(A) Auxiliary marking points to ensure complete and accurate seating of the prosthesis. by Long Li (6555)

Subjects:

A) RT-qPCR analysis of <i>Yap</i>, <i>Taz</i>, and <i>Tead2</i> shows a significant decrease in transcript levels over postnatal stages from P0 to P28. by Heather L. Dingwall (14573796)

The experimental technology combining a fluid shear stress experimental system with Atomic Force Microscopy (AFM). by Xinyao Zhao (5824427)

Subjects:

Measuring results of Hela cells subjected to different durations of fluid shear stress by Atomic Force Microscopy (AFM) by Xinyao Zhao (5824427)

Subjects:

Cephalometric measurement points. by Lijuan Liu (136685)

Subjects:

Measuring the Young’s modulus of Hela cells subjected to different durations of fluid shear stress by Atomic Force Microscopy (AFM). by Xinyao Zhao (5824427)

Subjects:

AFM probe is controlled to perform indentation assay on a Hela cell to record force curves for measuring cellular Young ‘s modulus. by Xinyao Zhao (5824427)

Subjects:

MiR-129-5p levels were decreased in mouse depression models. by Qiaozhen Qin (13159201)

“…The Y-axis represents the fold change, while the X-axis indicates the significance of differential expression. The gray points represent miRNAs with no significant change (p < 0.05, false discovery rate (FDR) q < 0.05), while red and blue points indicate upregulated and downregulated miRNAs (p < 0.05, FDR q < 0.05), respectively. …”

Data of Cement retention force(N) for each group in retention strength test. by Long Li (6555)

Subjects:

Cement retention force values(N) for each group in the cement retention strength test. by Long Li (6555)

Subjects:

(A) Thermocouple positions for the MIPS and MONO systems. (B) Preparation of bone cubes from fresh cow tibias further employed for ex vivo mechanical evaluation, osteotomy and bone... by Marsel Ganeyev (21453399)

Subjects:

All data points from Fig 2. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 5. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 8. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 3. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 1. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 4. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 9. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 7. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”

All data points from Fig 6. by Sara Hijazi (21656615)

“…Specifically, we observed that demyelination caused an impairment in the ability of PV interneurons to sustain high-frequency firing associated with a substantial decrease in Kv3-specific currents. We also found a significant impairment in PV interneuron autaptic self-inhibitory transmission, a feature implicated in temporal control of PV interneuron firing during cortical network activity. …”