Preprint / Version 1

The effects of hip flexion angle on quadriceps femoris muscle hypertrophy in the leg extension exercise

##article.authors##

  • Stian Larsen Department of Sports Science and Physical Education, Nord University, Levanger, Norway
  • Benjamin Sandvik Kristiansen Department of Sports Science and Physical Education, Nord University, Levanger, Norway
  • Paul Alan Swinton Department of Sport and Exercise, School of Health Sciences, Robert Gordon University, Aberdeen, United Kingdom
  • Milo Wolf Faculty of Sport, Health, and Social Sciences, Solent University, Southampton, United Kingdom
  • Andrea Bao Fredriksen Department of Sports Science and Physical Education, Nord University, Levanger, Norway
  • Hallvard Nygaard Falch Department of Sports Science and Physical Education, Nord University, Levanger, Norway
  • Roland van den Tillaar Department of Sports Science and Physical Education, Nord University, Levanger, Norway
  • Nordis Østerås Sandberg Department of Sports Science and Physical Education, Nord University, Levanger, Norway

DOI:

https://doi.org/10.51224/SRXIV.407

Keywords:

knee extension, rectus femoris, vastus lateralis, hypertrophy

Abstract

This study compared the effects of resistance training on quadriceps femoris hypertrophy while sitting upright (90° hip flexion) versus recumbent (40° hip flexion) when performing the leg extension exercise with similar knee flexion range of motion. We hypothesised that ten weeks of resistance training with 40° hip flexion in the leg extension would cause greater muscle hypertrophy of the rectus femoris but not vastus lateralis compared with 90° hip flexion. Twenty-two untrained men completed a ten-week intervention comprising two resistance training sessions per week with four sets of leg extension to momentarily concentric failure. A within-participant design was used, with lower limb side randomly allocated to the 40 or 90° condition. Muscle thickness of distal and proximal rectus femoris and vastus lateralis were quantified via ultrasound. Data were analysed within a Bayesian framework including univariate and multivariate mixed effect models with random effects to account for the within participant design. Differences between conditions were estimated as average treatment effects (ATE) and inferences made based on posterior distributions and Bayes Factors (BF). Results were consistent with the a-priori hypotheses, with ‘extreme’ evidence in support of a hypertrophic response favouring the 40° hip angle for the rectus femoris (BF>100; p(Distal/ATE & Proximal/ATE >0)>0.999), and ‘strong’ evidence in support of no difference in hypertrophic response for the vastus lateralis (BF = 0.07).  Therefore, when the goal is to increase overall quadriceps femoris hypertrophy we suggest training with reduced hip flexion in the leg extension exercise.

Metrics

Metrics Loading ...

References

Baz-Valle, E., Balsalobre-Fernández, C., Alix-Fages, C., & Santos-Concejero, J. (2022). A systematic review of the effects of different resistance training volumes on muscle hypertrophy. Journal of Human Kinetics, 81(1), 199-210.

Bürkner, P.-C. (2017). brms: An R package for Bayesian multilevel models using Stan. Journal of statistical software, 80, 1-28.

Cutts, A. (1988). The range of sarcomere lengths in the muscles of the human lower limb. Journal of anatomy, 160, 79.

Cutts, A. (1989). Sarcomere length changes in muscles of the human thigh during walking. Journal of anatomy, 166, 77.

Depaoli, S., & Van de Schoot, R. (2017). Improving transparency and replication in Bayesian statistics: The WAMBS-Checklist. Psychological methods, 22(2), 240.

Gronau, Q. F., Singmann, H., & Wagenmakers, E.-J. (2017). bridgesampling: An R package for estimating normalizing constants. arXiv preprint arXiv:1710.08162.

Kipp, K., Kim, H., & Wolf, W. I. (2022). Muscle-specific contributions to lower extremity net joint moments while squatting with different external loads. Journal of Strength and Conditioning Research, 36(2), 324-331.

Kojic, F., Ranisavljev, I., Obradovic, M., Mandic, D., Pelemis, V., Paloc, M., & Duric, S. (2022). Does Back Squat Exercise Lead to Regional Hypertrophy among Quadriceps Femoris Muscles? International Journal of Environmental Research and Public Health, 19(23), 16226.

