Design of Multiple Metal Doped Ni Based Catalyst for Hydrogen Generation from Bio-oil Reforming at Mild-temperature

A new kind of multiple metal （Cu, Mg, Ce） doped Ni based mixed oxide catalyst, synthesized by the co-precipitation method, was used for efficient production of hydrogen from bio-oil reforming at 250-500℃. Two reforming processes, the conventional steam reforming （CSR） and the electrochemical catalytic reforming （ECR）, were performed for the bio-oil reforming. The catalyst with an atomic mol ratio of Ni：Cu：Mg：Ce：AI=5.6：1.1：1.9：1.0：9.9 exhibited very high reforming activity both in CSR and ECR processes, reaching 82.8% hydrogen yield at 500℃ in the CSR, yield of 91.1% at 400℃ and 3.1 A in the ECR, respectively. The influences of reforming temperature and the current through the catalyst in the ECR were investigated. It was observed that the reforming and decomposition of the bio-oil were significantly enhanced by the current. The promoting effects of current on the decomposition and reforming processes of bio-oil were further studied by using the model compounds of bio- oil （acetic acid and ethanol） under 101 kPa or low pressure （0.1 Pa） through the time of flight analysis. The catalyst also shows high water gas shift activity in the range of 300-600 ℃. The catalyst features and alterations in the bio-oil reforming were characterized by the ICP, XRD, XPS and BET measurements. The mechanism of bio-oil reforming was discussed based on the study of the elemental reactions and catalyst characterizations. The research catalyst, potentially, may be a practical catalyst for high efficient production of hydrogen from reforming of bio-oil at mild-temperature.

PLG-g-mPEG Mediated Multifunctional Nanoparticles for Photoacoustic Imaging Guided Combined Chemo/Photothermal Antitumor Therapy

Under laser irradiation,photothermal therapy(PTT)effectively ablates tumors above 50℃.However,hyperthermia can cause additional damage due to the inevitable heat spread to surrounding healthy tissue.Herein,nanoparticles named as GI@P NPs were designed for enhanced PTT with heat shock protein 90(HSP90)inhibition at temperatures below 50℃to achieve optimal cancer therapy and avoid surrounding damage.GI@P NPs were done by co-loading Garcinia cambogia acid(GA)and photosensitizer IR783 in polymer PLG-g-mPEG to form a nanomedicine,where IR783 with excellent photoacoustic(PA)signal acted as an excellent photothermal therapeutic agent that converted the laser energy into heat to kill tumor cells,GA was used as antitumor drug for chemotherapy and an inhibitor of HSP90 to overcome the heat resistance of tumors for efficient cryo-photothermal therapy,and PLG-g-mPEG can encapsulate IR783 and GA to increase biocompatibility and accumulate effectively in the tumor.After GI@P NPs were injected into the mice,we could observe that the PA signals gradually increased in the tumor region and showed the strongest PA signals at 12 h.Under laser irradiation,the tumor temperature of the mice could raise to about 43.5℃,and the tumor was significantly inhibited after long-term monitoring by PA imaging.As a result,gentle PTT produced by GI@P NPs exhibited good antitumor effects at relatively low temperature and minimized nonspecific thermal damage to normal tissues.The GI@P NPs as nanomedicine enriched our understanding of various applications of polymeric carriers,especially in the biomedical field.