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Showing 1 - 20 results of 62 for search '(( significant decrease decrease ) OR ( significant ((point decrease) OR (cost decreased)) ))~', query time: 0.50s Refine Results
  1. 1
    Development of a CRISPR/Cas-Based Detection Platform for Tracking Decreased Susceptibility to Cephalosporins in Neisseria gonorrheae

    Development of a CRISPR/Cas-Based Detection Platform for Tracking Decreased Susceptibility to Cephalosporins in Neisseria gonorrheae by Ziyuan Zhao (2889005)

    Published 2025
    “…Its integration with microfluidic chip offers an affordable and user-friendly diagnostic solution, making it highly valuable for timely infectious disease diagnosis and resistance monitoring. It also holds significant potential for point-of-care testing in resource-limited areas.…”
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  2. 2
    Mean ± SD values of unipedal stance parameters evaluated at the different time points of the postural training session.

    Mean ± SD values of unipedal stance parameters evaluated at the different time points of the postural training session. by Cristina Dolciotti (16317330)

    Published 2025
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  3. 3
    Training History: The x-axis represents the number of epochs, and the y-axis represents the L2 error for the four selected data points.

    Training History: The x-axis represents the number of epochs, and the y-axis represents the L2 error for the four selected data points. by Mouad Klai (20818364)

    Published 2025
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  4. 4
    Time course of Path Length, LFS and Velocity during postural training.

    Time course of Path Length, LFS and Velocity during postural training. by Cristina Dolciotti (16317330)

    Published 2025
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  5. 5
    Time course of 95% Area, X and Y Amplitude Sway during postural training.

    Time course of 95% Area, X and Y Amplitude Sway during postural training. by Cristina Dolciotti (16317330)

    Published 2025
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  6. 6
    Between-group differences in 95% Area, Y Sway Amplitude and LFS during postural training.

    Between-group differences in 95% Area, Y Sway Amplitude and LFS during postural training. by Cristina Dolciotti (16317330)

    Published 2025
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  7. 7
    Relation between training-related changes in unipedal and bipedal stance.

    Relation between training-related changes in unipedal and bipedal stance. by Cristina Dolciotti (16317330)

    Published 2025
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  8. 8
    Relation of the changes in Y Sway Amplitude and LFS induced by postural training with those in 95% Area.

    Relation of the changes in Y Sway Amplitude and LFS induced by postural training with those in 95% Area. by Cristina Dolciotti (16317330)

    Published 2025
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  9. 9
    Consolidation of training-induced changes in unipedal stance: Path Length, X Sway Amplitude and Velocity.

    Consolidation of training-induced changes in unipedal stance: Path Length, X Sway Amplitude and Velocity. by Cristina Dolciotti (16317330)

    Published 2025
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  10. 10
    Training-induced changes in bipedal stance.

    Training-induced changes in bipedal stance. by Cristina Dolciotti (16317330)

    Published 2025
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  11. 11
    Consolidation of training-induced changes in unipedal stance: 95% Area, Y Sway Amplitude and LFS.

    Consolidation of training-induced changes in unipedal stance: 95% Area, Y Sway Amplitude and LFS. by Cristina Dolciotti (16317330)

    Published 2025
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  12. 12
    Functional characterization of skinned myocardium prepared from Epac1TG.

    Functional characterization of skinned myocardium prepared from Epac1TG. by Yoshiki Ohnuki (576298)

    Published 2025
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  13. 13
    Summary statistics of key variables.

    Summary statistics of key variables. by Saul Estrin (8629173)

    Published 2024
    “…We find that in developing countries, as urban economic density increases, innovation first increases and then begins to decrease beyond a certain point, with the decline being most prominent in the largest cities. …”
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  14. 14
    Amplitude for A/L = 0.29.

    Amplitude for A/L = 0.29. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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  15. 15
    Top view of the experimental setup.

    Top view of the experimental setup. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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  16. 16
    Amplitude for A/L = 0.338.

    Amplitude for A/L = 0.338. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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  17. 17
    Parameters of energy harvesting.

    Parameters of energy harvesting. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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  18. 18
    Graph for Max Amplitude/Length at G<sub>y</sub> = 0.

    Graph for Max Amplitude/Length at G<sub>y</sub> = 0. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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  19. 19
    Amplitude for A/L = 0.02.

    Amplitude for A/L = 0.02. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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  20. 20
    Graph for maximum Frequency at G<sub>y</sub> = 0.

    Graph for maximum Frequency at G<sub>y</sub> = 0. by Muhammad Hammad Bucha (21736111)

    Published 2025
    “…The flapping frequency, amplitude, and optimal power of the rough cylinders were analyzed and compared with that of smooth cylinders experimentally, and the optimum point () in terms of power was attained. Increased surface roughness significantly reduced power output, flapping frequency, and amplitude. …”
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