Latent inductive effect of rapamycin administration on CK18 expression in mammary organoids contrasts with its negative effect on milk protein expression. by Anna Kosenko (12908417)

“…Rapamycin was omitted from the medium for an additional week, then the medium was changed to DMEM/F12 containing insulin, hydrocortisone and prolactin. A. Latent induction of CK18 relative expression by rapamycin administration. …”

Disruption of the viral cyclin results in a reduced frequency of LANA::βla+ cells in the lungs of C57BL/6J mice after intranasal infection. by Brian F. Niemeyer (11707995)

Triple B←N Lewis Pair-Functionalized Triazatruxenes with Large Stokes Shifts by Yufeng Zhang (195768)

“…The introduction of B←N Lewis pairs not only results in a large decrease in the HOMO–LUMO gap but also lowers the LUMO to −3.00 eV. …”

Sparse projection to latent structures discriminant analysis (sPLS-DA) of the metabolites. by Xue-Fei Liu (11156387)

ECoG timescales decrease during spatial attention. by Isabel Raposo (21615517)

Cyclin deficient virus has a similar cellular distribution to wild-type γHV68 during primary infection of C57BL/6J mice. by Brian F. Niemeyer (11707995)

Decreased visceral nociceptive responses induced by <i>Toxoplasma gondii</i> chronic infection relies on peripheral opioid signaling. by Alexis Audibert (21213531)

Expression of lipid biosynthetic genes is decreased with polyamine depletion. by Yazmin E. Cruz-Pulido (20285238)

Impact of large choroidal vessels (LCV) and topographical orientation on percentage of flow deficit (FD%) values. by Valentin Hacker (9956024)

Tissue, days post-infection (dpi) and the top 10 most significant genes with increased and decreased expression with valid gene symbols for the response contrasts. by Gillian P. McHugo (8965919)

Cell-to-cell mtDNA variability for larger mtDNA populations. by Robert C. Glastad (10692277)

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Active Diffusion of Self-Propelled Particles in Flexible Polymer Networks by Yeongjin Kim (10878837)

“…However, when the particle size is increased to be comparable to the mesh size, the active particles explore the polymer network via the trapping-and-hopping mechanism. If the particle is larger than the mesh, it captures the collective viscoelastic dynamics from the polymer network at short times and the simple diffusion of the total system at large times. …”

Single cell RNA-sequencing demonstrates comparable cellular distribution of latent virus infection between WT and cycKO LANA expressing cells, with a modest reduction in viral gene... by Brian F. Niemeyer (11707995)

Density of the dominant population as a function of the dilution rate, <i>w</i>. by Juan A. Bonachela (3264462)