Image_3_Tocilizumab (TCZ) Decreases Angiogenesis in Rheumatoid Arthritis Through Its Regulatory Effect on miR-146a-5p and EMMPRIN/CD147.jpeg by Devy Zisman (11838428)

“…In vitro, the accumulation in the supernatants of the pro-angiogenic factors EMMPRIN, VEGF and MMP-9 was increased by co-culturing the HT1080 fibroblasts and the U937 monocytes, while the accumulation of the anti-angiogenic factor thrombospondin-1 (Tsp-1) and the expression levels of miR-146a-5p were reduced. Transfection of HT1080 cells with the miR-146a-5p mimic, decreased the accumulation of EMMPRIN, VEGF and MMP-9. …”

Image_4_Tocilizumab (TCZ) Decreases Angiogenesis in Rheumatoid Arthritis Through Its Regulatory Effect on miR-146a-5p and EMMPRIN/CD147.jpeg by Devy Zisman (11838428)

“…In vitro, the accumulation in the supernatants of the pro-angiogenic factors EMMPRIN, VEGF and MMP-9 was increased by co-culturing the HT1080 fibroblasts and the U937 monocytes, while the accumulation of the anti-angiogenic factor thrombospondin-1 (Tsp-1) and the expression levels of miR-146a-5p were reduced. Transfection of HT1080 cells with the miR-146a-5p mimic, decreased the accumulation of EMMPRIN, VEGF and MMP-9. …”

Image_2_Tocilizumab (TCZ) Decreases Angiogenesis in Rheumatoid Arthritis Through Its Regulatory Effect on miR-146a-5p and EMMPRIN/CD147.jpeg by Devy Zisman (11838428)

“…In vitro, the accumulation in the supernatants of the pro-angiogenic factors EMMPRIN, VEGF and MMP-9 was increased by co-culturing the HT1080 fibroblasts and the U937 monocytes, while the accumulation of the anti-angiogenic factor thrombospondin-1 (Tsp-1) and the expression levels of miR-146a-5p were reduced. Transfection of HT1080 cells with the miR-146a-5p mimic, decreased the accumulation of EMMPRIN, VEGF and MMP-9. …”

Image_1_Tocilizumab (TCZ) Decreases Angiogenesis in Rheumatoid Arthritis Through Its Regulatory Effect on miR-146a-5p and EMMPRIN/CD147.jpeg by Devy Zisman (11838428)

“…In vitro, the accumulation in the supernatants of the pro-angiogenic factors EMMPRIN, VEGF and MMP-9 was increased by co-culturing the HT1080 fibroblasts and the U937 monocytes, while the accumulation of the anti-angiogenic factor thrombospondin-1 (Tsp-1) and the expression levels of miR-146a-5p were reduced. Transfection of HT1080 cells with the miR-146a-5p mimic, decreased the accumulation of EMMPRIN, VEGF and MMP-9. …”

HFA decreased expression of osteoclastic markers in alveolar bone. by Mani Alikhani (5180768)

Increasing temperature decreases oxygen concentration and decreasing oxygen content decreases neuronal excitability. by Yuguo Yu (172221)

“…Increasing temperature can dramatically decrease oxygen levels. B. Response of layer 2/3 pyramidal cells (n = 5) to the intracellular injection of a depolarizing current pulse (200 pA, 500 ms) at different temperatures (same experiments as in A). …”

Dispersion-temperature of microgels decreases at lower pHs. by Chi-Shuo Chen (234719)

“…<p>As pH is reduced from 8.0 (black) to 7.7 (blue) to 7.5 (red) to 7.3 (green), non-linear microgel dispersion-temperature changes were observed while pH decreases. …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Tandem Imaging of Breath Ethanol and Acetaldehyde Based on Multiwavelength Enzymatic Biofluorometry by Kenta Iitani (4175995)

“…Each mesh exhibited selective responses to the target VOCs, with no significant impact on the dynamic range observed in either the single or tandem configurations (EtOH 1–300 ppm, AcH 0.2–5 ppm). The 90% response time was close after time–domain image differential analysis (EtOH = 26 s and AcH = 15 s). …”

Vacuolar dynamics after a rapid temperature decrease. by Noriaki Kadohama (382080)

“…<p>Vacuolar membrane labeled with FM1-43 (green) and chlorophyll fluorescence (magenta) in palisade mesophyll cells of saintpaulia leaf were observed before (A) and 10 min after (B) a rapid temperature decrease from 25°C to 5°C and kept at 5°C for 1 min. …”