Composite organohydrogels have been widely used in wearable electronics.However,it remains a great challenge to develop mechanically robust and multifunctional composite organohydrogels with good dispersion of nanofil...Composite organohydrogels have been widely used in wearable electronics.However,it remains a great challenge to develop mechanically robust and multifunctional composite organohydrogels with good dispersion of nanofillers and strong interfacial interactions.Here,multifunctional nanofiber composite reinforced organohydrogels(NCROs)are prepared.The NCRO with a sandwich-like structure possesses excellent multi-level interfacial bonding.Simultaneously,the synergistic strengthening and toughening mechanism at three different length scales endow the NCRO with outstanding mechanical properties with a tensile strength(up to 7.38±0.24 MPa),fracture strain(up to 941±17%),toughness(up to 31.59±1.53 MJ m~(-3))and fracture energy(up to 5.41±0.63 kJ m~(-2)).Moreover,the NCRO can be used for high performance electromagnetic interference shielding and strain sensing due to its high conductivity and excellent environmental tolerance such as anti-freezing performance.Remarkably,owing to the organohydrogel stabilized conductive network,the NCRO exhibits superior long-term sensing stability and durability compared to the nanofiber composite itself.This work provides new ideas for the design of high-strength,tough,stretchable,anti-freezing and conductive organohydrogels with potential applications in multifunctional and wearable electronics.展开更多
Background: The purpose of this study is to evaluate the clinical efficacy and safety of abraxane-based chemotherapy with/without nedaplatin in elderly patients with non-small-cell lung cancer (NSCLC). Materials an...Background: The purpose of this study is to evaluate the clinical efficacy and safety of abraxane-based chemotherapy with/without nedaplatin in elderly patients with non-small-cell lung cancer (NSCLC). Materials and methods: From October 2009 to January 2013, 48 elderly patients (≥65 years) with NSCLC were investigated in this clinical trial. The patients were randomized and equally allocated into arms A and AP- (A) abraxane (130 mg/m2, days 1, 8); (B) abraxane + nedaplatin (20 mg/m2 days 1-3, q3w). The parameters of objective response rate (ORR), disease control rate (DCR), progression-free survival (PFS), overall survival (OS) and side effects were evaluated between two arms. Results: Over 80% of the patients completed four cycles of chemotherapy. The total ORR was 21.3 %, DCR was 55.3%, PFS 4.5 months and OS 12.6 months. No significant difference was found between arms A and AP in terms of ORR (16.7% vs. 26.1%, P=0.665) or DCR (55.3% vs. 56.5%, P=0.871). The median PFS in arm A was 3.3 months [25-75% confidence interval (CI): 3.1-7.2] and 5.5 months (25-75% CI: 3.2-7.0) in arm AP with no statistical significance (P=0.640). The median OS in arm A was 12.6 months (25-75% CI: 5.7-26.2) and 15.1 months (25-75% CI: 6.4-35.3) in arm AP with no statistical significance (P=0.770). The side effects were mainly grade 1-2. The incidence of grade 3-4 toxicities was 29.1% in arm A and 62.5% in arm AP with a statistical significance (P=0.020). Conclusions: Compared with combined therapy, abraxane alone chemotherapy was beneficial for elderly NSCLC patients with better tolerability and less adverse events, whereas did not significantly differ in terms of ORR, DCR, PFS or OS.展开更多
Electrically conductive fibric composites(CFCs)have been widely used as electromagnetic interference(EMI)shielding materials;however,it is still difficult to achieve combination of strong interfacial adhesion,outstand...Electrically conductive fibric composites(CFCs)have been widely used as electromagnetic interference(EMI)shielding materials;however,it is still difficult to achieve combination of strong interfacial adhesion,outstanding water proof performance,multi-functionality and superb EMI shielding performance for the CFCs.Herein,we report a novel“photo-thermally induced interfacial sintering”method to prepare flexible and superhydrophobic CFCs with excellent interfacial adhesion.The CFC possesses dual conductive network composed of carbon nanofiber and silver nanoparticles(Ag NPs),and a conductivity of 112.1 S/cm,imparting to the material excellent Joule heating performance,revealing an large SE and SSE(59.4 dB and 333.9 dB mm^(-1))of the CFC in the X band,respectively.In addition,the CFC can maintain its superhydrophobicity,high conductivity and excellent EMI shielding performance after cyclic abrasion,stretching and ultrasonication washing.This“interfacial sintering”strategy provides a new way to fabricating multi-functional and durable conductive polymer composite.展开更多
基金financially supported by Natural Science Foundation of China(No.51873178)Qing Lan Project of Yangzhou University and Jiangsu Province+1 种基金High-end Talent Project of Yangzhou UniversityJiangsu Students'Innovation and Entrepreneurship Training Program(202211117059Z)。
文摘Composite organohydrogels have been widely used in wearable electronics.However,it remains a great challenge to develop mechanically robust and multifunctional composite organohydrogels with good dispersion of nanofillers and strong interfacial interactions.Here,multifunctional nanofiber composite reinforced organohydrogels(NCROs)are prepared.The NCRO with a sandwich-like structure possesses excellent multi-level interfacial bonding.Simultaneously,the synergistic strengthening and toughening mechanism at three different length scales endow the NCRO with outstanding mechanical properties with a tensile strength(up to 7.38±0.24 MPa),fracture strain(up to 941±17%),toughness(up to 31.59±1.53 MJ m~(-3))and fracture energy(up to 5.41±0.63 kJ m~(-2)).Moreover,the NCRO can be used for high performance electromagnetic interference shielding and strain sensing due to its high conductivity and excellent environmental tolerance such as anti-freezing performance.Remarkably,owing to the organohydrogel stabilized conductive network,the NCRO exhibits superior long-term sensing stability and durability compared to the nanofiber composite itself.This work provides new ideas for the design of high-strength,tough,stretchable,anti-freezing and conductive organohydrogels with potential applications in multifunctional and wearable electronics.
