8 research outputs found
Additional file 2: of Development and application of a monoclonal antibody-based blocking ELISA for detection of antibodies to Tembusu virus in multiple poultry species
Neutralizing activity of MAbs 9E4 and ROC analysis of the blocking ELISA. (PDF 370 kb
Additional file 1: of Development and application of a monoclonal antibody-based blocking ELISA for detection of antibodies to Tembusu virus in multiple poultry species
Recombinant plasmid construction and protein expression. (PDF 299 kb
Fully Transient 3D Origami Paper-Based Ammonia Gas Sensor Obtained by Facile MXene Spray Coating
Developing high-performance chemiresistive
gas sensors with mechanical
compliance for environmental or health-related biomarker monitoring
has recently drawn increasing research attention. Among them, two-dimensional
MXene materials hold great potential for room-temperature hazardous
gas (e.g., NH3) monitoring regardless of the complicated
fabrication process, insufficient 2D/3D flexibilities, and poor environmental
sustainability. Herein, a Ti3C2Tx MXene/gelatin ink was developed for patterning electrodes
through a facile spray coating. Particularly, the patterned Ti3C2Tx-based coating
exhibited good adhesion on the paper substrate against repeated peeling-off
and excellent mechanical flexibility against 1000 cyclic stretching.
The porous morphology of the coating facilitated the NH3 sensing ability. As a result, the 2D kirigami-shaped NH3 sensor exhibited a good response of 7% to 50 ppm of NH3 with detectable concentrations ranging from 5–500 ppm, decent
selectivity over interferences, etc., which could be well-maintained
even at 50% stretched state. In addition, with the help of mechanically
guided compressive buckling, 3D mesostructured MXene origamis could
be obtained, holding promise for detecting the coming direction and
height distribution of hazardous gas, e.g., the NH3. More
importantly, the as-fabricated MXene/gelatin origami paper could be
fully degraded in PBS/H2O2/cellulase solution
within 19 days, demonstrating its potential as a high-performance,
shape morphable, and environmentally friendly wearable gas sensor
Fully Transient 3D Origami Paper-Based Ammonia Gas Sensor Obtained by Facile MXene Spray Coating
Developing high-performance chemiresistive
gas sensors with mechanical
compliance for environmental or health-related biomarker monitoring
has recently drawn increasing research attention. Among them, two-dimensional
MXene materials hold great potential for room-temperature hazardous
gas (e.g., NH3) monitoring regardless of the complicated
fabrication process, insufficient 2D/3D flexibilities, and poor environmental
sustainability. Herein, a Ti3C2Tx MXene/gelatin ink was developed for patterning electrodes
through a facile spray coating. Particularly, the patterned Ti3C2Tx-based coating
exhibited good adhesion on the paper substrate against repeated peeling-off
and excellent mechanical flexibility against 1000 cyclic stretching.
The porous morphology of the coating facilitated the NH3 sensing ability. As a result, the 2D kirigami-shaped NH3 sensor exhibited a good response of 7% to 50 ppm of NH3 with detectable concentrations ranging from 5–500 ppm, decent
selectivity over interferences, etc., which could be well-maintained
even at 50% stretched state. In addition, with the help of mechanically
guided compressive buckling, 3D mesostructured MXene origamis could
be obtained, holding promise for detecting the coming direction and
height distribution of hazardous gas, e.g., the NH3. More
importantly, the as-fabricated MXene/gelatin origami paper could be
fully degraded in PBS/H2O2/cellulase solution
within 19 days, demonstrating its potential as a high-performance,
shape morphable, and environmentally friendly wearable gas sensor
Fully Transient 3D Origami Paper-Based Ammonia Gas Sensor Obtained by Facile MXene Spray Coating
Developing high-performance chemiresistive
gas sensors with mechanical
compliance for environmental or health-related biomarker monitoring
has recently drawn increasing research attention. Among them, two-dimensional
MXene materials hold great potential for room-temperature hazardous
gas (e.g., NH3) monitoring regardless of the complicated
fabrication process, insufficient 2D/3D flexibilities, and poor environmental
sustainability. Herein, a Ti3C2Tx MXene/gelatin ink was developed for patterning electrodes
through a facile spray coating. Particularly, the patterned Ti3C2Tx-based coating
exhibited good adhesion on the paper substrate against repeated peeling-off
and excellent mechanical flexibility against 1000 cyclic stretching.
