GXM decreases the trans-endothelial electrical resistance (TEER) and transmigration of <i>C</i>. <i>neoformans</i> through HBECs in a blood brain barrier (BBB) model. by Hiu Ham Lee (15374677)

Exploring the Potential of Metal–Organic Frameworks for Cryogenic Helium-Based Gas Gap Heat Switches via High-Throughput Computational Screening by Lingxiao Qin (18181961)

“…Structure–performance analysis reveals that 1/<i>v</i>_sor consistently increases first and then decreases with pore limiting diameter, largest cavity diameter, available pore volume, accessible surface area, helium void fraction, and bulk density. …”

The top 10 putative metabolites with the largest negative fold change between normal and thin cows. by Bhuripit Saraphol (20855573)

The top 10 putative metabolites with the largest positive fold change between normal and thin cows. by Bhuripit Saraphol (20855573)

Discovery of Selective Dopamine Receptor Ligands Derived from (−)-Stepholidine via C‑3 Alkoxylation and C‑3/C‑9 Dialkoxylation by Hari K. Namballa (13363787)

Discovery of Selective Dopamine Receptor Ligands Derived from (−)-Stepholidine via C‑3 Alkoxylation and C‑3/C‑9 Dialkoxylation by Hari K. Namballa (13363787)

S1 data_Hazen Main and Blister 2017 absolute diatom counts from Contrasting the ecological effects of decreasing ice cover versus accelerated glacial melt on the High Arctic's larg... by Neal Michelutti (688828)

“…Lake Hazen, the High Arctic's largest lake, has received an approximately 10-fold increase in glacial meltwater since its catchment glaciers shifted from net mass gain to net mass loss in 2007 CE, concurrent with recent warming. …”

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

MST1 upregulates CD36 expression via PPARγ. by Jianyang Li (461703)

Image 1_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Table 1_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.docx by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 5_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 4_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 2_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Image 3_Using sodium glycodeoxycholate to develop a temporary infant-like gut barrier model, in vitro.pdf by Francesca Bietto (21511316)

“…</p>Results<p>Our research demonstrates that GDC decreases Caco-2/HT29-MTX Trans-Epithelial Electrical Resistance (TEER) and increases paracellular permeability, without inflammation or cytotoxicity. …”

Inclusion and exclusion criteria delineated via the PCC (Population, Concept, Context) search framework. by Rabia Asghar (18840759)

Room-Temperature Self-Healable Glassy Semicrystalline Polymers via Ionic Aggregations by Pengxiang Si (5676260)

Room-Temperature Self-Healable Glassy Semicrystalline Polymers via Ionic Aggregations by Pengxiang Si (5676260)

Room-Temperature Self-Healable Glassy Semicrystalline Polymers via Ionic Aggregations by Pengxiang Si (5676260)

Room-Temperature Self-Healable Glassy Semicrystalline Polymers via Ionic Aggregations by Pengxiang Si (5676260)