Velocity- Based Approach to Strength Training: A Traditional Review

Yıl 2024, Cilt: 2 Sayı: 2, 1 - 12, 31.12.2024

Eda Baytaş , Mesut Tükenmez , Ezgi Ayaz

Öz

Velocity-based strength training is utilized by strength and conditioning coaches to assess athletes' strength loads in real-time. The main issues encountered in traditional strength training include the variability of athletes' daily one-repetition maximum (1-RM) strength and the decreasing validity of classical training methods due to technological advancements. This situation has prompted researchers to develop various new methods.
As an alternative to traditional strength training loads, velocity-based strength training (SBST) has been developed due to fluctuations in athletes' daily 1-RM strength. SBST allows for the use of data in strenght training. This review aims to examine the neuromuscular and physiological responses of speed-based approaches, highlighting their advantages and disadvantages while providing a guiding framework for velocity-based training systems.
The systems used to monitor movement speed today emphasize a speed-based approach rather than load tracking. The characteristics, advantages, and disadvantages of the systems used are discussed in detail.

Kuvvet Antrenmanlarına Hız Temelli Yaklaşım: Geleneksel Derleme

Öz

Hız temelli kuvvet antrenmanları, kuvvet kondisyonerleri tarafından sporcuların kuvvet yüklerini anlık olarak değerlendirmek amacıyla kullanılmaktadır. Geleneksel kuvvet antrenmanlarında karşılaşılan başlıca problemler, sporcuların günlük 1-TM (bir tekrar maksimum) kuvvetlerinin değişkenlik göstermesi ve teknolojinin gelişmesiyle birlikte klasik antrenman yöntemlerinin geçerliliğinin azalmasıdır. Bu durum, araştırmacıları farklı yeni metotlar geliştirmeye yöneltmiştir. Geleneksel kuvvet antrenmanlarında uygulanan yüklerin, sporcuların günlük 1-TM kuvvetindeki dalgalanmalar nedeniyle, alternatif bir yöntem olarak hız temelli kuvvet antrenmanı (HTKA) geliştirilmiştir. HTKA, direnç antrenmanlarında veri olarak kullanılmasına olanak tanımaktadır. Bu derleme, hız temelli yaklaşımların nöromüsküler ve fizyolojik yanıtlarını incelemek; avantajlı ve dezavantajlı yönlerini ele alarak hız temelli antrenman sistemlerini kılavuz niteliğinde sunmayı amaçlamıştır. Hareket hızının izlenmesi için kullanılan sistemler, günümüzde yük takibi yerine hız temelli yaklaşımı ön plana çıkarmaktadır. Kullanılan sistemlerin özellikleri, avantajları ve dezavantajları detaylı bir şekilde ele alınmıştır.

Anahtar Kelimeler

Kuvvet antrenmanı, hız temelli antrenman, hız temelli performans analizi, antrenman optimizasyonu

