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 28,634 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Primary pulmonary artery sarcoma is a very rare tumor. The prognosis of primary pulmonary artery sarcoma is extremely poor and it is reported as 1.5 months without treatment. Here we report our experience of surgical treatment of primary pulmonary artery sarcoma. A 66-year-old woman with a diagnosis of pulmonary sarcoma by chest computed tomography( CT) scan was referred to our hospital because of a loss of consciousness. An emergecy surgery was planned to eliminate the risk of sudden death. To avoid circulatory collapse, we placed her on extracorporeal bypass before anesthesia induction. The tumor extending from right ventricle outflow tract to bilateral pulmonary artery was removed and resected without leaving residual mass, but the surgical margin was positive, and adjuvant chemoradiotherapy was performed after discharge. In conclusion, surgical resection was succesfully conducted to avoid sudden death.
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PMID:[Surgical Treatment for Primary Pulmonary Artery Sarcoma;Report of a Case]. 3239 93

Recent advances in microscopy of living cells have established membraneless organelles as critical elements of diverse biological processes. The body of experimental work suggests that formation of such organelles is driven by liquid-liquid phase separation, a physical process that has been studied extensively for both simple liquids and mixtures of polymers. Here, we combine molecular dynamics simulations with polymer theory to show that the thermodynamic behavior of one particular biomolecular condensate-fused in sarcoma (FUS)-can be quantitatively accounted for at the level of the chain collapse theory. First, we show that a particle-based molecular dynamics model can reproduce known phase separation properties of a FUS condensate, including its critical concentration and susceptibility to mutations. Next, we obtain a polymer physics representation of a FUS condensate by examining the behavior of a single FUS protein as a function of temperature. We use the chain collapse theory to determine the thermodynamic properties of the condensate and to characterize changes in the single-chain conformation at the onset of phase separation. Altogether, our findings suggest that the phase behavior of FUS condensates can be explained by the properties of individual FUS proteins and that the change in the FUS conformation is the main force driving for the phase separation.
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PMID:Single-Protein Collapse Determines Phase Equilibria of a Biological Condensate. 3242 86


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