Exploration of the connected interface (S100A1/MDM2) section in MDM2. by Deepu Dowarha (5673440)

Exploration of the connected interface (S100A1/p53 (1–73)) section in S100A1. by Deepu Dowarha (5673440)

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. …”

Inducing an <i>in silico</i> open-state CNA and demonstrating the natural frequencies of the CNA N1-N2 domains. by Ali Madani (4217290)

Subjects:

Kylo-0603’s EC50 & tissue levels. by Xueqin lu (22250795)

Recommendations of no-fly zones for the colonies of common terns, Sandwich terns, black headed gulls, herring gulls and lesser black-backed gulls, great cormorants and Eurasian spo... by Estefania Velilla (22566709)

Change in per capita growth rate of intraspecies cooperating population implemented with a continuous model. by Yaron Goldberg (10164674)

Inhibition experiments with PP PLA₂. by Catherine A. Vulfius (676708)

Ustekinumab trough concentration are shown by responder status and anti-ustekinumab antibody (A) Patients with negative anti-ustekinumab antibody had significantly higher drug trou... by Hsien-Yi Chiu (799936)