/INNOVATION/newswire -- COMO, CO, ITALY -- SATURDAY, 16 NOVEMBER 2024, 03:20 UTC+1
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ISRAEL -- /INNOVATION/newswire -- Jul 24, 2020
The Venous Materials project by Hila Mor reimagines interactive materials inspired by nature's venous structures, offering dynamic tangible interactions through fluidic interfaces. This innovative project was completed in April 2020 at the MIT Media Lab, Tangible Media group, in Cambridge, MA.
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Hila Mor's Venous Materials project draws inspiration from the intricate venous structures found in nature and the human body, where color changes in veins can indicate internal and external physical conditions. The project envisions a new way to design dynamic tangible interactions using fluidic structures, responding to user pressure and motion with dynamic displayed patterns. These materials can animate dynamic graphics, create responsive objects, and visualize body movement and balance.
The technology behind Venous Materials is developed through research on Microfluidics, specifically designed for human interaction and UX design. A specialized computational tool was developed for the design process, simulating and visualizing the color change and flow display within the material according to user input. The production process involves laser engraving and manual lab processes, utilizing PDMS silicone and ecoline ink.
With prototypes mainly sized at 5cmX5cm, Venous Materials offer a unique way for users to interact with the material by deforming or applying pressure, driving fluid flow within internal channels to visualize dynamic responsive displays. This innovative approach provides a simple way to create and validate designs of fluidic structures, allowing for interactive applications to augment human movement and everyday objects.
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ISRAEL -- /INNOVATION/newswire -- Oct 14, 2020
Introducing Venous Materials, an innovative project by Hila Mor, which reimagines interactive sensor design inspired by the venous structures found in nature and the human body. Combining Microfluidics technology with user experience design, this project pushes the boundaries of material interaction and dynamic graphics.
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