and identified a regeneration defect in agin
90 s overexpressing COX-2, high glucose induced cell injury and increased both expression of the pro(ren
94 zation causes the least amount of myocardial cell injury and is associated with superior long-term ou
95 hese data suggest that miRNAs linked to beta-cell injury and islet inflammation might be useful bioma
99 for modulating downstream bioeffects such as cell injury and mechanotransduction in ultrasound therap
100 s point to Ndfip1 as a sensor protein during cell injury and Ndfip1 up-regulation as a cue for BRAT1
101 These activated zymogens then cause acinar cell injury and necrosis, a characteristic of pancreatit
105 ic renal allografts, which show both tubular cell injury and proliferation, display down-regulation o
107 the effects of hypercapnic acidosis on lung cell injury and repair by confocal microscopy in a model
109 tabolism are tightly linked to regulate AEC2 cell injury and subsequent fibrotic remodeling in the lu
110 d to induce disease directly by causing beta cell injury and subsequent release of autoantigens and i
111 e role against hypoxia/reoxygenation-induced cell injury and suggest the therapeutic potential of MSR
112 cantly but incompletely reducing endothelial cell injury and T cell infiltration into the graft one o
114 has been shown to occur in some contexts of cell injury and to be essential for loss of cell viabili
115 r pathways, upstream (eg, protecting against cell injury) and downstream (eg, regulating CCN2 activit
116 nstrated significant endothelial and Kupffer cell injury, and a progressive lesion developed 24 to 48
117 uced pathological calcium transients, acinar cell injury, and activation of c-Jun N-terminal kinase,
118 located to mitochondria early during tubular cell injury, and both siRNA knockdown of Drp1 and expres
119 ome and autophagosome formation, exacerbated cell injury, and decreased cell viability in cultured NR
120 on of insulin-producing cells, islet or beta-cell injury, and genetic models of impaired beta-cell fu
121 ocytes and neutrophils, vascular endothelial cell injury, and intense vasculocentric infiltrates with
122 ation between the characteristics of ICW and cell injury, and potential strategies to mitigate cavita
124 le in which ER stress promotes inflammation, cell injury, and steatosis and in which steatogenesis, i
125 eleased by neurocytotoxic Abs or other brain cell injury, and the resulting immune complexes stimulat
127 bile-induced NF-kappaB activation and acinar cell injury are mediated by calcineurin, and a mechanism
129 also attenuated inflammation and endothelial cell injury as demonstrated by reduced plasma levels of
130 y peptide prevented bile acid-induced acinar cell injury as measured by lactate dehydrogenase leakage
131 or 2 hours resulted in significantly reduced cell injury, as shown by lactate dehydrogenase-release a
133 terfering RNA, pharmacological analysis, and cell injury assays, we show that activation of TRPM7 cha
136 shear adaptation (P = 0.03) and evidence of cell injury at sites of nonuniform shear profiles that a
137 se and SLO is associated with augmented host cell injury beyond that produced by SLO alone, but the m
138 pectrin breakdown products, SBDPs) and glial cell injury biomarker, glial fibrillary acidic protein (
139 n degradation, which not only mediates local cell injury, but also induces damage to the transplanted
140 n from monocytes and cause airway epithelial cell injury, but the role of eDNA, NETs, and IL-1beta in
141 helpful in preventing chronic ER stress and cell injury by alleviating protein misfolding in the ER.
142 ished that lipid peroxidation contributes to cell injury by altering the basic physical properties an
144 effects of AMPK and that TGF-beta1 promoted cell injury by blocking AMPK-mediated tuberin phosphoryl
145 means to ameliorate oxidative stress-induced cell injury by either inhibiting Ser(36) phosphorylation
146 rier (BTB), PFOS was found to induce Sertoli cell injury by perturbing actin cytoskeleton through cha
147 was found to block the PFOS-induced Sertoli cell injury by rescuing the PFOS-induced F-actin dis-org
148 brain slices were used for quantification of cell injury by spectrophotometric measurement of formaza
149 contributes to the progression of myocardial cell injury, cardiac fibrosis, and left ventricular (LV)
152 LI in wild-type mice and reduced endothelial cell injury caused by mitochondrial extract-primed human
153 ory failure is a serious consequence of lung cell injury caused by treatment with high inhaled oxygen
156 across all 4 patients and were indicative of cell injury, death, and to a lesser extent, fibrosis.
