Your search keyword '"Schache AG"' showing total 16 results

1. Lower Limb Joint Mechanics during Maximal Accelerative and Decelerative Running.

Author

Fitzwilliam E, Steventon-Lorenzen N, Opar D, Schache AG, and Maniar N

Subjects

Humans, Biomechanical Phenomena, Male, Young Adult, Female, Adult, Lower Extremity physiology, Running physiology, Hip Joint physiology, Ankle Joint physiology, Acceleration, Knee Joint physiology, Deceleration

Abstract

Introduction: Maximal acceleration and deceleration tasks are frequently required in team sports, often occurring rapidly in response to external stimuli. Accelerating and decelerating can be associated with lower limb injuries; thus, knowledge of joint mechanics during these tasks can improve the understanding of both human high performance and injury mechanisms. The current study investigated the fundamental differences in lower limb joint mechanics when accelerating and decelerating by directly comparing the hip, knee, and ankle joint moments and work done between the two tasks., Methods: Twenty participants performed maximal effort acceleration and deceleration trials, with three-dimensional marker trajectories and ground reaction forces collected simultaneously. Experimental data were combined with inverse dynamics analysis to compute joint moments and work., Results: Net joint work for all lower limb joints was positive during acceleration and negative during deceleration. This occurred because of significantly greater positive work production from the ankle and hip during acceleration and significantly greater negative work production from all joints during deceleration. The largest contributions to positive work during acceleration came from the ankle, followed by the hip and knee joints, whereas the largest contributions to negative work during deceleration came from the knee and hip joints, followed by the ankle. Peak joint moments were significantly greater when decelerating compared with accelerating, except for the peak ankle plantarflexion and hip flexion moments, which were significantly greater when accelerating., Conclusions: Our findings may help to guide training interventions, which aim to enhance the performance of acceleration and deceleration tasks, while also mitigating the associated injury risk., (Copyright © 2024 by the American College of Sports Medicine.)

Published

2024

2. Muscle contributions to tibiofemoral shear forces and valgus and rotational joint moments during single leg drop landing.

Author

Maniar N, Schache AG, Pizzolato C, and Opar DA

Subjects

Adult, Anterior Cruciate Ligament Injuries physiopathology, Biomechanical Phenomena, Electromyography, Humans, Male, Rotation, Young Adult, Knee Joint physiology, Leg physiology, Muscle, Skeletal physiology, Weight-Bearing physiology

Abstract

Anterior cruciate ligament (ACL) injuries commonly occur during single-leg landing tasks and are a burdensome condition. Previous studies indicate that muscle forces play an important role in controlling ligamentous loading, yet these studies have typically used cadaveric models considering only the knee-spanning quadriceps, hamstrings, and gastrocnemius muscle groups. Any muscles (including non-knee-spanning muscles) capable of opposing the anterior shear joint reaction force and the valgus joint reaction moment are thought to have the greatest potential for protecting the ACL from injury. Thus, the purpose of this study was to investigate how lower-limb muscles modulate knee joint loading during a single-leg drop landing task. An electromyography-informed neuromusculoskeletal modeling approach was used to compute lower-limb muscle force contributions to the anterior shear joint reaction force and the valgus joint reaction moment at the knee during a single-leg drop landing task. The average shear joint reaction force ranged from 153 N of anterior shear force to 744 N of posterior shear force. The muscles that generated the greatest posterior shear force were the soleus, medial hamstrings, and biceps femoris, contributing up to 393 N, 359 N, and 162 N, respectively. The average frontal plane joint reaction moment ranged from a 19 Nm varus moment to a 6 Nm valgus moment. The valgus moment was primarily opposed by the gluteus medius, gluteus minimus, and soleus, with these muscles providing contributions of up to 38, 22, and 20 Nm toward a varus moment, respectively. The findings identify key muscles that mitigate loads on the ACL., (© 2020 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2020

3. Lower-limb joint mechanics during maximum acceleration sprinting.

Author

Schache AG, Lai AKM, Brown NAT, Crossley KM, and Pandy MG

Subjects

Acceleration, Adult, Biomechanical Phenomena, Female, Humans, Male, Video Recording, Ankle Joint physiology, Hip Joint physiology, Knee Joint physiology, Running physiology

