Elucidating the combined effect of intermittent hypoxia training and acetazolamide on hypoxia induced hematological and physiological changes.

As the number of people travelling to altitude increases, the risk of life threatening medical emergencies also increases. It is important that we have effective strategies to minimize the risk of altitude illness. In this study, an attempt was made to investigate the combined effect of non-pharmacological (Intermittent hypoxia training; IHT) and pharmacological (acetazolamide; ACZ) intervention as a prophylactic strategy in order to minimize the risk of high altitude hypoxic related problems using rats as an animal model. Male Sprague Dawley rats were subjected to IHT for 4 h consecutively for 5 days at 12% FiO2 under normobaric conditions with and without oral ACZ administration at 25 mg/kg body weight. Validation of the intervention was performed by exposing the rats to extreme hypoxia (EH) at 8% FiO2 to further assess the effect of IHT and ACZ on hypoxic acclimatization. The principal findings of this study is that the combined effect of IHT and ACZ improves the arterial oxygenation by alterations in hemodynamics and in blood gasometry, thereby resulting into an increase in the oxygen carrying capacity of the blood with increase in SpO2 (peripheral oxygen saturation). The present study showed that the combined effect of IHT with ACZ could be refined as a prophylactic measure for better outcomes during altitude ascent and rapid altitude acclimatization rather than IHT or ACZ alone.

Physiological and oxidative stress responses to intermittent hypoxia training in Sprague Dawley rats.

AIM: Rapid ascent to high altitude and inability to acclimatize lead to high-altitude illnesses. Intermittent hypoxia (IH) conditioning has been hypothesized as a non-pharmacological strategy aiming to improve adaptive responses during high altitude ascent. In the recent years, IH training (IHT) has become increasingly popular among recreational and professional athletes owing to its ability to mitigate high altitude related problems. This study aimed at exploring the role of IHT in altitude acclimatization. METHODS: Male Sprague Dawley rats were subjected to IHT for 4 h consecutively for 5 days at 12% FiO2 under normobaric conditions. To assess the effect of IHT in hypoxic acclimatization, animals were further exposed to extreme hypoxia (EH) at 8% FiO2. Oxygen saturation (SpO2), respiratory rate and heart rate were recorded during the exposure. Oxidative stress (ROS, MDA, and 4-HNE) and histopathological examinations were studied in the lung tissue sections. Hypoxia biomarkers, HIF-1α, EPO, VEGF, and BPGM were evaluated through western blotting in the lung tissue. RESULTS: Assessment of the IHT showed that SpO2 levels were found to be higher in the IH trained rats with a statistical difference of p < 0.01 in the first hour of hypoxia exposure as compared to the untrained rats. There was a significantly higher (p < 0.001) generation of ROS and MDA in the untrained rats as compared to the trained rats. Lipid peroxidation markers and systemic inflammatory marker were found to be expressed at much higher level in the untrained rats. There was a higher expression of HIF-1α (1.24-fold ↑), VEGF (1.14-fold ↑) and decrease in EPO (1.43-fold ↓) in the untrained rats as compared to trained rats. CONCLUSIONS: Preconditioning with IHT resulted in the reduction in hypoxia induced oxidative stress during extreme hypoxia exposure and thus, maintaining redox balance as well as adjustment in the physiological changes in rats.