Istanbul Airport takes the lead as the world's most connected airport, offering direct flights to 310 destinations worldwide. 🌍✈️
#istanbulairport
#globalconnectivity
#travelnews
#aviationhub
#flyeverywhere
#cameroon

Istanbul Airport takes the lead as the world's most connected airport, offering direct flights to 310 destinations worldwide. 🌍✈️
#istanbulairport
#globalconnectivity
#travelnews
#aviationhub
#flyeverywhere
#cameroon
Istanbul Airport takes the lead as the world's most connected airport, offering direct flights to 310 destinations worldwide. 🌍✈️
#istanbulairport
#globalconnectivity
#travelnews
#aviationhub
#flyeverywhere
#cameroon
🧬 Breakthrough in Vascular Disease Modeling! 🧬
Researchers at Texas A&M University have developed a next-gen microfluidic vessel-chip that replicates real human blood vessel conditions — including aneurysms, stenosis, and complex branching. This innovation offers a huge leap forward in understanding and treating vascular diseases.
Created by PhD researcher Abhishek Jain and master’s student Jennifer Lee, the chip uses human endothelial cells to mimic natural blood flow and vessel behavior, showing how these dynamics impact disease progression in real-time.
This groundbreaking technology could reduce the need for animal testing, accelerate personalized medicine, and pave the way for 4D organ-on-a-chip systems. Supported by NASA, NIH, the U.S. Army, and the FDA, it holds game-changing potential for both biomedical and space research.
📲 Follow this Facebook page for the latest tech updates and science news!
#vesselchip #biomedicalbreakthrough #organonchip #texasaminnovation #futuremedicine#cameroon
🧬 Breakthrough in Vascular Disease Modeling! 🧬
Researchers at Texas A&M University have developed a next-gen microfluidic vessel-chip that replicates real human blood vessel conditions — including aneurysms, stenosis, and complex branching. This innovation offers a huge leap forward in understanding and treating vascular diseases.
Created by PhD researcher Abhishek Jain and master’s student Jennifer Lee, the chip uses human endothelial cells to mimic natural blood flow and vessel behavior, showing how these dynamics impact disease progression in real-time.
This groundbreaking technology could reduce the need for animal testing, accelerate personalized medicine, and pave the way for 4D organ-on-a-chip systems. Supported by NASA, NIH, the U.S. Army, and the FDA, it holds game-changing potential for both biomedical and space research.
📲 Follow this Facebook page for the latest tech updates and science news!
#vesselchip #biomedicalbreakthrough #organonchip #texasaminnovation #futuremedicine#cameroon