Kooistra, R., De Ruiter, C., & De Haan, A. (2008). Knee angle-dependent oxygen consumption of human quadriceps muscles during maximal voluntary and electrically evoked contractions. European journal of applied physiology, 102, 233-242.

Kubo, K., Ikebukuro, T., & Yata, H. (2019). Effects of squat training with different depths on lower limb muscle volumes. European journal of applied physiology, 119(9), 1933-1942.

Lakens, D. (2022). Sample size justification. Collabra: Psychology, 8(1), 33267.

Larsen, S., Kristiansen, E., Nygaard Falch, H., Estifanos Haugen, M., Fimland, M. S., & van den Tillaar, R. (2022). Effects of barbell load on kinematics, kinetics, and myoelectric activity in back squats. Sports biomechanics, 1-15.

Lee, M. D., & Wagenmakers, E.-J. (2014). Bayesian cognitive modeling: A practical course. Cambridge university press.

Maeo, S., Huang, M., Wu, Y., Sakurai, H., Kusagawa, Y., Sugiyama, T., Kanehisa, H., & Isaka, T. (2021). Greater hamstrings muscle hypertrophy but similar damage protection after training at long versus short muscle lengths. Medicine and science in sports and exercise, 53(4), 825.

Maeo, S., Shan, X., Otsuka, S., Kanehisa, H., & Kawakami, Y. (2018). Single‐joint eccentric knee extension training preferentially trains the rectus femoris within the quadriceps muscles. Translational Sports Medicine, 1(5), 212-220.

Maeo, S., Wu, Y., Huang, M., Sakurai, H., Kusagawa, Y., Sugiyama, T., Kanehisa, H., & Isaka, T. (2023). Triceps brachii hypertrophy is substantially greater after elbow extension training performed in the overhead versus neutral arm position. European journal of sport science, 23(7), 1240-1250.

Magezi, D. A. (2015). Linear mixed-effects models for within-participant psychology experiments: an introductory tutorial and free, graphical user interface (LMMgui). Frontiers in psychology, 6, 110312.

McMahon, G., Morse, C. I., Burden, A., Winwood, K., & Onambélé, G. L. (2014). Muscular adaptations and insulin‐like growth factor‐1 responses to resistance training are stretch‐mediated. Muscle & nerve, 49(1), 108-119.

Mendiguchia, J., Alentorn-Geli, E., Idoate, F., & Myer, G. D. (2013). Rectus femoris muscle injuries in football: a clinically relevant review of mechanisms of injury, risk factors and preventive strategies. British journal of sports medicine, 47(6), 359-366.

Mitsuya, H., Nakazato, K., Hakkaku, T., & Okada, T. (2023). Hip flexion angle affects longitudinal muscle activity of the rectus femoris in leg extension exercise. European journal of applied physiology, 123(6), 1299-1309.

Morton, R. W., Murphy, K. T., McKellar, S. R., Schoenfeld, B. J., Henselmans, M., Helms, E., Aragon, A. A., Devries, M. C., Banfield, L., &

Krieger, J. W. (2018). A systematic review, meta-analysis and meta-regression of the effect of protein supplementation on resistance training-induced gains in muscle mass and strength in healthy adults. British journal of sports medicine, 52(6), 376-384.

Ottinger, C. R., Sharp, M. H., Stefan, M. W., Gheith, R. H., de la Espriella, F., & Wilson, J. M. (2023). Muscle hypertrophy response to range of motion in strength training: a novel approach to understanding the findings. Strength and Conditioning Journal, 45(2), 162-176.

Pedrosa, G. F., Lima, F. V., Schoenfeld, B. J., Lacerda, L. T., Simões, M. G., Pereira, M. R., Diniz, R. C., & Chagas, M. H. (2022). Partial range of motion training elicits favorable improvements in muscular adaptations when carried out at long muscle lengths. European journal of sport science, 22(8), 1250-1260.

