CTS-g-(AA-co-SS)/ISC hybrid hydrogel adsorbent with crosslinked network structure and superior adsorption performance for rare-earth metal ions was successfully synthesized in aqueous solution by a simple one-step f...CTS-g-(AA-co-SS)/ISC hybrid hydrogel adsorbent with crosslinked network structure and superior adsorption performance for rare-earth metal ions was successfully synthesized in aqueous solution by a simple one-step free-radical grafting polymerization reaction among acrylic acid(AA), sodium p-styrenesulfonate(SS) and chitosan(CTS) using illite/smectite clay(ISC) as the inorganic additive. The structure of the as-prepared CTS-g-(AA-co-SS)/ISC hydrogel adsorbent was characterized, and the reaction parameters such as AA/SS molar ratio and ISC content were optimized, and the effects of pH values, initial concentration and contact time on the adsorption performance for Ce(Ⅲ) and Gd(Ⅲ) were systematically evaluated. It was found that the maximum adsorption capacities of the hydrogel adsorbent toward Ce(Ⅲ) and Gd(Ⅲ) reached 174.05 and 223.79 mg/g, respectively, and the adsorption quickly achieved equilibrium within 15–20 min. The adsorbed Ce(Ⅲ) and Gd(Ⅲ) could be easily desorbed for recovery, and the used adsorbent was able to be regenerated for reuse. After five adsorption-desorption cycles, the regenerated adsorbent could still retain the adsorption capacities that were close to the initial value. The adsorption process was well described by pseudo-second-order kinetic mode and the Langmuir isotherm model, and the chemical complexation between ions and –COO~–was mainly responsible for the high adsorption capacity. As a whole, the hybrid hydrogel adsorbent was potential to be used for the adsorption and recovery of Ce(Ⅲ) and Gd(Ⅲ) from water.展开更多
A novel core-shell hydrogel bead was fabricated for effective removal of methylene blue dye from aqueous solutions.The core,made of sodium alginate-g-polyacrylamide and attapulgite nanofibers,was cross-linked by Calci...A novel core-shell hydrogel bead was fabricated for effective removal of methylene blue dye from aqueous solutions.The core,made of sodium alginate-g-polyacrylamide and attapulgite nanofibers,was cross-linked by Calcium ions(Ca^(2+)).The shell,composed of a chitosan/activated carbon mixture,was then coated onto the core.Fourier transform infrared spectroscopy confirmed the grafting polymerization of acrylamide onto sodium alginate.Scanning electron microscopy images showed the core-shell structure.The core exhibited a high water uptake ratio,facilitating the diffusion of methylene blue into the core.During the diffusion process,the methylene blue was first adsorbed by the shell and then further adsorbed by the core.Adsorption tests showed that the coreshell structure had a larger adsorption capacity than the core alone.The shell effectively enhanced the adsorption capacity to methylene blue compared to the single core.Methylene blue was adsorbed by activated carbon and chitosan in the shell,and the residual methylene blue diffused into the core and was further adsorbed.展开更多
Efficient light absorption and trapping are of vital importance for the solar water evaporation by hydrogel-based photothermal conversion materials.Conventional strategies are focused on the development of the composi...Efficient light absorption and trapping are of vital importance for the solar water evaporation by hydrogel-based photothermal conversion materials.Conventional strategies are focused on the development of the composition and structure of the hydrogers internal network.In our point of view,the importance of the surface structure of hydrogel has usually been underestimated or ignored.Here inspired by the excellent absorbance and water transportation ability of biological surface structure,the hierarchical structured hydrogel evaporators(HSEs)increased the light absorption,trapping,water transportation and water-air interface,which is the beneficial photothermal conversion and water evaporation.The HSEs showed a rapid evaporation rate of 1.77 kg·m^(-2)·h^(-1)at about 92%energy efficiency under one sun(1 kW·m^(-2)).Furthermore,the superhydrophilic window device was used in this work to collect the condensed water,which avoids the light-blocking caused by the water mist formed by the small droplets and the problem of the droplets stick on the device dropping back to the bulk water.Integrated with the excellent photothermal conversion hydrogel and superhydrophilic window equipment,this work provides efficient evaporation and desalination of hydrogel-based solar evaporators in practical large-scale applications.展开更多
