Intermittent Hypoxic Hyperoxic Treatment Device
Rlab's Intermittent Hypoxic Hyperoxic Training Device, also known as IHHT or the cell trainer, represents a cutting-edge solution in intelligent intermittent hypoxic hyperoxic training. By integrating advanced monitoring and precise gas delivery, this device provides users with a safe and effective means to enhance their physical health and overall well-being.
Intermittent Hypoxic Hyperoxic Treatment Overview
Intermittent Hypoxia-Hyperoxia Therapy (IHHT) is an innovative and safe approach that has demonstrated effectiveness in improving energy levels and reducing disease risk. IHHT is particularly effective in improving symptoms and functionality across a wide spectrum of health conditions, including cardiovascular, respiratory, musculoskeletal, neurological, and metabolic pathologies. It is also promising for elderly patients with multiple comorbidities, underscoring its comprehensive impact on health and well-being.
Mechanism of IHHT
IHHT involves breathing varying concentrations of oxygen through a mask, which promotes the regeneration of healthier mitochondria by eliminating damaged ones. Mitochondria, vital for energy production, can become damaged under stress. IHHT introduces mild respiratory stress that triggers a natural cellular "fine-tuning" response, enhancing cellular interactions between the environment and the body and potentially improving quality of life.
Scientific Recognition
The significance of IHHT was highlighted by the 2019 Nobel Prize in Physiology or Medicine, awarded to three scientists for their work on the mechanism of Hypoxia-Inducible Factor 1 (HIF-1). Their research elucidated how aerobic organisms adapt to changes in oxygen levels, influencing more than 1,000 genes downstream, including those that enhance erythropoiesis and the adaptability of respiratory and cardiovascular systems to hypoxic conditions.
Rlab's Technological Integration
Rlab's Intermittent Hypoxic Hyperoxic Training Device is based on the physiological adaptations of the human body at high altitudes and exercise science theories. This device offers a range of models, allowing users to select the one that best suits their needs. The product employs intelligent algorithms and real-time monitoring through blood oxygen saturation sensors and heart rate sensors to intermittently and precisely deliver mixed gases with different oxygen concentrations (9-34%). This process aims to improve physical function, burn fat, and shape the body more safely and comfortably.
Hyperbaric Oxygen Chamber
Rlab hyperbaric oxygen chamber is a civil hyperbaric chamber developed based on the standard of medical hyperbaric oxygen chambers, the pressure can be adjusted (1.3~2.0ATA), Rlab's hyperbaric oxygen chamber has independent research and development technology, including a manual automatic control valve, with oxygen production and pressure integrated technology and intelligent control system. There are many types of Rlab Hyperbaric oxygen chambers, you can choose your favorite hyperbaric oxygen chamber according to your needs.
How was hyperbaric oxygen therapy discovered?
The 2019 Nobel Prize in Physiology or Medicine revealed that cells are sensitive to the oxygen content of their environment, and under hypoxic conditions, the increase of molecules called hypoxia-inducible factor (HIF) leads to changes in the expression of more than 300 genes, prompting cells to switch to a metabolic mode completely different from the oxygen-rich state.
There are two forms of oxygen: conjugated oxygen and dissolved oxygen. Oxygen is found in two forms in the blood: hemoglobin-bound oxygen and dissolved oxygen in plasma.
Bound oxygen: hemoglobin in red blood cells is combined with oxygen, and its carrying capacity can be expressed by blood oxygen saturation, arterial oxygen saturation is 95~98%, and venous blood is 75%; Therefore, the hemoglobin content is relatively stable, and the oxygen saturation is relatively stable in healthy people.
Dissolved oxygen: The amount of oxygen dissolved in the plasma is much smaller than the amount of bound oxygen, and the amount of dissolved oxygen is directly proportional to the pressure. In some areas, the capillaries are narrow, and blood cells cannot pass through, so they have to rely on dissolved oxygen in the plasma.
In summary, the oxygen supply to the whole body can be improved by increasing the atmospheric pressure of the human environment and the oxygen concentration of the inhaled air.