158 demonstrate that following kidney epithelial cell injury, DNA repair, rather than cell proliferation,
160 abetes (CFRD) is thought to result from beta-cell injury due in part to pancreas exocrine damage and
164 nd render them more or less vulnerable to NK cell injury during autoimmune vasculitis, such as granul
165 how fiber structure and mechanics influences cell injury during cyclic airway reopening as occurs dur
168 (miRNAs) might be useful biomarkers of beta-cell injury/dysfunction that would allow more accurate s
169 rome is characterized by alveolar epithelial cell injury, edema formation, and intraalveolar contact
170 rat salivary Pa-4 epithelial cells to resist cell injury elicited by 1% O(2)- or hypoxia-mimetic desf
171 developments include the role of epithelial cell injury, endoplasmic reticulum stress and Wnt signal
172 (CS)-induced pulmonary and renal endothelial cell injury explains the association between albuminuria
174 inflammation, and endothelial and epithelial cell injury, followed by repair that can be adaptive and
175 orylation of GAPDH correlates with increased cell injury following oxidative stress, suggesting that
176 olution of alveolar edema in ARDS, including cell injury from unfavorable ventilator strategies or pa
178 and predisposition to altered metabolism and cell injury have contributed to our current understandin
179 lografts and then correlated with epithelial cell injury, immune cell accumulation, and collagen depo
180 r results suggest that pulmonary endothelial cell injury in a genetically susceptible mouse strain tr
182 system disorders, prevents apoptotic SH-SY5Y cell injury in an oxidative stress model of oxygen-gluco
184 pathobiology of AT deficiency, mechanisms of cell injury in diseases associated with aggregation-pron
185 DSA) causes complement-dependent endothelial cell injury in kidney transplants, as assessed by expres
186 icularly calcium ions, in neuronal and glial cell injury in multiple sclerosis, as well as in non-inf
190 after injury) to assess oxidative stress and cell injury in the hippocampus or 4 months after injury
191 red blood cells, which can cause endothelial cell injury in the kidney that may lead to thrombus form
192 ights the vascular occlusion and endothelial cell injury in the medulla that contribute to sickle cel
193 ramylasemia, edema, inflammation, and acinar cell injury in TLCS-induced, but not caerulein-induced,
194 e results revealed that propofol exacerbates cell injury in vascular smooth muscle cells with increas
195 gonize toxin activity, preventing human lung cell injury in vitro and protecting experimental animals
196 differ in their ability to cause endothelial cell injury in vitro, nor did antibiotic-mediated eradic
197 O(2) derived from urate oxidation to prevent cell injury in vitro; during therapy, disulfide-linked p
198 that can directly measure the extent of beta-cell injury in vivo in patients receiving islet grafts a
199 ecognize self-antigens under conditions (eg, cell injury) in which the self-tissue might elaborate im
200 d showed less hepatocellular and endothelial cell injury, in agreement with better-preserved liver hi
202 ell viability and cell number, and inhibited cell injury indicated by lower LDH activity in the media
203 creased protein-S-glutathionylation prior to cell injury, indicating that thiol oxidation is involved
204 insulin directly protects pancreatic acinar cell injury induced by bona fide pancreatitis-inducing a
205 re secondary to extensive tubular epithelial cell injury induced by the lytic replication of BKV.
209 closure of epithelial gaps in the absence of cell injury is governed by the collective migration of c
210 nance of the bronchial airway epithelium, CE cell injury is resolved through a mechanism involving re
211 of age, but, unlike in skeletal muscle, the cell injury is sublethal and causes only mild cardiomyop
212 The results showed that severe endothelial cell injury leading to hemorrhage in the brain and other
213 angial cell proliferation, whereas mesangial cell injury leads to foot process fusion and proteinuria
214 ed mice have pulmonary and renal endothelial cell injury linked to increased endothelial cell AGEs an
216 cell nuclear pleomorphism and focal tubular cell injury, lysis, and karyorrhexis were observed as ea
218 dentify clusterin as a pivotal factor in the cell injury mechanism of nephropathic cystinosis and pro
219 s an important role in restraining bystander cell injury mediated either by defined TCR transgenic T
220 MiRNAs including miR-375 (linked to beta-cell injury), miR-21 (associated with islet inflammation
222 Sox9(+) cells were traced in multiple oval cell injury models using both histology and fluorescence
225 tis by promoting pancreatic edema and acinar cell injury/necrosis and that this phenomenon is depende
226 ion also reduces pancreatic edema and acinar cell injury/necrosis in two dissimilar experimental mode
227 ic microangiopathies is vascular endothelial cell injury of various origins, resulting in microangiop
228 in the absence of histologically significant cell injury, often manifesting clinically as seizures.
