High-intensity exercise in optimally treated CHF patients showed faster fractional O2 extraction dynamics than controls (MRT 15.9 vs 19.0 s; P<0.05), indicating persistent circulatory limitations.
Observational (n=21)
Does optimally treated chronic heart failure alter microvascular oxygen delivery-to-utilization mismatch during high-intensity exercise compared to controls?
Despite optimal pharmacological treatment, central and peripheral circulatory adjustments still play a prominent role in limiting oxygen uptake kinetics and tolerance to heavy-intensity exercise in sedentary patients with chronic heart failure.
Absolute Event Rate: 15.9% vs 19%
p-value: p=<0.05
Impaired muscle blood flow at the onset of heavy-intensity exercise may transiently reduce microvascular O(2) pressure and decrease the rate of O(2) transfer from capillary to mitochondria in chronic heart failure (CHF). However, advances in the pharmacological treatment of CHF (e.g., angiotensin-converting enzyme inhibitors and third-generation beta-blockers) may have improved microvascular O(2) delivery to an extent that intramyocyte metabolic inertia might become the main locus of limitation of O(2) uptake (Vo(2)) kinetics. We assessed the rate of change of pulmonary Vo(2) (Vo(2)(p)), (estimated) fractional O(2) extraction in the vastus lateralis (approximately Deltadeoxy-Hb+Mb by near-infrared spectroscopy), and cardiac output (Qt) during high-intensity exercise performed to the limit of tolerance (Tlim) in 10 optimally treated sedentary patients (ejection fraction = 29 + or - 8%) and 11 controls. Sluggish Vo(2)(p) and Qt kinetics in patients were significantly related to lower Tlim values (P < 0.05). The dynamics of Deltadeoxy-Hb+Mb, however, were faster in patients than controls mean response time (MRT) = 15.9 + or - 2.0 s vs. 19.0 + or - 2.9 s; P < 0.05 with a subsequent response "overshoot" being found only in patients (7/10). Moreover, tauVo(2)/MRT-deoxy-Hb+Mb ratio was greater in patients (4.69 + or - 1.42 s vs. 2.25 + or - 0.77 s; P < 0.05) and related to Qt kinetics and Tlim (R = 0.89 and -0.78, respectively; P < 0.01). We conclude that despite the advances in the pharmacological treatment of CHF, disturbances in "central" and "peripheral" circulatory adjustments still play a prominent role in limiting Vo(2)(p) kinetics and tolerance to heavy-intensity exercise in nontrained patients.
Sperandio et al. (Fri,) conducted a observational in chronic heart failure (CHF) (n=21). High-intensity exercise vs. Controls was evaluated on Mean response time (MRT) of Delta[deoxy-Hb+Mb] (p=<0.05). High-intensity exercise in optimally treated CHF patients showed faster fractional O2 extraction dynamics than controls (MRT 15.9 vs 19.0 s; P<0.05), indicating persistent circulatory limitations.
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