Temperature-Responsive Peptide–Nucleotide Coacervates by Tiemei Lu (4244926)

“…Both the enthalpic and entropic parts of this nonelectrostatic interaction decrease in the order G/A/U/C/T, in accordance with nucleobase stacking free energies. …”

Potential miRNAs targeting PDE8A. by Thijs Booiman (185008)

“…#<p>Fold change in expression in which day 5 is compared to day 0; >1 is an increase and <1 is a decrease in expression.…”

Effect of CXB and DMC combinations on ATP supply derived from both glycolysis <i>plus</i> OxPhos in HeLa (A) and SiHA (B) cells. by Diana Xochiquetzal Robledo-Cadena (5265959)

Discovery of indolylpiperazinylpyrimidines with dual-target profiles at adenosine A_2A and dopamine D₂ receptors for Parkinson's disease treatment - Fig 5 by Yi-Ming Shao (577266)

“…<p>Dose-response curves of compound <b>5</b> (A), compound <b>6</b> (B) and (±)-PPHT.HCl (C) in D₂R-proteopolymersomes-based fluorescence polarisation (FP) competition assay with BODIPY-NAPS. …”

H₂O₂-induced mitochondrial size decrease is prevented by WY pre-treatment in hippocampal neurons. by Juan M. Zolezzi (586604)

Strong Electronic Communication by Direct Metal−Metal Interaction in Molecules with Halide-Bridged Dimolybdenum Pairs by F. Albert Cotton (1781341)

“…All three compounds show two reversible one-electron oxidation processes with potential separations (Δ<i>E</i>_1/2) between the two oxidation processes of 540, 499, and 440 mV, respectively. These Δ<i>E</i>_1/2 values show that the strength of the electronic coupling between the dimetal units decreases as the Mo₂···Mo₂ distance increases from <b>1</b> to <b>2</b>, and then to <b>3</b>. …”

The <i>E</i>. <i>multilocularis</i> antigen-specific IgG reactivity (OD) in alveolar echinococcosis (AE) patients and infection-free controls. by Beate Grüner (301524)

KAIST low-speed wind tunnel and its components. by Elliott Donghyun Kim (19469973)

“…Mie scattering, known for effectively decreasing short-wave infrared light, was employed by utilizing water aerosols having a diameter of 1 to 5 μm. …”

Scattering efficiency by particle diameter. by Elliott Donghyun Kim (19469973)

“…Mie scattering, known for effectively decreasing short-wave infrared light, was employed by utilizing water aerosols having a diameter of 1 to 5 μm. …”

Relative transmission rate by wavelength. by Elliott Donghyun Kim (19469973)

“…Mie scattering, known for effectively decreasing short-wave infrared light, was employed by utilizing water aerosols having a diameter of 1 to 5 μm. …”

The <i>E</i>. <i>multilocularis</i> antigen inducible cellular production by PBMC of chemokines and cytokines. by Beate Grüner (301524)

Master chronology index (n = 5 corals) of <i>O</i>. <i>faveolata</i> from 1992–2016. by D. Wendoline Sánchez-Pelcastre (17389582)

Fig 7 - by Jan Maleček (17396660)

Failure mode of the sample. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Positions of AE probes and strain gauges. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Sampling site. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Received AE waves. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Test schemes for soft rocks. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

Failure mode of the sample. by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”

S1 Table - by Zhenhua Wang (426041)

“…At the same temperature, shear strength increases at a rate of 5.6 MPa/°C with increasing confining pressure; as freezing temperature decreases, the shear strength increases at 0.34 MPa/°C, and cohesion increases at 0.6 MPa/°C. …”