Beckerkragh0079

Primary pulmonary intimal sarcoma is rare. Differentiating it from pulmonary thromboembolism is difficult because of similarities in clinical symptoms and imaging findings. Positron-emission tomography-computed tomography has been useful for diagnosing primary pulmonary intimal sarcoma. We describe a rare case of primary pulmonary intimal sarcoma that showed no abnormal 18F-fluorodeoxyglucose uptake on positron-emission tomography. We resected the mass and performed right ventricular outflow tract reconstruction. Proper diagnosis is necessary to determine appropriate therapy, Clinicians must consider the possibility of primary pulmonary intimal sarcoma even if imaging findings are inconsistent with the disease.Mycobacterium tuberculosis is a very rare cause of extracranial carotid artery pseudoaneurysm. A 39-year-old man presented with a rapidly increasing neck mass and hoarseness of voice for 15 days. He was on antitubercular treatment for pulmonary tuberculosis. Computed tomography angiography showed a large pseudoaneurysm of the right common carotid artery. Emergency surgery was performed to excise the pseudoaneurysm sac and repair the artery with a Dacron graft. Postoperative angiography showed normal flow in the carotids and cerebral circulation. Histology of the excised tissue was consistent with a tubercular etiology of the pseudoaneurysm.Redox imbalance and oxidative stress-related biomarkers are raising increasing consensus in the scientific community for their significant role in a wide range of human disorders. In this framework, the total antioxidant capacity (TAC), namely, the overall pattern of both enzymatic and nonenzymatic antioxidant compounds within the body, represents an important bioanalytical parameter. To date, however, antioxidant assays require costly instrumentations, laboratory setups, and reagents, and they are invasive. Yet, their accuracy typically suffers from strong sensitivity to interfering matrices and inability to detect the complete pattern of physiological antioxidant molecules, due to the use of reaction schemes and probes/substrates that are not sensitive to the diverse range of relevant target species. Here, we exploit the enzyme-mimetic properties of platinum nanoparticles combined with hydroxyl radical probes produced at the particle surface to develop an effective detection scheme that is sensitive to both single electron transfer (SET) and hydrogen atom transfer (HAT) reactions, thus covering all the physiologically relevant antioxidant species. Importantly, the nanozyme-enabled method allows fast (5 min), accurate, and noninvasive evaluation of the body TAC through saliva via simple naked-eye or smartphone-based inspection.Forged signature threatens the authenticity of personal identity. Here, an effective SERS anti-counterfeiting system is designed for personal signatures. Mixed ligands improve the complexity of Raman spectra and expand the coding capacity. Fourteen distinct combinations are created from mere five ligands, and great expansion is possible with modest expansion of the ligand library. click here On the other hand, the (Au-aggregate)@Ag@PSPAA nanostructure significantly increases the surface-enhanced Raman scattering (SERS) intensity and stability so that excellent performance is achieved in SERS detection. By integrating these strategies, SERS inks are produced and applied in signature anti-counterfeiting. The resulting spectra are converted to barcodes that are readily detected through a smart phone APP. With these improvements, this work brings SERS one step closer toward practical applications in signature anti-counterfeiting.Restless legs syndrome (RLS), also known as Willis-Ekbom Disease, is a sleep and neurological sensorimotor disorder. The prevalence of RLS is at ~ 5%-15% in the general population. RLS could severely impact the daytime work productivity and the life quality of patients. However, the current diagnostic methods fail to provide an accurate and timely diagnosis, and the pathophysiology of RLS is not fully understood. Glycomics can help to unravel the underlying biochemical mechanisms of RLS, to identify specific glycome changes, and to develop powerful biomarkers for early detection and guiding interventions. Herein, we undertook a shotgun glycomics approach to determine and characterize the potential glycan biomarker candidates in the blood serum of RLS patients. Glycan profiles and isomeric quantitations were assessed by LC-MS analysis and compared with healthy controls. 24 N-glycan biomarker candidates show substantial differences between RLS patients and controls after the Benjamini-Hochberg multiple testing correction. Among those structures, glycans with the composition of HexNAc6Hex8Fuc1NeuAc2, HexNAc6Hex6Fuc1NeuAc3, and HexNAc5Hex6Fuc1NeuAc2 show the most significant alteration in expression profile (p less then 0.001). Furthermore, 23 isomeric structures in the RLS cohorts show significant differences after the Benjamini-Hochberg multiple testing correction. HexNAc4Hex5Fuc1NeuAc2 (4512-3) and HexNAc6Hex7NeuAc3 (6703-1) (p less then 0.001) were down expressed in the RLS cohort. HexNAc6Hex7NeuAc3 (6703-2) and HexNAc5Hex6NeuAc3 (5603-5) (p less then 0.001) were expressed higher in the RLS cases. These results demonstrate that it is possible to detect specific glycome traits in individuals with RLS. The discovery of the N-glycan expression alterations might be useful in understanding the molecular mechanism of RLS, developing more refined and objective diagnostic methods, and discovering novel targeted therapeutic interventions.The physical and chemical characteristics of the edge states of graphene have been studied extensively as they affect the electrical properties of graphene significantly. Likewise, the edge states of graphene in contact with semiconductors or transition-metal dichalcogenides (TMDs) are expected to have a strong influence on the electrical properties of the resulting Schottky junction devices. We found that the edge states of graphene form chemical bonds with the ZnO layer, which limits the modulation of the Fermi level at the graphene-semiconductor junction, in a manner similar to Fermi level pinning in silicon devices. Therefore, we propose that graphene-based Schottky contact should be accomplished with minimal edge contact to reduce the limits imposed on the Fermi level modulation; this hypothesis has been experimentally verified, and its microscopic mechanism is further theoretically examined.