Bioluxpro is a device that utilizes red and near-infrared light technology. This device emits light (both red and infrared) through LEDs, a treatment known as Photobiomodulation (PBM).
Devices for red and near-infrared light therapy, like Bioluxpro, typically use diode lasers or LEDs to generate wavelengths of light that mimic those emitted by the sun. Our bodies have evolved to absorb and utilize this natural light as a form of electromagnetic radiation, using it as a source of energy for a wide variety of cellular processes.
The primarily accepted mechanism of red and near-infrared light therapy lies in providing mitochondria with better chances to synthesize energy. This, in turn, allows for increased ATP production and the distribution of energy where it is most needed.
As a result, this leads to:
- Elevated energy levels
- Pain relief
- Reduction of inflammation
- Acceleration in injury recovery
- Improved physical performance
- Enhancement in recovery after physical exertion
- Modulation of the immune response
- Improvement in sleep quality
- Regulation of hormonal balance
- Improvement in mental well-being
- Acceleration of wound healing
Our goal with Bioluxpro is to create a device with minimal or zero side effects that aids the body in its self-healing processes.
Bioluxpro for Pre-Conditioning and Post-Workout Recovery
The impact of Bioluxpro on athletic performance when applied before and after physical activities is noticeable. A study aimed at assessing endurance, fatigue levels, and recovery was conducted and controlled with a placebo group. Healthy individuals aged 25 to 45, including both men and women, were recruited.
The study consisted of two phases. In the initial phase, red light was used before exercise, while in the subsequent phase, it was used after exercise.
Each participant received a red light device and two simulated devices randomly. Red light was applied to specific muscle groups in four different locations, resulting in a total exposure time of 40 minutes. Performance assessments were conducted with a three-day interval between sessions. The number of exercise sets until reaching fatigue was used as the primary measure to assess effects at baseline and after red light application. Data were collected at three different times: immediately after red light use, one hour after application, and 24 hours later.
This study provides concrete real-world evidence supporting the greater effectiveness of red light compared to simulated devices. Further research is required to determine optimal parameters.
In both phases of the study, the use of red light, whether an hour before or after physical activity, led to comparable and significant improvements. Minimal differences were observed between the two simulated devices. The number of exercise sets performed until fatigue increased by approximately 45% when red light was applied before training and around 41% when administered after training, compared to baseline measurements.