Image_5_Safflower Yellow and Its Main Component HSYA Alleviate Diet-Induced Obesity in Mice: Possible Involvement of the Increased Antioxidant Enzymes in Liver and Adipose Tissue.j... by Kemin Yan (4924420)

Relative mean outbreak size reduction 1 − 〈Ω(<i>a</i> = 30%)〉/〈Ω(<i>a</i> = 0)〉 caused by DCT in different network topologies. by Angelique Burdinski (14227341)

“…<p>App participation was fixed at <i>a</i> = 30%, and symptom-based testing was assumed to lead to initial under-ascertainment factors of <i>UA</i>₀ ∈ {12, 4, 2.4} (<i>q</i> = 0.1, 0.3 and 0.5, respectively). …”

Integrin β4, αV, α5 and β3, were differentially regulated among the three cell lines in response to glucose. by Sirin A. I. Adham (662525)

“…Integrin α-V was significantly decreased under hypoglycemia only in MDA-MB-231P cells p = 0.001. …”

Validation of DEGs in UVA-irradiated S cells that are involved in skin senescence. by Seong-Wook Seo (5641799)

Summary of the effect of maternal immune activation on serotonin and dopamine. by Pei-Tan Hsueh (752475)

“…The cerebral 5-HT levels were significantly decreased at 5 and 8 weeks old (solid arrow), whereas the DA levels exhibited a trend towards a decrease (dotted arrow). …”

Active spread of mtDNAs in the network can increase and decrease cell-to-cell variability from cell divisions. by Robert C. Glastad (10692277)

“…Rows show different values of initial mutant proportion, with <i>h</i> = 0.1 in the top row and <i>h</i> = 0.5 in the bottom row. The three columns for each panel give decreasing network heterogeneity, expressed via different seed numbers, 4, 16 and 64 (more seed points give a more homogeneous network). …”

Image5_A distinct immune landscape in anti-synthetase syndrome profiled by a single-cell genomic study.jpeg by Jiayu Ding (12005975)

“…As ASS and MDA5⁺ DM have similar organ involvements, MDA5⁺ DM was used as a disease control. …”

Changes in baseline T-cell activation markers through week 12 and week 24 according to the linear regression model. a. by Tosi M. Mwakyandile (16408705)

Fig 2 - by Sigrid Nilsson (12647302)

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

A General in Situ Deposition Strategy for Synthesis of Janus Composite Fabrics with Co(CO₃)_0.5OH·0.11H₂O Nanoneedles for Oil–Water Separation by Luyang Hu (8689470)

“…Especially using the water wetted composite fabric as a separation cell, the built-in lyophobic layer originating from fluid passed through the nonwetting region of wetted fabric decreases the unfavorable contact between lyophobic interface and separated liquid, and the permeation flux is enhanced by 214.5% for water and by 112.5% for oil, respectively, compared to that in the pristine fabric, whereas it has no effect on the separation efficiency of a heavy oil–water mixture. …”

Image_1_Effects of Shear Stress on Production of FVIII and vWF in a Cell-Based Therapeutic for Hemophilia A.TIF by Brady Trevisan (10211405)

“…We found that flow conditions led to a significant increase in KLF2, which induces miRNAs that negatively regulate expression of FVIII and vWF, providing a mechanistic explanation for the reduced expression of these proteins in PLC under conditions of flow. …”

Table_1_Effects of Shear Stress on Production of FVIII and vWF in a Cell-Based Therapeutic for Hemophilia A.DOCX by Brady Trevisan (10211405)

“…We found that flow conditions led to a significant increase in KLF2, which induces miRNAs that negatively regulate expression of FVIII and vWF, providing a mechanistic explanation for the reduced expression of these proteins in PLC under conditions of flow. …”

The effect of exogenous ROS on DC lymphocytes. by Larisa Pereboeva (322533)