Abstract

We explored how humans adjust the stance phase mechanical function of their major lower-limb joints (hip, knee, ankle) during maximum acceleration sprinting. Experimental data [motion capture and ground reaction force (GRF)] were recorded from eight participants as they performed overground sprinting trials. Six alternative starting locations were used to obtain a dataset that incorporated the majority of the acceleration phase. Experimental data were combined with an inverse-dynamics-based analysis to calculate lower-limb joint mechanical variables. As forward acceleration magnitude decreased, the vertical GRF impulse remained nearly unchanged whereas the net horizontal GRF impulse became smaller as a result of less propulsion and more braking. Mechanical function was adjusted at all three joints, although more dramatic changes were observed at the hip and ankle. The impulse from the ankle plantar-flexor moment was almost always larger than those from the hip and knee extensor moments. Forward acceleration magnitude was linearly related to the impulses from the hip extensor moment ( R 2 =0.45) and the ankle plantar-flexor moment ( R 2 =0.47). Forward acceleration magnitude was also linearly related to the net work done at all three joints, with the ankle displaying the strongest relationship ( R 2 =0.64). The ankle produced the largest amount of positive work (1.55±0.17 J kg -1 ) of all the joints, and provided a significantly greater proportion of the summed amount of lower-limb positive work as running speed increased and forward acceleration magnitude decreased. We conclude that the hip and especially the ankle represent key sources of positive work during the stance phase of maximum acceleration sprinting., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2019. Published by The Company of Biologists Ltd.)

Published

2019

4. Lower limb biomechanics during low- and high-impact functional tasks differ between men and women with hip-related groin pain.

Author

King MG, Heerey JJ, Schache AG, Semciw AI, Middleton KJ, Sritharan P, Lawrenson PR, and Crossley KM

Subjects

Adolescent, Adult, Ankle physiopathology, Ankle Joint physiopathology, Biomechanical Phenomena, Cross-Sectional Studies, Female, Gait, Hip physiopathology, Humans, Knee physiopathology, Lower Extremity physiopathology, Male, Middle Aged, Pain Measurement, Rotation, Soccer, Walking, Young Adult, Arthralgia physiopathology, Groin physiopathology, Hip Joint physiopathology, Knee Joint physiopathology, Pain Management methods, Range of Motion, Articular

Abstract

Background: The effect of pain on lower limb biomechanics during walking has been found to be sex specific for certain joint diseases. However, it is not known if sex is an effect-modifier in people with hip pain. Therefore, the aim of the study was to determine the differences in lower limb biomechanics between men and women with hip-related groin pain during functional tasks., Methods: 65 male and 23 female football players with hip-related groin pain were recruited. Biomechanical data were recorded during walking and the single-leg drop jump. Hip, knee and ankle joint kinematics and kinetics were calculated. Differences between men and women were assessed using statistical parametric mapping., Findings: Walking: Men with hip-related groin pain walked with lower hip flexion and internal rotation angles during stance compared to women. During different sections of stance, men also displayed a lower hip adduction angle and 'external' adduction moment, a lower knee flexion angle and 'external' flexion moment, as well as greater 'external' dorsi-flexion moment and impulse. Single-leg drop jump: Men with hip-related groin pain displayed a lower hip flexion angle during early stance, and greater 'external' knee flexion and ankle dorsi-flexion moments. The impulse of the 'external' dorsi-flexion moment was also greater for men compared to women., Interpretation: Men and women with hip-related groin pain display differing lower limb biomechanics in both low and high impact tasks. Sex may therefore be a potential effect modifier in people with hip-related groin pain. Future research in this area should incorporate sex-specific analyses., Trial Registration Number: NA., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

