Your search keyword '"knee biomechanics"' showing total 600 results

551. Comparison of hip and knee biomechanics during gait for ‘good’ and ‘poor’ performers on a single leg squat task: A pilot study

Author

B. Alexander, Anthony G. Schache, and Kay M. Crossley

Subjects

medicine.medical_specialty, Gait (human), business.industry, Knee biomechanics, Physical therapy, Medicine, Physical Therapy, Sports Therapy and Rehabilitation, Orthopedics and Sports Medicine, Single leg squat, business, Task (project management)

Published

2009

552. Knee Biomechanics and Materials

Author

Braden C. Fleming and Malcolm H. Pope

Subjects

musculoskeletal diseases, medicine.medical_specialty, business.industry, Knee biomechanics, Anterior cruciate ligament, Total knee replacement, Biomechanics, Total knee arthroplasty, Degeneration (medical), Knee Joint, Physical medicine and rehabilitation, medicine.anatomical_structure, Medicine, business, Balance (ability)

Abstract

“Biomechanics is the study of forces and the effects that these forces have on the human body” (LeVeau 1984). From the orthopaedist’s perspective, there is a normal equilibrium between mechanical stress on the musculoskeletal system and its response to that stress. Any disturbance to this balance will eventually result in remodeling, degeneration, or failure of a structure. Within the realm of total knee replacement, it is necessary to understand fully the biomechanics of the normal joint since the objective of total knee arthroplasty is to re-establish normal joint function.

Published

1991

553. Visualising menisci-femur contact using deformable knee models

Author

Ying Zhu

Subjects

Software, Gait (human), Knee biomechanics, business.industry, Femur, 3d model, Neurology (clinical), Patient specific, business, Contact area, Simulation, Visualization

Abstract

Computational simulation can help improve our understanding of the knee biomechanics and orthopedic practice. However few computational knee models include a patient specific deformable menisci model. We present two new methods for simulating and visualising menisci-femur contact area during gait cycles, using patient specific knee models and motion data. Specifically we propose a template based 3D model reconstruction method that generates patient specific knee models. We also propose a new deformable menisci model for real-time applications. Our deformable model combines physics-based deformation and spatial deformation, making it easier for users to balance the physical realism and performance needs.

Published

2008

554. RELATIONSHIP BETWEEN THE KNEE VALGUS ANGLE AND EMG ACTIVITY OF THE LOWER EXTREMITY IN SINGLE - AND DOUBLE-LEG LANDING

Author

Y Urabe, M Nejishima, and S Yokoyama

Subjects

musculoskeletal diseases, medicine.medical_specialty, biology, business.industry, Knee biomechanics, Anterior cruciate ligament, Rehabilitation, Biomedical Engineering, Biophysics, musculoskeletal system, biology.organism_classification, body regions, Valgus, medicine.anatomical_structure, Physical medicine and rehabilitation, Open kinetic chain, Muscle strength, Medicine, Orthopedics and Sports Medicine, Hip abductor, business, human activities

Abstract

INTRODUCTION A significant correlation between the muscle strength of the lower extremity and knee valgus motion was reported by Claiborne et al. [1]. Their report stated that the hip abductor plays a significant role in the control of the knee valgus motion. Since muscle strength was measured in the open kinetic chain position, it may not reflect the lower extremity movement. Additionally, as a mechanism of noncontact anterior cruciate ligament injury, single-leg landing is generally at a higher risk than double-leg landing [2]. However, differences between the biomechanical characteristics of the lower extremity during singleand double-leg landing remain inconclusive. The aim of this study is to determine the effect of two different drop landing tasks on knee biomechanics and muscle activities.

Published

2007

555. The effect of ACL deficiency on knee biomechanics

Author

Guoan Li, Jeremy M. Moses, Louis E. DeFrate, Thomas J. Gill, and Ramprasad Papannagari

Subjects

medicine.medical_specialty, Physical medicine and rehabilitation, Knee biomechanics, business.industry, Rehabilitation, Biomedical Engineering, Biophysics, medicine, Orthopedics and Sports Medicine, business, Acl deficiency

Published

2006

556. Changes In Knee Biomechanics With Changes In Gait Speeds

Author

Paul A. Oakley, Scott K. Lynn, Patrick A. Costigan, and Samantha M. Reid

Subjects

medicine.medical_specialty, Physical medicine and rehabilitation, Gait (human), Knee biomechanics, business.industry, medicine, Physical Therapy, Sports Therapy and Rehabilitation, Orthopedics and Sports Medicine, business

Published

2005

557. Knee Recurvatum in Gait

Author

Lilla V Butler

Subjects

medicine.medical_specialty, Gait (human), Physical medicine and rehabilitation, Knee biomechanics, business.industry, Rehabilitation, Medicine, Physical Therapy, Sports Therapy and Rehabilitation, Neurology (clinical), business

Published

1996

558. Differential Effect of Total Knee Arthroplasty on Valgus and Varus Knee Biomechanics During Gait.

Author

Rodriguez JA, Bas MA, Orishimo KF, Robinson J, and Nicholas SJ

Subjects

Aged, Biomechanical Phenomena, Bone Plates, Female, Femur surgery, Humans, Knee surgery, Male, Middle Aged, Preoperative Period, Tibia surgery, Arthroplasty, Replacement, Knee adverse effects, Arthroplasty, Replacement, Knee methods, Gait, Knee Joint surgery, Osteoarthritis, Knee surgery

Abstract

Background: Total knee arthroplasty and its relation to gait abduction or adduction moment has not been fully described., Methods: Gait analysis was performed on 25 patients (27 knees) preoperatively, 6 months and 1 year after total knee arthroplasty. Reflective markers were placed on the lower extremity, and motion data were collected at 60 Hz using 6 infrared cameras. Ground reaction forces were recorded at 960 Hz with a force plate. Stance phase was divided into braking and propulsive phases. Coronal knee angles and moments were calculated. Repeated-measures analysis of variance was used to compare frontal plane knee impulse over time and between the braking and propulsive phases of stance., Results: In varus knees, static alignment was corrected from 2.2° varus to 3.3° valgus and in valgus knees from 15.2° valgus to 2.7° valgus (P < .010). Braking phase adduction impulse decreased from 0.145 to 0.111 at 6 months but increased to 0.126 Nm/kg s (P > .05) at 1 year. Propulsive phase impulse changed from 0.129 to 0.085 and persisted at 1 year. Impulse changed from 0.01 (abduction) to 0.11 Nm/kg s (adduction) at 6 months and persisted (P = .01)., Conclusion: Restoration of anatomic alignment and soft tissue balancing changes the lateral loading conditions of valgus knees. Both cases, between 6 months and 1 year, increased peak moment., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

559. Effects of two different degrees of lateral-wedge insoles on unilateral lower extremity load-bearing line in patients with medial knee osteoarthritis.

Author

Yılmaz B, Kesikburun S, Köroğlu O, Yaşar E, Göktepe AS, and Yazıcıoğlu K

Subjects

Aged, Biomechanical Phenomena, Female, Humans, Lower Extremity, Male, Middle Aged, Shoes, Foot Orthoses classification, Gait, Osteoarthritis, Knee rehabilitation, Posture, Weight-Bearing

Abstract

Objective: The aim of this study is to assess the effect of 5 and 10° lateral-wedge insoles on unilateral lower extremity load carrying line in patients with medial knee osteoarthritis using the L.A.S.A.R. posture alignment system., Patients and Methods: Twenty subjects (10 females and 10 males, mean age 67.7 ± 5.4 years (range: 58-78) with bilateral medial knee osteoarthritis were included in the study. The laser line projected on the person by the L.A.S.A.R. posture alignment system showed joint load carrying line. The location of the joint load carrying line in static standing with one foot on the force plate was assessed with barefoot, and 5° and 10° lateral-wedge insoles. Displacement of the load carrying line was measured using a ruler placed tangentially to the patella at the level of joint line., Results: The load carrying lines measured with 5° and 10° lateral-wedge insoles were significantly laterally located compared to that without wearing insole (p < 0.001). 10° lateral-wedge insole caused a significant more lateral shifting of the load carrying line than 5° lateral-wedge insole (p < 0.001)., Conclusion: Both wedge insoles was effective in moving of the unilateral lower extremity load carrying line to the lateral. Lateral wedged insoles are biomechanically effective and reduce loading of the medial compartment in patients with medial knee osteoarthritis., (Copyright © 2016 Turkish Association of Orthopaedics and Traumatology. Production and hosting by Elsevier B.V. All rights reserved.)

Published

2016

560. Immersive virtual reality improves movement patterns in patients after ACL reconstruction: implications for enhanced criteria-based return-to-sport rehabilitation.

Author

Gokeler A, Bisschop M, Myer GD, Benjaminse A, Dijkstra PU, van Keeken HG, van Raay JJ, Burgerhof JG, and Otten E

Subjects

Adolescent, Adult, Anterior Cruciate Ligament Injuries rehabilitation, Biomechanical Phenomena, Case-Control Studies, Female, Humans, Knee Joint physiology, Male, Middle Aged, Young Adult, Anterior Cruciate Ligament Injuries surgery, Anterior Cruciate Ligament Reconstruction rehabilitation, Movement physiology, Postoperative Care, Return to Sport, Virtual Reality Exposure Therapy

Abstract

Purpose: The purpose of this study was to evaluate the influence of immersion in a virtual reality environment on knee biomechanics in patients after ACL reconstruction (ACLR). It was hypothesized that virtual reality techniques aimed to change attentional focus would influence altered knee flexion angle, knee extension moment and peak vertical ground reaction force (vGRF) in patients following ACLR., Methods: Twenty athletes following ACLR and 20 healthy controls (CTRL) performed a step-down task in both a non-virtual reality environment and a virtual reality environment displaying a pedestrian traffic scene. A motion analysis system and force plates were used to measure kinematics and kinetics during a step-down task to analyse each single-leg landing., Results: A significant main effect was found for environment for knee flexion excursion (P = n.s.). Significant interaction differences were found between environment and groups for vGRF (P = 0.004), knee moment (P < 0.001), knee angle at peak vGRF (P = 0.01) and knee flexion excursion (P = 0.03). There was larger effect of virtual reality environment on knee biomechanics in patients after ACLR compared with controls., Conclusion: Patients after ACLR immersed in virtual reality environment demonstrated knee joint biomechanics that approximate those of CTRL. The results of this study indicate that a realistic virtual reality scenario may distract patients after ACLR from conscious motor control. Application of clinically available technology may aid in current rehabilitation programmes to target altered movement patterns after ACLR., Level of Evidence: Diagnostic study, Level III.

Published

2016

561. Evaluation of total knee mechanics using a crouching simulator with a synthetic knee substitute.

Author

Lowry M, Rosenbaum H, and Walker PS

Subjects

Biomechanical Phenomena, Equipment Design, Equipment Failure Analysis methods, Humans, Materials Testing methods, Equipment Failure Analysis instrumentation, Knee Prosthesis, Materials Testing instrumentation, Models, Biological

Abstract

Mechanical evaluation of total knees is frequently required for aspects such as wear, strength, kinematics, contact areas, and force transmission. In order to carry out such tests, we developed a crouching simulator, based on the Oxford-type machine, with novel features including a synthetic knee including ligaments. The instrumentation and data processing methods enabled the determination of contact area locations and interface forces and moments, for a full flexion-extension cycle. To demonstrate the use of the simulator, we carried out a comparison of two different total knee designs, cruciate retaining and substituting. The first part of the study describes the simulator design and the methodology for testing the knees without requiring cadaveric knee specimens. The degrees of freedom of the anatomic hip and ankle joints were reproduced. Flexion-extension was obtained by changing quadriceps length, while variable hamstring forces were applied using springs. The knee joint was represented by three-dimensional printed blocks on to which the total knee components were fixed. Pretensioned elastomeric bands of realistic stiffnesses passed through holes in the block at anatomical locations to represent ligaments. Motion capture of the knees during flexion, together with laser scanning and computer modeling, was used to reconstruct contact areas on the bearing surfaces. A method was also developed for measuring tibial component interface forces and moments as a comparative assessment of fixation. The method involved interposing Tekscan pads at locations on the interface. Overall, the crouching machine and the methodology could be used for many different mechanical measurements of total knee designs, adapted especially for comparative or parametric studies., (© IMechE 2016.)

