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Body Composition Matters When Designing and Prescribing HIIT Protocols to Individuals for Health Promotion

Authors:

Julien Steven Baker ,

Hong Kong Baptist University, Center for Health and Exercise Science Research, HK
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Binh Quach,

Hong Kong Baptist University, Center for Health and Exercise Science Research, HK
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Jiao Jiao,

Hong Kong Baptist University, Center for Health and Exercise Science Research, HK
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Wei Liang,

Hong Kong Baptist University, Center for Health and Exercise Science Research, HK
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Yang Gao

Hong Kong Baptist University, Center for Health and Exercise Science Research, HK
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Abstract

Many experimental studies use the quantification of aerobic and anaerobic ability as performance indicators and as injury rehabilitative measures. The measurement of aerobic performance can be quantified by the volume of oxygen consumed while exercising sub-maximally or at maximum capacity or intensity. Recently, high intensity interval training (HIIT) has emerged as a sustainable and effective method for improving cardiorespiratory fitness (CRF). HIIT has been proven to produce equal or greater improvements in cardio respiratory fitness (CRF) when compared to moderate intensity continuous exercise. HIIT has been described as an intermittent exercise period of short intense training bouts interspersed by different recovery periods. Whether using continuous aerobic or intermittent anaerobic training protocols to develop increased exercise capacity, the quantification of the active muscle mass contributing to the measurement outcome is important. Here we suggest that outcome measures should be based on lean tissue mass and not total body composition when examining individual responses to aerobic and anaerobic training protocols.
How to Cite: Baker, J. S., Quach, B., Jiao, J., Liang, W., & Gao, Y. (2020). Body Composition Matters When Designing and Prescribing HIIT Protocols to Individuals for Health Promotion. Physical Activity and Health, 4(1), 158–161. DOI: http://doi.org/10.5334/paah.68
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  Published on 01 Dec 2020
 Accepted on 06 Nov 2020            Submitted on 17 Oct 2020

Many experimental studies use the quantification of aerobic ability/cardiorespiratory fitness as an indicator of the health status of individuals (Ingle et al. 2020). Aerobic ability and capacity have also been used as a rehabilitative measure for cardiac event patients (Chirico et al. 2020), and as a method of relaxation training for cancer survivors (Cohen et al. 2020). The measurement of aerobic performance can be quantified by the volume of oxygen consumed while exercising sub-maximally or at maximum capacity or intensity. VO2max is defined as the maximum amount of oxygen in millilitres, used in one minute per kilogram of body weight. Aerobic ability and capacity is a primary factor for most types of sports and is powerfully correlated and related to the health status of individuals. Recently, high intensity interval training (HIIT) has emerged as a sustainable and effective method for improving cardiorespiratory fitness (CRF) in adolescents. HIIT has been proven to produce equal or greater improvements in CRF when compared to moderate intensity continuous exercise (Martin et al. 2020). HIIT has been described as an intermittent exercise period of short intense training bouts interspersed by different recovery periods. Two main forms of HIIT exist, and are collectively referred to as ‘high-intensity training (HIT)’ and ‘sprint interval training (SIT), respectively. HIT incorporates bouts of close to maximum intensity exercise performed between one to several minutes at between >80% peak oxygen uptake (or VO2peak) to <100% VO2peak, with several minutes of low-intensity recovery observed between sets (Wun et al. 2020). A typical example of the traditional SIT exercise protocol employs the Wingate anaerobic cycle ergometer test (WAnT) which consists of one or more 30-s or 10-s bouts of ‘all-out’ or supramaximal efforts (>100% VO2peak). The WAnT has also been classified as the ‘gold standard’ in the assessment of anaerobic power and capacity (Inbar et al. 1996). In relation to this, we read with interest the technical report by Savonen et al. (2012) published in the International Journal of Obesity, and were particularly interested in the section which stated that cardiorespiratory fitness is currently estimated by dividing maximal oxygen consumption (VO2max) by body weight (per-weight standard). The paper further suggested that the statistically correct way to neutralize the effect of weight on VO2max in each population was to perform an adjustment for body weight using regression techniques (adjusted standard). The paper also stated that the objective of the study was to quantify the bias introduced by the per-weight standard in a population distributed across different categories of body mass. The paper concluded that in comparisons across different categories of body mass, the per-weight standard systematically underestimated cardiorespiratory fitness in obese subjects. Use of the per-weight standard was seen to markedly inflate associations between poor fitness and co-morbidities of obesity. Further to this, Welshman et al. (2019) investigated the treadmill determined peak oxygen uptake data to examine whether traditional per body mass (ratio) scaling appropriately controls for body size differences in youth. Using simple methods based on correlation and regression analysis, they observed that the statistical relationship, which is assumed in ratio scaling, is not met in groups of similar aged young people. Their findings demonstrate how sample size and composition can influence relationships between body mass and peak oxygen uptake and show that mass exponent derived from log-linear regression effectively remove the effect of body mass. Because of the spurious conclusions based on the assessment of aerobic performance using different experimental and statistical methodologies, we would like to comment on the measurement of anaerobic ability in overweight and obese subjects. This is particularly relevant today and because of the popularity of high intensity exercise protocols has implications for obese populations and for populations with underlying co-morbidities. We feel that correct exercise prescription and assessment of anaerobic performance is as important as aerobic quantification and is relevant in relation to the study of exercise responses in the obese and overweight. This is particularly true if we are to effectively combat the current obesity epidemic. We also feel that valid and reliable measures are crucial for diagnostic credibility when evaluating success in training programme design in relation to related blood biochemistry and subsequent post exercise performance and evaluation.