5. Three-dimensional motion of the knee-joint complex during normal walking revealed by mobile biplane x-ray imaging.

Author

Gray HA, Guan S, Thomeer LT, Schache AG, de Steiger R, and Pandy MG

Subjects

Adult, Biomechanical Phenomena, Cross-Sectional Studies, Female, Femur physiology, Humans, Imaging, Three-Dimensional, Knee Joint diagnostic imaging, Male, Patella physiology, Radiography, Tibia physiology, Young Adult, Knee Joint physiology, Walking physiology

Abstract

Accurate knowledge of knee kinematics is important for a better understanding of normal joint function and for improving patient outcomes subsequent to joint reconstructive surgery. Limited information is available that accurately describes the relative movements of the bones at the knee in vivo, even for the most common of all activities: walking. We used a mobile X-ray imaging system to measure the three-dimensional motion of the entire knee-joint complex-femur, tibia, and patella-when humans walk over ground at their natural speeds. Data were recorded from 15 healthy individuals (9 males, 6 females; age 30.5 ± 6.2 years). The most pronounced rotational motion of the tibia was flexion-extension followed by internal-external rotation and abduction-adduction (peak-to-peak displacements: 70.7°, 9.2°, and 1.9°, respectively). Maximum anterior translation of the tibia was 6.5 mm and occurred in early swing, coinciding with peak knee flexion and peak internal rotation. The most prominent rotational motion of the patella was flexion-extension (peak-to-peak displacement: 50.5°). The tibia pivoted about the medial compartment of the tibiofemoral joint, conferring greater movements of the contact centers in the lateral compartment than the medial compartment (15.4 and 9.7 mm, respectively). Internal-external rotation, anterior-posterior translation and medial-lateral shift of the tibia as well as flexion-extension and anterior-posterior translation of the patella were each coupled to the knee flexion angle, as were movements of the contact centers at each joint. These fundamental data serve as a valuable resource for evaluating knee joint function in normal and pathological gait. The data are available in Supplementary_Material_Data.xlsx. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res., (© 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc.)

Published

2019

6. Athletes Rated as Poor Single-Leg Squat Performers Display Measurable Differences in Single-Leg Squat Biomechanics Compared With Good Performers.

Author

Garrick LE, Alexander BC, Schache AG, Pandy MG, Crossley KM, and Collins NJ

Subjects

Adult, Athletes, Biomechanical Phenomena, Cross-Sectional Studies, Female, Hip Joint physiopathology, Humans, Knee Joint physiopathology, Male, Movement, Posture, Torso, Foot Orthoses, Hip Joint physiology, Knee Joint physiology, Range of Motion, Articular

Abstract

Context: It is important to validate single-leg squat visual rating criteria used in clinical practice and research. Foot orthoses may improve single-leg squat performance in those who demonstrate biomechanics associated with increased risk of lower limb injury., Objective: Validate visual rating criteria proposed by Crossley et al, by determining whether athletes rated as poor single-leg squat performers display different single-leg squat biomechanics than good performers; and evaluate immediate effects of foot orthoses on single-leg squat biomechanics in poor performers., Design: Comparative cross-sectional study., Setting: University laboratory., Participants: 79 asymptomatic athletes underwent video classification of single-leg squat performance based on established visual rating criteria (overall impression, trunk posture, pelvis "in space," hip movement, and knee movement), and were rated as good (n = 23), fair (n = 41), or poor (n = 15) performers., Intervention: A subset of good (n = 16) and poor (n = 12) performers underwent biomechanical assessment, completing 5 continuous single-leg squats on their dominant limb while 3-dimensional motion analysis and ground reaction force data were recorded. Poor performers repeated the task standing on prefabricated foot orthoses., Main Outcome Measures: Peak external knee adduction moment (KAM) and peak angles for the trunk, hip, knee, and ankle., Results: Compared with good performers, poor performers had a significantly lower peak KAM (mean difference = 0.11 Nm/kg, 95% confidence interval = 0.02 to 0.2 Nm/kg), higher peak hip adduction angle (-4.3°, -7.6° to -0.9°), and higher peak trunk axial rotation toward their stance limb (3.8°, 0.4° to 7.2°). Foot orthoses significantly increased the peak KAM in poor performers (-0.06 Nm/kg, -0.1 to -0.01 Nm/kg), with values approximating those observed in good performers., Conclusions: Findings validate Crossley et al's visual rating criteria for single-leg squat performance in asymptomatic athletes, and suggest that "off-the-shelf" foot orthoses may be a simple intervention for poor performers to normalize the magnitude of the external KAM during single-leg squat.

