This study investigated changes in muscle oxidative metabolism and microvascular responsiveness induced by glucose ingestion in the upper and lower limb using near-infrared spectroscopy (NIRS). Fourteen individuals (27±1.4 years) underwent five vascular occlusion tests (VOT) (pre, 30, 60, 90 and 120 min after glucose challenge). NIRS-derived oxygen saturation (StO2) was measured on the forearm and leg muscle at each VOT. Muscle oxidative metabolism was determined by the StO2 downslope during cuff inflation (deoxygenation slope); microvascular responsiveness was estimated by the StO2 upslope (reperfusion slope) following cuff deflation. There was a significant increase in arm (p<0.05; 1-β=0.860) and leg (p<0.05; 1-β=1.000) oxidative metabolism activity as represented by the faster deoxygenation slope at 60, 90, and 120 min (0.08±0.03, 0.08±0.03, 0.08±0.02 %·s-1, respectively) (leg) and at 90 min (0.16±0.08 %·s-1) (arm) observed after glucose ingestion when compared to their respective pre values (leg= 0.06±0.02; arm= 0.11±0.04 %·s-1). There was a significant increase in arm (p<0.05; 1-β=0.880) and leg (p<0.05; 1-β=0.983) reperfusion slope at 60 (arm= 3.63 ± 2.1 %·s-1,; leg= 1.56±0.6 %·s-1), 90 (arm= 3.91±2.1 %·s-1; leg= 1.60±0.6 %·s-1) and 120 min (arm= 3.91±1.6 %·s-1; leg= 1.54±0.6 %·s-1) when compared to their pre glucose ingestion values (arm= 2.79±1.7 %·s-1; leg= 1.26±0.5%·s-1).. Our findings showed that NIRS-VOT technique is capable of detecting postprandial changes in muscle oxidative metabolism activity and microvascular reactivity in the upper and lower limb. Bullet point: NIRS-VOT is a promising non-invasive clinical approach that may help in the early, limb-specific detection of impairments in glucose oxidation and microvascular function.
Non-invasive and in vivo assessment of upper and lower limb skeletal muscle oxidative metabolism activity and microvascular responses to glucose ingestion in humans
Colosio, Alessandro;Pogliaghi, Silvia
2019-01-01
Abstract
This study investigated changes in muscle oxidative metabolism and microvascular responsiveness induced by glucose ingestion in the upper and lower limb using near-infrared spectroscopy (NIRS). Fourteen individuals (27±1.4 years) underwent five vascular occlusion tests (VOT) (pre, 30, 60, 90 and 120 min after glucose challenge). NIRS-derived oxygen saturation (StO2) was measured on the forearm and leg muscle at each VOT. Muscle oxidative metabolism was determined by the StO2 downslope during cuff inflation (deoxygenation slope); microvascular responsiveness was estimated by the StO2 upslope (reperfusion slope) following cuff deflation. There was a significant increase in arm (p<0.05; 1-β=0.860) and leg (p<0.05; 1-β=1.000) oxidative metabolism activity as represented by the faster deoxygenation slope at 60, 90, and 120 min (0.08±0.03, 0.08±0.03, 0.08±0.02 %·s-1, respectively) (leg) and at 90 min (0.16±0.08 %·s-1) (arm) observed after glucose ingestion when compared to their respective pre values (leg= 0.06±0.02; arm= 0.11±0.04 %·s-1). There was a significant increase in arm (p<0.05; 1-β=0.880) and leg (p<0.05; 1-β=0.983) reperfusion slope at 60 (arm= 3.63 ± 2.1 %·s-1,; leg= 1.56±0.6 %·s-1), 90 (arm= 3.91±2.1 %·s-1; leg= 1.60±0.6 %·s-1) and 120 min (arm= 3.91±1.6 %·s-1; leg= 1.54±0.6 %·s-1) when compared to their pre glucose ingestion values (arm= 2.79±1.7 %·s-1; leg= 1.26±0.5%·s-1).. Our findings showed that NIRS-VOT technique is capable of detecting postprandial changes in muscle oxidative metabolism activity and microvascular reactivity in the upper and lower limb. Bullet point: NIRS-VOT is a promising non-invasive clinical approach that may help in the early, limb-specific detection of impairments in glucose oxidation and microvascular function.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.