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The theory now is that longer wavelengths of light specifically from sunlight restore membrane potential in your mitochondria, whereas shorter wavelengths of light (such as from LEDs) reduce it. This needs testing, but it’s intriguing & brings together a lot of data. https://t.co/Zzm8TYIPtG
The theory now is that longer wavelengths of light specifically from sunlight restore membrane potential in your mitochondria, whereas shorter wavelengths of light (such as from LEDs) reduce it. This needs testing, but it’s an intriguing & brings together a lot of data. https://t.co/Zzm8TYIPtG
The theory now is that longer wavelengths of light specifically from sunlight restore membrane potential in your mitochondria, where a shorter wavelength light (such as from LEDs) reduces it. This needs testing, but it’s an intriguing & brings together a lot of data. https://t.co/Zzm8TYIPtG
Recent research highlights the potential of photobiomodulation, a technique using specific light signals to stimulate cellular recovery. Scientists in Grenoble have developed devices aimed at leveraging this approach, which shows promise but has also been misrepresented as a "miracle cure" by some practitioners. Complementing this, a new study from London demonstrates that exposure to infrared sunlight for just 15 minutes, even with eyes covered, can penetrate the human body and improve mitochondrial function and vision. The emerging theory suggests that longer wavelengths of natural sunlight restore mitochondrial membrane potential, enhancing cellular function, whereas shorter wavelengths from LED lights may reduce it. While these findings are promising, further testing is needed to fully understand the mechanisms and efficacy of different light wavelengths on human health.