Published

2018

7. Non-knee-spanning muscles contribute to tibiofemoral shear as well as valgus and rotational joint reaction moments during unanticipated sidestep cutting.

Author

Maniar N, Schache AG, Sritharan P, and Opar DA

Subjects

Adult, Anterior Cruciate Ligament Injuries prevention & control, Biomechanical Phenomena, Electromyography, Femur physiology, Humans, Male, Photogrammetry, Tibia physiology, Knee Joint physiology, Movement physiology, Muscle, Skeletal physiology

Abstract

Anterior cruciate ligament (ACL) injuries are a burdensome condition due to potential surgical requirements and increased risk of long term debilitation. Previous studies indicate that muscle forces play an important role in the development of ligamentous loading, yet these studies have typically used cadaveric models considering only the knee-spanning quadriceps, hamstrings and gastrocnemius muscle groups. Using a musculoskeletal modelling approach, we investigated how lower-limb muscles produce and oppose key tibiofemoral reaction forces and moments during the weight acceptance phase of unanticipated sidestep cutting. Muscles capable of opposing (or controlling the magnitude of) the anterior shear force and the external valgus moment at the knee are thought to be have the greatest potential for protecting the anterior cruciate ligament from injury. We found the best muscles for generating posterior shear to be the soleus, biceps femoris long head and medial hamstrings, providing up to 173N, 111N and 77N of force directly opposing the anterior shear force. The valgus moment was primarily opposed by the gluteus medius, gluteus maximus and piriformis, with these muscles providing contributions of up to 32 Nm, 19 Nm and 21 Nm towards a knee varus moment, respectively. Our findings highlight key muscle targets for ACL preventative and rehabilitative interventions.

Published

2018

8. In vivo six-degree-of-freedom knee-joint kinematics in overground and treadmill walking following total knee arthroplasty.

Author

Guan S, Gray HA, Schache AG, Feller J, de Steiger R, and Pandy MG

Subjects

Aged, Biomechanical Phenomena, Female, Gait, Humans, Male, Middle Aged, Arthroplasty, Replacement, Knee, Knee Joint physiology, Walking psychology

Abstract

No data are available to describe six-degree-of-freedom (6-DOF) knee-joint kinematics for one complete cycle of overground walking following total knee arthroplasty (TKA). The aims of this study were firstly, to measure 6-DOF knee-joint kinematics and condylar motion for overground walking following TKA; and secondly, to determine whether such data differed between overground and treadmill gait when participants walked at the same speed during both tasks. A unique mobile biplane X-ray imaging system enabled accurate measurement of 6-DOF TKA knee kinematics during overground walking by simultaneously tracking and imaging the joint. The largest rotations occurred for flexion-extension and internal-external rotation whereas the largest translations were associated with joint distraction and anterior-posterior drawer. Strong associations were found between flexion-extension and adduction-abduction (R 2  = 0.92), joint distraction (R 2  = 1.00), and anterior-posterior translation (R 2  = 0.77), providing evidence of kinematic coupling in the TKA knee. Although the measured kinematic profiles for overground walking were grossly similar to those for treadmill walking, several statistically significant differences were observed between the two conditions with respect to temporo-spatial parameters, 6-DOF knee-joint kinematics, and condylar contact locations and sliding. Thus, caution is advised when making recommendations regarding knee implant performance based on treadmill-measured knee-joint kinematic data. © 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 35:1634-1643, 2017., (© 2016 Orthopaedic Research Society. Published by Wiley Periodicals, Inc.)

Published

2017

9. The distribution of positive work and power generation amongst the lower-limb joints during walking normalises following recovery from traumatic brain injury.