Published

2016

562. Prediction of medial and lateral contact force of the knee joint during normal and turning gait after total knee replacement.

Author

Purevsuren T, Dorj A, Kim K, and Kim YH

Subjects

Biomechanical Phenomena physiology, Humans, Male, Posture physiology, Arthroplasty, Replacement, Knee, Gait physiology, Knee Joint physiology, Knee Joint surgery, Models, Biological

Abstract

The computational modeling approach has commonly been used to predict knee joint contact forces, muscle forces, and ligament loads during activities of daily living. Knowledge of these forces has several potential applications, for example, within design of equipment to protect the knee joint from injury and to plan adequate rehabilitation protocols, although clinical applications of computational models are still evolving and one of the limiting factors is model validation. The objective of this study was to extend previous modeling technique and to improve the validity of the model prediction using publicly available data set of the fifth "Grand Challenge Competition to Predict In Vivo Knee Loads." A two-stage modeling approach, which combines conventional inverse dynamic analysis (the first stage) with a multi-body subject-specific lower limb model (the second stage), was used to calculate medial and lateral compartment contact forces. The validation was performed by direct comparison of model predictions and experimental measurement of medial and lateral compartment contact forces during normal and turning gait. The model predictions of both medial and lateral contact forces showed strong correlations with experimental measurements in normal gait (r = 0.75 and 0.71) and in turning gait trials (r = 0.86 and 0.72), even though the current technique over-estimated medial compartment contact forces in swing phase. The correlation coefficient, Sprague and Geers metrics, and root mean squared error indicated that the lateral contact forces were predicted better than medial contact forces in comparison with the experimental measurements during both normal and turning gait trials., (© IMechE 2016.)

Published

2016

563. Biomechanical Effects of a Horizontal Medial Meniscal Tear and Subsequent Leaflet Resection.

Author

Brown MJ, Farrell JP, Kluczynski MA, and Marzo JM

Subjects

Aged, Aged, 80 and over, Biomechanical Phenomena physiology, Cadaver, Female, Humans, Male, Middle Aged, Osteoarthritis, Knee physiopathology, Rupture surgery, Knee Joint physiopathology, Menisci, Tibial surgery, Tibial Meniscus Injuries

Abstract

Background: Horizontal, degenerative tears of the medial meniscus and subsequent meniscectomy can compromise the biomechanical function of the meniscus in load transmission and weightbearing, leading to the development of radiographic and symptomatic tibiofemoral arthritis., Hypothesis: Resection of both leaflets of a horizontal medial meniscal tear will increase peak contact pressures and decrease contact areas in comparison with resection of only the inferior leaflet., Study Design: Controlled laboratory study., Methods: Twelve fresh-frozen human cadaveric knees had tibiofemoral peak contact pressures and contact areas under an 1800-N axial load measured by Tekscan in the control state. A horizontal tear was created in the posterior horn of the medial meniscus, and the knees were retested. The knees were tested a third time after resection of the inferior leaflet (single leaflet) and a final time after resection of the superior leaflet (both leaflets). The Friedman test was used to test for group differences in peak pressure (psi) and contact area (mm(2)) between test conditions (native, tear, inferior leaflet resection, and resection of both leaflets)., Results: For the medial compartment, there was a statistically significant difference in peak pressure (P = .03) but not in contact area (P = .70) between testing conditions. Median peak pressure in the medial compartment was significantly greater for resection of both leaflets compared with the tear (406.5 vs 294.7 psi, respectively; P = .002). Median contact area in the medial compartment was greatest for resection of both leaflets (602.7 mm(2)), but there were no statistically significant differences between test conditions (P = .70). For the lateral compartment, there were no statistically significant differences in peak pressure (P = .99) or contact area (P = .77) between test conditions., Conclusion: Resection of a single inferior leaflet after a horizontal medial meniscal tear preserves much of the original biomechanical function of the meniscus. Resection of both leaflets leads to a significant increase in contact pressure dispersed over the same contact area, which results in an undesirable biomechanical environment., Clinical Relevance: Arthroscopic inferior leaflet resection is a viable option for providing symptomatic relief of horizontal medial meniscal tears and preserves the ability of the meniscus to absorb axial loading on the knee joint, theoretically decreasing the risk of subsequent osteoarthritis., (© 2016 The Author(s).)

Published

2016

564. Running Injuries: The Infrapatellar Fat Pad and Plica Injuries.

Author

McConnell J

Subjects

Adipose Tissue innervation, Arthroscopy, Biomechanical Phenomena, Humans, Magnetic Resonance Imaging, Muscular Atrophy etiology, Muscular Atrophy prevention & control, Pain Measurement, Patella, Range of Motion, Articular, Weight-Bearing, Adipose Tissue injuries, Knee Injuries diagnosis, Knee Injuries therapy, Pain Management methods, Running injuries, Synovial Membrane injuries

Abstract

When considering knee pain in runners, clinicians differentiate sources of symptoms and determine their cause. Knee problems arise when a runner increases the amount/frequency of the loading through the lower limb. The way the loading is distributed through the knee determines which tissues are abnormally loaded. Knee problems cannot be considered in isolation, requiring a thorough investigation of static and dynamic lower limb mechanics, and footwear and surfaces. This article examines potential sources of knee pain and explores the role of the infrapatellar fat pad and synovial plica in the mechanics of the knee and its involvement in knee symptoms., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

565. Investigation of Anterior Cruciate Ligament and Medial Collateral Ligament Biomechanics during 6-Degree-of-Freedom, Robotically-Simulated Athletic Tasks

Author

Bates, Nathaniel A.

Subjects

Biomedical Research, anterior cruciate ligament, medial collateral ligament, knee biomechanics, robotic joint manipulation, knee ligament injury, intra-articular joint mechanics

Abstract

The anterior cruciate ligament (ACL) passively stabilizes the knee and plays a complex role in joint restraint during tibiofemoral articulations. ACL injuries are traumatic events that have short and long term consequences for affected athletes. Unfortunately, treatment through ACL reconstruction fails to completely restore native knee biomechanics or reduce the early onset of osteoarthritis following rupture. Therefore, the best treatment for ACL injuries may be to prevent their occurrence. To enhance ACL injury prevention, investigators must enhance the understanding of underlying, intra-articular mechanics that precede rupture.Use of robotic technology has allowed investigators to better examine native knee biomechanics during simulated clinical tests and gait. However, ACL injuries do not frequently occur during gait, but during athletic tasks that involve rapid deceleration or change in direction. The objective of these studies was to utilize in vivo recorded, three-dimensional kinematics to derive six-degree-of-freedom robotic simulations of athletic tasks that can assess native tibiofemoral mechanics in scenarios related to ACL injury. The created model successfully articulated cadaveric lower extremities though drop vertical jump and sidestep cutting tasks without specimen damage.The ACL serves as a secondary restraint to knee abduction and internal tibial rotation and, therefore, can be loaded through multiple rotational perturbations. Investigators dispute over which planes of motion contribute most significantly to ACL injury. The presented model found that combined knee rotations evoked the greatest ACL strains, but isolated knee abduction accounted for the majority of this loading. The model was then utilized to define how and why concomitant medial collateral ligament (MCL) injuries only occur in 30% of ACL ruptures, despite the shared mechanism of abduction loading for both ligaments. It was observed that during controlled athletic tasks the MCL was generally less loaded and strained and, therefore, less exposed to injury risk than the ACL. Finally, ACL injuries are gender-specific events with higher incidence rates in female athletes. Mechanical assessment of sex-specific kinematic simulations of athletic tasks revealed that neither joint loads nor ligament strains exhibited increased injury risk in females. This therefore supported that the conditions simulated in these studies indicated non-contact ACL injuries may be “black swan” events, a product of unanticipated and abnormal joint loading generated from an unexpected loss of neuromuscular control.Clinically, the current investigations indicated that preventive measures should continue to focus on reduction of knee abduction in order to lower ACL injury incidence. Greater baseline loading within the ACL than the MCL during athletic tasks supported how ACL rupture occurs with limited concomitant MCL injuries. The absence of observed gender differences, relative to ACL protection, indicated gender-specific training and rehabilitation protocols should be unnecessary as structural loading during regulated athletic tasks is comparable. Findings from these investigations advance the understanding of intra-articular knee biomechanics and can be incorporated into efforts to prevent ACL injuries. Future considerations should focus on further development of subject-specific simulation models that address additional sources of joint perturbation as well as the application of present models to the evaluation and efficacious improvement of current repair and reconstruction methods.

Published

2014

566. Obesity-Associated Morbidities in Children and Adolescents: The Correlates Between Knee Biomechanics, Musculoskeletal Impairments, Limitations in Health Related Quality of Life, and Cardiovascular Risk

Author

Briggs, Matthew S.

Subjects

Health, Health Care, Medicine, Physical Therapy, Public Health, Sports Medicine, Childhood Obesity, Knee Biomechanics, Knee Alignment, 3-D Motion Analysis, External Knee Moment, Knee Strength, Hip Strength, Single Leg Hop, Single Leg Balance Anterior Reach, Health Related Quality of Life, C-Reactive Protein, Metabolic Syndrome

Abstract

Alarmingly, pediatric obesity rates have tripled in the past 30 years and with over 30% of youth in the United States consider either overweight or obese. Children and adolescents who are obese face many of the same health concerns as adults including musculoskeletal, psychological, and cardiovascular morbidities. Furthermore, obese youth are more likely to be obese as adults. It could be hypothesized that in obese youth lower extremity musculoskeletal impairments and limitations may adversely impact functional ability and associated activity levels with subsequent limitations on health related quality of life and cardiovascular health. These negative attributes related to obesity in youth create a compelling the need to better understand their mechanisms and relationships. The overall purpose of this dissertation is to better understand the relationships between musculoskeletal impairments and limitations to components of health in obese youth. The results outlined in this dissertation from two cross-sectional studies in 20 obese and 20 matched healthy weight youth indicate that obese youth stand in greater knee abduction alignment demonstrate decreased external frontal plane knee moments during walking. In addition measures of frontal plane knee alignment in obese youth do not correlate with frontal plane knee loading during walking or jogging. Further, hip and knee strength may adversely affect functional ability while performance on hopping and balance related tasks may predict health related quality of life in obese youth. Finally, in a retrospective study of 183 obese youth enrolled in a medical weight management program it was determined that obese youth with high levels of C-reactive protein are at almost 5 times the odds of developing metabolic syndrome compared to obese youth with normal levels of C-reactive protein. However, measures of cardiorespiratory fitness, health related quality of life, and reports of musculoskeletal pain do not predict cardiovascular risk in obese youth. Overall, results from these studies demonstrate frontal plane knee alignment and frontal plane knee joint loading patterns do not correlate while contributions of lower extremity strength to lower extremity function and lower extremity function to health related quality of life differ between obese and healthy weight youth. In addition, high levels of C-reactive protein increase the risk of metabolic syndrome in obese youth whereas poorer cardiorespiratory fitness, poorer health related quality of life, and reports of musculoskeletal pain do not increase the risk of metabolic syndrome in obese children and adolescents. These results have potentially significant clinical implications on how musculoskeletal morbidities in obese youth are addressed and evaluated. Future research should focus on determining how the factors related to musculoskeletal impairments and limitations may influence levels of physical activity participation and in turn overall health. Ultimately, the results from these current and future studies may be used to optimize and personalize treatment strategies to reduce cardiovascular risk and improve health related quality of life in obese youth and limit the consequences of obesity into adulthood.

