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)

Decreased surface TCR/CD3 expression in Jurkat signaling mutant lines and primary T cells deleted for Lat. by Evan Markegard (203863)

The ischemic brain of the MCAO model. by Wei Zou (107458)

Fig 3 - by Steven Decker (13767223)

“…<p>A: The distance traveled in an open-field arena was measured to test locomotor activity after injection of vehicle, 2 g/kg ethanol (EtOH), 3 or 6 mg/kg dFBr and 3 or 6 mg/kg dFBr+ 2 g/kg EtOH. n = 10–15 SD rats. 2g/kg EtOH significantly decreases locomotion in SD rats, while dFBr alone does not affect locomotion significantly in comparison to vehicle-treated rats. …”

Fig 2 - by Tachpon Techarang (12295244)

HSF2 is a positive regulator of EBV spontaneous lytic cycle in gastric epithelial cells. by Lorenza Cutrone (21144285)

Spacer decreases p53 transactivation, promoter occupancy and binding in yeast and mammalian cells and <i>in vitro</i>. by Jennifer J. Jordan (53318)

Transgenic FAR expression significantly decreases fly survival and increases bacterial load 24-hours post-injection. by Sophia C. Parks (11624976)

ER-α36 expression and cell injury in ischemic stroke models. by Wei Zou (107458)

Multivariable odds ratios (95% confidence intervals) for factors associated with each comorbidity. by Sharon E. Cox (7243847)

Socio-demographic and TB-related characteristics of study participants at enrollment. by Sharon E. Cox (7243847)

Systolic and diastolic blood pressure by age in those with and without hypertension and new vs pre-existing diagnoses. by Sharon E. Cox (7243847)

Map of study sites in the three regions of the Philippines. by Sharon E. Cox (7243847)