Search results for "Impact loading"

showing 6 items of 6 documents

Impact loading history modulates hip fracture load and location : A finite element simulation study of the proximal femur in female athletes

2018

Sideways falls impose high stress on the thin superolateral cortical bone of the femoral neck, the region regarded as a fracture-prone region of the hip. Exercise training is a natural mode of mechanical loading to make bone more robust. Exercise-induced adaptation of cortical bone along the femoral neck has been previously demonstrated. However, it is unknown whether this adaption modulates hip fracture behavior. The purpose of this study was to investigate the influence of specific exercise loading history on fall-induced hip fracture behavior by estimating fracture load and location with proximal femur finite element (FE) models created from magnetic resonance images (MRI) of 111 women w…

02 engineering and technologyFinite element simulationWeight-Bearing0302 clinical medicinemurtumatreisiluuOrthopedics and Sports MedicineFemurOrthodonticsHip fractureluustomedicine.diagnostic_testbiologyProximal femurexerciseRehabilitationfallingfemoral neckta3142lonkkamurtumatBiomechanical Phenomenamedicine.anatomical_structureFemalevahvistaminenAdultFinite Element Analysis0206 medical engineeringBiomedical EngineeringBiophysics030209 endocrinology & metabolismbone strengthYoung Adult03 medical and health sciencesmedicineHumansFemoral neckHip Fracturesbusiness.industryAthletesMagnetic resonance imagingfinite element modelingmedicine.diseasebiology.organism_classification020601 biomedical engineeringAthletesImpact loadingAccidental FallsCortical bonebusinesshuman activitiesJournal of Biomechanics
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Foot Strike Pattern, Step Rate, and Trunk Posture Combined Gait Modifications to Reduce Impact Loading during Running

2019

Elevated impact loading can be detrimental to runners as it has been linked to the increased risk of tibial stress fracture and plantar fasciitis. The objective of this study was to investigate the combined effects of foot strike pattern, step rate, and anterior trunk lean gait modifications on impact loading in runners. Nineteen healthy runners performed 12 separate gait modification trials involving: three foot strike patterns (rearfoot, midfoot, and forefoot strike), two step rates (natural and 10% increased), and two anterior trunk lean postures (natural and 10-degree increased flexion). Overall, forefoot strike combined with increased step rate led to the lowest impact loading rates, a…

AdultMaleFoot strikelanding patternmedicine.medical_specialtyFractures Stress0206 medical engineeringBiomedical EngineeringBiophysicsPlantar fasciitis02 engineering and technologyRunningjuoksu03 medical and health sciences0302 clinical medicinePhysical medicine and rehabilitationGait (human)medicineHumansOrthopedics and Sports MedicineRange of Motion ArticularTrunk postureta315GaitpostureryhtiFootbusiness.industryForefootRehabilitationvertical loadingTorso020601 biomedical engineeringTrunkBiomechanical PhenomenaTibial Fracturesbody regionsImpact loadingFemalecadencebiomekaniikkamedicine.symptombusinessCadencehuman activities030217 neurology & neurosurgerydistance runnersJournal of Biomechanics
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Running in highly cushioned shoes increases leg stiffness and amplifies impact loading

2018

AbstractRunning shoe cushioning has become a standard method for managing impact loading and consequent injuries due to running. However, despite decades of shoe technology developments and the fact that shoes have become increasingly cushioned, aimed to ease the impact on runners’ legs, running injuries have not decreased. To better understand the shoe cushioning paradox, we examined impact loading and the spring-like mechanics of running in a conventional control running shoe and a highly cushioned maximalist shoe at two training speeds, 10 and 14.5 km/h. We found that highly cushioned maximalist shoes alter spring-like running mechanics and amplify rather than attenuate impact loading. T…