The porous morphology of the coating facilitated the NH3 sensing ability. As a result, the 2D kirigami-shaped NH3 sensor exhibited a good response of 7% to 50 ppm of NH3 with detectable concentrations ranging from 5–500 ppm, decent
selectivity over interferences, etc., which could be well-maintained
even at 50% stretched state. In addition, with the help of mechanically
guided compressive buckling, 3D mesostructured MXene origamis could
be obtained, holding promise for detecting the coming direction and
height distribution of hazardous gas, e.g., the NH3. More
importantly, the as-fabricated MXene/gelatin origami paper could be
fully degraded in PBS/H2O2/cellulase solution
within 19 days, demonstrating its potential as a high-performance,
shape morphable, and environmentally friendly wearable gas sensor
Fully Transient 3D Origami Paper-Based Ammonia Gas Sensor Obtained by Facile MXene Spray Coating
Developing high-performance chemiresistive
gas sensors with mechanical
compliance for environmental or health-related biomarker monitoring
has recently drawn increasing research attention. Among them, two-dimensional
MXene materials hold great potential for room-temperature hazardous
gas (e.g., NH3) monitoring regardless of the complicated
fabrication process, insufficient 2D/3D flexibilities, and poor environmental
sustainability. Herein, a Ti3C2Tx MXene/gelatin ink was developed for patterning electrodes
through a facile spray coating. Particularly, the patterned Ti3C2Tx-based coating
exhibited good adhesion on the paper substrate against repeated peeling-off
and excellent mechanical flexibility against 1000 cyclic stretching.
The porous morphology of the coating facilitated the NH3 sensing ability. As a result, the 2D kirigami-shaped NH3 sensor exhibited a good response of 7% to 50 ppm of NH3 with detectable concentrations ranging from 5–500 ppm, decent
selectivity over interferences, etc., which could be well-maintained
even at 50% stretched state. In addition, with the help of mechanically
guided compressive buckling, 3D mesostructured MXene origamis could
be obtained, holding promise for detecting the coming direction and
height distribution of hazardous gas, e.g., the NH3. More
importantly, the as-fabricated MXene/gelatin origami paper could be
fully degraded in PBS/H2O2/cellulase solution
within 19 days, demonstrating its potential as a high-performance,
shape morphable, and environmentally friendly wearable gas sensor
Fully Transient 3D Origami Paper-Based Ammonia Gas Sensor Obtained by Facile MXene Spray Coating
Developing high-performance chemiresistive
gas sensors with mechanical
compliance for environmental or health-related biomarker monitoring
has recently drawn increasing research attention. Among them, two-dimensional
MXene materials hold great potential for room-temperature hazardous
gas (e.g., NH3) monitoring regardless of the complicated
fabrication process, insufficient 2D/3D flexibilities, and poor environmental
sustainability. Herein, a Ti3C2Tx MXene/gelatin ink was developed for patterning electrodes
through a facile spray coating. Particularly, the patterned Ti3C2Tx-based coating
exhibited good adhesion on the paper substrate against repeated peeling-off
and excellent mechanical flexibility against 1000 cyclic stretching.
The porous morphology of the coating facilitated the NH3 sensing ability. As a result, the 2D kirigami-shaped NH3 sensor exhibited a good response of 7% to 50 ppm of NH3 with detectable concentrations ranging from 5–500 ppm, decent
selectivity over interferences, etc., which could be well-maintained
even at 50% stretched state. In addition, with the help of mechanically
guided compressive buckling, 3D mesostructured MXene origamis could
be obtained, holding promise for detecting the coming direction and
height distribution of hazardous gas, e.g., the NH3. More
importantly, the as-fabricated MXene/gelatin origami paper could be
fully degraded in PBS/H2O2/cellulase solution
within 19 days, demonstrating its potential as a high-performance,
shape morphable, and environmentally friendly wearable gas sensor
Fully Transient 3D Origami Paper-Based Ammonia Gas Sensor Obtained by Facile MXene Spray Coating
Developing high-performance chemiresistive
gas sensors with mechanical
compliance for environmental or health-related biomarker monitoring
has recently drawn increasing research attention. Among them, two-dimensional
MXene materials hold great potential for room-temperature hazardous
gas (e.g., NH3) monitoring regardless of the complicated
fabrication process, insufficient 2D/3D flexibilities, and poor environmental
sustainability. Herein, a Ti3C2Tx MXene/gelatin ink was developed for patterning electrodes
through a facile spray coating. Particularly, the patterned Ti3C2Tx-based coating
exhibited good adhesion on the paper substrate against repeated peeling-off
and excellent mechanical flexibility against 1000 cyclic stretching.
The porous morphology of the coating facilitated the NH3 sensing ability. As a result, the 2D kirigami-shaped NH3 sensor exhibited a good response of 7% to 50 ppm of NH3 with detectable concentrations ranging from 5–500 ppm, decent
selectivity over interferences, etc., which could be well-maintained
even at 50% stretched state. In addition, with the help of mechanically
guided compressive buckling, 3D mesostructured MXene origamis could
be obtained, holding promise for detecting the coming direction and
height distribution of hazardous gas, e.g., the NH3. More
importantly, the as-fabricated MXene/gelatin origami paper could be
fully degraded in PBS/H2O2/cellulase solution
within 19 days, demonstrating its potential as a high-performance,
shape morphable, and environmentally friendly wearable gas sensor