Pairwise comparisons of laser power output between cycles. by Pukkapol Suvannachart (9427650)

Subjects:

Impact of large choroidal vessels (LCV) and topographical orientation on percentage of flow deficit (FD%) values. by Valentin Hacker (9956024)

Knockout of <i>NbNBR1</i> decreases TYLCV-BJ infection. by Tingting Zhou (163678)

Expression of NFATc1 is decreased in <i>Tcirg1</i>-knockdown osteoclasts. by Dongyan Zhang (640677)

Decrease of muscle weakness and degeneration with mutants of UPS components. by Cécile Ribot (11944875)

Extracting one cycle of AVF sounds. by Keiko Tanaka (83031)

“…This study aimed to clarify the relationships between the sound properties of blood flow through arteriovenous fistulas and a medical/surgical history of patients undergoing hemodialysis by analyzing the distribution of sound frequencies from 100 to 4,000 Hz. Data were collected from 53 patients to identify two key parameters: the time point within one cycle of arteriovenous fistula sounds where the power distribution reached its peak, expressed as a percentage, and the specific frequency where the power was highest within the analyzed range. …”

Radiation can decrease the expression of the SCFAs in colon contents. by Liying Zhang (102453)

Perturbation of binucleation decreases yolk protein expression and lipid transport to the germline. by Lotte M. van Rijnberk (3716362)

Mononucleation of the intestine causes an X chromosome specific decrease in expression levels. by Lotte M. van Rijnberk (3716362)

Decreased <i>Bgl-</i>FaNaC expression in the left parietal ganglion following <i>S</i>. <i>mansoni</i> infection. by Laura C. Vicente-Rodríguez (16437803)

“…<p><b>a-c:</b> Decreased <i>Bgl</i>-FaNaC hybridization on the dorsal surface of the left parietal ganglion in infected specimens. …”

nsP4-C483Y or Q192L mutations decrease sensitivity to 4′-FlU. by Peiqi Yin (6533747)

ECoG timescales decrease during spatial attention. by Isabel Raposo (21615517)

“…If power was above the threshold (<i>z</i> > 1.96) for a minimum of 10% of the time window (500 ms) after the cue, the channel was considered hemifield-selective. …”

Percentage of exhale flux penetrating through the mask fabric for different values of <i>c</i>_<i>k</i>; a–c and d–f decreasing porosity for outward and inward protection model respectively; <i>k</i>_<i>L</i> is head loss coefficient for inward protection model. by Akshay Anand (118579)

Table_1_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_4_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Table_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_4_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Image_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.TIF by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”

Table_3_Physiology of Highly Radioresistant Escherichia coli After Experimental Evolution for 100 Cycles of Selection.xlsx by Steven T. Bruckbauer (6256799)

“…Utilizing experimental evolution and continuing previous work, we have generated the most IR-resistant Escherichia coli populations developed to date. After 100 cycles of selection, the dose required to kill 99% the four replicate populations (IR9-100, IR10-100, IR11-100, and IR12-100) has increased from 750 Gy to approximately 3,000 Gy. …”