In absence of HGT, an infinite-allele model provides a diversity-maintenance mechanism with an intrinsic time scale. by Simone Pompei (134652)

Semi-log plot of the FIFA countries ranked by their decreasing “order of importance” through the FIFA coefficient; the best 5-parameter function, Eq (5), is shown. by Marcel Ausloos (748325)

L-[1-¹⁴C]Met oxidation as a percentage of dose, representing the change in Cys synthesis, in enterally fed piglets receiving graded levels of Cys and 0.25 g kg<sup>-1</s... by Anna K. Shoveller (6208457)

<i>c-REL</i> knockout leads to significantly decreased expression levels of NF-κB family member and cell cycle-associated genes. by Carsten Slotta (4326091)

“…<p><b>A:</b> qPCR analysis showing significantly decreased mRNA levels of NF-κB family members <i>RELA</i>, <i>NFKB1 (p50)</i>, <i>NFKB2</i> (<i>p52)</i>, <i>IKBKE</i> and <i>TBK1</i> in <i>c-REL</i> knockout cells compared to wildtype cells. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

Self-Repair of Structure and Bioactivity in a Supramolecular Nanostructure by Charlotte H. Chen (5915282)

“…Thermal energy in this cycle enables noncovalent interactions to reconfigure the nanostructures into the thermodynamically preferred long nanofibers, a repair process that is impeded by kinetic traps. …”

The OmpA (I, δ) allele is enriched in ExPEC relative to environmental isolates. by Chunyu Liao (4436998)

The mean and variance of the cable length can be independently controlled within the antenna model. by Lishibanya Mohapatra (759979)

“…Parameters used for the polymerization and depolymerisation rate were <i>r</i> = 370 s^-1, <i>d</i> = 45 s^-1, <i>k</i>_<i>off</i> = 0.5 s^-1(red) and 50 s^-1(blue); for chosen values of <i>k</i>_<i>off</i>, the rate <i>w</i> was calculated from <a href="http://www.ploscompbiol.org/article/info:doi/10.1371/journal.pcbi.1004160#pcbi.1004160.e005" target="_blank">Eq 1</a> for the mean length. …”

Decreased glycosylated α-DG and laminin levels distal to the glial dome in <i>Large</i>^{<i>myd/myd</i>} mice. by Shigefumi Morioka (8893511)

Renin–angiotensin–aldosterone system inhibition with losartan significantly inhibited transforming growth factor-β1/Smads pathway and decreased Snail expression in vitro. by Chiao-Yin Sun (174213)

“…<p>A: ELISA analysis showed that losartan (1, 10, and 100 uM) significantly decreased the transforming growth factor-β1 concentration in the culture medium of PKSV cells treated with indoxyl sulfate (IS) (50 mg/L) and <i>p</i>-cresol sulfate (PCS) (50 mg/L). …”

Overexpression of TNFAIP9 alleviated the renal fibrosis caused by 5/6 Nx in C57 mice. by Ying Chen (9697)

Overexpression of TNFAIP9 inhibited the TGF-β-induced fibrosis in HK-2 cells. by Ying Chen (9697)