High-intensity cycle ergometry has been widely employed previously to assess indices of muscle performance during maximal exercise. Traditionally, the resistive force established for such a test is determined for the WAnT using resistive forces calculated from total body mass (TBM) multiplied by a ratio standard, e.g.: 75g.kg-1 × TBM.

McInnis and Balady (1999) observed that individuals who weigh the same might have very different body compositions that include variations in lean body mass and fat content. Van mil et al. (1996) recommended that optimal performance during high intensity cycle ergometry was highly related to an individual’s fat-free mass (FFM), or to the mass of the muscles that are contributing to the test. Inbar et al. (1996) have suggested that FFM or active muscle mass may provide a more realistic assessment of anaerobic ability during high intensity exercise performance. These statements agree with the earlier suggestions of Wilkie (1960) who stated that resistive forces used during cycle ergometry should be matched as closely as possible to active muscle output.

Body mass and not the composition is the frequently used index to determine resistive force selection during high-intensity cycle ergometer exercise, and because power is the product of both resistive force and velocity, over- or under-estimations in power performance and assessment may occur. This may be particularly pronounced in overweight populations where resistive forces based on TBM may overestimate the capacity of the active muscle mass that contributes to the performance of the test.

Baker and Davies (2006) investigated the anaerobic potential of an overweight and obese population using two resistive force selection procedures namely, TBM and FFM. The TBM resistive force protocol was inclusive of the fat component of body composition, whereas the FFM protocol was not. The study examined maximal exercise performance during friction broken cycle ergometry of 10 s duration. Subjects were assigned in a random fashion to either the TBM or FFM experimental protocol. Eleven apparently healthy male university students (age: 22.3 ± 2 yrs; % body fat: 27.1 ± 2 %; determined hydrostatically) participated in the study (see Tables 1 and 2). A large significant difference (P < 0.01) in peak power output (PPO) was recorded between the TBM and FFM experimental conditions (1029 ± 98 W in TBM vs. 1397 ± 146 W in FFM). The findings of the study indicated that greater peak power outputs were obtainable when resistive forces reflected FFM as opposed to TBM. These results have implications similar to those of Savonen et al. (2012) and indicate that the assessment of exercise performance should relate to the active muscle tissues performing the task. This finding is extremely important to accurately assess effective exercise prescription, diagnostic capacity, clinical examination, and associated biochemistry in overweight and obese individuals. The findings also suggest that resistive force selection methods used in the assessment of anaerobic performance need to be reconsidered in obese and healthy populations, when anaerobic ability is the diagnostic measure of interest.

