Abstract: A sensor and a method of using the sensor are disclosed. The sensor includes a conductive region in electrical communication with two electrodes, the conductive region including a MXene material combined with a mercaptoimidazolyl metal-ligand complex, wherein the MXene has the formula Mn+1Xn and M is at least one of a Group 3 transition metal, Group 4 transition metal, Group 5 transition metal, and Group 6 transition metal, X is carbon, nitrogen or a combination thereof, and n has a value of 1 to 3. The sensor can be used to detect volatile compounds that have a double or triple bond.

Abstract: A sensor and a method of using the sensor are disclosed. The sensor includes a conductive region in electrical communication with two electrodes, the conductive region including metallic nanowires, nanosized particles of a dichalcogenide, and a mercaptoimidazolyl metal-ligand complex. The sensor can be used to detect volatile compounds that have a double or triple bond.

Abstract: A sensor and a method of using the sensor are disclosed. The sensor includes a conductive region in electrical communication with two electrodes, the conductive region including a MXene material combined with a mercaptoimidazolyl metal-ligand complex, wherein the MXene has the formula Mn+1Xn and M is a Group 3 transition metal, Group 4 transition metal, Group 5 transition metal, and Group 6 transition metal, X is carbon, nitrogen or a combination thereof, and n has a value of 1 to 3. The sensor can be used to detect volatile compounds that have a double or triple bond.

Abstract: A ?PAD may include a substrate comprising a substrate. The ?PAD may further include a non-polar material printed on a surface of the substrate such that a portion the surface is exposed. The exposed portion may include a receiving area, a plurality of test areas, and a plurality of channels disposed between the receiving area and the test areas. The ?PAD may further include colorimetric sensors respectively positioned in the test areas. The channel regions may be configured to receive an analyte solution from the receiving area and direct the analyte solution to the colorimetric sensors. A system may perform image processing on captured images of the ?PAD to provide multiplexed analysis of analyte solutions applied to the ?PAD.

Abstract: Bioresorbable porous biocomposites for orthopaedic applications. In an exemplary embodiment of a resorbable orthopaedic implant of the present disclosure, the implant comprises a porous alloy of at least a first metal and a second metal sintered together, the alloy configured to resorb into a body at substantially an atomic level without flaking off, wherein a porosity of the implant is defined by a first plurality of interconnected holes having a first range of sizes.

Abstract: A sensor and a method of using the sensor are disclosed. The sensor includes a conductive region in electrical communication with two electrodes, the conductive region including single-walled carbon nanotubes, nanosized particles of a metal dichalcogenide, and a mercaptoimidazolyl metal-ligand complex. The sensor can be used to detect volatile compounds that have a double or triple bond.

Abstract: A sensor and a method of using the sensor are disclosed. The sensor includes a conductive region in electrical communication with two electrodes, the conductive region including metallic nanowires, nanosized particles of a dichalcogenide, and a mercaptoimidazolyl metal-ligand complex. The sensor can be used to detect volatile compounds that have a double or triple bond.

Abstract: In one embodiment, 3-Aminopropyltriethoxysilane (APTES) functionalized graphene oxide (APTES-GO) wrapped SiO2 particle composite (SiO2@APTES-GO) was prepared via the self-assembly process of APTES-GO sheets and SiO2 particles. Transmission electron microscopy (TEM) and Attenuated Total Reflectance-Fourier Transform Infrared spectroscopy (ATR-FTIR) confirmed wrapping of the SiO2 particles by the APTES-GO sheets. A biosensor based on electrochemical impedance spectroscopy (EIS) was constructed and used to sensitively detect dengue DNA and dengue RNA via primer hybridization using different oligonucleotide sequences. The results demonstrated that the SiO2@APTES-GO electrode material led to enhanced sensitivity, selectivity and detection limit, compared to both APTES-GO and APTES-SiO2.

Abstract: Natural biopolymers in the form of cellulose nanocrystals (CNC) are shown to have the required characteristics to serve as chemically reactive biotemplates for metallic and semiconductor nanomaterial synthesis. Silver (Ag), gold (Au), copper (Cu) and platinum (Pt), cadmium sulfide (CdS), zinc sulfide (ZnS) and lead sulfide (PbS) nanoparticles, nanoparticle chains and nanowires may be synthesized on CNCs by exposing metallic precursor salts to a cationic surfactant, cetyltrimethylammonium bromide (CTAB), and a reducing agent. The nanoparticle density and particle size may be controlled by varying the concentration of CTAB, pH of the salt solution, as well as the reduction time or reaction time between the reducing agent and the metal precursor.