Anders T. Nygren

Effects of dynamic ischaemic training on human skeletal muscle dimensions

Abstract The effect of training under conditions of local leg ischaemia on muscle area and fibre dimensions was studied in nine males. Leg ischaemia was induced by enclosing the legs in a pressure chamber and sealing the opening with a rubber membrane at the level of the crotch. Air pressure over the legs was 50 mmHg. The subjects performed 16 sessions (45 min) of one-legged supine strenuous ischaemic training during 4 weeks. Exercise intensity was maintained as high as possible during the whole session. The contralateral leg served as a control leg and remained passive during exercise. Before and after the training period, muscle fibre dimensions were determined from biopsy samples taken from the m. vastus lateralis, and leg muscle dimensions were assessed by magnetic resonance imaging (MRI). In the trained leg, mean fibre area increased by 12% (P < 0.05). The MRI-assessed cross-sectional area of the vastus group increased by 4% (P=0.01). In the control leg, mean fibre area and the cross-sectional area of the vastus group were unchanged, while those of the adductor muscle group decreased by 4% (P < 0.05). It is concluded that a short period of strenuous ischaemic endurance training increases the cross-sectional area of the ischaemically trained muscle group, as measured both by MRI and from muscle biopsy samples. In contrast, the adductor muscles in the contralateral thigh showed a decreased cross-sectional area (as assessed by MRI), possibly due to the effects of the strenuous contralateral training, by mechanisms that have yet to be identified.

Skeletal Muscle Perfusion During Exercise Using Gd-DTPA Bolus Detection

The study was performed to evaluate if skeletal muscle perfusion can be determined during exercise using an IV bolus injection of Gd-DTPA. A fast spoiled gradient echo sequence (T1 weighted) was used with intermittent imaging during one-legged plantar flexion at different workloads. Between repetitive flexions, a 2-sec rest allowed magnetic resonance imaging (MRI) of the lower legs and measurements of the blood flow in the popliteal artery by ultrasonography for subsequent calculation of muscle perfusion. Maximal signal intensity, upslope and downslope of the bolus, mean transit time, and integrated curve area were measured within regions of interest bilaterally. The skeletal muscle perfusion estimated by ultrasonography increased in the exercising leg from 4 ml x 100 g(-1) x min(-1) at rest to 38 ml at low, 86 ml at medium, and 110 ml x 100 g(-1) x min(-1) at high workload. The SImax increased from 1.38 +/- 0.12 to 1.58 +/- 0.15 and the negative slope of the peak nonsignificantly from - 2.38 +/- 1.75 to - 12.05 +/- 9. 71. All obtained MRI parameters could visually separate the muscles into exercising, nonexercising, and presumably low active muscles. It is concluded that the signal intensity curve using a fast spoiled gradient echo sequence did not overall quantitatively mirror the perfusion, evaluated as the blood flow measured by ultrasonography. However, the signal intensity seemed to follow the blood flow velocity within a limited range of 15-60 cm x sec(-1), corresponding to 35-90 ml x 100 g(-1) x min(-1). Nonetheless, it might be useful when studying ischemia or endothelial dysfunction in skeletal muscles during exercise.

Changes in cross-sectional area in human exercising and non-exercising skeletal muscles

Abstract This research was performed to study how the cross-sectional area (CSA) changes in the skeletal muscles of exercising (E-leg) and contralateral non-exercising (N-leg) legs and to evaluate to what extent changes in CSA mirror changes in blood flow or extravascular water displacement. Seven healthy volunteers performed plantar flexion exercise at three different exercise intensities for 10 min each. Six plantar flexions followed by a 2-s rest in between allowed repeated measurement of the blood flow to the lower limbs by duplex ultrasonography in the popliteal artery and CSA by magnetic resonance imaging. The CSA was measured using manual planimetry at rest and after 3 and 9 min of the exercise periods. The CSA increased in the E-leg by 4.5% and decreased in the N-leg by −2.4%, from rest to highest exercise intensity. Post-exercise imaging of the E-leg showed a bi-phasic recovery of CSA with a rapid phase followed by a slower phase while the blood flow very rapidly returned almost to basal. The time course of the post-exercise decrease indicated that about 50% of the increase in CSA at the highest exercise intensity might have been a result of extravascular water displacement and 50% of an increase in the vasculature volume related to the flow increase. The CSA reduction in N-leg seems to have been related to vasoconstriction, probably mainly of the capacitance vessels since blood flow was not reduced.

Elevated Troponin Levels in Acute Stroke Patients Predict Long-term Mortality

BACKGROUND Elevated plasma levels of troponin in acute stroke patients are common and have in several studies been shown to predict in-hospital and short-term mortality. Little is, however, known about the long-term prognosis of these patients. The aim of this study was to determine patient characteristics and 5-year mortality in patients with acute stroke and troponin elevation on admission. METHODS A retrospective cohort study of all consecutive patients with acute stroke and a plasma troponin I (TnI) analyzed on admission to Danderyd Hospital between January 1, 2005, and January 1, 2006 (n = 247). Patient characteristics were obtained from the Swedish National Stroke Register, Riksstroke, as well as hospital records. Mortality data were obtained from the Swedish Cause of Death Register. RESULTS There were 133 patients (54%) with TnI less than .03 μg/L (normal), 74 patients (30%) with TnI .03-.11 μg/L (low elevation), and 40 patients (16%) with TnI greater than .11 μg/L (high elevation). TnI elevations were associated with a higher age, prior ischemic stroke, chronic heart failure, renal insufficiency, stroke severity, and ST segment elevation or depression on admission. The rate of hyperlipidemia decreased with increasing TnI. Adjusted for age and comorbidity, elevated TnI values on admission had a significantly and sustained increased mortality over the 5-year follow-up, with a hazard ratio of 1.90 (95% confidence interval, 1.33-2.70). CONCLUSIONS Troponin elevation in patients with acute stroke, even when adjusted for several possible confounders, is associated with an almost 2-fold increased risk of 5-year mortality.

Delayed contrast agent kinetics in ischemic skeletal muscle

To detect skeletal muscle ischemia with first‐pass gadolinium (Gd) kinetics after exercise.

Shortened T2 after exercise in ischemic skeletal muscle

To detect skeletal muscle ischemia with transverse relaxometry after ischemic exercise.