文摘Background: The purpose of this study is to evaluate the clinical efficacy and safety of abraxane-based chemotherapy with/without nedaplatin in elderly patients with non-small-cell lung cancer (NSCLC). Materials and methods: From October 2009 to January 2013, 48 elderly patients (≥65 years) with NSCLC were investigated in this clinical trial. The patients were randomized and equally allocated into arms A and AP- (A) abraxane (130 mg/m2, days 1, 8); (B) abraxane + nedaplatin (20 mg/m2 days 1-3, q3w). The parameters of objective response rate (ORR), disease control rate (DCR), progression-free survival (PFS), overall survival (OS) and side effects were evaluated between two arms. Results: Over 80% of the patients completed four cycles of chemotherapy. The total ORR was 21.3 %, DCR was 55.3%, PFS 4.5 months and OS 12.6 months. No significant difference was found between arms A and AP in terms of ORR (16.7% vs. 26.1%, P=0.665) or DCR (55.3% vs. 56.5%, P=0.871). The median PFS in arm A was 3.3 months [25-75% confidence interval (CI): 3.1-7.2] and 5.5 months (25-75% CI: 3.2-7.0) in arm AP with no statistical significance (P=0.640). The median OS in arm A was 12.6 months (25-75% CI: 5.7-26.2) and 15.1 months (25-75% CI: 6.4-35.3) in arm AP with no statistical significance (P=0.770). The side effects were mainly grade 1-2. The incidence of grade 3-4 toxicities was 29.1% in arm A and 62.5% in arm AP with a statistical significance (P=0.020). Conclusions: Compared with combined therapy, abraxane alone chemotherapy was beneficial for elderly NSCLC patients with better tolerability and less adverse events, whereas did not significantly differ in terms of ORR, DCR, PFS or OS.
基金financially supported by National Natural Science Foundation of China(No.51873178,No.21673203)the Opening Project of State Key Laboratory of Polymer Materials Engineering(Sichuan Unversity)(No.sklpme2020-4-03)+4 种基金Qing Lan Project of Yangzhou University and Jiangsu ProvinceHigh-end Talent Project of Yangzhou Universitythe Priority Academic Program Development of Jiangsu Higher Education InstitutionsPostgraduate Research&Practice Innovation Program of Jiangsu province(No.KYCX18_2364,No.KYCX20_2977)Outstanding Doctoral Dissertation Fund of Yangzhou University
文摘Electrically conductive fibric composites(CFCs)have been widely used as electromagnetic interference(EMI)shielding materials;however,it is still difficult to achieve combination of strong interfacial adhesion,outstanding water proof performance,multi-functionality and superb EMI shielding performance for the CFCs.Herein,we report a novel“photo-thermally induced interfacial sintering”method to prepare flexible and superhydrophobic CFCs with excellent interfacial adhesion.The CFC possesses dual conductive network composed of carbon nanofiber and silver nanoparticles(Ag NPs),and a conductivity of 112.1 S/cm,imparting to the material excellent Joule heating performance,revealing an large SE and SSE(59.4 dB and 333.9 dB mm^(-1))of the CFC in the X band,respectively.In addition,the CFC can maintain its superhydrophobicity,high conductivity and excellent EMI shielding performance after cyclic abrasion,stretching and ultrasonication washing.This“interfacial sintering”strategy provides a new way to fabricating multi-functional and durable conductive polymer composite.