Author

Williams G and Schache AG

Subjects

Adult, Brain Injuries physiopathology, Cross-Sectional Studies, Female, Follow-Up Studies, Humans, Lower Extremity physiopathology, Male, Mobility Limitation, Physical Therapy Modalities, Ankle Joint physiopathology, Brain Injuries rehabilitation, Gait physiology, Hip Joint physiopathology, Knee Joint physiopathology, Recovery of Function, Walking physiology

Abstract

Objective: To determine whether better walking performance following recovery from traumatic brain injury (TBI) is attributable to an accentuation of compensatory strategies or an improvement in the way positive work is done and power is generated by the lower-limb joints., Setting: A large metropolitan rehabilitation hospital., Participants: Thirty-five ambulant people with extremely-severe TBI who were attending physiotherapy for mobility limitations, and a comparative sample of 25 healthy controls (HC)., Design: Cross-sectional cohort study with six month follow-up., Main Measures: Positive work done and average power (i.e. over time) generation by the hip, knee and ankle during stance as well as self-selected gait velocity., Results: In comparison to HCs, TBI participants walked at baseline with a significantly (p<.01) reduced contribution from the ankle to total lower-limb average power generation (and positive work done) during stance, and a significantly (p=.03) greater contribution from the hip. However, this compensatory strategy resolved over time such that at six month follow-up no significant differences in the relative contributions from the ankle and hip were identified for the TBI participants when compared to HCs., Conclusion: Better walking performance following recovery from TBI is attributable to an improvement in the way positive work is done and power is generated by the lower-limb joints rather than an accentuation of compensatory strategies., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

10. Are knee biomechanics different in those with and without patellofemoral osteoarthritis after anterior cruciate ligament reconstruction?

Author

Culvenor AG, Schache AG, Vicenzino B, Pandy MG, Collins NJ, Cook JL, and Crossley KM

Subjects

Adult, Biomechanical Phenomena, Cross-Sectional Studies, Female, Gait, Humans, Knee Joint physiopathology, Male, Middle Aged, Osteoarthritis, Knee diagnosis, Osteoarthritis, Knee physiopathology, Physical Examination, Range of Motion, Articular, Retrospective Studies, Risk Factors, Running, Treatment Outcome, Video Recording, Walking, Anterior Cruciate Ligament Reconstruction adverse effects, Knee Joint surgery, Osteoarthritis, Knee etiology

Abstract

Objective: Patellofemoral (PF) osteoarthritis (OA) is prevalent following anterior cruciate ligament reconstruction (ACLR). This study aimed to investigate differences in transverse plane rotation between knees with varus and valgus alignment during gait in people with and without PFOA after ACLR., Methods: Thirty-six individuals who were mean ± SD 9 ± 2 years post-ACLR (18 radiographic PFOA and 18 no knee OA) participated in this cross-sectional study. Knee internal-external rotation angles were measured using a 3-dimensional motion analysis system during walking and running. Weight-bearing frontal plane knee alignment, measured with an inclinometer, was used to classify participants as having varus or valgus alignment. Two-way analysis of covariance was used to assess the effect of both PFOA and frontal plane knee alignment on dynamic knee internal-external rotation., Results: Significant interactions were found between PFOA status and frontal plane alignment on knee internal-external rotation angles during walking (P = 0.019) and running (P = 0.002). Tests of simple effects revealed that during walking, individuals with valgus alignment and PFOA demonstrated a mean 3.9° (95% confidence interval [95% CI] 0.7, 7.1) less knee internal rotation than those with valgus alignment and no OA. During running this difference increased to 6.1° (95% CI 1.8, 10.4). For individuals with varus alignment, no significant effects were observed., Conclusion: Less knee internal rotation during gait was found in individuals with PFOA and valgus alignment. A rotational shift of this magnitude may be sufficient to initiate or accelerate patellofemoral cartilage degeneration. Prospective studies are required to determine if these altered kinematic patterns result from, or contribute to, PFOA development after reconstruction.

