GEA Videos no-reply@gea.com https://video.gea.com en-us Visualplatform http://blogs.law.harvard.edu/tech/rss GEA Videos episodic no https://video.gea.com/files/rv1.68/sitelogo.gif https://video.gea.com http://video.gea.com/turning-tunicates-into-tomorrows <p>Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine biomass, reduces chemical usage and energy waste, and supports circular bioeconomy in sustainable packaging. Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine biomass, reduces chemical usage and energy waste, and supports circular bioeconomy in sustainable packaging. This work was carried out with the support of WebTech, in collaboration with the University of São Paulo, and with the participation of Renato Damasio, PhD student at SUNY.</p><p><a href="http://video.gea.com/turning-tunicates-into-tomorrows"><img src="http://video.gea.com/64968576/114222652/dabf57aabfc5c4cbbc9b64716654c76e/standard/download-10-thumbnail.jpg" width="75" height=""/></a></p> http://video.gea.com/photo/114222652 Thu, 03 Jul 2025 14:24:11 GMT Turning tunicates into tomorrow’s packaging: A nanocellulose breakthrough Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine biomass, reduces chemical usage and energy waste, and supports circular bioeconomy in sustainable packaging. Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine biomass, reduces chemical usage and energy waste, and supports circular bioeconomy in sustainable packaging. This work was carried out with the support of WebTech, in collaboration with the University of São Paulo, and with the participation of Renato Damasio, PhD student at SUNY. Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine... GEA Videos 01:42 <p>Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine biomass, reduces chemical usage and energy waste, and supports circular bioeconomy in sustainable packaging. Explore the homogenization of tunicate-derived tunic to produce nanocellulose pulp—focusing on mechanical defibrillation for high‑crystallinity, high‑aspect ratio fibers. Learn how this eco‑friendly mechanical process uses renewable marine biomass, reduces chemical usage and energy waste, and supports circular bioeconomy in sustainable packaging. This work was carried out with the support of WebTech, in collaboration with the University of São Paulo, and with the participation of Renato Damasio, PhD student at SUNY.</p><p><a href="http://video.gea.com/turning-tunicates-into-tomorrows"><img src="http://video.gea.com/64968576/114222652/dabf57aabfc5c4cbbc9b64716654c76e/standard/download-10-thumbnail.jpg" width="75" height=""/></a></p> Chemical Homogenizers Homogenizers Ariete Series Homogenizers Pilot Plant Homogenizers Table-top Homogenizing NanoVALVE http://video.gea.com/nanocellulose-bioprinting-at-tu <p>At Graz University of Technology, researchers, thanks to a Panther Lab Homogenizer 3006, start with eucalyptus cellulose sheets to extract nanocellulose, which becomes a special bio-ink for 3D printers. The result is the ability to print veins, arteries, and tracheas.</p><p><a href="http://video.gea.com/nanocellulose-bioprinting-at-tu"><img src="http://video.gea.com/64968566/107848067/24efcb8a768fe39bfbe29471aaff827a/standard/download-7-thumbnail.jpg" width="75" height=""/></a></p> http://video.gea.com/photo/107848067 Thu, 19 Dec 2024 09:31:39 GMT Nanocellulose bioprinting at TU Graz At Graz University of Technology, researchers, thanks to a Panther Lab Homogenizer 3006, start with eucalyptus cellulose sheets to extract nanocellulose, which becomes a special bio-ink for 3D printers. The result is the ability to print veins, arteries, and tracheas. At Graz University of Technology, researchers, thanks to a Panther Lab Homogenizer 3006, start with eucalyptus cellulose sheets to extract nanocellulose, which becomes a special bio-ink for 3D printers. The result is the ability to print veins,... GEA Videos 03:50 <p>At Graz University of Technology, researchers, thanks to a Panther Lab Homogenizer 3006, start with eucalyptus cellulose sheets to extract nanocellulose, which becomes a special bio-ink for 3D printers. The result is the ability to print veins, arteries, and tracheas.</p><p><a href="http://video.gea.com/nanocellulose-bioprinting-at-tu"><img src="http://video.gea.com/64968566/107848067/24efcb8a768fe39bfbe29471aaff827a/standard/download-7-thumbnail.jpg" width="75" height=""/></a></p> Homogenizers Homogenizers Pilot Plant Pharma & healthcare