Kaynakça

• Aagaard, P. (2003). Training-induced changes in neural function. Exercise and Sport Sciences Reviews, 31(2), 61-67.
• Ahmad, N., Ghazilla, R. A. R., Khairi, N. M., & Kasi, V. (2013). Reviews on various inertial measurement unit (IMU) sensor applications. International Journal of Signal Processing Systems, 1(2), 256-262.
• Andersen, L. L., Andersen, J. L., Zebis, M. K., & Aagaard, P. (2010). Early and late rate of force development: differential adaptive responses to resistance training?. Scandinavian journal of medicine & science in sports, 20(1), e162-e169.
• Atabaş, E. G. (2022). Hıza dayalı ve geleneksel kuvvet antrenmanlarının bazı fizyolojik ve motorik özellikler üzerine etkisinin karşılaştırılması. Pamukkale Üniversitesi, Sağlık Bilimleri Enstitüsü, (Tez Danışmanı: Doç. Dr. Ayşegül Yapıcı). Denizli.
• Aydos, L, Pepe, H. ve Karakuş, H. (2004). “Bazı Takım ve Ferdi Sporlarda Relatif Kuvvet Değerlerinin Araştırılması”. Gazi Üniversitesi Kırşehir Eğitim Fakültesi Dergisi, 5(2), 305-315
• Balsalobre-Fernández, C., & Torres-Ronda, L. (2021). The implementation of velocity-based training paradigm for team sports: framework, technologies, practical recommendations and challenges. Sports, 9(4), 47.
• Balsalobre-Fernández, C., Marchante, D., Baz-Valle, E., Alonso-Molero, I., Jiménez, S. L., & Muñóz-López, M. (2017). Analysis of wearable and smartphone-based technologies for the measurement of barbell velocity in different resistance training exercises. Frontiers in Physiology, 8, 649.
• Bazuelo-Ruiz, B., Padial, P., Garcia-Ramos, A., Morales-Artacho, A. J., Miranda, M. T., & Feriche, B. (2015).
• Predicting Maximal Dynamic Strength From the Load- Velocity Relationship in Squat Exercise. Journal of Strength and Conditioning Research, 29(7), 1999-2005.
• Behm, D. G., & Sale, D. G. (1993). Velocity specificity of resistance training. Sports Medicine, 15(6), 374-388. Bompa, T. O. (2007). Antrenman kuramı ve yöntemi, Spor Yayınevi ve Kitabevi. Baskı, Ankara.
• Buchheit, M., & Laursen, P. B. (2013). High-Intensity Interval Training, Solutions to the Programming Puzzle. Sports Medicine, 43(5), 313-338.
• Clarkson, P. M., & Hubal, M. J. (2002). Exercise-induced muscle damage in humans. American Journal of Physical Medicine & Rehabilitation, 81(11), 52-S69.
• Clemente, F. M., Akyildiz, Z., Pino-Ortega, J., & Rico-González, M. (2021). Validity and reliability of the inertial measurement unit for barbell velocity assessments: A systematic review. Sensors, 21(7), 2511
• Cormie, P., McBride, J. M., & McCaulley, G. O. (2007). Power-time, force-time, and velocity-time curve analysis of the countermovement jump: Impact of training. Journal of Strength and Conditioning Research, 21(3), 763–769. https://doi.org/10.1519/R-22436.1
• Cormie, P., McGuigan, M. R., & Newton, R. U. (2010). Adaptations in athletic performance after ballistic power versus strength training. Medicine & Science in Sports & Exercise, 42(8), 1582-1598.
• Cunanan, A. J., DeWeese, B. H., Wagle, J. P., Carroll, K. M., Sausaman, R., Hornsby, W. G., ... & Stone, M. H. (2018). The general adaptation syndrome: a foundation for the concept of periodization. Sports Medicine, 48, 787-797.
• Çetin, O., Kaya, S., Sungur, Y., & Demirtaş, B. (2022). Direnç Antrenmanlarına Güncel Yaklaşım: Hız Temelli Antrenman: Geleneksel Derleme. Türkiye Klinikleri Journal of Sports Sciences, 14(1).
• Dahlin, M. (2018). The use of velocity-based training in strength and power training - A systematic review (Dissertation).
• Devaney, J. M., Hoffman, E. P., Gordish-Dressman, H., Kearns, A., Zambraski, E., & Clarkson, P. M. (2007). IGF-II gene region polymorphisms related to exertional muscle damage. Journal of applied physiology, 102(5), 1815-1823.
• Galiano, C., Pareja-Blanco, F., de Mora, J. H., & de Villarreal, E. S. (2022). Low-velocity loss induces similar strength gains to moderate-velocity loss during resistance training. The Journal of Strength & Conditioning Research, 36(2), 340-345.
• Garcı´a-Ramos A, Pestan˜a-Melero FL, Pe´rez-Castilla A, Rojas FJ, Gregory Haff G. (2018). Mean velocity vs. Mean propulsive velocity vs. Peak velocity: Which variable determines bench press relative load with higher reliability? J Strength Cond Res 32: 1273–1279.
