S5 Fig - by Xinyue Yang (629144)

“…On day 8, the rats were transferred to a simulated climate cabin, At 0, 50, 100, and 150 min, the core temperature (Tc) was measured respectively. …”

Presentation_1_Eosinophils Decrease Pulmonary Metastatic Mammary Tumor Growth.pptx by Rachel A. Cederberg (12827564)

“…We found that IL5Tg mice exhibit reduced pulmonary metastatic colonization and decreased metastatic tumor burden compared to wild-type (WT) mice or eosinophil-deficient mice. …”

Effect of different doses of the defatted extract (DE) of the leaves of <i>S. malaccense</i> and <i>S. samarangense</i> on urea and creatinine levels. Data represented as mean±SEM... by Fatma A. Moharram (9276104)

Subjects:

Effect of DE of <i>S. malaccense</i> and <i>S. samarangense</i> leaves on histopathological examination of the kidney tissues. by Fatma A. Moharram (9276104)

Subjects:

Estimated total phenolic content (TPC), and total flavonoid content (TFC) in the defatted extract (DE) of <i>S. malaccense</i> and <i>S. samarangense</i> leaves. by Fatma A. Moharram (9276104)

Subjects:

Effect of DE of <i>S. malaccense</i> and <i>S. samarangense</i> on A) GSH, B) SOD, C) TNF-α, D) IL-1β, E) p-NF-κB, and F) Caspase-3 levels. by Fatma A. Moharram (9276104)

Subjects:

Effect of DE of <i>S. malaccense</i> and <i>S. samarangense</i> leaves on A) ATP, B) p-mTOR, C) beclin-1, and D) p-AMPK levels. by Fatma A. Moharram (9276104)

Subjects:

Effect of different doses (mg/Kg) of the defatted extract (DE) of the leaves of <i>S. malaccense</i> and <i>S. samarangense</i> on serum ALT and AST levels. Data represented as mea... by Fatma A. Moharram (9276104)

Subjects:

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”