Metabolite concentrations in the <i>cop</i>^- strain after 30, 60 and 90 minutes of adding 0 or 5 μM Cu(II). by Javiera Norambuena (137228)

Two-dimensional NMR spectroscopy of the O1 polysaccharide heterologously expressed in <i>E</i>. <i>coli</i>. by Paeton L. Wantuch (1667614)

A working mechanism representing the E2/ER-mediated cardioprotection from I/R injury via p38β and MnSOD. by Tao Luo (232520)

Image_5_Extensive Healthy Donor Age/Gender Adjustments and Propensity Score Matching Reveal Physiology of Multiple Sclerosis Through Immunophenotyping.tif by Paavali A. Hannikainen (9698444)

HIV-specific CD4⁺ T-cell responses were amplified by IL-2 treatment and inversely correlate with VL after treatment interruption. by Vedran Brezar (337452)

Structural and Photophysical Properties of Lathanide(III) Complexes with a Novel Octadentate Iminophenolate Bibracchial Lariat Ether by Marina González-Lorenzo (2680309)

“…Both sidearms of <b>L</b><b>³</b> are on the same side of the crown moiety, resulting in a syn conformation. Likewise, the lone pair of both pivotal nitrogen atoms is directed inward of the receptor cavity in an <i>endo</i>−<i>endo</i> arrangement and the coordination polyhedron around the lanthanide ion may be described as a distorted square antiprism that shows a deformation toward a square prism by ca. 11°. …”

HC-070 reduces time spent immobile in the FST in a dose and exposure-dependent fashion. by Stefan Just (4811358)

Synthesis, Structure, and Optical-Limiting Properties of Heterobimetallic [M₃CuS₄] Cuboidal Clusters (M = Mo or W) with Terminal Phosphine Ligands by Marta Feliz (2206738)

“…The tungsten cluster <b>6</b> shows a unique quasi-reversible reduction wave at <i>E</i>_1/2 = −0.71 V. …”

Knockdown of OIP5-AS1 leads to reduced cell apoptosis in I/R cell models. by Jingyan Yang (7120994)

Photographs of the left eye before (A-E) and after (F-H) systemic corticosteroids therapy in a 39-year-old woman with AZOOR. by Saho Saito (731215)

“…<p>(A) Fundus photograph shows normal retinal appearance except for narrowing and tortuosity of the retinal arteries (arrowheads). …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”

Three-Dimensional Cell Entrapment as a Function of the Weight Percent of Peptide-Amphiphile Hydrogels by Carolyn M. Scott (1588174)

“…To form such a scaffold, 5 mol % of a bioactive PR_g fibronectin-mimetic peptide-amphiphile was mixed with 95 mol % of a diluent peptide-amphiphile (E2) whose purpose was to neutralize electrostatic interactions, increase the gelation kinetics, and promote cell survival. …”