As a major component of lignin and abundantly existing in softwood and hardwood, ferulic acid has been used as a lignin-related compound for lignin biodegradation study. Biodegradation of ferulic acid by Cupriavidus s...As a major component of lignin and abundantly existing in softwood and hardwood, ferulic acid has been used as a lignin-related compound for lignin biodegradation study. Biodegradation of ferulic acid by Cupriavidus sp. B-8, a newly isolated strain, was studied. This strain is able to utilize a wide range of lignin-related aromatic compounds as the sole carbon and energy source, including guaiacol, veratric acid, vanillic acid, cinnamic acid, p-coumaric acid, ferulic acid, and sinapic acid. In addition, the effects of different concentrations of ferulic acid on growth of Cupriavidus sp. B-8 were studied. The growth of Cupriavidus sp. B-8 is better under the condition of lower concentration. High-performance liquid chromatography (HPLC) analysis reveals that above 95% of ferulic acid is degraded within 12 h by Cupriavidus sp. B-8. Based on identification of biodegradation intermediates and further metabolites, the biodegradation pathway of ferulic acid by Cupriavidus sp. B-8 was proposed. Ferulic acid is initially converted to 4-vinylguaiacol, and further oxidized to vanillic acid and protocatechuic acid.展开更多
Wet-resistant flexible electronics have acquired increasing attention on applications in wet environments,such as sweaty skin, rainy weather, biological fluids, and underwater. However, it remains challenging to achie...Wet-resistant flexible electronics have acquired increasing attention on applications in wet environments,such as sweaty skin, rainy weather, biological fluids, and underwater. However, it remains challenging to achieve nonswelling and underwater self-healing hydrogel sensors for the mechanical perception in aqueous solutions. Herein, a selfhealing and non-swellable hydrogel is successfully fabricated,which presents an automatically healing behavior in various aquatic environments, including deionized water, seawater,sweat, alkali and acidic aqueous solutions. Moreover, the hydrogel demonstrates high stretchability and stable electromechanical sensing properties in water. Furthermore, an electronic skin is designed with the features of fast responsiveness, reliability, and high sensitivity for detecting breathing, speaking, coughing, and diverse body movements. The self-healing hydrogel sensors enable a brilliant mechanical sensibility for detecting a series of dynamic stimuli in air and underwater, even after the healing of fracture interface in water. The underwater self-healing and anti-swelling hydrogel would provide enticing potential on various stable electronic devices for aquatic environments, such as implantable electrodes, triboelectric nanogenerators, and underwater soft robotics.展开更多
Wound healing has invariably been a fundamental health concern,demanding manpower and materials and causing financial burdens.In this research,inspired by the hemostatic function of platelets,we proposed a novel bioni...Wound healing has invariably been a fundamental health concern,demanding manpower and materials and causing financial burdens.In this research,inspired by the hemostatic function of platelets,we proposed a novel bionic hydrogel by covalent amidation crosslinking natural platelet and alginate for wound healing.With the natural functional groups,the platelet-derived hydrogel exhibited outstanding biocompatibility and blood compatibility.By changing the addition ratio of platelets to alginates,the mechanical properties of the achieved hydrogel were variable to cater to different wound environments.Furthermore,silver nanoparticles could be loaded into the void space of the hydrogel which endowed the composites with superior anti-infective properties.We have demonstrated that the bio-inspired platelet hydrogel could promote hemostasis of acute tissue damage,prevent bacterial proliferation,and promote angiogenesis,collagen deposition,and granulation tissue formation in wound healing.These features signify the potential values of the bio-inspired platelet hydrogel in clinical applications.展开更多
基金Foundation item: Project(50925417) supported by the National Science Fund for Distinguished Young Scholars of China Project(50830301) supported by the National Natural Science Foundation of China Project(2011467062) supported by National Research Fund for Public Benefit (Environmental Protection) Industries, China
文摘As a major component of lignin and abundantly existing in softwood and hardwood, ferulic acid has been used as a lignin-related compound for lignin biodegradation study. Biodegradation of ferulic acid by Cupriavidus sp. B-8, a newly isolated strain, was studied. This strain is able to utilize a wide range of lignin-related aromatic compounds as the sole carbon and energy source, including guaiacol, veratric acid, vanillic acid, cinnamic acid, p-coumaric acid, ferulic acid, and sinapic acid. In addition, the effects of different concentrations of ferulic acid on growth of Cupriavidus sp. B-8 were studied. The growth of Cupriavidus sp. B-8 is better under the condition of lower concentration. High-performance liquid chromatography (HPLC) analysis reveals that above 95% of ferulic acid is degraded within 12 h by Cupriavidus sp. B-8. Based on identification of biodegradation intermediates and further metabolites, the biodegradation pathway of ferulic acid by Cupriavidus sp. B-8 was proposed. Ferulic acid is initially converted to 4-vinylguaiacol, and further oxidized to vanillic acid and protocatechuic acid.
基金supported by the National Natural Science Foundation of China (51873024)the grant from Science and Technology Department of Jilin Province (20200708102YY)。
文摘Wet-resistant flexible electronics have acquired increasing attention on applications in wet environments,such as sweaty skin, rainy weather, biological fluids, and underwater. However, it remains challenging to achieve nonswelling and underwater self-healing hydrogel sensors for the mechanical perception in aqueous solutions. Herein, a selfhealing and non-swellable hydrogel is successfully fabricated,which presents an automatically healing behavior in various aquatic environments, including deionized water, seawater,sweat, alkali and acidic aqueous solutions. Moreover, the hydrogel demonstrates high stretchability and stable electromechanical sensing properties in water. Furthermore, an electronic skin is designed with the features of fast responsiveness, reliability, and high sensitivity for detecting breathing, speaking, coughing, and diverse body movements. The self-healing hydrogel sensors enable a brilliant mechanical sensibility for detecting a series of dynamic stimuli in air and underwater, even after the healing of fracture interface in water. The underwater self-healing and anti-swelling hydrogel would provide enticing potential on various stable electronic devices for aquatic environments, such as implantable electrodes, triboelectric nanogenerators, and underwater soft robotics.
基金supported by the National Key Research and Development Program of China(2020YFA0908200)the National Natural Science Foundation of China(52073060 and 22002061)+1 种基金the Natural Science Foundation of Jiangsu(BK20200551)the Shenzhen Fundamental Research Program(JCYJ20190813152616459 and JCYJ20210324133214038)。
文摘Wound healing has invariably been a fundamental health concern,demanding manpower and materials and causing financial burdens.In this research,inspired by the hemostatic function of platelets,we proposed a novel bionic hydrogel by covalent amidation crosslinking natural platelet and alginate for wound healing.With the natural functional groups,the platelet-derived hydrogel exhibited outstanding biocompatibility and blood compatibility.By changing the addition ratio of platelets to alginates,the mechanical properties of the achieved hydrogel were variable to cater to different wound environments.Furthermore,silver nanoparticles could be loaded into the void space of the hydrogel which endowed the composites with superior anti-infective properties.We have demonstrated that the bio-inspired platelet hydrogel could promote hemostasis of acute tissue damage,prevent bacterial proliferation,and promote angiogenesis,collagen deposition,and granulation tissue formation in wound healing.These features signify the potential values of the bio-inspired platelet hydrogel in clinical applications.
