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After Nearly a Decade of Research, the World's First Graphene Condom is Launched

Christopher Ehlers READ TIME: 5 MIN.

After nearly a decade of research and development, ONE Condoms has launched the world's first graphene condom. Discovered in 2004, graphene captured international attention as the thinnest, strongest, and most conductive material on the planet. Called a "wonder material" by NASA, you can now bring this coveted material into the bedroom.

"Graphene is like a magic ingredient for condoms. It provides incredible thinness, strength, flexibility, and heat transfer – all the things you want in a condom. Our hybrid graphene-latex condom addresses some of the most common condom complaints head on, including pleasure, sensation, and comfort," said Davin Wedel, CEO and founder of ONE Condoms via a press release.

According to the release, Graphene received international attention in 2010, when physicists experimenting with its capabilities were awarded a Nobel Prize in Physics. The discovery of graphene has been a catalyst for innovation across industries, including space travel and renewable energy. Today's arrival of ONE Flex marks a massive development in sexual health innovation.

"Our scientists spent nearly ten years developing a hybrid condom by molecularly bonding graphene with natural rubber latex, resulting in one of the world's thinnest condoms," said Wedel.

Why Make Condoms with Graphene?

Why Make Condoms with Graphene?

Condoms remain the only tool that help prevent both sexually transmitted infections and unintended pregnancies. Despite their widespread availability, complaints about pleasure, fit, and comfort have challenged health outcomes for decades. Thanks to graphene's capabilities, encouraging condom use may be easier than ever before. In a clinical trial, ONE Flex was preferred two to one over standard latex condoms.

"Imagine the impact of a condom that could make safer sex as pleasurable as unprotected sex," said Wedel. "In order to have a dramatic impact on public health, we continue to reinvent the condom to get as close to a skin-on-skin feel as possible."

What Are the Benefits of Graphene Condoms?

Graphene is 200 times stronger than steel and 1 million times thinner than human hair. It is also the most conductive solid ever discovered.

When bonded together, graphene molecules fill the space between latex molecules, creating a new material that advances thinness, flexibility, and thermal conductivity. The result is a comfortable condom fit that enhances pleasure, connection, and sensation.

On its own, latex is an insulator, which keeps you from feeling your partner's natural body heat. Graphene, on the other hand, is the most conductive material on the planet. Because ONE Flex molecularly combines latex with graphene, the condom increases body heat transfer by 85% compared to standard latex condoms. This results in more sensation and a natural, skin-on-skin feeling.

One of the top complaints about ultra-thin condoms is a tight and restrictive feeling. When combined with graphene, latex can stretch farther without feeling tighter. Due to the capabilities of graphene, ONE Flex condoms are ultra-thin without losing flexibility, sensation, or comfort.

"Ten years of research and development is no minor undertaking, but we have remained deeply motivated by our vision of increasing condom access and use across populations. The release of ONE Flex is a huge step forward, and we are proud to be at the forefront of an innovation with massive implications for the sexual wellbeing of our planet," says Wedel.

Are ONE® Flex™ Condoms Cleared by the FDA?

Yes. ONE Flex condoms are FDA-cleared for the prevention of STIs and unintended pregnancies, and the technological advancement is safeguarded by a patent. Thanks to carbon-based graphene, the condom has a natural charcoal hue. All ONE Condoms are vegan-friendly, non-GMO, nontoxic, and free from any harmful chemicals. All ONE Condoms are packaged in tubes made from 100% recycled paper.


Head over to One Condoms to see what all the fuss is about.


by Christopher Ehlers

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