Published

2014

567. Forward lunge knee biomechanics before and after partial meniscectomy.

Author

Hall M, Nielsen JH, Holsgaard-Larsen A, Nielsen DB, Creaby MW, and Thorlund JB

Subjects

Adult, Biomechanical Phenomena, Female, Humans, Knee Injuries complications, Knee Injuries physiopathology, Knee Joint physiopathology, Male, Middle Aged, Osteoarthritis, Knee physiopathology, Range of Motion, Articular, Tibial Meniscus Injuries, Treatment Outcome, Arthroscopy methods, Gait physiology, Knee Injuries surgery, Knee Joint surgery, Menisci, Tibial surgery, Osteoarthritis, Knee surgery, Plastic Surgery Procedures methods

Abstract

Background: Patients following meniscectomy are at increased risk of developing knee osteoarthritis in the tibiofemoral compartment and at the patellofemoral joint. As osteoarthritis is widely considered a mechanical disease, it is important to understand the potential effect of arthroscopic partial meniscectomy (APM) on knee joint mechanics. The purpose of this study was to evaluate changes in knee joint biomechanics during a forward lunge in patients with a suspected degenerative meniscal tear from before to three months after APM., Methods: Twenty-two patients (35-55 years old) with a suspected degenerative medial meniscal tear participated in this study. Three dimensional knee biomechanics were assessed on the injured and contralateral leg before and three months after APM. The visual analogue scale was used to assess knee pain and the Knee Injury Osteoarthritis Outcome Score was used to assess sport/recreation function and knee-related confidence before and after APM., Results: The external peak knee flexion moment reduced in the APM leg compared to the contralateral leg (mean difference (95% CI)) -1.08 (-1.80 to -0.35) (Nm/(BW × HT)%), p = 0.004. Peak knee flexion angle also reduced in the APM leg compared to the contralateral leg -3.94 (-6.27 to -1.60) degrees, p = 0.001. There was no change in knee pain between the APM leg and contralateral leg (p=0.118). Self-reported sport/recreation function improved (p = 0.004)., Conclusions: Although patients self-reported less difficulty during strenuous tasks following APM, patients used less knee flexion, a strategy that may limit excessive patellar loads during forward lunge in the recently operated leg., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015

568. THE EFFECTS OF ANTICIPATION ON THE MECHANICS OF THE KNEE DURING SINGLE-LEG CUTTING TASKS: A SYSTEMATIC REVIEW.

Author

Almonroeder TG, Garcia E, and Kurt M

Abstract

Background: ACL injuries are common in sports, which has resulted in the development of risk screening and injury prevention programs to target modifiable neuromuscular risk factors. Previous studies which have analyzed single-leg cutting tasks have reported that the anticipation status of the task (pre-planned vs. unanticipated) has a significant effect on the mechanics of the knee., Hypothesis/purpose: The purpose of this systematic review is to assess the effect of anticipation on the mechanics of the knee in the sagittal, frontal, and transverse planes during tasks which athletes frequently perform during competition., Study Design: Systematic Review., Methods: The following databases were searched using relevant key words and search limits: Pub Med, SPORTDiscus, CINAHL, and Web of Science. A modified version of the Downs and Black checklist was used to assess the methodological quality of the articles by two independent reviewers., Results: 284 articles were identified during the initial database search. After a screening process, 34 articles underwent further review. Of these articles, 13 met the criteria for inclusion in this systematic review., Conclusions: It appears that tasks which do not allow a subject to pre-plan their movement strategy promote knee mechanics which may increase an athlete's risk of injury., Clinical Relevance: Clinicians involved in the development and implementation of ACL injury risk screening and prevention programs may want to consider incorporating tasks which do not allow time for pre-planning. These unanticipated tasks may more closely mimic the demands of the sports environment and may promote mechanics which increase the risk of injury., Level of Evidence: Level 1b.

Published

2015

569. Male-Female Differences in Knee Laxity and Stiffness: A Cadaveric Study.

Author

Boguszewski DV, Cheung EC, Joshi NB, Markolf KL, and McAllister DR

Subjects

Adult, Anterior Cruciate Ligament Injuries, Biomechanical Phenomena, Cadaver, Female, Humans, Knee Injuries physiopathology, Male, Middle Aged, Range of Motion, Articular, Risk Factors, Rotation, Torque, Joint Instability physiopathology, Knee physiology, Knee physiopathology

Abstract

Background: It has been reported that over 70% of anterior cruciate ligament (ACL) injuries occur in noncontact situations and that females are at 2 to 8 times greater risk of ACL injury than males. Increased joint laxity and reduced knee stiffness in female knees have been suggested as possible explanations for the higher ACL injury rates in females., Hypothesis: Compared with male knees, female knees will demonstrate increased laxity and reduced stiffness along the anterior-posterior (AP), internal-external (IE), and varus-valgus (VV) directions., Study Design: Controlled laboratory study., Methods: Forty-seven fresh-frozen human cadaveric knees were tested (22 male and 25 female) by use of a robotic system. Mean ages were 34.6 years (range, 19-45 years) for males and 28.4 years (range, 16-42 years) for females. Joint laxity and stiffness were measured from force-vs-displacement or torque-vs-rotation curves recorded for 3 modes of testing: ± 134 N AP force, ± 5 N · m IE torque, and ± 10 N · m VV moment., Results: Compared with male knees, female knees had greater internal laxity from 0° to 50° flexion (P < .01; maximum difference of 8.3° at 50° of flexion) and greater valgus laxity from 0° to 50° of flexion (P < .05; maximum difference of 1.6° at 50° of flexion). However, female knees exhibited greater anterior laxity only at 50° of flexion (P < .03; difference of 1.3 mm). No significant male-female differences in anterior or posterior stiffness were found. Male knees had 42% greater internal stiffness from 0° to 30° of flexion (P < .03), 35% greater valgus stiffness at 10° of flexion (P < .03), and 19% greater varus stiffness at 50° of flexion (P < .03)., Conclusion: Female knees demonstrated significantly increased laxity and reduced stiffness compared with males. This finding was not uniform but was dependent on the direction tested and the knee flexion angle., Clinical Relevance: Understanding the risk factors for noncontact ACL injury is important for injury prevention. In combination with other female-specific risk factors, increased knee laxity may be a contributing factor associated with the higher rate of female ACL injuries., (© 2015 The Author(s).)

Published

2015

570. KNEE BIOMECHANICS DURING REHABILITATION EXERCISES

Author

Glenn S. Fleisig, Kevin E. Wilk, L Snyder-Mackler, Rafael F. Escamilla, and B C. Fleming

Subjects

medicine.medical_specialty, Physical medicine and rehabilitation, Rehabilitation, business.industry, Knee biomechanics, medicine.medical_treatment, medicine, Physical Therapy, Sports Therapy and Rehabilitation, Orthopedics and Sports Medicine, business

Published

2001

571. The Effect of Surgical Technique During Total Knee Arthroplasty on Knee Joint Stability

Author

Hutter, Erin E.

Subjects

Biomechanics, Mechanical Engineering, TKA, total knee arthroplasty, knee biomechanics, surgical navigation system, knee stability, knee model, subject-specific model

Abstract

Total knee arthroplasty (TKA) is a common surgical procedure which reduces pain and restores joint function in patients with advanced knee osteoarthritis. In 2005, there were approximately 523,000 TKA surgeries performed in the US and this number is expected to increase to 3.48 million by 2030. Although TKA is an effective intervention, suboptimal outcomes do occur, causing many patients to have difficulty carrying out activities of daily living. Many of these suboptimal outcomes are believed to be the result of poor component alignment and soft tissue balancing during TKA. While surgeons have a keen sense of what is acceptable joint stability, there is no objective definition and they do not know precisely how their actions during surgery affect postoperative stability. The goal of my dissertation research is to determine the relationship between surgical technique and knee joint stability. A successful TKA is dependent on many factors, but component alignment has been identified as particularly important. A variety of techniques exist to establish the rotation of the tibial component and the impact of this variability is unknown. To address this void, we performed a cadaver study to determine how tibial component rotation affects knee stability. We used a surgical navigation system and a custom stability device to measure knee stability and passive kinematics on 10 specimens with the tibial component aligned to 4 commonly used axes. Our study showed that for all rotations, TKA produces a “softer” knee, but showed little change based on the tibial alignment alone. Knee stability during TKA is usually assessed as a surgeon manually manipulates the knee and decides if the joint has acceptable laxity and stiffness. This subjective method does not objectively quantify stability and has unknown repeatability. Using the navigation system and custom stability tool from the cadaver study, we are the first to group to intra-operatively characterized knee stability during a TKA by measuring the force applied by the surgeon and the resulting knee motion on 15 patients. Results from this initial cohort demonstrate that our system is reliable and that TKA generally results in a looser knee.In addition to subjective assessments of stability, some surgeons use the “gap technique” to achieve a balanced joint which aims to establish equal gaps in flexion and extension between the bone cuts on the femur and the tibia. However, it is not thoroughly understood how TKA component alignment affects the gaps or the frontal plane biomechanics of the knee. Using a computer simulation that accurately models the stability testing done in the OR and in the lab, we varied TKA component alignment to determine the effect on the gaps between the bone cuts and the biomechanical behavior of the joint. Our model showed that alignments that achieve balanced gaps do not necessarily result in balanced frontal plane behavior. This dissertation advances the understanding of how TKA changes the stability of the knee. The methodology presented in this dissertation lays the groundwork for future orthopaedic research involving the use novel measurement tools inside the OR and computer modeling.

Published

2013

572. Injury Risk Estimation Expertise: Interdisciplinary Differences in Performance on the ACL Injury Risk Estimation Quiz.

Author

Petushek EJ, Ward P, Cokely ET, and Myer GD

Abstract

Background: Simple observational assessment of movement is a potentially low-cost method for anterior cruciate ligament (ACL) injury screening and prevention. Although many individuals utilize some form of observational assessment of movement, there are currently no substantial data on group skill differences in observational screening of ACL injury risk., Purpose/hypothesis: The purpose of this study was to compare various groups' abilities to visually assess ACL injury risk as well as the associated strategies and ACL knowledge levels. The hypothesis was that sports medicine professionals would perform better than coaches and exercise science academics/students and that these subgroups would all perform better than parents and other general population members., Study Design: Cross-sectional study; Level of evidence, 3., Methods: A total of 428 individuals, including physicians, physical therapists, athletic trainers, strength and conditioning coaches, exercise science researchers/students, athletes, parents, and members of the general public participated in the study. Participants completed the ACL Injury Risk Estimation Quiz (ACL-IQ) and answered questions related to assessment strategy and ACL knowledge., Results: Strength and conditioning coaches, athletic trainers, physical therapists, and exercise science students exhibited consistently superior ACL injury risk estimation ability (+2 SD) as compared with sport coaches, parents of athletes, and members of the general public. The performance of a substantial number of individuals in the exercise sciences/sports medicines (approximately 40%) was similar to or exceeded clinical instrument-based biomechanical assessment methods (eg, ACL nomogram). Parents, sport coaches, and the general public had lower ACL-IQ, likely due to their lower ACL knowledge and to rating the importance of knee/thigh motion lower and weight and jump height higher., Conclusion: Substantial cross-professional/group differences in visual ACL injury risk estimation exist. The relatively profound differences in injury risk estimation accuracy and their potential implications for risk screening suggest the need for additional training and outreach (see http://www.ACL-IQ.org)., Clinical Relevance: Parents and sport coaches would likely benefit from training or use of decision support tools such as the ACL nomogram to assess ACL injury risk. In addition, physicians and other sports medicine professionals may also benefit from improving risk estimation performance to reach clinical biomechanical standards.

