Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Microscopic Movement of Slow-Diffusing Nanoparticles in Cylindrical Nanopores Studied with Three-Dimensional Tracking by Luyang Zhao (1903252)

“…In viscous solvents, the particle steps decrease proportionally to the increment of the viscosity, leading to macroscopically slow diffusion. …”

Losartan does not decrease macrophage and MDSC infiltration. by Shanna A. Arnold (183991)

Downregulation of Opa1 and Marf does affect type II NB numbers but affect differentiated cells in lineage. by Dnyanesh Dubal (12085942)

Subjects:

Analysis of change in mature INPs, GMCs and neurons in the type II NB lineage on depletion of mitochondrial morphology proteins. by Dnyanesh Dubal (12085942)

Subjects:

<i>S</i>. <i>aureus</i> binding activity to Seraph^® 100 during a prolonged treatment period. by Malin-Theres Seffer (14808772)

Flowchart of the steps involved in the high-throughput exoproteome screening assay (HESA). by Marion Schoof (11999106)

(A) Digital designing of premolar to decrease 1 mm of root surface, (B) 3D printed tooth compared to artificial tooth of model. by Samar S. Alaghbari (21863491)

Elementary Steps in Olefin Metathesis: Nickelacyclobutanes via Cycloaddition to Nickel Carbenes by Samantha K. Cormier (16872384)

“…We describe Ni(PP)(=CPh₂) complexes that provide this missing evidence. …”

The oxygen level (kPa) for 50 and 100% habitat loss for each species and season under a doubling of atmospheric CO₂. by Emily Slesinger (6837740)

<i>WNT10A</i>^–/–KO skin wound showing reduced fibrosis/fibrogenesis associated with the decreased expression of stromagenesis-related genes. by Ke-Yong Wang (234594)

Decreased numbers of motor neurons in Tc1 and Dp(16)1Yey mice. by Sheona Watson-Scales (586942)

Delphinidin alters VEGF-A splicing to increase VEGF-A₁₆₅b and decrease total VEGF-A expression. by Megan Stevens (3964886)

“…<p><b>A)</b> Treatment of podocytes with delphinidin chloride (10 μg/ml) under normal glucose (NG; 5 mM glucose + 25 mM mannitol) and high glucose (HG; 30 mM glucose, 1 ng/ml TNFα, 1 ng/ml IL-6, and 100 nM insulin) for 48 hrs increased the protein expression of VEGF-A₁₆₅b relative to total VEGF-A₁₆₅ (quantified in <b>B</b>; *p<0.05 vs NG, †p<0.05 vs HG; n = 3 biological repeats; One-way ANOVA with Bonferroni post-hoc test for comparison between pairs; <b>A</b>—the same blot was first probed with VEGF-A₁₆₅b before stripping and reprobing with panVEGF-A). …”

Incubation of V79-CYP3A94/DD-POR cells with Shield-1 leads to a decrease of POR protein. by Ramona Dettwiler (664360)