AdultMalemusculoskeletal diseasesrasitusvammatComputer sciencelcsh:MedicineHEEL STRIKEMASSbone quality and biomechanicsurheilujalkineetArticlejuoksuGROUND REACTION FORCES03 medical and health sciences0302 clinical medicineotorhinolaryngologic diseasesHumans315 Sport and fitness sciencesGround reaction forcelcsh:ScienceHeel strikeWORKLeg stiffnessLegMultidisciplinaryRunning injuriesbusiness.industryWork (physics)lcsh:Rtechnology industry and agricultureCushioning030229 sport sciencesStructural engineeringShoesbody regionsMECHANICSRUNNERSImpact loadingLoading rateINJURIESlcsh:Qbiomekaniikkabusiness030217 neurology & neurosurgeryScientific Reports
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Experimental characterization of composite laminates under low-velocity multi-impact loading

2019

The use of composite materials undergoes a significant growth in many industries including aeronautic, railway, and automotive. Laminated composites are often subjected to severe loading conditions...

Materials scienceMechanical EngineeringDelamination02 engineering and technologyComposite laminates021001 nanoscience & nanotechnologyCharacterization (materials science)020303 mechanical engineering & transports0203 mechanical engineeringMechanics of MaterialsImpact loadingMaterials ChemistryCeramics and CompositesLaminated compositesComposite material0210 nano-technologyJournal of Composite Materials
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Influence of custom-made and prefabricated insoles before and after an intense run

2017

[EN] Each time the foot contacts the ground during running there is a rapid deceleration that results in a shock wave that is transmitted from the foot to the head. The fatigue of the musculoskeletal system during running may decrease the ability of the body to absorb those shock waves and increase the risk of injury. Insoles are commonly prescribed to prevent injuries, and both custom-made and prefabricated insoles have been observed to reduce shock accelerations during running. However, no study to date has included a direct comparison of their behaviour measured over the same group of athletes, and therefore great controversy still exists regarding their effectiveness in reducing impact …

Shock waveMaleCritical Care and Emergency MedicinePhysiologylcsh:MedicineAccelerometerPathology and Laboratory MedicineMaterial FatigueRunning0302 clinical medicineMaterials PhysicsMedicine and Health SciencesTreadmillGroung Reaction Forcelcsh:ScienceMusculoskeletal SystemFatigueTrauma MedicineMultidisciplinaryPhysicsClassical MechanicsFoamShock (mechanics)Muscle FatiguePhysical SciencesLegsEngineering and TechnologyFemaleAnatomyShock AttenuationTraumatic InjuryResearch ArticleAdultmedicine.medical_specialtyMaterials by StructureMaterials ScienceSTRIDE03 medical and health sciencesAccelerationYoung AdultPhysical medicine and rehabilitationSigns and SymptomsDiagnostic MedicineTEORIA DE LA SEÑAL Y COMUNICACIONESmedicineHumansTibial Stress-FractureDamage Mechanicsbusiness.industryBiological Locomotionlcsh:RLimbs (Anatomy)Biology and Life Sciences030229 sport sciencesStride lengthShoesAthletesMusculoskeletal InjuryImpact loadingExercise Testlcsh:QFeet (Anatomy)ElectronicsAccelerometersbusiness030217 neurology & neurosurgery
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Self-selected running gait modifications reduce acute impact loading, awkwardness, and effort

2021

Impact loading has been associated with running-related injuries, and gait retraining has been suggested as a means of reducing impact loading and lowering the risk of injury. However, gait retraining can lead to increased perceived awkwardness and effort. The influence of specifically trained and self-selected running gait modifications on acute impact loading, perceived awkwardness and effort is currently unclear. Sixteen habitual rearfoot/midfoot runners performed forefoot strike pattern, increased step rate, anterior trunk lean and self-selected running gait modifications on an instrumented treadmill based on real-time biofeedback. Impact loading, perceived awkwardness and effort scores…

medicine.medical_specialtyGait retrainingbusiness.industry0206 medical engineeringPhysical Therapy Sports Therapy and Rehabilitation030229 sport sciences02 engineering and technology020601 biomedical engineeringbody regions03 medical and health sciencesRunning gait0302 clinical medicinePhysical medicine and rehabilitationGait (human)Impact loadingmedicineOrthopedics and Sports Medicinebusinesshuman activitiesSports Biomechanics
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