Published

2015

573. Length Changes of the Anterolateral Ligament During Passive Knee Motion: A Human Cadaveric Study.

Author

Zens M, Niemeyer P, Ruhhammer J, Bernstein A, Woias P, Mayr HO, Südkamp NP, and Feucht MJ

Subjects

Aged, 80 and over, Anterior Cruciate Ligament surgery, Anterior Cruciate Ligament Injuries, Arthroscopy, Biomechanical Phenomena, Cadaver, Female, Humans, Knee Injuries surgery, Knee Joint surgery, Male, Rotation, Anterior Cruciate Ligament pathology, Anterior Cruciate Ligament Reconstruction methods, Knee Injuries physiopathology, Knee Joint physiopathology, Range of Motion, Articular

Abstract

Background: Persistent rotatory instability after anterior cruciate ligament (ACL) reconstruction may be a result of unaddressed insufficiency of the anterolateral structures. Recent publications about the anatomy of the anterolateral ligament (ALL) have led to a renewed interest in lateral extra-articular procedures, and several authors have proposed ALL reconstruction to supplement intra-articular ACL reconstruction. However, only limited knowledge about the biomechanical characteristics of the ALL exists., Purpose/hypothesis: The purpose of this study was to analyze length changes of the ALL during passive knee motion. The study hypothesis was that the ALL lengthens with knee flexion and internal tibial rotation., Study Design: Controlled laboratory study., Methods: The ALL of 6 cadaveric knees was dissected. Specimens were mounted in a specifically designed test rig that allowed unconstrained passive flexion/extension movement between 0° and 90° as well as external/internal tibial rotation of 25° at various flexion angles. Highly elastic, capacitive polydimethylsiloxane strain gauges were attached to the insertion sites of the ALL. Length changes were recorded continuously at flexion angles between 0° and 90° and during internal/external tibial rotation at 0°, 15°, 30°, 45°, 60°, 75°, and 90°. All measurements were calculated as the relative length change (%) of the ALL compared with 0° of flexion and neutral rotation., Results: The mean relative length of the ALL significantly increased with increasing knee flexion (P < .001), with an estimated mean length change of +0.15% per degree. Both internal and external tibial rotation were independent determinants for length change; internal rotation significantly increased the length of the ALL (P < .001), whereas external rotation significantly decreased its length (P < .001). The mean length change with internal rotation increased with knee flexion, with a significantly greater length change at 90° compared with 0° (P = .048), 15° (P = .033), and 30° (P = .015). The maximum mean length change was +33.77% ± 9.62%, which was observed at 25° of internal rotation and 90° of flexion., Conclusion: The ALL is a nonisometric structure that tensions with knee flexion and internal tibial rotation. Length changes with internal rotation were greater at higher flexion angles, with the greatest length change of the ALL observed at 90° of flexion., Clinical Relevance: The ALL can be considered a stabilizer against internal tibial rotation, especially at deep flexion angles. With regard to ALL reconstruction procedures, tensioning and fixation of the graft should be performed near 90° of flexion because graft tensioning near extension may cause excessive ligament strain with increasing knee flexion., (© 2015 The Author(s).)

Published

2015

574. A Novel Methodology for the Simulation of Athletic Tasks on Cadaveric Knee Joints with Respect to In Vivo Kinematics.

Author

Bates NA, Nesbitt RJ, Shearn JT, Myer GD, and Hewett TE

Subjects

Biomechanical Phenomena, Cadaver, Humans, Knee Joint anatomy & histology, Male, Range of Motion, Articular physiology, Computer Simulation, Knee Joint physiology, Models, Biological

Abstract

Six degree of freedom (6-DOF) robotic manipulators have simulated clinical tests and gait on cadaveric knees to examine knee biomechanics. However, these activities do not necessarily emulate the kinematics and kinetics that lead to anterior cruciate ligament (ACL) rupture. The purpose of this study was to determine the techniques needed to derive reproducible, in vitro simulations from in vivo skin-marker kinematics recorded during simulated athletic tasks. Input of raw, in vivo, skin-marker-derived motion capture kinematics consistently resulted in specimen failure. The protocol described in this study developed an in-depth methodology to adapt in vivo kinematic recordings into 6-DOF knee motion simulations for drop vertical jumps and sidestep cutting. Our simulation method repeatably produced kinetics consistent with vertical ground reaction patterns while preserving specimen integrity. Athletic task simulation represents an advancement that allows investigators to examine ACL-intact and graft biomechanics during motions that generate greater kinetics, and the athletic tasks are more representative of documented cases of ligament rupture. Establishment of baseline functional mechanics within the knee joint during athletic tasks will serve to advance the prevention, repair and rehabilitation of ACL injuries.

Published

2015

575. Validation of a method for combining biplanar radiography and magnetic resonance imaging to estimate knee cartilage contact.

Author

Thorhauer E and Tashman S

Subjects

Biobehavioral Sciences, Biomechanical Phenomena, Cartilage, Articular physiology, Humans, Knee Joint physiology, Lasers, Male, Middle Aged, Software, Weight-Bearing, Cartilage, Articular diagnostic imaging, Knee Joint diagnostic imaging, Magnetic Resonance Imaging methods, Multimodal Imaging methods, Tomography, X-Ray Computed methods

Abstract

Combining accurate bone kinematics data from biplane radiography with cartilage models from magnetic resonance imaging, it is possible to estimate tibiofemoral cartilage contact area and centroid location. Proper validation of such estimates, however, has not been performed under loading conditions approximating functional tasks, such as gait, squatting, and stair descent. The goal of this study was to perform an in vitro validation to resolve the accuracy of cartilage contact estimations in comparison to a laser scanning gold standard. Results demonstrated acceptable reliability and accuracy for both contact area and centroid location estimates. Root mean square errors in contact area averaged 8.4% and 4.4% of the medial and lateral compartmental areas, respectively. Modified Sorensen-Dice agreement scores of contact regions averaged 0.81 ± 0.07 for medial and 0.83 ± 0.07 for lateral compartments. These validated methods have applications for in vivo assessment of a variety of patient populations and physical activities, and may lead to greater understanding of the relationships between knee cartilage function, effects of joint injury and treatment, and the development of osteoarthritis., (Copyright © 2015 IPEM. Published by Elsevier Ltd. All rights reserved.)

Published

2015

576. THE INFLUENCE OF HIP STRENGTH ON KNEE KINEMATICS DURING A SINGLE-LEGGED MEDIAL DROP LANDING AMONG COMPETITIVE COLLEGIATE BASKETBALL PLAYERS.

Author

Suzuki H, Omori G, Uematsu D, Nishino K, and Endo N

Abstract

Background: A smaller knee flexion angle and larger knee valgus angle during weight-bearing activities have been identified as risk factors for non-contact anterior cruciate ligament (ACL) injuries. To prevent such injuries, attention has been focused on the role of hip strength in knee motion control. However, gender differences in the relationship between hip strength and knee kinematics during weight-bearing activities in the frontal plane have not been evaluated., Hypothesis/purpose: The purpose of this study was to determine the influence of hip strength on knee kinematics in both genders during a single-legged landing task in the frontal plane. The hypotheses were that 1) subjects with a greater hip strength would demonstrate larger knee flexion and smaller knee valgus and internal rotation angles and 2) no gender differences would exist during the single-legged landing task., Methods: Forty-three Japanese collegiate basketball players (20 males, 23 females) participated in this study. Three-dimensional motion analysis was used to evaluate knee kinematics during a single-legged medial drop landing (SML). A hand-held dynamometer was used to assess hip extensor (HEXT), abductor (HAB), and external rotator (in two positions: seated position [SHER] and prone [PHER]) isometric strength. Spearman rank correlation coefficients (ρ) were determined for correlations between hip strength and knee kinematics at initial contact (IC) and peak (PK) during SML (p < 0.05)., Results: Negative correlations were observed between the knee valgus angle at IC and HEXT (ρ = -0.48, p = 0.02), HAB (ρ = -0.46, p = 0.03) and PHER (ρ = -0.44, p = 0.04) strength in females. In addition, a significant positive correlation was observed between the knee flexion angle at PK and HEXT strength (ρ = 0.61, p = 0.004) in males., Conclusions: Significant correlations between hip strength and knee kinematics during SML were observed in both genders. Hip strength may, therefore, play an important role in knee motion control during sports activities, suggesting that increased hip strength may help to prevent non-contact ACL injuries in athletes of both genders. Moreover, gender-specific programs may be needed to control abnormal knee motion, as the influence of hip strength on knee kinematics may differ based on gender., Level of Evidence: 3.

Published

2015

577. Relative strain in the anterior cruciate ligament and medial collateral ligament during simulated jump landing and sidestep cutting tasks: implications for injury risk.

Author

Bates NA, Nesbitt RJ, Shearn JT, Myer GD, and Hewett TE

Subjects

Anterior Cruciate Ligament Injuries, Biomechanical Phenomena physiology, Body Weight physiology, Cadaver, Exercise physiology, Female, Humans, Knee Injuries physiopathology, Knee Joint physiology, Male, Medial Collateral Ligament, Knee injuries, Middle Aged, Random Allocation, Range of Motion, Articular physiology, Risk Factors, Robotics, Rupture physiopathology, Sports physiology, Sprains and Strains physiopathology, Stress, Physiological physiology, Torque, Anterior Cruciate Ligament physiology, Medial Collateral Ligament, Knee physiology

Abstract

Background: The medial collateral (MCL) and anterior cruciate ligaments (ACL) are, respectively, the primary and secondary ligamentous restraints against knee abduction, which is a component of the valgus collapse often associated with ACL rupture during athletic tasks. Despite this correlation in function, MCL ruptures occur concomitantly in only 20% to 40% of ACL injuries., Hypothesis/purpose: The purpose of this investigation was to determine how athletic tasks load the knee joint in a manner that could lead to ACL failure without concomitant MCL failure. It was hypothesized that (1) the ACL would provide greater overall contribution to intact knee forces than the MCL during simulated motion tasks and (2) the ACL would show greater relative peak strain compared with the MCL during simulated motion tasks., Study Design: Controlled laboratory study., Methods: A 6-degrees-of-freedom robotic manipulator articulated 18 cadaveric knees through simulations of kinematics recorded from in vivo drop vertical jump and sidestep cutting tasks. Specimens were articulated in the intact-knee and isolated-ligament conditions. After simulation, each ACL and MCL was failed in uniaxial tension along its fiber orientations., Results: During a drop vertical jump simulation, the ACL experienced greater peak strain than the MCL (6.1% vs 0.4%; P < .01). The isolated ACL expressed greater peak anterior force (4.8% vs 0.3% body weight; P < .01), medial force (1.6% vs 0.4% body weight; P < .01), flexion torque (8.4 vs 0.4 N·m; P < .01), abduction torque (2.6 vs 0.3 N·m; P < .01), and adduction torque (0.5 vs 0.0 N·m; P = .03) than the isolated MCL. During failure testing, ACL specimens preferentially loaded in the anteromedial bundle failed at 637 N, while MCL failure occurred at 776 N., Conclusion: During controlled physiologic athletic tasks, the ACL provides greater contributions to knee restraint than the MCL, which is generally unstrained and minimally loaded., Clinical Relevance: Current findings support that multiplanar loading during athletic tasks preferentially loads the ACL over the MCL, leaving the ACL more susceptible to injury. An enhanced understanding of joint loading during in vivo tasks may provide insight that enhances the efficacy of injury prevention protocols., (© 2015 The Author(s).)