Published

2014

11. Strain energy in the femoral neck during exercise.

Author

Martelli S, Kersh ME, Schache AG, and Pandy MG

Subjects

Adult, Aged, 80 and over, Female, Femur, Finite Element Analysis, Homeostasis, Humans, Models, Anatomic, Sports, Stress, Mechanical, Tensile Strength, Weight-Bearing, Exercise, Femur Neck physiology, Hip Joint physiology, Knee Joint physiology, Osteoporosis physiopathology, Osteoporotic Fractures physiopathology

Abstract

Physical activity is recommended to mitigate the incidence of hip osteoporotic fractures by improving femoral neck strength. However, results from clinical studies are highly variable and unclear about the effects of physical activity on femoral neck strength. We ranked physical activities recommended for promoting bone health based on calculations of strain energy in the femoral neck. According to adaptive bone-remodeling theory, bone formation occurs when the strain energy (S) exceeds its homeostatic value by 75%. The potential effectiveness of activity type was assessed by normalizing strain energy by the applied external load. Tensile strain provided an indication of bone fracture. External force and joint motion data for 15 low- and high-load weight-bearing and resistance-based activities were used. High-load activities included weight-bearing activities generating a ground force above 1 body-weight and maximal resistance exercises about the hip and the knee. Calculations of femoral loads were based on musculoskeletal and finite-element models. Eight of the fifteen activities were likely to trigger bone formation, with isokinetic hip extension (ΔS=722%), one-legged long jump (ΔS=572%), and isokinetic knee flexion (ΔS=418%) inducing the highest strain energy increase. Knee flexion induced approximately ten times the normalized strain energy induced by hip adduction. Strain and strain energy were strongly correlated with the hip-joint reaction force (R(2)=0.90-0.99; p<0.05) for all activities, though the peak load location was activity-dependent. None of the exercises was likely to cause fracture. Femoral neck mechanics is activity-dependent and maximum isokinetic hip-extension and knee-flexion exercises are possible alternative solutions to impact activities for improving femoral neck strength., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

12. The effects of a varus unloader brace for lateral tibiofemoral osteoarthritis and valgus malalignment after anterior cruciate ligament reconstruction: a single case study.

Author

Hart HF, Ackland DC, Schache AG, Pandy MG, Collins NJ, and Crossley KM

Subjects

Anterior Cruciate Ligament Reconstruction, Biomechanical Phenomena physiology, Humans, Male, Middle Aged, Osteoarthritis physiopathology, Osteoarthritis surgery, Treatment Outcome, Braces, Gait physiology, Knee Joint surgery, Osteoarthritis rehabilitation

Abstract

We investigated the immediate effects of a varus knee brace on knee symptoms and knee-joint biomechanics in an individual with predominant lateral tibiofemoral joint osteoarthritis (TFJOA) and valgus malalignment after anterior cruciate ligament (ACL) reconstruction. A varus unloader brace was prescribed to a 48-year-old male with predominant lateral radiographic and symptomatic TFJOA and valgus malalignment eight-years following ACL reconstruction. During a step-down task, the participant rated knee pain, task-difficulty, knee-stability and knee-confidence on four separate visual analogue scales. Quantitative gait analysis was conducted during self-selected walking trials under three test conditions in a randomized order: (i) no brace; (ii) brace without frontal plane adjustment (no varus re-alignment); and (ii) brace with frontal plane adjustment (varus re-alignment). Post-processing of gait data involved calculation of knee kinematics and net joint moments for the reconstructed limb. The participant reported improved pain (3%), task difficulty (41%), stability (46%) and confidence (49%) when performing the step-down task with the brace. The varus brace resulted in immediate reductions in knee abduction angle (24%) and internal rotation angle (56%), and increased knee adduction moment (18%). These findings provide preliminary evidence for potentially beneficial effects of bracing on knee-symptoms and biomechanics in individuals with lateral TFJOA after reconstruction.

