Illustration of the progression of COVID-19 over a 100 day time period. by Mackenzie Dalton (14093874)

Analysis of the ¹H–¹⁵N HSQC spectrum of the labeled RAGE V domain with unlabeled S100A12. by Jian Wei Chiou (3106578)

“…<p>(a) Overlay of the ¹H–¹⁵N HSQC spectra of 0.5 mM ¹⁵N-labeled RAGE V domain (red) and the spectra of the complex with 0.5 mM unlabeled S100A12 (blue). …”

Analysis of the ¹H–¹⁵N HSQC spectra of S100A12 in complex with the unlabeled RAGE V domain. by Jian Wei Chiou (3106578)

“…<p>(a) Overlay of the ¹H–¹⁵N HSQC spectra of 0.76 mM ¹⁵N-labeled S100A12 (red) and S100A12 in complex with 0.76 mM unlabeled RAGE V domain (green). …”

Species richness (<i>SR</i>, upper panels) and Shannon’s entropy (<i>SE</i>, lower panels) vs. the rate in which new species are trying to invade the community, <i>νN</i>. by Immanuel Meyer (12306666)

“…However, as the number of temporal niches decreases global competition puts a hurdle against invasion, as every invader must compete with niche-specialists. …”

Aβ and 22C11 agonist decreased cholesterol uptake whereas the sAPP-derived peptide and SM-ϕ stimulated increased cholesterol uptake by Caco-2 cells. by Kendra L. Puig (334788)

Vasodilator effect of BPP-BrachyNH₂ and captopril (10⁻⁹–3 × 10⁻⁵ M) on rat thoracic aorta. by Daniel Dias Rufino Arcanjo (536744)

Execution Steps of the EOF Algorithm. by Zezhi Lin (22521663)

Port-sourced PM₁₀ (μg/m³) attributable deaths/100,000 population at the 2017 Barcelona neighbourhood level. by Natalie Mueller (3406370)

Overview of pipeline steps and study design. by Alireza Talesh Jafadideh (14227404)

Stepped-Wedge Trial Diagram. by Sugy Choi (800862)

“…</p><p>Methods and analysis</p><p>The QM2-RC encompasses three interconnected projects (Project 1, 2, and 3) aimed at developing a quality management strategy and evaluating its impact on system performance across New York State. …”

Geometric mean anti-<i>Na</i>-GST-1 IgG subclass levels over time. by David J. Diemert (8135568)

Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Bonding, Ion Mobility, and Rate-Limiting Steps in Deintercalation Reactions with ThCr₂Si₂-type KNi₂Se₂ by James R. Neilson (1896145)

“…Here, we study the nature of metal–metal bonding in the ThCr₂Si₂ structure type by probing the rate-limiting steps in the oxidative deintercalation of KNi₂Se₂. …”

Effects of S100A6 on CayBP/SIP-mediated β –catenin degradation. by Xiaoxuan Ning (334218)

“…<p>(A) Co-immunoprecipitation assay showed that truncated mutant CacyBP/SIPΔS100 bind both Skp1 and Siah1, suggesting S100A6 did not affect the formation of Siah1-CacyBP/SIP-Skp1 unbiquitin ligase complex. …”

Reduced cellular glucose uptake in response to insulin and decreased expression of a mitochondrial ETC complex subunit in <i>ALAS1</i>-knockdown C2C12 myocytes. by Shinichi Saitoh (4794345)

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”

Parrotfish Teeth: Stiff Biominerals Whose Microstructure Makes Them Tough and Abrasion-Resistant To Bite Stony Corals by Matthew A. Marcus (115744)

“…To investigate how their teeth endure the associated contact stresses, we examine the chemical composition, nano- and microscale structure, and the mechanical properties of the steephead parrotfish <i>Chlorurus microrhinos</i> tooth. Its enameloid is a fluorapatite (Ca₅(PO₄)₃F) biomineral with outstanding mechanical characteristics: the mean elastic modulus is 124 GPa, and the mean hardness near the biting surface is 7.3 GPa, making this one of the stiffest and hardest biominerals measured; the mean indentation yield strength is above 6 GPa, and the mean fracture toughness is ∼2.5 MPa·m^1/2, relatively high for a highly mineralized material. …”