Parx Materials develops bacteria-resistant plastics

Parx Materials developed a technology to make polymers resistant to bacteria, molds and biofilm by making use of a trace element with the utmost biological importance. The technology is inspired by nature, inspired by the way the defense mechanism of the human skin is protecting us against germs and viruses. The trace element of Zinc is vital for a good functioning of our immune system and by integrating this element in polymers Parx Materials is able to create an antimicrobial performance of 99.9% and higher.

 

Viruses do not multiply or proliferate on normal surfaces but are known to survive up to 2-3 days on plastic surfaces. Now in independent tests executed following the ISO 21702 norm, using the Human Corona E229 virus, prove that the Parx Materials technology shows a significant effect against this virus. The technology is reducing the virus 5 times faster than on normal solid plastic surfaces. The technology also brings down the H1N1 virus by 99.99% in just 8 hours in textiles fabricated with the technology.  

 

 

The Parx Materials technology is unique as it is the only effective broad-spectrum solution available today not using toxic substances, not migrating and not compromising the material in any way. That means nothing harmful or toxic is put inside the product, the material characteristics are not changed, recyclability is not changed and there is nothing coming out of the material. Nothing is leaching out means also that the technology does not lose any functionality over time. It is a true 100% safe and sustainable solution and with a high efficacy preventing the adhesion and proliferation of bacteria and preventing biofilm formation on plastic surfaces with now also a proven efficacy against viruses.

 

The virus tests were not executed with current Covid-19 causing virus as this is currently prohibited for commercial laboratories. But the E229 Coronavirus was selected as it has a good number of similarities to the Covid-19 virus. 

 

Because of the unique characteristics of the technology it can be used in almost any plastic surface creating a surface with an intrinsic resistance to bacteria, molds, fungi, biofilm and viruses.