Refalo, M. C., Helms, E. R., Robinson, Z. P., Hamilton, D. L., & Fyfe, J. J. (2024). Similar muscle hypertrophy following eight weeks of resistance training to momentary muscular failure or with repetitions-in-reserve in resistance-trained individuals. Journal of sports sciences, 1-17.

Roberts, M. D., McCarthy, J. J., Hornberger, T. A., Phillips, S. M., Mackey, A. L., Nader, G. A., Boppart, M. D., Kavazis, A. N., Reidy, P. T., & Ogasawara, R. (2023). Mechanisms of mechanical overload-induced skeletal muscle hypertrophy: current understanding and future directions. Physiological reviews, 103(4), 2679-2757.

Schad, D. J., Nicenboim, B., Bürkner, P.-C., Betancourt, M., & Vasishth, S. (2022). Workflow techniques for the robust use of bayes factors. Psychological methods.

Schoenfeld. (2010). The mechanisms of muscle hypertrophy and their application to resistance training. The Journal of Strength & Conditioning Research, 24(10), 2857-2872.

Schoenfeld, Androulakis-Korakakis, P., Coleman, M., Burke, R., & Piñero, A. (2023). SMART-LD: A tool for critically appraising risk of bias and reporting quality in longitudinal resistance training interventions.

Son, J., Indresano, A., Sheppard, K., Ward, S. R., & Lieber, R. L. (2018). Intraoperative and biomechanical studies of human vastus lateralis and vastus medialis sarcomere length operating range. Journal of biomechanics, 67, 91-97.

Steele, J., Endres, A., Fisher, J., Gentil, P., & Giessing, J. (2017). Ability to predict repetitions to momentary failure is not perfectly accurate, though improves with resistance training experience. PeerJ, 5, e4105.

Swinton, P. (2024). Adequate statistical power in strength and conditioning may be achieved through longer interventions and high frequency outcome measurement.

Swinton, P. A., Burgess, K., Hall, A., Greig, L., Psyllas, J., Aspe, R., Maughan, P., & Murphy, A. (2022). Interpreting magnitude of change in strength and conditioning: Effect size selection, threshold values and Bayesian updating. Journal of sports sciences, 40(18), 2047-2054.

van de Schoot, R., Depaoli, S., King, R., Kramer, B., Märtens, K., Tadesse, M. G., Vannucci, M., Gelman, A., Veen, D., & Willemsen, J. (2021). Bayesian statistics and modelling. Nature Reviews Methods Primers, 1(1), 1.

Wakahara, T., Ema, R., Miyamoto, N., & Kawakami, Y. (2017). Inter‐and intramuscular differences in training‐induced hypertrophy of the quadriceps femoris: association with muscle activation during the first training session. Clinical physiology and functional imaging, 37(4), 405-412.

Wakahara, T., Fukutani, A., Kawakami, Y., & Yanai, T. (2013). Nonuniform muscle hypertrophy: its relation to muscle activation in training session. Medicine & Science in Sports & Exercise, 45(11), 2158-2165.

Wolf, M., Androulakis-Korakakis, P., Fisher, J., Schoenfeld, B., & Steele, J. (2023). Partial vs full range of motion resistance training: A systematic review and meta-analysis. International Journal of Strength and Conditioning, 3(1).

Zabaleta-Korta, A., Fernández-Peña, E., Torres-Unda, J., Francés, M., Zubillaga, A., & Santos-Concejero, J. (2023). Regional Hypertrophy: The Effect of Exercises at Long and Short Muscle Lengths in Recreationally Trained Women. Journal of Human Kinetics, 88.

Zabaleta-Korta, A., Fernández-Peña, E., Torres-Unda, J., Garbisu-Hualde, A., & Santos-Concejero, J. (2021). The role of exercise selection in regional Muscle Hypertrophy: A randomized controlled trial. Journal of sports sciences, 39(20), 2298-2304.

Downloads

Posted

2024-05-09

Categories

License

Copyright (c) 2024 Stian Larsen, Benjamin Sandvik Kristiansen, Paul Alan Swinton, Milo Wolf, Andrea Bao Fredriksen, Hallvard Nygaard Falch, Roland van den Tillaar, Nordis Østerås Sandberg (Author)

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

Share