Objectives’ To observe the effects of reflux esophagitis(RE) on the lung function and alrway reactivity,and study the mechanism of airway hyperresponsiveness(AHR) in patients with RE.Methods. Lung function measuremen...Objectives’ To observe the effects of reflux esophagitis(RE) on the lung function and alrway reactivity,and study the mechanism of airway hyperresponsiveness(AHR) in patients with RE.Methods. Lung function measurements and airway provocation tests were performed in 31 RE patientsand 35 control subjects’ TXB, and PGF,. were determined in 20 cases of each group.Results. In RE patients the lung function was lower and the rate of AHR was higher than control sub-jects (P<0. 05). Among RE patients 25 % had higher airway sensitivity (Dminr 3u ). The TXB2 of REpatients with AHR was higher than those without AHR’ Dmin correlated significantly with TXB2 (r=0. 653, P<0. 05).Concluswhs’ RE could damage the lung function. The rate of AHR was 61 %, the high airway sensltivity was probably potential asthma, and TXB2 may play a role in the pathogenesis of AHR.展开更多
Harvesting the promising high energy density of advanced electrode materials in lithium-ion batteries is critically dependent on a mechanistic understanding on how the materials function and degrade along with the bat...Harvesting the promising high energy density of advanced electrode materials in lithium-ion batteries is critically dependent on a mechanistic understanding on how the materials function and degrade along with the battery cycling.Here,we tracked phase transformations during(de)lithiation of Sb_(2)Se_(3) single crystals using in situ high-resolution transmission electron microscopy(HRTEM)technique,and revealed electro-chemo-mechanical evolution at the reaction interface.The effect of this electro-chemo-mechanical coupling has a complicated interplay on the lithiation kinetics and causes various types of defects at the reaction front,including dislocation dipoles,antiphase boundaries,and cracks.In return,the formed cracks and related defects build a path for fast diffusion of lithium ions and trigger a highly anisotropic lithiation at the twisted reaction front,giving rise to the formation of presumably "dead" Sb_(2)Se_(3) nanodomains in amorphous Li_(x)Sb_(2)Se_(3).The detailed mechanistic understanding may facilitate the rational design of high-capacity electrode materials for battery applications.展开更多
文摘Objectives’ To observe the effects of reflux esophagitis(RE) on the lung function and alrway reactivity,and study the mechanism of airway hyperresponsiveness(AHR) in patients with RE.Methods. Lung function measurements and airway provocation tests were performed in 31 RE patientsand 35 control subjects’ TXB, and PGF,. were determined in 20 cases of each group.Results. In RE patients the lung function was lower and the rate of AHR was higher than control sub-jects (P<0. 05). Among RE patients 25 % had higher airway sensitivity (Dminr 3u ). The TXB2 of REpatients with AHR was higher than those without AHR’ Dmin correlated significantly with TXB2 (r=0. 653, P<0. 05).Concluswhs’ RE could damage the lung function. The rate of AHR was 61 %, the high airway sensltivity was probably potential asthma, and TXB2 may play a role in the pathogenesis of AHR.
基金supported by the National Key R&D Program of China(2018YFB1304902)the National Natural Science Foundation of China(11904372,U1813211,and 12004034)+2 种基金Beijing Institute of Technology Research Fund Program for Young ScholarsBeijing Institute of Technology Laboratory Research Project(2019BITSYA03)China Postdoctoral Science Foundation Funded Project(2021M690386)。
文摘Harvesting the promising high energy density of advanced electrode materials in lithium-ion batteries is critically dependent on a mechanistic understanding on how the materials function and degrade along with the battery cycling.Here,we tracked phase transformations during(de)lithiation of Sb_(2)Se_(3) single crystals using in situ high-resolution transmission electron microscopy(HRTEM)technique,and revealed electro-chemo-mechanical evolution at the reaction interface.The effect of this electro-chemo-mechanical coupling has a complicated interplay on the lithiation kinetics and causes various types of defects at the reaction front,including dislocation dipoles,antiphase boundaries,and cracks.In return,the formed cracks and related defects build a path for fast diffusion of lithium ions and trigger a highly anisotropic lithiation at the twisted reaction front,giving rise to the formation of presumably "dead" Sb_(2)Se_(3) nanodomains in amorphous Li_(x)Sb_(2)Se_(3).The detailed mechanistic understanding may facilitate the rational design of high-capacity electrode materials for battery applications.