• González-Badillo, J. J., & Sánchez-Medina, L. (2010). Movement velocity as a measure of loading intensity in resistance training. International Journal of Sports Medicine, 31(05), 347-352.
• Gonzalez-Badillo, J. J., & Yanez-Garcia, J. M. (2017). Velocity loss as a variable for monitoring resistance exercise. International Journal of Sports Medicine, 38(3), 217-225.
• Häkkinen, K., & Komi, P. V. (1986). Effects of explosive strength training on physical performance and muscle structure in male and female athletes. International Journal of Sports Medicine, 7(3), 197-204.
• Harris, N. K., Cronin, J., Taylor, K. L., Boris, J., & Sheppard, J. (2010). Understanding position transducer technology for strength and conditioning practitioners. Strength & Conditioning Journal, 32(4), 66-79.
• Held, S., Speer, K., Rappelt, L., Wicker, P., & Donath, L. (2022). The effectiveness of traditional vs. velocity-based strength training on explosive and maximal strength performance: A network meta-analysis. Frontiers in physiology, 13, 926972.
• Hubal, M. J., Devaney, J. M., Hoffman, E. P., Zambraski, E. J., Gordish-Dressman, H., Kearns, A. K., ... & Clarkson, P. M. (2010). CCL2 and CCR2 polymorphisms are associated with markers of exercise-induced skeletal muscle damage. Journal of applied physiology, 108(6), 1651-1658.
• Kim, J., & Lee, J. (2015). The relationship of creatine kinase variability with body composition and muscle damage markers following eccentric muscle contractions. Journal of exercise nutrition & biochemistry, 19(2), 123.
• Lahti, J., Jiménez-Reyes, P., Cross, M. R., Samozino, P., Chassaing, P., Simond-Cote, B., ... & Morin, J. B. (2020). Individual sprint force-velocity profile adaptations to in-season assisted and resisted velocity-based training in professional rugby. Sports, 8(5), 74.
• Maffiuletti, N. A. (2010). Physiological and methodological aspects of neuromuscular electrical stimulation. European Journal of Applied Physiology, 110(2), 223-234.
• Mann, J. Bryan, CSCS1,2; Ivey, Patrick A. Sayers, Stephen P. (2015). Velocity-Based Training in Football. Strength and Conditioning Journal 37(6), 52-57. DOI: 10.1519/SSC.0000000000000177.
• McArdle, W. D., Katch, F. I., & Katch, V. L. (2010). Exercise Physiology: Nutrition, Energy, and Human Performance. Lippincott Williams & Wilkins.
• McBurnie, A. J., Allen, K. P., Garry, M., Martin, M., Jones, P. A., Comfort, P., & McMahon, J. J. (2019). The benefits and limitations of predicting one repetition maximum using the load-velocity relationship. Strength & Conditioning Journal, 41(6), 28-40.
• Orser, K., Agar-Newman, D. J., Tsai, M. C., & Klimstra, M. (2020). The validity of the Push Band 2.0 to determine speed and power during progressively loaded squat jumps. Sports Biomechanics, 23(1), 109–117. https://doi.org/10.1080/14763141.2020.1829691
• Özkaya, G., Jung, H. R., Jeong, I. S., Choi, M. R., Shin, M. Y., Lin, X., ... & Lee, K. K. (2018). Three-dimensional motion capture data during repetitive overarm throwing practice. Scientific data, 5(1), 1-6.
• Padulo, J., Mignogna, P., Mignardi, S., Tonni, F., & D’ottavio, S. (2012). Effect of different pushing speeds on bench press. International journal of sports medicine, 33(05), 376-380.
• Pareja-Blanco, F., Sánchez-Medina, L., Suárez-Arrones, L., & González-Badillo, J. J. (2017). Effects of velocity loss during resistance training on performance in professional soccer players. International journal of sports physiology and performance, 12(4), 512-519.
• Pareja-Blanco f, Alcazar J, sánchez-Valdepe-as J, Cornejo-Daza PJ, Piqueras-sanchiz f, Mora-Vela R, et al. (2020). Velocity loss as a critical variable determining the adaptations to strength training. Med sci sports Exercise. 52(8):1752-62.
• Peake, J. M., Suzuki, K., Wilson, G., Hordern, M., Nosaka, K., Mackinnon, L., & Coombes, J. S. (2005). Exercise-induced muscle damage, plasma cytokines, and markers of neutrophil activation. Medicine and science in sports and exercise, 37(5), 737-745.
• Perez-Castilla, A., Piepoli, A., Delgado-García, G., Garrido-Blanca, G., & García-Ramos, A. (2019). Reliability and concurrent validity of seven commercially available devices for the assessment of movement velocity at different intensities during the bench press. The Journal of Strength & Conditioning Research, 33(5), 1258-1265.
