In the pursuit of healthier indoor environments, air filtration has become an essential component. With the advent of advanced technologies, traditional air filters have made significant strides in capturing airborne contaminants. However, a new player in the field, KorganoTech, has taken air filtration to unparalleled heights with their pathogen air filters. Let's explore the key differences between KorganoTech's pathogen air filters and traditional air filters and understand how they revolutionize indoor air quality.
Targeting Airborne Pathogens:
Traditional air filters are primarily designed to capture larger particles like dust, pollen, and pet dander. While they provide some level of protection against airborne pathogens, their efficiency in capturing viruses and bacteria is limited due to the pathogens' small size.
On the other hand, KorganoTech's pathogen air filters are purpose-built to target and deactivate airborne pathogens. Leveraging methods to degrade virus/bacteria's DNA, these filters can neutralize pathogens at the genetic level, rendering them harmless and preventing their replication or spread.
Advanced Filtration Technology:
Traditional air filters usually employ mechanical filtration, where particles are trapped in the filter media as air passes through. While this method is effective for larger particles, it may not be as efficient in capturing smaller airborne pathogens.
On the other hand, KorganoTech utilizes nanotechnology utilizes nanotechnology for deactivating viruses and bacteria based on the following mechanisms ( see picture below);
- Oxidative Stress: Copper nanoparticles can generate reactive oxygen species (ROS) upon contact with biological material. These ROS are highly reactive molecules that can damage cellular structures, including proteins, lipids, and nucleic acids. When the ROS accumulate to a toxic level, it can lead to the destruction of bacteria and viruses.
- Cell Membrane Disruption: Copper nanoparticles can physically interact with the cell membranes of bacteria and viruses, causing disruption or damage. This can result in the leakage of essential cellular components and eventually lead to cell death.
- DNA/RNA Interaction: Copper nanoparticles may bind to the genetic material (DNA/RNA) of bacteria and viruses, interfering with their replication and transcription processes. This disruption can prevent the microorganisms from multiplying and, eventually, lead to their demise.
- Inhibition of Enzymes: Copper nanoparticles can inhibit specific enzymes necessary for the survival and reproduction of bacteria and viruses. By disrupting vital metabolic pathways, the nanoparticles can impede their growth and survival.
- Antimicrobial Release: Some copper nanoparticles are engineered to release copper ions gradually. These copper ions have potent antimicrobial properties and can attack bacteria and viruses by multiple mechanisms, as mentioned above.
Enhanced Indoor Air Quality:
Traditional air filters contribute to improving indoor air quality by reducing the concentration of common allergens and pollutants. However, they may fall short in providing comprehensive protection against infectious airborne pathogens.
KorganoTech's pathogen air filters not only ensure cleaner air by removing common pollutants but also offer an advanced layer of protection against harmful pathogens, helping to create a healthier indoor environment.
In the quest for cleaner, safer indoor air, the distinction between KorganoTech's pathogen air filters and traditional air filters is significant. While traditional filters serve a vital role in capturing common allergens and pollutants, KorganoTech's innovative pathogen air filters take air filtration to a whole new level. By actively targeting and deactivating airborne pathogens at the genetic level, these revolutionary filters offer unparalleled protection, ensuring that indoor spaces become sanctuaries of health and well-being. As technology continues to evolve, embracing advancements like KorganoTech's pathogen air filters will undoubtedly shape a healthier future for all.