Randomized Crossover Trial

A - Click here for explanation of classification scheme.

NEUTRAL: See Quality Criteria Checklist below.

To investigate the effect of exercise intensities on post-prandial lipemia and insulin resistance in middle-aged men with metabolic syndrome. We hypothesized that exercising at a higher intensity would more effectively attenuate a fat-rich meal-induced post-prandial lipemia and reduce insulin resistance than low intensity.

• Sedentary males with metabolic syndrome
• Provided informed consent
• Characteristics of metabolic syndrome were:
  • Fasting TG of 150mg per dL or more
  • HOMA-IR more than 2.5
  • BMI 30kg/m² or more
  • Waist-to-hip ratio higher than 0.90
• Based on the classification by the World Health Organization, the subjects had characteristics of metabolic syndrome.

Not described.

Design

Randomized crossover trial.

Blinding Used

Implied with measurements.

Intervention

• Exercise trials: Each subject performed a control trial (no exercise) and three exercise trials at 40%, 60% and 70% of their VO_2max. The order of the trials was randomized and there were one to two weeks wash-out period between the trials. All subjects had a fat-rich meal in each trial.
• In the exercise trials, subjects jogged on a treadmill for one hour at a designated intensity 12 hours prior to a fat meal ingestion
• The milkshake composed of a combination of 270ml of whipping cream and 65g of specialty ice cream with walnuts (980kcal, 100g fat, 17g carbohydrates and 3g protein).

Statistical Analysis

• A two-way (trial x time) analysis of variance (ANOVA) with repeated-measures was performed to test the effects of exercise intensities on TG and insulin data
• The magnitude of total TG response was also quantified as TG AUC score (the area score under TG concentration curve over an eight-hour period) according to the trapezoidal rule
• TG AUC score is a conventional index indicating plasma TG response to a fat-meal intake
• Data of TG AUC score, fasting glucose and HOMA-IR were analyzed using one-way ANOVA with repeated measures
• An ANOVA with significant F ratios (P<0.05) was followed by Tukey post-hoc tests
• SAS software was used to perform the analysis
• All data are reported as means ±SE.

Timing of Measurements

• At initial visit, body mass index (BMI), body composition and waist-to-hip ratio were measured
• After the initial assessment, subjects performed a VO_2max test
• During each trial, blood samples were taken at zero hours (before the meal) and two, four, six and eight hours after the meal
• There were one to two weeks wash-out period between the trials.

 Dependent Variables

• Post-prandial hypertriglyceridemia (PPL) and insulin resistance: Ten ml of blood were drawn for each sample and collected in a vacutainer containing EDTA. Blood samples were separated by centrifugation at 4° Celsius for 15 minutes at 2,000g. Plasma TG and cholesterol concentrations were measured enzymatically using diagnostic kits.
• Plasma glucose levels were measured using a diagnostic kit
• Insulin levels were analyzed using a radioimmunoassays
• Total HDL-C was measured by precipitating apolipoprotein B-containing lipoproteins with heparin-MnCl₂ 
• HOMA-IR was calculated using Microsoft Excel based HOMA-IR calculator provided by the Oxford Center for Diabetes, Endocrinology and Metabolism
• The intra-assay coefficients of variation for TG, total cholesterol, HDL-C, glucose and insulin were 1.5%, 0.8%, 1.4%, 1.9% and 2.8% respectively
• Body composition was assessed using the sum of three skin-fold measurements specific for males (chest, abdomen and thigh). The mean of three measurements at each site was used to estimate body density and percent body fat.

Independent Variables

• Exercise trials: Each subject performed a control trial (no exercise) and three exercise trials at 40%, 60% and 70% of their VO_2max
• In the exercise trials, subjects jogged on a treadmill for one hour at a designated intensity 12 hours prior to a fat-meal ingestion
• All subjects had a fat-rich meal in each trial. The milkshake composed of a combination of 270ml of whipping cream and 65g of specialty ice cream with walnuts (980kcal, 100g fat, 17g carbohydrates and 3g protein).

• Initial N:10 men
• Attrition (final N): 10 men
• Age: Mean age 40.1+2.2 years
• Anthropometrics:
  • Mean body mass index (kg/m²) 31.3±1.3
  • Mean fasting triglycerides (mg per dL) 263±25
• Location: San Antonio, Texas.

Key Findings

• The fasting plasma glucose concentration in the 70% intensity was lower than the non-exercise control (P=0.004), whereas 40% and 60% intensities did not elicit such glucose-lowering effects
• The TG AUC score in 40%T was 30% lower (P=0.003), 60%T was 31% lower (P=0.02) and 70%T was 39% lower (P=0.02) than control
• There were no significant differences in the TG AUC scores among the exercise trials (P>0.05)
• The insulin concentrations in both 60%T and 70%T were lower than Control (P<0.01), which did not differ from 40%T
• HOMA-IR in both 60% T (P=0.041) and 70%T (P=0.002) were lower than Control but not different from 40% T (HOMA-IR: Control=3.05±0.40, 40%T=2.67±0.35, 60%T=2.49±0.31, 70%T=2.21±0.27).

 

 

 

 

The results from this study demonstrate that exercising at 40, 60, or 70% VO₂ max prior to a fat-rich meal ingestion noticeably attenuates postprandial lipemia response in subjects with the metabolic syndrome.  These findings suggest that for physically inactive individuals with metabolic syndrome exercising at low to moderate intensity may be sufficient to attenuate postprandial lipemia and increase insulin sensitivity, whereas higher intensity exercise may be needed to normalize blood glucose.  These data may provide an exercise-oriented therapeutic measure to individuals with metabolic syndrome.

Not-for-profit

American Heart Association grant # 0150795Y Other non-profit:

Small sample size. Only men were studied.