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. …”

Cell cycle accumulation at G2/M in MTDH knockdown Hec50co cells at 24 hours after LBH589 or LBH589 and TRAIL treatment. by Xiangbing Meng (200278)

“…<p>(A) Cell cycle profiles were determined in control or MTDH knockdown Hec50co cells at 24 hours after treatment with 20 nM LBH589, 25 ng/ml TRAIL, or LBH589 and TRAIL in combination. …”

Oxidation of L-[1-¹⁴C]Cys as a percentage of dose in enterally fed piglets receiving graded levels of Cys and 0.25 g kg^-1 d^-1 Met. by Anna K. Shoveller (6208457)

<i>In vitro</i> drug susceptibility of a panel of recent clinical <i>L</i>. <i>infantum</i> isolates against antileishmanial reference drugs in THP-1, bone-marrow derived macrophag... by Sarah Hendrickx (321143)

Preformed biofilm. by Rodrigo Rollin-Pinheiro (239450)

Biofilm formation. by Rodrigo Rollin-Pinheiro (239450)

Benchmarking the Predictive Power of Ligand Efficiency Indices in QSAR by Isidro Cortes-Ciriano (1450789)

“…Two studies published in this journal showed that higher predictive power on external molecules can be achieved by using ligand efficiency indices as the dependent variable instead of a metric of potency (IC₅₀) or binding affinity (<i>K</i>_<i>i</i>). …”

The effect of alexidine, amorolfine and olorofim on <i>S</i>. <i>aurantiacum</i> morphology and cell parameters. by Rodrigo Rollin-Pinheiro (239450)

Genotoxicity of free <i>versus</i> PLGA-adsorbed benzo(a)pyrene. by Rodolphe Carpentier (4357222)

Investigating Autoignition Characteristics of Ammonia/Heptamethylnonane Mixtures Over Wide Pressure Ranges: Rapid Compression Machine Measurements and Kinetic Modeling Study by Yongxiang Zhang (31421)

“…For the mixture with the lowest NH₃ energy ratio of 50%, non-Arrhenius-type behavior was observed at a pressure of 20 bar, while it transfers to a monotonic decrease of IDTs with increasing temperature at a pressure of 40 bar. …”

Investigating Autoignition Characteristics of Ammonia/Heptamethylnonane Mixtures Over Wide Pressure Ranges: Rapid Compression Machine Measurements and Kinetic Modeling Study by Yongxiang Zhang (31421)

“…For the mixture with the lowest NH₃ energy ratio of 50%, non-Arrhenius-type behavior was observed at a pressure of 20 bar, while it transfers to a monotonic decrease of IDTs with increasing temperature at a pressure of 40 bar. …”

Investigating Autoignition Characteristics of Ammonia/Heptamethylnonane Mixtures Over Wide Pressure Ranges: Rapid Compression Machine Measurements and Kinetic Modeling Study by Yongxiang Zhang (31421)

“…For the mixture with the lowest NH₃ energy ratio of 50%, non-Arrhenius-type behavior was observed at a pressure of 20 bar, while it transfers to a monotonic decrease of IDTs with increasing temperature at a pressure of 40 bar. …”

Investigating Autoignition Characteristics of Ammonia/Heptamethylnonane Mixtures Over Wide Pressure Ranges: Rapid Compression Machine Measurements and Kinetic Modeling Study by Yongxiang Zhang (31421)

“…For the mixture with the lowest NH₃ energy ratio of 50%, non-Arrhenius-type behavior was observed at a pressure of 20 bar, while it transfers to a monotonic decrease of IDTs with increasing temperature at a pressure of 40 bar. …”