• Randell, A. D., Cronin, J. B., Keogh, J. W., Gill, N. D., & Pedersen, M. C. (2011). Effect of instantaneous performance feedback during 6 weeks of velocity-based resistance training on sport-specific performance tests. The Journal of Strength & Conditioning Research, 25(1), 87-93.
• Rojas-Jaramillo, A., León-Sánchez, G., Calvo-Lluch, Á., González-Badillo, J. J., & Rodríguez-Rosell, D. (2024). Comparison of 10% vs. 30% Velocity Loss during Squat Training with Low Loads on Strength and Sport-Specific Performance in Young Soccer Players. Sports, 12(2), 43.
• Ronnestad, B. R., Kvamme, N. H., Sunde, A., & Raastad, T. (2008). Short-term effects of strength and plyometric training on sprint and jump performance in professional soccer players. The Journal of Strength & Conditioning Research, 22(3), 773-780.
• Rossi, C., Vasiljevic, I., Manojlovic, M., Trivic, T., Ranisavljev, M., Stajer, V., ... & Drid, P. (2024). Optimizing strength training protocols in young females: A comparative study of velocity-based and percentage-based training programs. Heliyon, 10(9).
• Sanchez-Medina, L., & González-Badillo, J. J. (2011). Velocity loss as an indicator of neuromuscular fatigue during resistance training. Medicine and science in sports and exercise, 43(9), 1725-1734.
• Sekulović, V., Jezdimirović-Stojanović, T., Andrić, N., Elizondo-Donado, A., Martin, D., Mikić, M., & Stojanović, M. D. (2024). Effects of In-Season Velocity-Based vs. Traditional Resistance Training in Elite Youth Male Soccer Players. Applied Sciences, 14(20), 9192.
• Soslu R., Çuvalcıoğlu, İ. Hıza dayalı direnç antrenmanları: Kuvvet ve güç performansını etkiler mi? INSAC Acad Stu on Health Sci 2021, 24.
• Spiteri, T., Cochrane, J. L., Hart, N. H., Haff, G. G., & Nimphius, S. (2013). Effect of strength on plant foot kinetics and kinematics during a change of direction task. European journal of sport science, 13(6), 646-652.
• Suchomel, T. J., Nimphius, S., & Stone, M. H. (2016). The importance of muscular strength in athletic performance. Sports medicine, 46, 1419-1449.
• Tomasevicz, C. L., Hasenkamp, R. M., Ridenour, D. T., & Bach, C. W. (2020). Validity and reliability assessment of 3-D camera-based capture barbell velocity tracking device. Journal of science and medicine in sport, 23(1), 7-14.
• Weakley, J. J., Till, K., Read, D. B., Leduc, C., Roe, G. A., Phibbs, P. J., ... & Jones, B. (2021b). Jump training in rugby union players: barbell or hexagonal bar?. The Journal of Strength & Conditioning Research, 35(3), 754-761.
• Weakley, J. J., Till, K., Read, D. B., Roe, G. A., Darrall-Jones, J., Phibbs, P. J., & Jones, B. (2017). The effects of traditional, superset, and tri-set resistance training structures on perceived intensity and physiological responses. European journal of applied physiology, 117, 1877-1889.
• Weakley, J., Chalkley, D., Johnston, R., García-Ramos, A., Townshend, A., Dorrell, H., ... & Cole, M. (2020). Criterion validity, and interunit and between-day reliability of the FLEX for measuring barbell velocity during commonly used resistance training exercises. The Journal of Strength & Conditioning Research, 34(6), 1519-1524.
• Weakley, J., Mann, B., Banyard, H., McLaren, S., Scott, T., & Garcia-Ramos, A. (2021a). Velocity-based training: From theory to application. Strength & Conditioning Journal, 43(2), 31-49.
• Weakley, J., McLaren, S., Ramirez-Lopez, C., García-Ramos, A., Dalton-Barron, N., Banyard, H., ... & Jones, B. (2020). Application of velocity loss thresholds during free-weight resistance training: Responses and reproducibility of perceptual, metabolic, and neuromuscular outcomes. Journal of Sports Sciences, 38(5), 477-485.
• Weakley, J., Munteanu, G., Cowley, N., Johnston, R., Morrison, M., Gardiner, C., ... & García-Ramos, A. (2023). The criterion validity and between-day reliability of the perch for measuring barbell velocity during commonly used resistance training exercises. The Journal of Strength & Conditioning Research, 37(4), 787-792.
• Zhang, X., Feng, S., Peng, R., & Li, H. (2022). The role of velocity-based training (VBT) in enhancing athletic performance in trained individuals: A meta-analysis of controlled trials. International journal of environmental research and public health, 19(15), 9252.