Published

2015

578. Use of inertial sensors to predict pivot-shift grade and diagnose an ACL injury during preoperative testing.

Author

Borgstrom PH, Markolf KL, Wang Y, Xu X, Yang PR, Joshi NB, Yeranosian MG, Petrigliano FA, Hame SL, Kaiser WJ, and McAllister DR

Subjects

Adolescent, Adult, Anterior Cruciate Ligament surgery, Biomechanical Phenomena, Cohort Studies, Female, Humans, Joint Instability classification, Joint Instability surgery, Knee Injuries classification, Knee Injuries diagnosis, Knee Injuries surgery, Knee Joint surgery, Male, Middle Aged, Physical Examination methods, Preoperative Care methods, Tibia, Young Adult, Anterior Cruciate Ligament Injuries, Anterior Cruciate Ligament Reconstruction methods, Joint Instability diagnosis, Knee Joint pathology

Abstract

Background: The pivot-shift (PS) examination is used to demonstrate knee instability and detect anterior cruciate ligament (ACL) injury. Prior studies using inertial sensors identified the ACL-deficient knee with reasonable accuracy, but none addressed the more difficult problem of using these sensors to determine whether a subject has an ACL deficiency and to correctly assign a PS grade to a patient's knee., Hypothesis: Inertial sensor data recorded during a PS examination can accurately predict ACL deficiency and the PS score assigned by the examining physician., Study Design: Cohort study (diagnosis); Level of evidence, 2., Methods: A total of 32 patients with unilateral ACL deficiency and 29 with intact ACLs in both knees had inertial sensor modules strapped to the tibia and femur of each limb for preoperative PS testing under anesthesia. Support vector machine (SVM) methods assessed PS grades on the basis of these data, with the examiner's clinical grading shift used as ground truth. A fusion of regression and SVM classification techniques diagnosed ACL deficiency., Results: The clinically determined PS grades of all 122 knees were as follows: 0 (n = 69), +1 (n = 23), +2 (n = 27), and +3 (n = 3). The SVM classification analysis was 77% accurate in correctly classifying these grades, with 98% of computed PS grades falling within ±1 grade of the clinically determined value. The system fusion algorithm diagnosed ACL deficiency in an individual with an overall accuracy of 97%. This method yielded 6% false negatives and 0% false positives., Conclusion: This study used inertial sensor technology with SVM algorithms to accurately determine clinically assigned PS grades in ACL-intact and ACL-deficient knees. By extending the assessment to a separate group of patients without ACL injury, the inertial sensor data demonstrated highly accurate diagnosis of ACL deficiency., (© 2015 The Author(s).)

Published

2015

579. The Influence of Hamstrings Loading on Patellofemoral Biomechanics: A Finite Element Study

Author

Shah, Kushal S.

Subjects

Biomechanics, Biomedical Engineering, Biomedical Research, Knee Biomechanics, Patellofemoral, Finite Element Analysis, FEA, Hamstrings

Abstract

Patellofemoral pain can be caused due to overloading, overuse, patellar malalignment or trauma. Lateral malalignment of patella is observed commonly to cause PF pain. There are various non-operative treatments employed before exploring surgical options. Muscle strengthening is one of the non-operative treatments for relieving patellofemoral pain. However, strengthening of the wrong muscle group could further the lateral malalignment exacerbate the situation. In previous in-vitro studies it has been observed that hamstrings activation causes posterior shift and external rotation of the tibia which could lead to lateral orientation of the patellar tendon resulting in the lateral shift of the patella furthering malalignment in symptomatic knee. Due to the nature of in-vitro studies it limits the physiological conditions and surgical procedures that can be evaluated over the time of study. Thus, the main aim of the current study was to create a validated finite element model to characterize the influence of hamstrings loading on patellofemoral pressures and kinematics. The model was validated by a correlation and regression analysis taking into account the variations due to anatomy, loading conditions and flexion angle between the finite element model and the experimental results. The relationship between the two methods was significant for predicting maximum contact pressure, mean contact pressure and patellar flexion. There was a positive correlation for predicting patellar tilt between the two methods. Hydrostatic pressures, contact shear forces and octahedral shear stresses were the additional parameters obtained from the finite element model which helped to characterize the 3D state of stress in the cartilage. In the finite element model, paired t-tests were performed to test the variations on hamstrings loading on pressure and kinematic parameters and the additional parameters computed to characterize the 3D stress-state. The current model can be used further to simulate surgeries like tibial tuberosity transfers which affect the patellofemoral pressures and kinematics.

Published

2012

580. Characterizing the Ovine Stifle Model as a Preclinical Biomechanical Surrogate for the Human Knee

Author

Herfat, Mohammadsafa T.

Subjects

Biomedical Research, knee biomechanics, activities of daily living, kinematics, 3D kinetics, ovine, animal model

Abstract

The long term goal of this research is to protect knee joint surfaces after knee surgery, thereby reducing the incidence of osteoarthritis. The objective of this dissertation was to determine if the ovine stifle joint is a suitable preclinical biomechanical model for the human knee. Using a 6 degree of freedom (DOF) robot, we applied simulated human and ovine in vivo motions to human knee and ovine stifle joints to measure the 3D joint and ACL kinetics. In addition, we investigated the biomechanical contributions of the other major knee structures. The in vivo studies were designed to determine the effect of surgically implanting motion and force sensors on ovine gait by monitoring the vertical ground reaction forces (VGRFs). Following surgery, we simultaneously measured VGRFs, knee kinematics, and the output from an arthroscopically implantable force probe (AIFP) which was implanted into the ACL. The kinematics were then simulated and applied to the operated joints, while measuring the 3D joint forces and moments. The AIFP output was used to validate the reproduced motions. Finally, we determined the effect of perturbing a simulated in vivo motion on 3D joint and ACL kinetics, which allowed us to investigate the potential effect of motion recording and reproduction errors on force and moment measurements. Applying simulated human and ovine in vivo motions to human knee and ovine stifle joints resulted in few significant kinetic differences between the human and ovine intact joints and ACLs. For a simulated 6 DOF ovine motion applied to the ovine stifle joint, the bony interaction and medial meniscus were the major restraints during the stance phase of gait, whereas the MCL and ACL were the key restraints during the swing phase. The contributions of the ovine structures for a simulated 6 DOF in vivo motion are similar to the roles previously reported for the human. The in vivo studies revealed that surgery to implant motion and force sensors decreased average and peak VGRFs less than 10% and 20%, respectively, across all combinations of speed and grade. VGRF measurements acquired before and after surgery were consistent among animals, with a coefficient of variation averaging no more than 18% for all activities. Increasing treadmill speed only increased hind limb peak VGRFs, whereas increasing treadmill grade significantly increased hind limb average and peak VGRFs. Finally, we investigated the effect of motion recording and recreation errors on kinetic measurements acquired using a robot. The starting position of the in vivo ovine motion was adjusted (perturbed) in each degree of freedom to levels comparable to the extents of our motion recording and recreation errors. Perturbing a simulated in vivo motion in each degree of freedom indicated that only translational perturbations significantly affected the intact knee and ACL kinetics. Also, the average ACL resultant forces across all subjects and perturbations were less than 10% of the average ACL failure load. This dissertation characterized the ovine stifle joint as a biomechanical surrogate for the human knee and validated a robotic methodology for measuring 3D joint and tissue kinetics using in vivo motions acquired during relevant activities of daily living (ADLs). Based on the 3D knee kinetics, the ovine stifle joint is a suitable biomechanical surrogate for the human knee. The novel methodology used to measure the 3D knee kinematics and kinetics for various ADLs has many applications to future orthopaedic research, notably in the areas of functional tissue engineering and sports medicine.

Published

2011

581. Subject Specific Computational Models of the Knee to Predict Anterior Cruciate Ligament Injury

Author

Borotikar, Bhushan S.

Subjects

Biomedical Research, knee joint model, ACL, biomechanics, large scale optimization, ACL injury, knee biomechanics

Abstract

Knee joint is a complex joint involving multiple interactions between cartilage, bone, muscles, ligaments, tendons and neural control. Anterior Cruciate Ligament (ACL) is one ligament in the knee joint that frequently gets injured during various sports or recreational activities. ACL injuries are common in college level and professional athletes especially in females and the injury rate is growing in epidemic proportions despite significant increase in the research focusing on neuromuscular and proprioceptive training programs. Most ACL injuries lead to surgical reconstruction followed by a lengthy rehabilitation program impacting the health and performance of the athlete. Furthermore, the athlete is still at the risk of early onset of osteoarthritis. Regardless of the gender disparity in the ACL injury rates, a clear understanding of the underlying injury mechanisms is required in order to reduce the incidence of these injuries.Computational modeling is a resourceful and cost effective tool to investigate the biomechanics of the knee. The aim of this study was twofold. The first aim was to develop subject specific computational models of the knee joint and the second aim to gain an improved understanding of the ACL injury mechanisms using the subject specific models. We used a quasi-static, multi-body modeling approach and developed MRI based tibio-femoral computational knee joint models. Experimental joint laxity and combined loading data was obtained using five cadaveric knee specimens and a state-of-the-art robotic system. Ligament zero strain lengths and insertion points were optimized using joint laxity data. Combined loading and ACL strain data were used for model validations. ACL injury simulations were performed using factorial design approach comprising of multiple factors and levels to replicate a large and rich set of loading states. This thesis is an extensive work covering all the details of the ACL injury project explained above and highlighting the importance of 1) computational modeling in injury biomechanics, 2) incorporating subject specificity in the models, and 3) validating the models to establish credibility. Techniques used in this study can be employed in developing subject specific injury prevention strategies. These models can be further used to identify gender specific risk factors associated with the ACL injury.

Published

2009

582. Computational investigation of the time-dependent contact behaviour of the human tibiofemoral joint under body weight.

Author

Meng Q, Jin Z, Wilcox R, and Fisher J

Subjects

Aged, Computer Simulation, Elasticity physiology, Female, Friction, Humans, Pressure, Stress, Mechanical, Surface Properties, Synovial Fluid physiology, Viscosity, Body Weight physiology, Cartilage, Articular physiology, Femur physiology, Knee Joint physiology, Models, Biological, Tibia physiology

Abstract

The knee joint is one of the most common sites for osteoarthritis, the onset and progression of which are believed to relate to the mechanical environment of cartilage. To understand this environment, it is necessary to take into account the complex biphasic contact interactions of the cartilage and menisci. In this study, the time-dependent contact behaviour of an intact and a meniscectomized human tibiofemoral joint was characterized under body weight using a computational model. Good agreement in the contact area and femoral displacement under static loads were found between model predictions of this study and published experimental measurements. The time-dependent results indicated that as loading time progressed, the contact area and femoral vertical displacement of both intact and meniscectomized joints increased. More load was transferred to the cartilage-cartilage interface over time. However, the portions of load borne by the lateral and medial compartments did not greatly vary with time. Additionally, during the whole simulation period, the maximum compressive stress in the meniscectomized joint was higher than that in the intact joint. The fluid pressure in the intact and meniscectomized joints remained remarkably high at the condyle centres, but the fluid pressure at the cartilage-meniscus interface decreased faster than that at the condyle centres as loading time progressed. The above findings provide further insights into the mechanical environment of the cartilage and meniscus within the human knee joint., (© IMechE 2014.)

Published

2014

583. The use of rapid prototyped implants to simulate knee joint abnormalities for in vitro testing: a validation study with replica implants of the native trochlea.

