High Intensity Interval Training Clinical Trial
Official title:
The Effects of Low-Volume High Intensity Interval Training and Circuit Training on Maximal Oxygen Uptake
High intensity interval training (HIIT) and circuit training (CT) are popular methods of exercise, eliciting improvements in cardiorespiratory fitness (CRF). However direct comparisons of these two training methods are limited.
Study Design Participants were enrolled in a randomised control trial at the University of
Hull to either eight weeks of High intensity interval training (HIIT) or Circuit Training
(CT) (two supervised sessions per week, accompanied by an exercise physiologist). A sample
size of 38 using G Power 3.1 software was calculated based on previously published data in
which the mean difference between HIIT and Moderate Intensity Continuous Training (MICT) was
3.2 ml.kg-1.min-1 with a pooled standard deviation of 3 ml.kg-1.min-1. Statistical
significance was set at 0.05 and power set to 0.95. To allow for 10% attrition 42 individuals
were recruited to the study. To assess the effectiveness of the interventions as determined
by maximal oxygen consumption (VO2max), a maximal cardiopulmonary exercise test (CPET) to
volitional exhaustion on an electronically braked cycle ergometer at baseline (visit one),
and following an eight-week exercise intervention of HIIT or CT (visit two) was conducted.
When attending the assessments participants were asked not to take part in any strenuous
exercise 24 hours prior to the appointment, to wear suitable comfortable clothing and avoid a
large meal. Visit two CPET was performed within six days of completing the exercise
interventions. A thorough warm-up and cool down before and after each exercise session. All
were asked to maintain their habitual physical activity patterns during the intervention.
Body mass index (BMI) was calculated by dividing body weight by height in meters squared and
was presented as kg.m-2. Resting blood pressure was measured after 15 minutes of rest using a
sphygmomanometer (A.C. Cossor & Son Ltd, London UK) and stethoscope (3M Healthcare, St Paul,
MN). To provide a comprehensive account of the study the Consensus on Exercise Reporting
Template (CERT) was consulted.
Participants Ethical approval was provided by the School of Life Sciences ethics committee at
the University of Hull which was in accordance with the 1964 Helsinki declaration and its
later amendments or comparable ethical standards. A total of 42 apparently healthy men and
women between the age of 18-65 years were recruited to the study. Enrolled individuals
reported no medical history of cardiometabolic or limiting respiratory disease, were
non-smokers, had a body mass index <30 kg.m-2, classified as recreationally active and none
were taking any medication that would affect heart rate. As a condition of enrolment, those
over 45 years obtained written medical clearance from a general practitioner and underwent
resting and exercise 12-lead electrocardiogram (ECG) (GE Healthcare, Chalfont St Giles,
United Kingdom). Written informed consent and a pre-exercise medical questionnaire was
completed by all.
Cardiopulmonary Exercise Testing Maximal CPETs were conducted in accordance with the American
Thoracic Society (ATS) and the American College of Chest Physicians (ACCP) guidelines. An
Oxycon pro (Jaeger, Hoechburg, Germany) breath by breath metabolic cart was used to collect
respiratory gas exchange data. Automatic and manual calibration evaluated ambient
temperature, humidity, barometric pressure and altitude. Calibration of the air flow volume
was conducted using a 3 litre syringe and by automatic calibration. Two-point gas calibration
was also conducted to ensure accurate measures of inspired oxygen and expired carbon dioxide.
Tests were performed on a GE e-bike ergometer (GE Healthcare, Buckinghamshire, UK) using a
ramp protocol. The protocol consisted of a three-minute rest phase, three minutes of unloaded
cycling, followed by a personalised ramp test (ramp rate ranged between 15 and 30 watts) with
work rate continually increased every one to three seconds. Participants performed the same
ramp rate pre and post testing. Participants were asked to pedal at a cadence of 70 rpm until
they reached volitional exhaustion at a protocol duration between eight to twelve minutes.
Self-reported rating of perceived exertion (RPE) scores using the 6-20 scale and heart rate
(HR) (FT1 heart rate monitor, Polar Electro, Finland) was recorded during the last five
seconds of each minute of the test, at maximum exercise and during the recovery period.
Together with verbal encouragement to volitional exhaustion, VO2max was attained by
participants achieving at least two of the following criteria, VO2 plateau as determined by a
failure of VO2 increase by 150 ml/min with further increases in workload analysed by breath
by breath gas exchange data averaged over 15 seconds, respiratory exchange ratio (RER) >
1.10, achieve > 85% age predicated heart rate maximum (HRmax) and a RPE > 17 on the 6-20 Borg
scale. VO2 at the ventilatory anaerobic threshold (VAT) was defined using the V slope method
and verified using ventilatory equivalents. Peak power output (PPO) (watts) and HRmax were
defined as the highest value achieved during the CPET with maximum oxygen and heart rate (VO2
/HR) determined by the ratio of VO2max and HRmax.
Training Interventions The HIIT group were asked to perform ten one-minute HIIT intervals,
each followed by one minute of active recovery (AR) (total exercise time 20 minutes).
Resulting from the CPET, HIIT was set at above 85% HRmax with a specific HR designated for
this criterion. Active recovery was set at a load corresponding to 25-50 watts. Sessions were
performed on a Wattbike trainer (Wattbike Ltd, Nottingham, UK). The CT group completed a
practical seven-station mixed modality exercise circuit (cycle ergometer, rower, treadmill,
sit to stand/squats, knee to elbow and leg kickback with bicep curl) at an intensity of
60-80% HRmax (calculated from CPET). No resistance equipment was involved, only body weight.
Participants initially performed 20 minutes of CT with duration increased by five minutes per
week until the desired 40 minutes. Each station was occupied for three to six minutes
depending on session duration, moving from one station to the next with minimal rest. During
both interventions, HR was measured in last 5 seconds of each station/interval using a FT1
polar heart rate monitor (Polar Electro, Finland) with each CT session timed using a stop
watch (Axprod S.L, Guipuzcoa, Spain). Intensity for both interventions was adjusted
throughout by the investigator to ensure an appropriate HR range and successful completion of
the protocol. Participants were made aware of their HR ranges and verbal encouragement was
given by the physiologist to help achieve and maintain these thresholds. Energy expenditure
between HIIT and CT was not matched.
To assess the validity of the exercise interventions, participant fidelity to the desired
exercise intensity was determined using cut points of >85% HRmax and 60-80% HRmax for HIIT
and CT respectively and reported using previous examples. These values were calculated using
the participants mean heart rate for each individual interval or station over the 16 sessions
and was expressed as a percentage of HRmax as determined by CPET at visit 1. Specific
fidelity thresholds were consulted to determine low (<50%), moderate (50-70%) and high (>70%)
compliance. Adherence was determined as a percentage of completed sessions, with 14 (> 85%)
being the threshold for completion.
Statistical Analysis Statistical analysis was conducted using Statistical Package for the
Social Sciences (SPSS) version 24 (IBM, New York, USA). An independent t-test was used to
identify group differences at baseline. Assumptions of normality were verified using the
Shapiro-Wilk test. Skewness and kurtosis of distribution was visually examined. Non-normally
distributed data was presented as median and interquartile range (IQR). A two-way (condition
x time) repeated measures analysis of variance (ANOVA) was used to compare CRF pre-and
post-training. Post-hoc analysis for the main effects and interactions was assessed using a
Bonferroni adjustment. Group differences were compared using independent t tests. Variables
were displayed as mean with 95% confidence intervals (95% CI) or standard deviation where
specified. Partial eta squared effect sizes were also calculated with 0.01, 0.06 and 0.14
representing small, medium and large effect sizes, respectively.
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