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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

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

“…As a contrast, the particles in sticky pores are microscopically active by showing limited reduction of step sizes. …”

Fibrosis markers. by Dwight D. Harris (14484648)

Cold-Burst Method for Nanoparticle Formation with Natural Triglyceride Oils by Diana Cholakova (2897222)

“…Mean drop diameters of ca. 50–100 nm were achieved with some of the studied oils. …”

Cold-Burst Method for Nanoparticle Formation with Natural Triglyceride Oils by Diana Cholakova (2897222)

“…Mean drop diameters of ca. 50–100 nm were achieved with some of the studied oils. …”

Cold-Burst Method for Nanoparticle Formation with Natural Triglyceride Oils by Diana Cholakova (2897222)

“…Mean drop diameters of ca. 50–100 nm were achieved with some of the studied oils. …”

Comparison of the response to a step of light of 20 s duration and equivalent to about 250 Rh*/s in control conditions (black) and in the presence of GsMTx-4 (red) from the same ce... by Ulisse Bocchero (9128127)

Process steps in the Entscheidungsnavi. by Christian Hannes (17817132)

S100A9: A Potential Biomarker for the Progression of Non-Alcoholic Fatty Liver Disease and the Diagnosis of Non-Alcoholic Steatohepatitis by Xiaolin Liu (403100)

“…Microarray was performed to assess gene expression changes in rat livers. We find that gene expression of s100a9 was higher in NAFL group compared with control, and was increased in NASH groups and decreased in NAFL + T2DM group compared with NAFL. …”

Table_4_Good News — Bad News: Combined Ocean Change Drivers Decrease Survival but Have No Negative Impact on Nutritional Value and Organoleptic Quality of the Northern Shrimp.pdf by Mathilde Chemel (9190907)

Table_3_Good News — Bad News: Combined Ocean Change Drivers Decrease Survival but Have No Negative Impact on Nutritional Value and Organoleptic Quality of the Northern Shrimp.pdf by Mathilde Chemel (9190907)

Immunoblotting for TGF-beta, alpha-actinin, MMP-13, and mTOR. by Dwight D. Harris (14484648)

Immunoblotting for JAK, STAT, and SMAD. by Dwight D. Harris (14484648)

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)