Published

2013

13. Effect of running speed on lower limb joint kinetics.

Author

Schache AG, Blanch PD, Dorn TW, Brown NA, Rosemond D, and Pandy MG

Subjects

Adult, Biomechanical Phenomena physiology, Female, Humans, Male, Torque, Young Adult, Ankle Joint physiology, Knee Joint physiology, Muscle, Skeletal physiology, Running physiology

Abstract

Purpose: Knowledge regarding the biomechanical function of the lower limb muscle groups across a range of running speeds is important in improving the existing understanding of human high performance as well as in aiding in the identification of factors that might be related to injury. The purpose of this study was to evaluate the effect of running speed on lower limb joint kinetics., Methods: Kinematic and ground reaction force data were collected from eight participants (five males and three females) during steady-state running on an indoor synthetic track at four discrete speeds: 3.50±0.04, 5.02±0.10, 6.97±0.09, and 8.95±0.70 m·s. A standard inverse-dynamics approach was used to compute three-dimensional torques at the hip, knee, and ankle joints, from which net powers and work were also calculated. A total of 33 torque, power, and work variables were extracted from the data set, and their magnitudes were statistically analyzed for significant speed effects., Results: The torques developed about the lower limb joints during running displayed identifiable profiles in all three anatomical planes. The sagittal-plane torques, net powers, and work done at the hip and knee during terminal swing demonstrated the largest increases in absolute magnitude with faster running. In contrast, the work done at the knee joint during stance was unaffected by increasing running speed, whereas the work done at the ankle joint during stance increased when running speed changed from 3.50 to 5.02 m·s, but it appeared to plateau thereafter., Conclusions: Of all the major lower limb muscle groups, the hip extensor and knee flexor muscles during terminal swing demonstrated the most dramatic increase in biomechanical load when running speed progressed toward maximal sprinting.

Published

2011

14. Non-invasive assessment of soft-tissue artifact and its effect on knee joint kinematics during functional activity.

Author

Akbarshahi M, Schache AG, Fernandez JW, Baker R, Banks S, and Pandy MG

Subjects

Adult, Biomechanical Phenomena, Fluoroscopy, Hip physiology, Humans, Knee Joint diagnostic imaging, Magnetic Resonance Imaging, Male, Imaging, Three-Dimensional, Knee Joint physiology, Models, Biological, Range of Motion, Articular physiology

Abstract

The soft-tissue interface between skin-mounted markers and the underlying bones poses a major limitation to accurate, non-invasive measurement of joint kinematics. The aim of this study was twofold: first, to quantify lower limb soft-tissue artifact in young healthy subjects during functional activity; and second, to determine the effect of soft-tissue artifact on the calculation of knee joint kinematics. Subject-specific bone models generated from magnetic resonance imaging (MRI) were used in conjunction with X-ray images obtained from single-plane fluoroscopy to determine three-dimensional knee joint kinematics for four separate tasks: open-chain knee flexion, hip axial rotation, level walking, and a step-up. Knee joint kinematics was derived using the anatomical frames from the MRI-based, 3D bone models together with the data from video motion capture and X-ray fluoroscopy. Soft-tissue artifact was defined as the degree of movement of each marker in the anteroposterior, proximodistal and mediolateral directions of the corresponding anatomical frame. A number of different skin-marker clusters (total of 180) were used to calculate knee joint rotations, and the results were compared against those obtained from fluoroscopy. Although a consistent pattern of soft-tissue artifact was found for each task across all subjects, the magnitudes of soft-tissue artifact were subject-, task- and location-dependent. Soft-tissue artifact for the thigh markers was substantially greater than that for the shank markers. Markers positioned in the vicinity of the knee joint showed considerable movement, with root mean square errors as high as 29.3mm. The maximum root mean square errors for calculating knee joint rotations occurred for the open-chain knee flexion task and were 24.3 degrees , 17.8 degrees and 14.5 degrees for flexion, internal-external rotation and abduction-adduction, respectively. The present results on soft-tissue artifact, based on fluoroscopic measurements in healthy adult subjects, may be helpful in developing location- and direction-specific weighting factors for use in global optimization algorithms aimed at minimizing the effects of soft-tissue artifact on calculations of knee joint rotations., (Copyright 2010 Elsevier Ltd. All rights reserved.)

Published

2010

15. Targeted physiotherapy for patellofemoral joint osteoarthritis: a protocol for a randomised, single-blind controlled trial.

