about
The development of a segment-based musculoskeletal model of the lower limb: introducing FreeBodyAdjusting powerlifting performances for differences in body mass.Quantifying delayed-onset muscle soreness: a comparison of unidimensional and multidimensional instrumentation.The relationship between the number of repetitions performed at given intensities is different in endurance and strength trained athletesOn the role of the patella, ACL and joint contact forces in the extension of the knee.Lighter and heavier initial loads yield similar gains in strength when employing a progressive wave loading scheme.Hip and knee joint loading during vertical jumping and push jerking.Intersegmental moment analysis characterizes the partial correspondence of jumping and jerking.Effect of a gluteal activation warm-up on explosive exercise performance.The effect of weightlifting shoes on the kinetics and kinematics of the back squat.In Vivo Knee Contact Force Prediction Using Patient-Specific Musculoskeletal Geometry in a Segment-Based Computational Model.The sensitivity of a lower limb model to axial rotation offsets and muscle bounds at the knee.Reliability and Minimal Detectable Change Values for Predictions of Knee Forces during Gait and Stair Ascent Derived from the FreeBody Musculoskeletal Model of the Lower Limb.Effects of an 8-week strength training intervention on tibiofemoral joint loading during landing: a cohort study.Peak Power Output in the Bench Pull Is Maximized After Four Weeks of Specific Power Training.The development of lower limb musculoskeletal models with clinical relevance is dependent upon the fidelity of the mathematical description of the lower limb. Part 2: Patient-specific geometry.An optimization-based simultaneous approach to the determination of muscular, ligamentous, and joint contact forces provides insight into musculoligamentous interaction.An optimization approach to inverse dynamics provides insight as to the function of the biarticular muscles during vertical jumping.An important role of the biarticular hamstrings is to exert internal/external rotation moments on the tibia during vertical jumpingThe Magical Horizontal Force Muscle? A Preliminary Study Examining the "Force-Vector" TheoryKnee and hip joint forces--sensitivity to the degrees of freedom classification at the kneeLower-extremity musculoskeletal geometry affects the calculation of patellofemoral forces in vertical jumping and weightliftingSpecial issue on musculoskele modelling of the lower limbThe role of the biarticular hamstrings and gastrocnemius muscles in closed chain lower limb extensionRelative Intensity Influences the Degree of Correspondence of Jump Squats and Push Jerks to Countermovement JumpsThe patella: A mechanical determinant of coordination during vertical jumpingAdvertising paid and unpaid job roles in sport: an updated position statement from the UK Strength and Conditioning AssociationKnee Forces During Landing in Men and WomenPrincipal Component Analysis Reveals the Proximal to Distal Pattern in Vertical Jumping Is Governed by Two Functional Degrees of Freedom
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description
hulumtues
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հետազոտող
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name
Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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type
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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Daniel Cleather
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P1053
B-5314-2012
P106
P21
P214
30145910202227022668
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P3829
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0000-0001-7852-3440
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