Network plot of the distribution of AE signals in each SOC of penicillamine. by Wenlong Qian (22608053)

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Comparison of the first 30 high signal intensity adverse events (AEs) between penicillamine and trientine. by Wenlong Qian (22608053)

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Comparison of system organ classification (SOC) Distribution of adverse events between penicillamine and trientine. by Wenlong Qian (22608053)

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Time to onset of -associated adverse events and Weibull distribution analysis. by Wenlong Qian (22608053)

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Wayne diagram showing the PT positive signaling network of two copper chelators in the FAERS database. by Wenlong Qian (22608053)

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Signal intersection and signal distribution characteristics. by Wenlong Qian (22608053)

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A Time to onset of adverse events induced by penicillamine. by Wenlong Qian (22608053)

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Time to onset of adverse events induced by trientine. by Wenlong Qian (22608053)

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Number of reports by region for the two drugs. by Wenlong Qian (22608053)

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All Adverse Event Signals Screened by Penicillamine Gender Subgroup Analysis (FAERS). by Wenlong Qian (22608053)

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Forest plot and volcano plot of ROR values (95% CI) for the first 30 high signal intensity AEs of penicillamine versus trientine. by Wenlong Qian (22608053)

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PT and SOC for the positive signal detection of two drugs in the FAERS database. by Wenlong Qian (22608053)

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Forest plot of ROR values used to assess gender differences in penicillamine-related AEs. by Wenlong Qian (22608053)

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Formula and signal detection criteria for reporting odds ratio (ROR), proportional reporting ratio (PRR) and Bayesian confidence propagation neural network (BCPNN). by Wenlong Qian (22608053)

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Multi-scale analysis showing the proportion of deviance explained by the different estimates of parasitoid diversity and abundance when using different buffer radii (i.e. 100m, 200... by Marina Mazón (19452511)

CNOT-Efficient Circuits for Arbitrary Rank Many-Body Fermionic and Qubit Excitations by Ilias Magoulas (4807101)

“…Recently, Yordanov et al. [<i>Phys. Rev. A</i><b>102</b>, 062612 (2020); <i>Commun. …”

CNOT-Efficient Circuits for Arbitrary Rank Many-Body Fermionic and Qubit Excitations by Ilias Magoulas (4807101)

“…Recently, Yordanov et al. [<i>Phys. Rev. A</i><b>102</b>, 062612 (2020); <i>Commun. …”

Fig 1 - by Mario Pannunzi (553941)

“…If separate sources emit the odorants (bottom panel), they will arrive in a less correlated way, and NSIs have almost no effect, resulting in larger ORN responses. ORN response data shown is based on a preliminary model. d) <b>Hypothesis 3</b>: The lateral inhibition caused by the presence of NSIs decrease the ceiling effect for high concentrations and therefore shift the right boundary of the dynamic range to higher concentrations, so increasing the dynamic range.…”

Gridding Triboelectric Nanogenerator for Raindrop Energy Harvesting by Bolang Cheng (11461820)

“…Under the impact of simulated raindrops from a shower at a flow rate of 0.137 mL/(cm²·s), the open-circuit voltage (<i>V</i>_oc) and the short-circuit current density (<i>J</i>_sc) of the G-TENG reach 400 V and 2.5 mA/m², respectively. …”

Gridding Triboelectric Nanogenerator for Raindrop Energy Harvesting by Bolang Cheng (11461820)

“…Under the impact of simulated raindrops from a shower at a flow rate of 0.137 mL/(cm²·s), the open-circuit voltage (<i>V</i>_oc) and the short-circuit current density (<i>J</i>_sc) of the G-TENG reach 400 V and 2.5 mA/m², respectively. …”