Placebo Controlled Study for Characterisation of Immunological Effects and Safety of Active O2

The nutritional product Active O2 (Adelholzener Alpenquellen GmbH) is a table water which contains an oxygen amount of 40 mg/l, a 15-fold higher amount compared to non-oxygenised products.

In this study the evaluation of immunological parameters which characterise the function of the immune system is planned in subjects ingesting the test product Active O2 in comparison with a placebo group. The study rationale refers to an established mechanistic hypothesis, which links gastro-intestinal hypoxia during and after strenuous exercise with an impairment of the immune system function.

During periods of exercise and physiological stress situations, the body primarily focuses on blood supply of the cardiovascular system, skeletal muscles and skin. Therefore, it is assumed that immunological effects during and after strenuous exercise are related - at least in part - to reduced blood flow in splanchnic organs which in turn leads to hypoxia induced damage of intestinal tissue, particularly the mucosal tissue, and to enhanced permeability for pathogens [1-6].

A phenomenon well described in scientific literature is related to athletes suffering from infections, particularly in the upper respiratory tract, after strenuous exercise. Significantly higher endotoxin concentrations (lipopolysaccharides) could be detected in the blood of athletes after strenuous competitions when compared to control groups [7].

In scientific studies, a decrease in the number of circulating immune cells as well as a reduced host defence function after strenuous and sustained exercise has been demonstrated in-vivo and by application of immunological in-vitro methods. Significant decreases in T-lymphocytes, T-helper cells type 1 as well as in Natural Killer cells (NK) could be shown. However, B-cells and T-helper cells type 2 are not affected in a comparable magnitude [8-10].

In one study a significant increase in regulatory T-cells (Treg) has been assessed after 45 min of swim exercise in adolescents [11]. These cells play a major role in the inhibition of effector T cell function and thus have a pronounced immunosuppressive effect. Furthermore, it has been shown that Treg-cell activity is directly linked to the occurrence of hypoxia in damaged tissues [12].

Immune responses due to exercise are complex and depend on numerous additional factors (e.g. stress hormones, reactive oxygen species) as well as on the intensity of exercise level [13-15].

Nonetheless, oxygen susceptibility of regulatory immunocompetent cells as well as integrity of the mucosal barrier function may play an important role in protection and/or modification of the immune response including the integrity of epithelial tight junctions and M-cell related transcytosis of pathogens to highly organised lymphoid structures for effective immune responses [4; 12; 16]. A strong correlation between intestinal hypoxia during strenuous exercise and the magnitude of intestinal mucosa damage has been demonstrated by plasma levels of the surrogate parameter intestinal fatty acid binding protein (I-FABP), a specific biomarker for mucosal damage in the small intestine [4; 17].

The hypothesis to be investigated in this study is that the oxygen content of Active O2 may - at least in part - compensate the hypoxic situation in the surface of the gut wall, when ingested during and after exercise. Luminal supply of oxygenated water potentially might protect mucosal tissue from ischemia related damage and could modulate immune responses. As a consequence, the overall situation of the immune system might improve. Such an effect should be reflected in the pharmacodynamic parameters determined in this study.

A first interim analysis of the previous pilot part of this study, including the results of 12 healthy subjects, revealed statistically significant differences between both treatments for leukocytes, CD8+-lymphocytes and NK cells. Significant differences in cytokine production and additional immunological parameters were not detectable in comparison of both treatments and no trends were observed which might indicate any treatment effect. Therefore, the second part of this clinical trial will be performed with a focus on the pharmacodynamic parameters from the pilot part for which statistically significant differences between treatments have been observed. However, additional inclusion of I FABP analysis is considered reasonable as this surrogate parameter specifically reflects quantifiable impairment and potential local oxygen effects on intestinal mucosa barrier function.

According to EU regulation No 1924/2006 on nutrition and health claims made on foods, nutrition producing companies must show scientific data with substantiation as a prerequisite for advertisement dealing with health related claims [17]. Thus, the clinical trial is planned to further investigate a potentially beneficial effect of Active O2 when ingested during and after exercise.