Human skeletal muscle intracellular oxygenation: the impact of ambient oxygen availability

Abstract

Intracellular oxygen (O₂) availability and the impact of ambient hypoxia have far reaching ramifications in terms of cell signalling and homeostasis; however, in vivo cellular oxygenation has been an elusive variable to assess. Within skeletal muscle the extent to which myoglobin desaturates (deoxy‐Mb) and the extent of this desaturation in relation to O₂ availability provide an endogenous probe for intracellular O₂ partial pressure (P). By combining proton nuclear magnetic resonance spectroscopy (¹H NMRS) at a high field strength (4 T), assessing a large muscle volume in a highly efficient coil, and extended signal averaging (30 min) we assessed the level of skeletal muscle deoxy‐Mb in 10 healthy men (30 ± 4 years) at rest in both normoxia and hypoxia (10% O₂). In normoxia there was an average deoxy‐Mb signal of 9 ± 1%, which, when converted to P using an O₂/Mb half‐saturation (P₅₀) of 3.2 mmHg, revealed an P of 34 ± 6 mmHg. In ambient hypoxia the deoxy‐Mb signal rose to 13 ± 3% (P= 23 ± 6 mmHg). However, intersubject variation in the defence of arterial oxygenation (S) in hypoxia (S range: 86–67%) revealed a significant relationship between the changes in S and P(r²= 0.5). These data are the first to document resting intracellular oxygenation in human skeletal muscle, highlighting the relatively high P values that contrast markedly with those previously recorded during exercise (∼2–5 mmHg). Additionally, the impact of ambient hypoxia on P and the relationship between changes in S and P stress the importance of the O₂ cascade from air to cell that ultimately effects O₂ availability and O₂ sensing at the cellular level.