table5_Identification of Plitidepsin as Potent Inhibitor of SARS-CoV-2-Induced Cytopathic Effect After a Drug Repurposing Screen.pdf by Jordi Rodon (201558)

“…Here, we have screened existing drugs approved for human use in a variety of diseases, to compare how they counteract SARS-CoV-2-induced cytopathic effect and viral replication in vitro. …”

Inverse relationship between poison exon usage and expression of multiple sodium channels during mouse brain development. by Yuliya Voskobiynyk (9954619)

“…<p>(A) <i>Scn1a</i> transcripts including exon 20N are highly expressed in the developing mouse brain and decrease dramatically after birth (aqua bars), with a corresponding developmental increase in <i>Scn1a</i> expression (blue bars). …”

PI+ CD3+ T cells decrease at day 14 after IR while PI+ CD3- cells decrease at all time points. by Jordan A. Gunning (18143970)

Heat-treated spores show a decrease in the overall number of spores that are able to germinate and grow out within 5 hours. by Rachna Pandey (394151)

Blocking of MC1R, MC2R or MC5R causes a decrease in the enucleation ratio of erythrocytes. by Eriko Simamura (720229)

“…Cell number is significantly decreased after treatment with anti-MC2R nAb for 5 days; however, treatment with anti-MC1R nAb or anti-MC5R nAb does not have a significant effect (n = 3, ANOVA). …”

At E9.5 Actb^−/− neural crest cells show a significant decrease of cadherin-11 expression. by Davina Tondeleir (426905)

“…<p>(A) Quantification of N-cadherin intensities in Actb^+/+ and Actb^−/− migratory cells adjacent to the neural tube at E8.5 and E9.5 (left graph, Y-axis: relative intensities) and colocalization of N-cadherin with p75 in migratory cells at E8.5 and E9.5 (right graph, Y-axis: colocalization index on a scale from 0 to 1). …”

Trend of temperature decrease in thermogradient freezer during the night from 7:00 P.M. to 5:00 A.M. by Alireza Hasanfard (13919335)

“…<p>Trend of temperature decrease in thermogradient freezer during the night from 7:00 P.M. to 5:00 A.M.…”

Shifting <i>V. cholerae</i> from glucose-based to starch-based conditions leads to a decrease in CT production. by Juliane Kühn (669504)

rVλ6Wil fibrils cause a decrease in cardiomyocytes MTT reduction without inducing cell death. by Helen P. McWilliams-Koeppen (116503)

“…(C) Cell number, quantified using crystal violet (black) did not decrease over 72 h of incubation with 1 μM rVλ6Wil fibrils despite a decrease in MMT reduction (grey; n = 3 samples per time point). …”

Sensitivity analysis of the lag time steps and maximum growth rate simulations from (A) and (B): Fig 5C, (C) and (D): Fig 6C, (E) and (F): Fig 9C and 9F. by Zoe Nahas (22250651)

“…<p>In each case, the number of lag days and maximum growth rate was calculated from 100 simulations performed for 120 time steps, with all parameter values increased or decreased by 5%, as compared to the plots in the main text. …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…The oxidation of EtOH by ADH_OX in the presence of NAD⁺ produced NADH, which was subsequently oxidized by diaphorase (DP) with resazurin, leading to the resorufin formation, characterized by red fluorescence (excitation at 560 nm and fluorescence at 590 nm). Reduction of AcH by ADH_RD consumed NADH, leading to a decrease in blue fluorescence (ex. 340 nm, fl. 490 nm). …”