4D printing has attracted great interest since the concept was introduced in 2012. The past 5 years have witnessed rapid advances in both 4D printing processes and materials. Unlike 3D printing, 4D printing allows the...4D printing has attracted great interest since the concept was introduced in 2012. The past 5 years have witnessed rapid advances in both 4D printing processes and materials. Unlike 3D printing, 4D printing allows the printed part to change its shape and function with time in response to change in external conditions such as temperature, light, electricity, and water. In this review, we first overview the history of 4D printing and discuss its definition. We then summarize recent technological advances in 4D printing with focuses on methods, materials, and their intrinsic links. Finally, we discuss potential applications and offer perspectives for this exciting new field.展开更多
Cardiac fibrosis has emerged as the primary cause of morbidity,disability,and even mortality in numerous nations.In light of the advancements in precision medicine strategies,substantial attention has been directed to...Cardiac fibrosis has emerged as the primary cause of morbidity,disability,and even mortality in numerous nations.In light of the advancements in precision medicine strategies,substantial attention has been directed toward the development of a practical and precise drug screening platform customized for individual patients.In this study,we introduce a biomimetic cardiac fibrosis-on-a-chip incorporating structural color hydrogels(SCHs)to enable optical high-throughput drug screening.By cocultivating a substantial proportion of cardiac fibroblasts(CFBs)with cardiomyocytes on the SCH,this biomimetic fibrotic microtissue successfully replicates the structural components and biomechanical properties associated with cardiac fibrosis.More importantly,the structural color shift observed in the SCH can be indicative of cardiac contraction and relaxation,making it a valuable tool for evaluating fibrosis progression.By incorporating such fibrotic microtissue into a microfluidic gradient chip,we develop a biomimetic optical cardiac fibrosis-on-a-chip platform that accurately and efficiently screens potential anti-fibrotic drugs.These characteristics suggest that this microphysiological platform possesses the capability to establish a preclinical framework for screening cardiac drugs,and may even contribute to the advancement ofprecisionmedicine.展开更多
基金Project supported by the National Natural Science Foundation of China(51403221,21377135,U1407114)the“863”Project of the Chinese Ministry of Science and Technology(2013AA032003)
文摘CTS-g-(AA-co-SS)/ISC hybrid hydrogel adsorbent with crosslinked network structure and superior adsorption performance for rare-earth metal ions was successfully synthesized in aqueous solution by a simple one-step free-radical grafting polymerization reaction among acrylic acid(AA), sodium p-styrenesulfonate(SS) and chitosan(CTS) using illite/smectite clay(ISC) as the inorganic additive. The structure of the as-prepared CTS-g-(AA-co-SS)/ISC hydrogel adsorbent was characterized, and the reaction parameters such as AA/SS molar ratio and ISC content were optimized, and the effects of pH values, initial concentration and contact time on the adsorption performance for Ce(Ⅲ) and Gd(Ⅲ) were systematically evaluated. It was found that the maximum adsorption capacities of the hydrogel adsorbent toward Ce(Ⅲ) and Gd(Ⅲ) reached 174.05 and 223.79 mg/g, respectively, and the adsorption quickly achieved equilibrium within 15–20 min. The adsorbed Ce(Ⅲ) and Gd(Ⅲ) could be easily desorbed for recovery, and the used adsorbent was able to be regenerated for reuse. After five adsorption-desorption cycles, the regenerated adsorbent could still retain the adsorption capacities that were close to the initial value. The adsorption process was well described by pseudo-second-order kinetic mode and the Langmuir isotherm model, and the chemical complexation between ions and –COO~–was mainly responsible for the high adsorption capacity. As a whole, the hybrid hydrogel adsorbent was potential to be used for the adsorption and recovery of Ce(Ⅲ) and Gd(Ⅲ) from water.