229 lenging to study the impact of dopamine (DA) cell injury on corticostriatal activity in vivo due to l
230 els have been used as biomarkers to evaluate cell injury or activation in patients with pathological
231 ssion, we have investigated the effect of DA cell injury or DA receptor antagonism on immediate-early
232 ption of this dynamic equilibrium may herald cell injury or death and may contribute to developmental
233 istology and TUNEL staining did not indicate cell injury or death in the lung, liver, kidney, spleen,
234 astrocyte immunoreactivity-indicating either cell injury or death-and functionally disrupted the BBB
237 GI2 on hypoxia/reoxygenation-induced tubular cells injury or I/R kidneys by measuring oxidative stres
238 nable development of interventions to reduce cell injury, our research has focused on understanding m
239 that act as sensors of microbial presence or cell injury, Paneth cells as the main epithelial cell ty
240 ding should facilitate the identification of cell injury pathways and corresponding therapeutic targe
244 to this neuropathy, we examined a marker of cell injury/regeneration (activating transcription facto
246 acute neutrophilic inflammatory response to cell injury requires the signaling protein myeloid diffe
247 ge to the peripheral nerves triggers Schwann cell injury response in the distal nerves in an event te
249 e whereas (99m)Tc-duramycin, a new marker of cell injury, senses cell death via apoptosis or necrosis
251 cellular defenses on neurotoxicant-elicited cell injury, SH-SY5Y cells were pretreated with D3T for
252 l requirements for specific versus bystander cell injury suggest that there are opportunities for inh
253 rovide a mechanism to account for the severe cell injury that follows hypoxia and reoxygenation when
254 rhosis develops after a long period of liver-cell injury that leads to the deposition of collagen, le
255 taneously conditions endothelial and Kupffer cell injury that may ultimately lead to the failure of t
256 ning tissue homeostasis in the face of local cell injury that occurs on a regular basis in many organ
257 ent cascade is an ancient means of detecting cell injury that precedes the evolution of adaptive immu
258 iculate actin is a marker for sepsis-induced cell injury, that plasma gelsolin has a crucial protecti
259 the stressful conditions (e.g., infection or cell injury), the exact roles of these molecules in the
261 The translocation of HMGB1, a marker of cell injury, the downregulation of proteins that functio
262 athogenesis including the role of structural cell injury, the pathogenic role of macrophages and lymp
263 as not associated with increased hippocampal cell injury, the trauma-induced reductions in CBF and po
264 inoleic acid metabolites are released during cell injury, these findings suggest a mechanism for inte
265 o fibrosis after proximal tubular epithelial cell injury, this mechanism may have widespread relevanc
266 Bile acid exposure causes pancreatic acinar cell injury through a sustained rise in cytosolic Ca(2+)
267 es bile acid-induced pancreatitis and acinar cell injury through aberrant intracellular Ca(2+) signal
269 compensatory changes in response to Purkinje cell injury, thus illustrating an important feature of P
271 aling pathway appears to amplify cytotoxic T cell injury to the epidermal basal cell compartment.
272 autophagy and its pathological role in renal cell injury using in vitro and in vivo models of ischemi
274 pathologic angiogenesis in relation to glial cell injury, VEGF protein, and mRNA levels of key mediat
275 a greater reduction in metabolic crisis and cell injury volumes compared to a cerebral perfusion pre
277 ytes were exposed to type I collagen (COL1); cell injury was assessed by morphologic and biochemical
280 dUTP nick-end labeling staining, widespread cell injury was observed in SFTPC-/- and SFTPC+/+ mice 1
281 oxetine to improve hyperglycemic endothelial cell injury was unique among serotonin reuptake blockers
282 del of naphthalene-induced airway epithelial cell injury, we showed that necrosis activates the ASC i
283 lation, foam cell generation and endothelial cell injury were all increased by hyperlipidemia, wherea
284 urements of optic nerve and retinal ganglion cell injury were assessed by magnetic resonance imaging
287 ty acid binding protein, a marker of tubular cell injury, were dramatically reduced by PP but not NPP
288 olar lavage RTI40 levels, a marker of type I cell injury, were similar with or without recruitment ma
289 llular activation of digestive zymogens, and cell injury when these responses are induced by exposure
290 ng molecule that is generated in response to cell injury where it orchestrates tissue protection and
292 hic transition, host cell adherence, or host cell injury, which are all established virulence attribu
293 yperamylasemia, pancreatic edema, and acinar cell injury, which closely mimic pancreatitis in humans.
294 associated with vasculopathy and endothelial cell injury, which could potentially increase the risk o
296 lular Zn(2+) accumulation and Zn(2+)-induced cell injury, while silencing TRPM7 by small interfering
297 (AP) suggest a strong association of acinar cell injury with cathepsin B-dependent intracellular act
298 d to correlate strongly with the severity of cell injury, with CICW in the range of 33 mum/s to 93 mu
300 uently leads to a self-amplifying cascade of cell injury within the lung from which the lung cannot r