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The Importance, Challenges, and Developments of Biomechanical Load Measurements in Multidirectional Sports. 🔗 https://t.co/u2ZE9G6LF1 FIGURE 4| Two examples of structural load measurement devices that are field-viable. Left:  a shear wave tensiometer for directly measuring

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The Importance, Challenges, and Developments of Biomechanical Load Measurements in Multidirectional Sports 🔗 https://t.co/u2ZE9G6LF1 FIGURE 3| An example of in vitro mechanical testing for bone samples exposed to various running-specific loading profiles (Loundagin et al.,

The Importance, Challenges, and Developments of Biomechanical Load Measurements in Multidirectional Sports 🔗 https://t.co/u2ZE9G6LF1 FIGURE 2 | Overview of biomechanical load metrics. The feasibility of measuring various load metrics is indicated on the y-axis, and ranges from

The Importance, Challenges, and Developments of Biomechanical Load Measurements in Multidirectional Sports 🔗 https://t.co/u2ZE9G6LF1 FIGURE 1 | Schematic representation of the distinct physiological loads and adaptations of the cardiovascular system, and the biomechanical

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📢Our Blog is Live! The Importance, Challenges, and Developments of Biomechanical Load Measurements in Multidirectional Sports🏃🏽 In this blog we explore: 🦵🏽Biomechanical loads and load-adaptation pathways 📲Emerging technologies and future directions for field-based monitoring

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/3ODArMufZj Figure 9| Hamstring related performance changes post repeated sprints (A) and individual pelvic movement changes (B). Adapted from Carmona et al. 24. MVIC:

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/NS5FHl0yQY Figure 8| The relationship between creatine kinase recovery and gastrocnemius stretch reflex recovery from a fatiguing SSC task Author: @lahti_johan 🧑‍🏫

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/NS5FHl0yQY Figure 7| GRF and kinematic changes during stance at maximal velocity from one participant during a non-fatigued state and a fatigued state from separate

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/NS5FHl0yQY Figure 6| Ground Reaction Force profiles of a sprint (A) and drop jump from 50 cm, completed pre- and post a full marathon Author: @lahti_johan 🧑‍🏫

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/NS5FHl0yQY Figure 5| Muscle energy absorption capacity during a non-fatigued and fatigued state. Author: @lahti_johan 🧑‍🏫 #Biomechanics #Sprinting #Hamstrings

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/NS5FHl0yQY Figure 4| Typical traces of fatigue seen in SSC studies from different variables, adapted from Nicol et al. All measurements are done on the triceps surae and

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Injury Risk. 🔗 https://t.co/NS5FHl0yQY FIGURE 3| Progression of SSC fatigue. Adapted from Komi et al. RFD: Rate of force development, MVC: Maximal voluntary contraction. ⚡️ Author: @lahti_johan 🧑‍🏫

Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Risk Injury. FIGURE 2 | Distribution of hamstring injuries in football during the first and second half. A) Distribution of hamstring injuries, B) distribution of Biceps Femoris LH, Semitendinosus,

✅NEW BLOG! Effects of Fatigue Induced by Sprinting on Biomechanics and Potential Hamstring Risk Injury. FIGURE 1 | Hip and Knee joint power (A) and hamstring MTU length (B) during maximal sprinting 🏃🏽 Author: @lahti_johan ✍🏽 🔗 https://t.co/3ODArMufZj #Biomechanics