文摘A novel core-shell hydrogel bead was fabricated for effective removal of methylene blue dye from aqueous solutions.The core,made of sodium alginate-g-polyacrylamide and attapulgite nanofibers,was cross-linked by Calcium ions(Ca^(2+)).The shell,composed of a chitosan/activated carbon mixture,was then coated onto the core.Fourier transform infrared spectroscopy confirmed the grafting polymerization of acrylamide onto sodium alginate.Scanning electron microscopy images showed the core-shell structure.The core exhibited a high water uptake ratio,facilitating the diffusion of methylene blue into the core.During the diffusion process,the methylene blue was first adsorbed by the shell and then further adsorbed by the core.Adsorption tests showed that the coreshell structure had a larger adsorption capacity than the core alone.The shell effectively enhanced the adsorption capacity to methylene blue compared to the single core.Methylene blue was adsorbed by activated carbon and chitosan in the shell,and the residual methylene blue diffused into the core and was further adsorbed.
基金We thank Prof.Cunming Yu and Dr.Xiao Xiao for providing COMSLO simulation.This work was supported by the National Natural Science Funds for Distinguished Young Scholar(No.21725401)the National Key R&D Program of China(No.2017YFA0207800)+1 种基金the 111 project(B14009)the Fundamental Research Funds for the Central Universities.
文摘Efficient light absorption and trapping are of vital importance for the solar water evaporation by hydrogel-based photothermal conversion materials.Conventional strategies are focused on the development of the composition and structure of the hydrogers internal network.In our point of view,the importance of the surface structure of hydrogel has usually been underestimated or ignored.Here inspired by the excellent absorbance and water transportation ability of biological surface structure,the hierarchical structured hydrogel evaporators(HSEs)increased the light absorption,trapping,water transportation and water-air interface,which is the beneficial photothermal conversion and water evaporation.The HSEs showed a rapid evaporation rate of 1.77 kg·m^(-2)·h^(-1)at about 92%energy efficiency under one sun(1 kW·m^(-2)).Furthermore,the superhydrophilic window device was used in this work to collect the condensed water,which avoids the light-blocking caused by the water mist formed by the small droplets and the problem of the droplets stick on the device dropping back to the bulk water.Integrated with the excellent photothermal conversion hydrogel and superhydrophilic window equipment,this work provides efficient evaporation and desalination of hydrogel-based solar evaporators in practical large-scale applications.
基金financially supported by the National Natural Science Funds for Distinguished Young Scholar (No.21625402)the National Natural Science Funds for Youths (No.21604070)
文摘4D printing has attracted great interest since the concept was introduced in 2012. The past 5 years have witnessed rapid advances in both 4D printing processes and materials. Unlike 3D printing, 4D printing allows the printed part to change its shape and function with time in response to change in external conditions such as temperature, light, electricity, and water. In this review, we first overview the history of 4D printing and discuss its definition. We then summarize recent technological advances in 4D printing with focuses on methods, materials, and their intrinsic links. Finally, we discuss potential applications and offer perspectives for this exciting new field.
基金supported by the National Key Research and Development Program of China(2020YFA0710800 and 2020YFA0908200)the Key Program of the National Natural Science Foundation of China(81930043 and 82330055)+2 种基金the National Natural Science Foundation of China(T2225003,82001719,52073060,and 61927805)the Nanjing Medical Science and Technique Development Foundation(ZKX21019)the Clinical Trials from Nanjing Drum Tower Hospital(2022-LCYJ-ZD-01).
文摘Cardiac fibrosis has emerged as the primary cause of morbidity,disability,and even mortality in numerous nations.In light of the advancements in precision medicine strategies,substantial attention has been directed toward the development of a practical and precise drug screening platform customized for individual patients.In this study,we introduce a biomimetic cardiac fibrosis-on-a-chip incorporating structural color hydrogels(SCHs)to enable optical high-throughput drug screening.By cocultivating a substantial proportion of cardiac fibroblasts(CFBs)with cardiomyocytes on the SCH,this biomimetic fibrotic microtissue successfully replicates the structural components and biomechanical properties associated with cardiac fibrosis.More importantly,the structural color shift observed in the SCH can be indicative of cardiac contraction and relaxation,making it a valuable tool for evaluating fibrosis progression.By incorporating such fibrotic microtissue into a microfluidic gradient chip,we develop a biomimetic optical cardiac fibrosis-on-a-chip platform that accurately and efficiently screens potential anti-fibrotic drugs.These characteristics suggest that this microphysiological platform possesses the capability to establish a preclinical framework for screening cardiac drugs,and may even contribute to the advancement ofprecisionmedicine.