Author

Crossley KM, Vicenzino B, Pandy MG, Schache AG, and Hinman RS

Subjects

Adult, Aged, Aged, 80 and over, Athletic Tape, Femur physiopathology, Follow-Up Studies, Humans, Linear Models, Middle Aged, Muscle Strength physiology, Osteoarthritis, Knee rehabilitation, Outcome Assessment, Health Care, Patella physiopathology, Single-Blind Method, Treatment Outcome, Knee Joint physiopathology, Osteoarthritis, Knee physiopathology, Osteoarthritis, Knee therapy, Patient Education as Topic, Physical Therapy Modalities

Abstract

Background: The patellofemoral joint (PFJ) is one compartment of the knee that is frequently affected by osteoarthritis (OA) and is a potent source of OA symptoms. However, there is a dearth of evidence for compartment-specific treatments for PFJ OA. Therefore, this project aims to evaluate whether a physiotherapy treatment, targeted to the PFJ, results in greater improvements in pain and physical function than a physiotherapy education intervention in people with symptomatic and radiographic PFJ OA., Methods: 90 people with PFJ OA (PFJ-specific history, signs and symptoms and radiographic evidence of PFJ OA) will be recruited from the community and randomly allocated into one of two treatments. A randomised controlled trial adhering to CONSORT guidelines will evaluate the efficacy of physiotherapy (8 individual sessions over 12 weeks, as well as a home exercise program 4 times/week) compared to a physiotherapist-delivered OA education control treatment (8 individual sessions over 12 weeks). Physiotherapy treatment will consist of (i) quadriceps muscle retraining; (ii) quadriceps and hip muscle strengthening; (iii) patellar taping; (iv) manual PFJ and soft tissue mobilisation; and (v) OA education. Resistance and dosage of exercises will be tailored to the participant's functional level and clinical state. Primary outcomes will be evaluated by a blinded examiner at baseline, 12 weeks and 9 months using validated and reliable pain, physical function and perceived global effect scales. All analyses will be conducted on an intention-to-treat basis using linear mixed regression models, including respective baseline scores as a covariate, subjects as a random effect, treatment condition as a fixed factor and the covariate by treatment interaction., Conclusion: This RCT is targeting PFJ OA, an important sub-group of knee OA patients, with a specifically designed conservative intervention. The project's outcome will influence PFJ OA rehabilitation, with the potential to reduce the personal and societal burden of this increasing public health problem., Trial Registration: Australia New Zealand Clinical Trials Registry ACTRN12608000288325.

Published

2008

16. Defining the knee joint flexion-extension axis for purposes of quantitative gait analysis: an evaluation of methods.

Author

Schache AG, Baker R, and Lamoreux LW

Subjects

Adult, Female, Hip Joint physiology, Humans, Male, Physical Examination methods, Range of Motion, Articular, Gait, Knee Joint physiology

Abstract

Minimising measurement variability associated with hip axial rotation and avoiding knee joint angle cross-talk are two fundamental objectives of any method used to define the knee joint flexion-extension axis for purposes of quantitative gait analysis. The aim of this experiment was to compare three different methods of defining this axis: the knee alignment device (KAD) method, a method based on the transepicondylar axis (TEA) and an alternative numerical method (Dynamic). The former two methods are common approaches that have been applied clinically in many quantitative gait analysis laboratories; the latter is an optimisation procedure. A cohort of 20 subjects performed three different functional tasks (normal gait; squat; non-weight bearing knee flexion) on repeated occasions. Three-dimensional hip and knee angles were computed using the three alternative methods of defining the knee joint flexion-extension axis. The repeatability of hip axial rotation measurements during normal gait was found to be significantly better for the Dynamic method (p<0.01). Furthermore, both the variance in the knee varus-valgus kinematic profile and the degree of knee joint angle cross-talk were smallest for the Dynamic method across all functional tasks. The Dynamic method therefore provided superior results in comparison to the KAD and TEA-based methods and thus represents an attractive solution for orientating the knee joint flexion-extension axis for purposes of quantitative gait analysis.

Published

2006