Author

Van Haver A, De Roo K, De Beule M, Van Cauter S, Labey L, De Baets P, Claessens T, and Verdonk P

Subjects

Aged, Aged, 80 and over, Cadaver, Female, Femur physiology, Femur surgery, Humans, Knee surgery, Male, Patella physiology, Patella surgery, Biomechanical Phenomena physiology, Knee physiology, Knee Prosthesis, Models, Biological

Abstract

To investigate the biomechanical effect of skeletal knee joint abnormalities, the authors propose to implant pathologically shaped rapid prototyped implants in cadaver knee specimens. This new method was validated by replacing the native trochlea by a replica implant on four cadaver knees with the aid of cadaver-specific guiding instruments. The accuracy of the guiding instruments was assessed by measuring the rotational errors of the cutting planes (on average 3.01° in extension and 1.18° in external/internal rotation). During a squat and open chain simulation, the patella showed small differences in its articulation with the native trochlea and the replica trochlea, which could partially be explained by the rotational errors of the implants. This study concludes that this method is valid to investigate the effect of knee joint abnormalities with a replica implant as a control condition to account for the influence of material properties and rotational errors of the implant., (© IMechE 2014.)

Published

2014

584. Vertical Tears of the Lateral Meniscus: Effects on In Vitro Tibiofemoral Joint Mechanics.

Author

Goyal KS, Pan TJ, Tran D, Dumpe SC, Zhang X, and Harner CD

Abstract

Background: Lateral meniscal tears are often seen with acute anterior cruciate ligament (ACL) injury and may be left in situ, repaired, or treated with meniscectomy. Clinical studies have shown good outcomes with vertical tears left in situ and poor outcomes following meniscectomy. However, clinically relevant studies are needed to establish a biomechanical foundation for treatment of these tears, particularly regarding the effects of meniscectomy., Purpose: To compare tibiofemoral joint mechanics following vertical lateral meniscal tears and meniscectomies. We hypothesized that a peripheral vertical tear of the lateral meniscus would alter joint mechanics, increasing contact pressure and area, and that more drastic effects would be seen following meniscectomy, at higher knee flexion angles, and with increased loads., Study Design: Controlled laboratory study., Methods: Ten fresh-frozen cadaveric knees (average age, 55 ± 12 years) were tested with 5 lateral meniscus states: intact, short vertical tear, extended vertical tear, posterior horn partial meniscectomy (rim intact), and posterior horn subtotal meniscectomy (rim excised). The specimens were loaded axially at knee flexion angles of 0°, 30°, and 60°, and musculotendinous forces were applied, simulating a 2-legged squat. Intra-articular contact pressures were measured using pressure-sensitive Fuji film. Kinematic data were acquired through digitization of fiducial markers., Results: Vertical tears did not cause a significant change in contact pressure or area. Partial meniscectomy increased maximum contact pressures in the lateral compartment at 30° and 60° from 5.3 MPa to 7.2 MPa and 7.6 MPa, respectively (P = .02, P = .007). Subtotal meniscectomy (8.4 MPa) significantly increased contact pressure compared with partial meniscectomy (7.6 MPa) at 60° (P = .04). Both meniscectomy states significantly increased contact pressures with increasing flexion from 0° to 60° (P < .001, P < .001)., Conclusion: Vertical tears of the lateral meniscus during a simulated 2-legged squat did not significantly change contact pressures and areas compared with an intact meniscus. However, treating these tears with partial and complete meniscectomy significantly increased maximum contact pressures., Clinical Relevance: Biomechanical evidence supports treating vertical lateral meniscus tears with meniscal-sparing techniques as opposed to meniscectomy, which may lead to progressive degenerative joint disease from altered joint biomechanics.

Published

2014

585. Clinical biomechanics of instability related to total knee arthroplasty.

Author

Athwal KK, Hunt NC, Davies AJ, Deehan DJ, and Amis AA

Subjects

Biomechanical Phenomena physiology, Cadaver, Humans, Ligaments, Articular physiology, Reoperation, Treatment Failure, Arthroplasty, Replacement, Knee adverse effects, Arthroplasty, Replacement, Knee methods, Joint Instability diagnosis, Joint Instability etiology, Joint Instability prevention & control, Knee Joint surgery, Knee Prosthesis, Prosthesis Design

Abstract

Background: Tibiofemoral instability is a common reason for total knee arthroplasty failure, and may be attributed to soft tissue deficiency and incorrect ligament balancing. There are many different designs of implant with varying levels of constraint to overcome this instability; however there is little advice for surgeons to assess which is suitable for a specific patient, and soft tissue balance testing during arthroplasty is very subjective., Method: The current theories on primary and secondary soft tissue restraints to anterior/posterior, varus/valgus, and internal/external rotational motion of the knee are discussed. The paper reviews biomechanics literature to evaluate instability in the intact and implanted knee., Findings: The paper highlights important intra- and extra-capsular structures in the knee and describes the techniques used by clinicians to assess instability perioperatively. In vitro cadaveric studies were found to be a very useful tool in comparing different implants and contributions of different soft tissues., Interpretation: In vitro cadaveric studies can be utilised in helping less experienced surgeons with soft tissue releases and determining the correct implant. For this to happen, more biomechanical studies must be done to show the impact of release sequences on implanted cadavers, as well as determining if increasingly constrained implants restore the stability of the knee to pre-deficient conditions., (Copyright © 2013. Published by Elsevier Ltd.)

Published

2014

586. Biomechanical characteristics of 3 pivot-shift maneuvers for the anterior cruciate ligament-deficient knee: in vivo evaluation with an electromagnetic sensor system.

Author

Kitamura N, Yokota M, Kondo E, Miyatake S, Nagamune K, and Yasuda K

Subjects

Adolescent, Adult, Anterior Cruciate Ligament physiopathology, Biomechanical Phenomena, Electromagnetic Fields, Female, Humans, Male, Middle Aged, Young Adult, Anterior Cruciate Ligament Injuries, Knee Joint physiopathology, Physical Examination methods

Abstract

Background: A disadvantage of pivot-shift maneuvers is that the examiner has to subjectively evaluate the degree of pivot shift observed. It is unknown whether the various maneuvers are biomechanically identical., Purpose: To compare biomechanical features of 3 clinical maneuvers for the anterior cruciate ligament (ACL)-deficient knee: the pivot-shift test, the jerk test, and the N-test., Study Design: Controlled laboratory study., Methods: A total of 28 patients with an isolated ACL injury were examined by use of 3 pivot-shift maneuvers (pivot-shift test, jerk test, and N-test). An electromagnetic sensor system was used to evaluate the 3-dimensional knee kinematics of each patient's injured and uninjured knees during each maneuver. Peak coupled anterior tibial translation (pCAT) and maximal acceleration of posterior translation (APT) were measured relative to results during a flexion-extension motion in each test., Results: The pCAT of the pivot-shift test was significantly greater than that of both the jerk test and the N-test (P = .0020 and P < .0001, respectively); there was no statistical difference in pCAT between the jerk test and the N-test. The APT of the N-test was significantly greater than that of both the pivot-shift test and the jerk test (P < .0001), while there was no statistical difference between the pivot-shift and the jerk tests. There was no correlation between pCAT and APT in each test., Conclusion: The pivot-shift test, jerk test, and N-test have different biomechanical characteristics to induce the pivot-shift phenomenon in the ACL-deficient knee. The pivot-shift test produced the largest side-to-side difference in pCAT, whereas the N-test provoked the largest side-to-side difference in APT., Clinical Relevance: The biomechanical differences in pivot-shift maneuvers are caused by technical differences, and clinicians should understand these biomechanical differences while practicing the maneuvers. The electromagnetic sensor system is clinically useful for quantifying the pivot-shift phenomenon.

Published

2013

587. Trunk and hip biomechanics influence anterior cruciate loading mechanisms in physically active participants.

Author

Frank B, Bell DR, Norcross MF, Blackburn JT, Goerger BM, and Padua DA

Subjects

Female, Healthy Volunteers, Humans, Male, Regression Analysis, Torso physiology, Weight-Bearing physiology, Young Adult, Anterior Cruciate Ligament physiology, Hip Joint physiology, Knee Joint physiology

Abstract

Background: Excessive trunk motion and deficits in neuromuscular control (NMC) of the lumbopelvic hip complex are risk factors for anterior cruciate ligament (ACL) injury. However, the relationship between trunk motion, NMC of the lumbopelvic hip complex, and triplanar knee loads during a sidestep cutting task has not been examined., Purpose: To determine if there is an association between multiplanar trunk motion, NMC of the lumbopelvic hip complex, and triplanar knee loads with ACL injury during a sidestep cutting task., Study Design: Descriptive laboratory study., Methods: The hip and knee biomechanics and trunk motion of 30 participants (15 male, 15 female) were analyzed during a sidestep cutting task using an optoelectric camera system interfaced to a force plate. Trunk and lower extremity biomechanics were calculated from the kinematic and ground-reaction force data during the first 50% of the stance time during the cutting task. Pearson product moment correlation coefficients were calculated between trunk and lower extremity biomechanics. Multiple linear regression analyses were carried out to determine the amount of variance in triplanar knee loading explained by trunk motion and hip moments., Results: A greater internal knee varus moment (mean, 0.11 ± 0.12 N·m/kg*m) was associated with less transverse-plane trunk rotation away from the stance limb (mean, 20.25° ± 4.42°; r = -0.46, P = .011) and a greater internal hip adduction moment (mean, 0.33 ± 0.25 N·m/kg*m; r = 0.83, P < .05). A greater internal knee external rotation moment (mean, 0.11 ± 0.08 N·m/kg*m) was associated with a greater forward trunk flexion (mean, 7.62° ± 5.28°; r = 0.42, P = .020) and a greater hip internal rotation moment (mean, 0.15 ± 0.16 N·m/kg*m; r = 0.59, P = .001). Trunk rotation and hip adduction moment explained 81% (P < .05) of the variance in knee varus moment. Trunk flexion and hip internal rotation moment explained 48% (P < .05) of the variance in knee external rotation moment., Conclusion: Limited trunk rotation displacement toward the new direction of travel and hip adduction moment are associated with an increased internal knee varus moment, while a combined increase in trunk flexion displacement and hip internal rotation moment is associated with a higher internal knee external rotation moment., Clinical Relevance: Prevention interventions for ACL injury should encourage trunk rotation toward the new direction of travel and limit excessive trunk flexion while adjusting frontal- and transverse-plane hip NMC.

Published

2013

588. Influence of cartilage and menisci on the sagittal slope of the tibial plateaus.

Author

Cinotti G, Sessa P, Ragusa G, Ripani FR, Postacchini R, Masciangelo R, and Giannicola G

Subjects

Adolescent, Adult, Biomechanical Phenomena, Data Interpretation, Statistical, Female, Humans, Magnetic Resonance Imaging, Male, Middle Aged, Sex Factors, Young Adult, Cartilage anatomy & histology, Knee Joint anatomy & histology, Menisci, Tibial anatomy & histology, Tibia anatomy & histology

Abstract

We analyzed the magnetic resonance studies of the knee in 80 subjects, 45 men and 35 women with a mean age of 38.9 years, who showed no pathological condition of the joint. Using an imaging visualization software, the sagittal longitudinal axis of the tibia was identified. The angle between this axis and a line tangent to the bone profile of the tibial plateau (bone slope) and to the superior border of the menisci (meniscal slope) were calculated. Thickness of anterior and posterior portion of menisci and underlying cartilage were also measured. The bone slope averaged 8° and 7.7° on the medial and lateral sides, respectively. The mean meniscal slope was 4.1° and 3.3° on the medial and lateral sides, respectively, with a significant difference compared with the bone slope. Menisci and underlying cartilage were significantly thicker in their posterior than their anterior portion (7.6 and 5.2 mm, respectively, in the medial compartment; 8.6 and 5.2 mm, respectively, in the lateral compartment). The presence of cartilage and menisci implies a significant decrease in the posterior tibial slope. In the lateral compartment, the greater the bone slope, the larger the difference between bone and meniscal slope, which means that a marked posterior tilt of the lateral tibial plateau is decreased by the cartilage and meniscus. These findings should be taken into account in planning surgical procedures which affect the slope of the articular tibial surface., (Copyright © 2012 Wiley Periodicals, Inc.)

