Image 14_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 7_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 4_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Table 5_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.doc by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Table 4_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.doc by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 10_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 6_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 1_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 13_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Table 1_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.docx by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 15_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 11_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 12_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Image 9_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.tif by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Table 9_Deciphering the oncogenic network: how C1QTNF1-AS1 modulates osteosarcoma through miR-34a-5p and glycolytic pathways.xlsx by Yu Zhang (12946)

“…</p>Results<p>The findings indicated a significant decrease in C1QTNF1-AS1 expression levels in OS cells compared to normal osteoblasts. …”

Hydrate-Based Gas Storage Made Greener: Methane Hydrate Formation Enhancement with a Low-Toxicity Promoter by Katipot Inkong (7979942)

“…The results demonstrate that higher temperatures lead to lower gas uptake and slower hydrate formation kinetics, as increased temperature reduces heat distribution efficiency. Additionally, the effect of pressure variations (from 8 to 4 MPa at 288.2 K) was analyzed, revealing that a lower pressure decreases both the gas uptake and formation kinetics due to a reduced driving force. …”

Hydrate-Based Gas Storage Made Greener: Methane Hydrate Formation Enhancement with a Low-Toxicity Promoter by Katipot Inkong (7979942)

“…The results demonstrate that higher temperatures lead to lower gas uptake and slower hydrate formation kinetics, as increased temperature reduces heat distribution efficiency. Additionally, the effect of pressure variations (from 8 to 4 MPa at 288.2 K) was analyzed, revealing that a lower pressure decreases both the gas uptake and formation kinetics due to a reduced driving force. …”

Hydrate-Based Gas Storage Made Greener: Methane Hydrate Formation Enhancement with a Low-Toxicity Promoter by Katipot Inkong (7979942)

“…The results demonstrate that higher temperatures lead to lower gas uptake and slower hydrate formation kinetics, as increased temperature reduces heat distribution efficiency. Additionally, the effect of pressure variations (from 8 to 4 MPa at 288.2 K) was analyzed, revealing that a lower pressure decreases both the gas uptake and formation kinetics due to a reduced driving force. …”

Hydrate-Based Gas Storage Made Greener: Methane Hydrate Formation Enhancement with a Low-Toxicity Promoter by Katipot Inkong (7979942)

“…The results demonstrate that higher temperatures lead to lower gas uptake and slower hydrate formation kinetics, as increased temperature reduces heat distribution efficiency. Additionally, the effect of pressure variations (from 8 to 4 MPa at 288.2 K) was analyzed, revealing that a lower pressure decreases both the gas uptake and formation kinetics due to a reduced driving force. …”

Hydrate-Based Gas Storage Made Greener: Methane Hydrate Formation Enhancement with a Low-Toxicity Promoter by Katipot Inkong (7979942)

“…The results demonstrate that higher temperatures lead to lower gas uptake and slower hydrate formation kinetics, as increased temperature reduces heat distribution efficiency. Additionally, the effect of pressure variations (from 8 to 4 MPa at 288.2 K) was analyzed, revealing that a lower pressure decreases both the gas uptake and formation kinetics due to a reduced driving force. …”