Table 1

Age and anthropometric characteristics of subjects (N = 11).


Means ± SD

Age (yrs) 22.3 ± 2
Stature (cms) 188.5 ± 7
TBM (kg) 100 ± 5
% Fat 27.1 ± 2
FFM (kg) 73.2 ± 5

Table 2

Descriptive analysis of cycle ergometer test results (N = 11).


TBM
Means ± SD
FFM
Means ± SD
P value

PPO (W) 1029 ± 98 1397 ± 146 < 0.01
T to PPO (s) 4 ± 1.4 2 ± 1 < 0.01
R/f (kg) 7.5± 0.4 5.5 ± 0.4 < 0.01
P/revs (rpm) 98 ± 8 139 ± 6 < 0.01
HR (bpm) pre 68 ± 10 66 ± 11 > 0.05
HR (bpm) post 167 ± 8 165 ± 8 > 0.05

In summary, to achieve more effective and reliable exercise treatment effects, more scientific consideration needs to be implemented in relation to body composition when designing HIIT exercise programs and prescribing relevant exercise protocols. This is particularly important and necessary, especially when targeting overweight and obese individuals as experimental subjects.

Key

PPO Peak power output
T to PPO Time to peak power output
R/f Resistive force
P/revs Pedal revolutions
HR Heart Rate

Competing Interests

The authors have no competing interests to declare.

References

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  2. Chirico, D., Davidson, T. W., Terada, T., Scott, K., Keast, M. L., Reid, R. D., Pipe, A. L., & Reed, J. L. (2020). Using the 6-min walk test to monitor peak oxygen uptake response to cardiac rehabilitation in patients with heart Failure. Journal of Cardiopulmonary Rehabilitation and Prevention, - Volume Publish Ahead of Print – Issue -. DOI: https://doi.org/10.1097/HCR.0000000000000517 

  3. Cohen, J., Rogers, W. A., Petruzzello, S., Trinh, L., & Mullen, S. P. (2020). Acute effects of aerobic exercise and relaxation training on fatigue in breast cancer survivors: A feasibility trial. Psycho-Oncology. DOI: https://doi.org/10.1002/pon.5561 

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  6. Martin-Smith, R., Cox, A., Buchan, D. S., Baker, J. S., Grace, F., & Sculthorpe, N. (2020). High intensity interval training (HIIT) improves cardiorespiratory fitness (CRF) in healthy, overweight and obese adolescents: a systematic review and meta-analysis of controlled studies. International Journal of Environmental Research and Public Health, 17(8), 2955. DOI: https://doi.org/10.3390/ijerph17082955 

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  9. Van mil, E., Schoeber, N., Calvert, R., & Bar-Or, O. (1996). Optimization of force in the Wingate Test for children with a neuromuscular disease. Medicine and Science in Sport and Exercise, 28(9), 1087–92. DOI: https://doi.org/10.1097/00005768-199609000-00002 

  10. Welsman, J., & Armstrong, N. (2019). Interpreting Aerobic Fitness in Youth: The Fallacy of Ratio Scaling. Pediatric Exercise Science, 31(2), 184–190. DOI: https://doi.org/10.1123/pes.2018-0141 

  11. Wilkie, D. R. (1960). Man as a source of mechanical power. Ergonomics, 3, 1–8. DOI: https://doi.org/10.1080/00140136008930462 

  12. Wun, C. H., Zhang, M. J., Ho, B. H., McGeough, K., Tan, F., & Aziz, A. R. (2020). Efficacy of a six-week dispersed Wingate-cycle training protocol on peak aerobic power, leg strength, insulin sensitivity, blood lipids and quality of life in healthy adults. International Journal of Environmental Research and Public Health, 17(13), 4860. DOI: https://doi.org/10.3390/ijerph17134860 

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