Published

2013

589. Osteolysis around total knee arthroplasty: a review of pathogenetic mechanisms.

Author

Gallo J, Goodman SB, Konttinen YT, Wimmer MA, and Holinka M

Subjects

Animals, Humans, Models, Biological, Prosthesis Failure, Biocompatible Materials adverse effects, Knee Joint physiopathology, Knee Prosthesis adverse effects, Osteolysis etiology, Osteolysis physiopathology

Abstract

Aseptic loosening and other wear-related complications are some of the most frequent late reasons for revision of total knee arthroplasty (TKA). Periprosthetic osteolysis (PPOL) pre-dates aseptic loosening in many cases, indicating the clinical significance of this pathogenic mechanism. A variety of implant-, surgery- and host-related factors have been delineated to explain the development of PPOL. These factors influence the development of PPOL because of changes in mechanical stresses within the vicinity of the prosthetic device, excessive wear of the polyethylene liner, and joint fluid pressure and flow acting on the peri-implant bone. The process of aseptic loosening is initially governed by factors such as implant/limb alignment, device fixation quality and muscle coordination/strength. Later, large numbers of wear particles detached from TKA trigger and perpetuate particle disease, as highlighted by progressive growth of inflammatory/granulomatous tissue around the joint cavity. An increased accumulation of osteoclasts at the bone-implant interface, impairment of osteoblast function, mechanical stresses and increased production of joint fluid contribute to bone resorption and subsequent loosening of the implant. In addition, hypersensitivity and adverse reactions to metal debris may contribute to aseptic TKA failure, but should be determined more precisely. Patient activity level appears to be the most important factor when the long-term development of PPOL is considered. Surgical technique, implant design and material factors are the most important preventative factors, because they influence both the generation of wear debris and excessive mechanical stresses. New generations of bearing surfaces and designs for TKA should carefully address these important issues in extensive preclinical studies. Currently, there is little evidence that PPOL can be prevented by pharmacological intervention., (Copyright © 2013 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.)

Published

2013

590. Tracking Knee Joint Functional Axes through Tikhonov Filtering and Plűcker Coordinates.

Author

Kim W, Kim YH, Veloso AP, and Kohles SS

Abstract

Researchers have reported several compensation methods to estimate bone and joint position from a cluster of skin-mounted markers as influenced by Soft Tissue Artifacts (STA). Tikhonov Regularization Filtering (TRF) as a means to estimate Instantaneous Screw Axes (ISA) was introduced here as a means to reduce the displacement of a rigid body to its simplest geometric form. Recent studies have suggested that the ISA of the knee, i.e., Knee Functional Axes (KFA), might be closely connected to the estimation of constraint forces such as those due to medial and lateral connective tissues. The estimations of ISAs were known to be highly sensitive to noisy data, which may be mathematically ill-posed, requiring smoothing such as that conducted by regularization. The main contribution in this work was to establish the reciprocal connection between the KFA and Ground Reaction Forces (GRF) as a means to estimate joint constraint forces. Presented results compare the computational performance with published kinetic and kinematic joint data generated from an instrumented total knee replacement. Implications of these preliminary findings with respect to dynamic alignment as a functional anatomic metric are discussed.

Published

2013

591. Knee biomechanics and total knee replacement

Author

T. Scott Stanwyck, Jorge O. Galante, and Thomas P. Andriacchi

Subjects

musculoskeletal diseases, Knee Joint, Knee biomechanics, Total knee replacement, Prosthesis Design, Cruciate ligament, Fixation (surgical), medicine, Humans, Prosthesis design, Orthopedics and Sports Medicine, Femur, Cementation, Orthodontics, Tibia, business.industry, Biomechanics, musculoskeletal system, Biomechanical Phenomena, Prosthesis Failure, medicine.anatomical_structure, Stress, Mechanical, Implant, Knee Prosthesis, business, human activities

Abstract

The biomechanics of the knee joint provide an important basis for the rationale in the design and selection of appropriate total knee arthroplasty. This article examines knee biomechanics in terms of patient function, prosthesis design, cruciate ligament retention, alignment, and fixation of the tibial component. While design and surgical technique for total knee replacement progress, a better understanding of the characteristics of joint loading, stress distribution, and the biologic response of bone to stress will provide the potential to improve both function and implant longevity.

Published

1986

592. Review of some basic assumptions in knee biomechanics

Author

M. Nissan

Subjects

medicine.medical_specialty, Engineering, Knee Joint, Tibia, Computers, Knee biomechanics, business.industry, Muscles, Rehabilitation, Work (physics), Biomedical Engineering, Biophysics, Anatomy, musculoskeletal system, Biomechanical Phenomena, Line of action, Physical medicine and rehabilitation, Ligaments, Articular, medicine, Humans, Knee, Orthopedics and Sports Medicine, business, Locomotion

Abstract

A considerable number of geometric and kinesiologic assumptions are used in the process of knee biomechanic analysis. Some of these were assessed in the work reported here, using specially made computer programmes. The results concerning eight of the assumptions are reported in this paper. Cut-Off-Frequency ( COF ) of 10 Hz was found to be adequate for the data filtration. The assumption of the intercondylar force point of action lying on the tibial plateau along an M - L axis and the definition of the geometric knee center were shown to be questionable, causing probably big mistakes in the evaluation of knee forces and moments. The relatively low sensitivity to the definition of muscles and ligaments line of action was shown. Agonistic and antagonistic activity of muscles and loading of ligaments were shown to be possible and helpful in balancing the knee. The usually assumed in-phase, balanced activity of the hamstrings muscles or the gastrocnemius heads were shown to be a possibility, although an out-of-phase or unbalanced activity was also possible.

Published

1980

593. A 5° medial wedge reduces frontal but not saggital plane motion during jump landing in highly trained women athletes.

Author

Joseph MF, Denegar CR, Horn E, Macdougall B, Rahl M, Sheehan J, Trojian T, Anderson JM, Clark JE, and Kraemer WJ

Abstract

Lower extremity mechanics during landing have been linked to traumatic and nontraumatic knee injuries, particularly in women's athletics. The effects of efforts to mitigate these risks have not been fully elucidated. We previously reported that a 5° medial wedge reduced ankle eversion and knee valgus. In the present report we further investigated the effect of a 5° medial wedge inserted in the shoes of female athletes on frontal plane hip motion, as well as ankle, knee, hip, and trunk saggital plane motion during a jump landing task. Kinematic data were obtained from 10 intercollegiate female athletes during jump landings from a 31 cm platform with and without a 5° medial wedge. Hip adduction was reduced 1.98° (95% CI 0.97-2.99°) by the medial wedge but saggital plane motions were unaffected. A 5° medial wedge reduces frontal plane motion and takes the knee away from a position associated with anterior cruciate ligament injury and patellofemoral pain syndrome. Although frontal plane motion was not captured it is unlikely to have increased in a bilateral landing task. Thus, it is likely that greater muscle forces were generated in these highly trained athletes to dissipate ground reaction forces when a medial wedge was in place. Additional investigation in younger and lesser trained athletes is warranted to assess the impact of orthotic devices on knee joint mechanics.

Published

2010

594. Influence of medial meniscectomy on stress distribution of the femoral cartilage in porcine knees: a 3D reconstructed T2 mapping study

Author

Kenya Murase, Shinichi Tamura, Nobuhiko Sugano, Hisashi Tanaka, T. Shiomi, Takashi Nishii, and H. Yoshikawa

Subjects

Cartilage, Articular, Cartilage T2, Swine, Biomedical Engineering, Three dimension, Knee Joint, medicine.disease_cause, Menisci, Tibial, Weight-bearing, Weight-Bearing, Arthroscopy, Rheumatology, Medicine, Animals, Orthopedics and Sports Medicine, Meniscectomy, medicine.diagnostic_test, business.industry, Knee biomechanics, Cartilage, Magnetic resonance imaging, Anatomy, Femoral cartilage, Compression (physics), Magnetic Resonance Imaging, Stifle, Sagittal plane, Disease Models, Animal, medicine.anatomical_structure, business, Medial meniscus, MRI

Abstract

SummaryObjectivePrevious studies have shown that meniscectomy results in an increase of local load transmission and may cause degeneration of the knee cartilage. Using 3D reconstructed T2 mapping, we examined the influence on the femoral cartilage under loading after medial meniscectomy.DesignTen porcine knees were imaged using a pressure device and a 3.0-T magnetic resonance imaging (MRI) system. Consecutive sagittal T2 maps were obtained in neutral alignment with and without compression, and under compression at 10° varus alignment. After medial meniscectomy, the aforementioned MRI was repeated. Cartilage T2 before and after meniscectomy under each condition were compared at the 12 regions of interest (ROIs) defined on the 3D weight-bearing area of the femoral cartilage.ResultsBefore meniscectomy, large decreases in T2 under neutral compression were mainly seen at the anterior and central ROIs of the medial cartilage, which shifted to the posterior ROIs after meniscectomy. There were significant differences in decrease in T2 ratio with loading before and after meniscectomy (9.8%/4.3% at the anterior zone, 4.0%/11.4% at the posterior zone, P

595. Anterolateral knee biomechanics

Author

Andrew A. Amis

Subjects

Joint Instability, musculoskeletal diseases, Knee Joint, Rotation, STRUCTURAL-PROPERTIES, Knee biomechanics, MEDIAL COLLATERAL LIGAMENT, Tibial internal rotation, 03 medical and health sciences, 0302 clinical medicine, ROTATORY INSTABILITY, Anterolateral rotatory instability, ILIOTIBIAL TRACT, Medicine, Humans, Knee, Biomechanics, Orthopedics and Sports Medicine, Anterior Cruciate Ligament, PIVOT SHIFT TEST, 1106 Human Movement And Sports Science, 030222 orthopedics, Science & Technology, business.industry, Anterior Cruciate Ligament Injuries, ACL, Internal rotation, TIBIAL DISPLACEMENT, 1103 Clinical Sciences, IN-VITRO, 030229 sport sciences, Anatomy, musculoskeletal system, LENGTH CHANGES, Biomechanical Phenomena, Joint Deformities, Acquired, Orthopedics, Rotatory instability, Ilio-tibial band, Ligaments, Articular, Surgery, business, Life Sciences & Biomedicine, Sport Sciences, SEGOND FRACTURE

Abstract

This article reviews the evidence for the roles of the anterolateral soft-tissue structures in rotatory stability of the knee, including their structural properties, isometry, and contributions to resisting tibial internal rotation. These data then lead to a biomechanical demonstration that the ilio-tibial band is the most important structure for the restraint of anterolateral rotatory instability. Level of evidence V.

