Introducing Plaxin™

 
 

Plaxin® is our unique solution to the problem of common plastics that have grown to dominate the world. Our system uses a mix of nano-technology, biological coating and organic materials that all work together in a complex process that allows us to beat entropy dynamically.

image (2).png

More than just a bioplastic

Biodegradable and compostable packaging materials made of cellulose, polylactide or starch blends have long been on the market. However, these biopolymers are of limited use because they cannot properly protect food against moisture and oxygen. These materials are too permeable to moisture, oxygen, carbon dioxide and flavorings. Biosignatures can now be applied directly to the fiber material in the formulation to enable use of these materials.

Nanotechnological basis

Plaxin is essentially made up of inorganic-organic hybrid polymers. The living cells replicate a living cell through the use of nanotechnology. This class of materials’ barrier properties are good at keeping out gases, moisture and aromas. Plaxin that will use biodegradable components of organic origin to replace non-biodegradable organic components from fossil sources, are the next evolutionary stage of this development.

How Plaxin works?

Plaxin consists of organic particles that form a hardened surface when exposed to specific solvents. The inorganic particle in the liquid form provides the heat needed to activate the surface of the chemical substance. The heat produced is anaerobic which allows the surface of the liquid vapor to turn a yellow-brown color and reinforce itself. Once the liquid crystallizes, the particles are forced out through the pores they left through diffusion of air. Thus, the Plaxin in a mixer can be said to be a biocompatible liquid - pliant, supple, easily molded yet fixed strong upon setting.

image (1).png

Plaxin as Building Material

To achieve their novel design, the Plaxin research team is also working on a compound called Plaxin 02, which is a novel, biocompatibility molecule that combines NMR bands with molecular-level properties to yield a compound without any other binding site and therefore, it was able to resist heat, chemical, and mechanical stress that normally would attract entropy. Through a system of liquid coating or renewal the cells of the Plaxin are rejuvenated anew - resulting in a strong, long-lasting material.