Owing to the low pH value in tumor and cancer cells,drug delivery systems based on pH-responsive polymer nanocarriers have been extensively explored for anticancer chemotherapy.Herein,we developed a pH-responsive doxo...Owing to the low pH value in tumor and cancer cells,drug delivery systems based on pH-responsive polymer nanocarriers have been extensively explored for anticancer chemotherapy.Herein,we developed a pH-responsive doxonibicin(EXDX)nanocapsule(named as DNanoCapsule)prepared by combining in-situ polymerization teclinique with high-gravity antisolvent precipitation technique throngh an amphiphilic polymerized surface ligand.DNanoCapsules show an obvious spherical core-shell structure with a single DOX nanoparticle encapsulated in the polymer layer.Dissolution rate studies prove that the DNanoCapsules have robust dnig-release profiles under acidic environments due to the division of the pH-sensitive cross-linker,which triggers thecollapse of the polymer layer.The in vitro investigations demonstrated that the DNanoCapsules exhibited higli cellular uptake efficiency and cytotoxicity for both HeLa and MCF-7 cancer cells.Tlierefore,this work may provide a promising strategy to design and develop various stimuli-responsive drug nanocapsules tor the treatment of cancer or other diseases.展开更多
Effects of reaction temperature and methane gas hourly space velocity (GHSV) on methane decomposition over non-supported Ni catalyst have been investigated in this work.Methane molecules activation,Ni particles grow...Effects of reaction temperature and methane gas hourly space velocity (GHSV) on methane decomposition over non-supported Ni catalyst have been investigated in this work.Methane molecules activation,Ni particles growth and nano-carbon diffusion were the main factors influencing methane decomposition stability of non-supported Ni.The results of methane decomposition activity test on the non-supported Ni catalyst showed that the prepared non-supported Ni could exhibit a good methane decomposition performance with 273 gC/gNi and 2667 molH2/molNi at 500 -C and 45000 mL/(gcat h).Scanning electron microscope (SEM),X-ray powder diffraction (XRD) and temperature-programmed oxi- dation (TPO) have been carried out to characterize the used catalysts.The deposited carbon was carbon nanofibers,among which graphitic carbon formation increased with the reaction time of methane decomposition.Ni particle size was not the decisive factor during the carbon growing stage.展开更多
基金Supported by the National Natural Science Foundation of China(Nos.2147601&21622601)the National Key R&D Pro gram of China(No.2015CB932101).
文摘Owing to the low pH value in tumor and cancer cells,drug delivery systems based on pH-responsive polymer nanocarriers have been extensively explored for anticancer chemotherapy.Herein,we developed a pH-responsive doxonibicin(EXDX)nanocapsule(named as DNanoCapsule)prepared by combining in-situ polymerization teclinique with high-gravity antisolvent precipitation technique throngh an amphiphilic polymerized surface ligand.DNanoCapsules show an obvious spherical core-shell structure with a single DOX nanoparticle encapsulated in the polymer layer.Dissolution rate studies prove that the DNanoCapsules have robust dnig-release profiles under acidic environments due to the division of the pH-sensitive cross-linker,which triggers thecollapse of the polymer layer.The in vitro investigations demonstrated that the DNanoCapsules exhibited higli cellular uptake efficiency and cytotoxicity for both HeLa and MCF-7 cancer cells.Tlierefore,this work may provide a promising strategy to design and develop various stimuli-responsive drug nanocapsules tor the treatment of cancer or other diseases.
文摘Effects of reaction temperature and methane gas hourly space velocity (GHSV) on methane decomposition over non-supported Ni catalyst have been investigated in this work.Methane molecules activation,Ni particles growth and nano-carbon diffusion were the main factors influencing methane decomposition stability of non-supported Ni.The results of methane decomposition activity test on the non-supported Ni catalyst showed that the prepared non-supported Ni could exhibit a good methane decomposition performance with 273 gC/gNi and 2667 molH2/molNi at 500 -C and 45000 mL/(gcat h).Scanning electron microscope (SEM),X-ray powder diffraction (XRD) and temperature-programmed oxi- dation (TPO) have been carried out to characterize the used catalysts.The deposited carbon was carbon nanofibers,among which graphitic carbon formation increased with the reaction time of methane decomposition.Ni particle size was not the decisive factor during the carbon growing stage.