596. Design and application of a biomechanical test bench to investigate knee joint injuries

Abstract

Einleitung Das Knie gehört aufgrund der Größe, Komplexität sowie hohen Belastungen zu den verletzungsempfindlichsten Gelenken. Die kombinierten biomechanischen und kinematischen Auswirkungen von Kniegelenksverletzungen sowie deren Behandlungsmöglichkeiten sind bisher nur unzureichend bekannt und untersucht. Die vorliegende PhD Arbeit beschreibt die Entwicklung und Konstruktion sowie die erste Anwendung eines neuen biomechanischen Simulators zur in vitro Testung von Kniegelenken. Die erste Anwendung befasste sich mit der Validierung bezüglich der Reproduzierbarkeit sowie Sensibilität des neuen Testaufbaus. Der neuentwickelte Kniegelenksimulator Durch die Anordnung verschiedenster Dreh- und Gleitlager erlaubt der Testaufbau Kniegelenksbewegungen in allen sechs Freiheitsgraden. Die Kniegelenksbewegungen und die daraus resultierenden Belastungen werden durch eine aktive Ansteuerung der wichtigsten Kniemuskeln erzeugt. Fünf pneumatische Zylinder erzeugen die Muskelkräfte des Quadriceps (vastus medialis, vastus lateralis, vastus intermedius/ rectus femoris) sowie der Hamstrings (biceps femoris, semimembranosus/ semitendinosus). Die Kniegelenkskinematik und Muskelkräfte werden zeitgleich erfasst. Ein aktives Regel- und Steuerungsprogramm wurde erfolgreich entwickelt und implementiert. Methode Vier humane Kniegelenke wurden für die Validierungstests verwendet. Im ersten Schritt wurden die nativen Knie jeweils dreimal zu je sieben Flexion-Extension-Zyklen zwischen 5° und 60° bewegt. Um zu überprüfen ob der neuentwickelte Testaufbau Unterschiede in der Kniekinematik und Muskelkräfte zwischen den verschiedenen Kniezuständen detektieren kann, wurde im ersten Schritt das hintere Kreuzband und im zweiten Schritt zusätzlich das laterale Seitenband durchtrennt. Das Testprotokoll wurde für alle Kniezustände konstant gehalten (3×(7×5°–60°)). Ausgewertet wurden die kinematischen Daten (varus-valgus Rotation, Innen-Außenrotation und anteriore-posteriore Translation) sowie die maximalen, Introduction Due to the complexity and high loading, the knee is one of the most vulnerable joints. Surgeries to restore the physiological conditions and the function of an injured knee have a major impact on the forces in the musculoskeletal structures. Up to now, the effects of injuries, as well as the impact of their therapies on the knee kinematics combined with the resulting loads have not been studied extensively. This PhD project presents the design and application of a novel biomechanical test bench for the in vitro evaluation of the knee joint. The aim of the initial application was to validate the reproducibility, as well as the sensitivity of the test bench. The novel test bench for the knee joint With several bearings, the novel biomechanical test bench allows the kinematics of the knee joint to be studied in all six degrees of freedom. The loading of the knee and flexion-extension movements are induced by active muscle forces. Five pneumatic cylinders are used to simulate the quadriceps (vastus medialis, vastus lateralis, vastus intermedius/ rectus femoris) and the hamstring muscles (biceps femoris, semimembranosus/ semitendinosus). Actively applied muscle forces and knee kinematics are measured simultaneously. An active feedback control system has successfully been developed and implemented. Methods In the first part of the validation tests, four fresh frozen native knees were tested three times each with seven flexion–extension cycles between 5° and 60°. Afterwards, the posterior cruciate ligament and finally the lateral collateral ligament were dissected. All knees states were tested in identical conditions (3×(7×5°–60°)) in order to evaluate whether the novel test bench is capable of detecting differences in knee kinematics and muscle loads between a native and an injured state. Kinematic data for the knee (varus–valgus rotation, internal–external rotation, and changes in anterior–posterior translation), as well as the maximal muscle forces were eva, Dipl.-Ing. Christian Heinz Heinrichs, Zusammenfassung in englischer Sprache, Dissertation Medical University of Innsbruck 2018

597. Clinical implications of knee biomechanics

Author

Donald B. Kettelkamp

Subjects

musculoskeletal diseases, medicine.medical_specialty, Reconstructive surgery, Rotation, Knee biomechanics, Body weight, Arthritis, Rheumatoid, Motion, Activities of Daily Living, Deformity, medicine, Humans, Femur, Knee, Tibia, Stance phase, business.industry, Arthritis, Articular surface, musculoskeletal system, Surgery, Biomechanical Phenomena, Potentiometry, medicine.symptom, business, Locomotion

Abstract

Motion and forces at the knee have clinical implications in reconstructive surgery. The discussion of these implications is based on the following biomechanical information. Normal knee motion during simple activities of daily living utilizes up to 110° of flexion-extension and 15° of abduction-adduction and rotation. The instant centers of motion and surface velocities become abnormal with intra-articular derangement. The average area of articular surface contact between the tibia and femur on the medial plateau is 1.6 times larger than the lateral. Under static conditions, the compression force per unit area is increased by deformity. The forces acting through the knee during walking approximate three times body weight. Rheumatoid and degenerative arthritis are associated with decreased stance phase flexion-extension.

Published

1973

598. [Untitled]

Subjects

030203 arthritis & rheumatology, 0301 basic medicine, General Veterinary, Knee biomechanics, business.industry, Painful knee, Disease progression, Translational medicine, Osteoarthritis, Meniscus (anatomy), musculoskeletal system, medicine.disease, Bioinformatics, Pathophysiology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Knee pain, medicine, medicine.symptom, business

Abstract

Serious knee pain and related disability have an annual prevalence of approximately 25% on those over the age of 55 years. As curative treatments for the common knee problems are not available to date, knee pathologies typically progress and often lead to osteoarthritis (OA). While the roles that the meniscus plays in knee biomechanics are well characterized, biological mechanisms underlying meniscus pathophysiology and roles in knee pain and OA progression are not fully clear. Experimental treatments for knee disorders that are successful in animal models often produce unsatisfactory results in humans due to species differences or the inability to fully replicate disease progression in experimental animals. The use of animals with spontaneous knee pathologies, such as dogs, can significantly help addressing this issue. As microscopic and macroscopic anatomy of the canine and human menisci are similar, spontaneous meniscal pathologies in canine patients are thought to be highly relevant for translational medicine. However, it is not clear whether the biomolecular mechanisms of pain, degradation of extracellular matrix, and inflammatory responses are species dependent. The aims of this review are (1) to provide an overview of the anatomy, physiology, and pathology of the human and canine meniscus, (2) to compare the known signaling pathways involved in spontaneous meniscus pathology between both species, and (3) to assess the relevance of dogs with spontaneous meniscal pathology as a translational model. Understanding these mechanisms in human and canine meniscus can help to advance diagnostic and therapeutic strategies for painful knee disorders and improve clinical decision making.

599. Human knee laxity in ACL-deficient and physiological contralateral joints: intra-operative measurements using a navigation system

Author

Pierre Imbert, Claudio Belvedere, and Alberto Leardini

Subjects

Adult, Joint Instability, Male, musculoskeletal diseases, Clinical tests, Intra operative, Adolescent, Knee Joint, Anterior cruciate ligament, Knee surgical navigation, Biomedical Engineering, Knee joint laxity, Lachman test, Knee instability tests, Drawer test, Biomaterials, Intraoperative Period, Young Adult, medicine, Humans, Radiology, Nuclear Medicine and imaging, ACL-deficiency knee, Anterior Cruciate Ligament, Acl deficient, Orthodontics, Radiological and Ultrasound Technology, business.industry, Knee biomechanics, Research, General Medicine, Anatomy, Contralateral healthy knee, Middle Aged, musculoskeletal system, medicine.anatomical_structure, Knee laxity, Female, business

Abstract

Background The comprehension of human knee laxity and of the failures of relevant surgical reconstructions of the anterior cruciate ligament (ACL) can be enhanced by the knowledge of the laximetric status of the contralateral healthy knee (CHK). Rarely this is available in patients, directly from the skeletal structures, and for a number of the standard clinical tests. The general aim of this study was to measure the extent to which laxity occurs immediately before surgery in the ACL deficient knee (ADK) with respect to CHK, in a number of standard clinical evaluation tests. Method Thirty-two patients with ACL deficiency were analyzed at ADK and at CHK by a navigation system immediately before reconstructions. Knee laxity was assessed based on digitized anatomical references during the antero-posterior drawer, Lachman, internal-external rotation, varus-valgus, and pivot-shift tests. Antero-posterior laxity was normalized based on patient-specific length of the tibial plateau. Results In the drawer test, statistical significance (p

600. Specific muscle strength is reduced in female knees with incidcence radiographic osteoarthritis

Author

T. Dannhauer, David T. Felson, Wolfgang Wirth, Jingbo Niu, M. Sattler, and Felix Eckstein

Subjects

musculoskeletal diseases, Knee biomechanics, business.industry, Radiography, Biomedical Engineering, Isometric exercise, Osteoarthritis, Thigh, medicine.disease, musculoskeletal system, Specific strength, medicine.anatomical_structure, Rheumatology, Statistical significance, Muscle strength, medicine, Orthopedics and Sports Medicine, Nuclear medicine, business

Abstract

s / Osteoarthritis and Cartilage 21 (2013) S63–S312 S220 415 SPECIFIC MUSCLE STRENGTH IS REDUCED IN FEMALE KNEES WITH INCIDCENCE RADIOGRAPHIC OSTEOARTHRITIS M. Sattler y, J. Niu z, T. Dannhauer y, W. Wirth y, D. Felson z, F. Eckstein y. y Paracelsus Med. Univ., Salzburg, Austria; zClin. Epidemiology Res. & Training Unit, Boston Univ. Sch. of Med., Boston, MA, USA Purpose: Quadriceps strength plays an important role in knee biomechanics. Quadriceps weakness has been shown to be related to the onset of knee symptoms in women, but has not been associated with incident radiographic knee OA (KOA). However, previous studies have not examined muscle specific strength, a potentially more physiologically relevant measure of strength that accounts for the individual cross sectional area (CSA) of muscles. Here we explore whether specific strength differs between knees with incident radiographic KOA vs. nonincident controls. Methods: Of 4796 Osteoarthritis Initiative participants, we studied knees that showed incident radiographic KOA (central readings, fixed flexion radiographs). These were defined as Kellgren and Lawrence grade (KLG) 0 or 1 knees at baseline, in which the combination of a definite osteophyte AND joint space loss (OARSI JSN>grade1) developed by 48 month follow up. These knees were matched by baseline KLG0/KLG1 frequency (w30%/70%) to control knees without incident KOA at 48M. Of 447 case and control knees, 342 had axial T1weighted spinecho MRIs of the thigh AND maximal isometric strength measures of the extensors and flexors (Good Strength Chair, Metitur). To determine CSAs of the quads, hamstrings and adductors, we selected an MRI slice located at 30% femoral length (distal to proximal) based on an estimate derived from body height. Strength was normalized to weight (norm_strength1⁄4strength/weight). Muscle quality was evaluated by computing spec_strength (the primary analysis), and by the mean and standard deviation (SD) of the T1weighted thigh muscle MRI signal intensity (as a proxy of fatty infiltration). Cases and controls were compared using conditional logistic regression. Results: Of 179 knees with incident radiographic KOA, 113 were female (age 60.8, BMI 29.2) and 66 male (60.4; 29.4); of 195 non-incident knees, 113 were female (60.8, 27.0) and 82 male (59.4; 27.7). Quad spec_strength was found significantly (-12%) lower in incident vs. nonincident knees (Table 1). Quad strength (-7.1%) and norm_strength (-15%) were also significantly lower, quad CSA significantly greater (+6.5%), and the mean and SD quad MRI signal intensity greater (w5%, not significant) in incident vs. non-incident knees (Table 1). Similar relationships were observed in the flexors and adductors. In male knees, in contrast, the observed thigh muscle spec_strength was greater in incident than in non-incident knees, but the difference did not reach statistical significance. Conclusion: In women (but not in men), incident radiographic KOA is found to be associated with lower muscle strength per unit CSA (spec_strength) and per unit weight (norm_strength). Obesity, which is independently associated with incident radiographic KOA inwomen, may be associated with fatty infiltration of thigh muscles, and may cause an unfavourable ratio between loading and muscular stabilization of the knee. Our findings suggest that important relations of muscle function and risk of radiographic KOA exist and are detected with physiologically relevant measures of strength (i.e. specific strength). Quadriceps muscle status in incident and non-incident female knees Incident Non-incident