Your search keyword '"Duda, G."' showing total 12 results

1. In vivo hip joint loads and pedal forces during ergometer cycling.

Author

Damm P, Dymke J, Bender A, Duda G, and Bergmann G

Subjects

Aged, Biomechanical Phenomena, Humans, Male, Middle Aged, Arthroplasty, Replacement, Hip, Bicycling physiology, Hip Joint physiology

Abstract

The rising prevalence of osteoarthritis and an increase in total hip replacements calls for attention to potential therapeutic activities. Cycling is considered as a low impact exercise for the hip joint and hence recommended. However, there are limited data about hip joint loading to support this claim. The aim of this study was to measure synchronously the in vivo hip joint loads and pedal forces during cycling. The in vivo hip joint loads were measured in 5 patients with instrumented hip implants. Data were collected at several combinations of power and cadence, at two saddle heights. Joint loads and pedal forces showed strong linear correlation with power. So the relationship between the external pedal forces and internal joint forces was shown. While cycling at different cadences the minimum joint loads were acquired at 60RPM. The lower saddle height configuration results in an approximately 15% increase compared to normal saddle height. The results offered new insights into the actual effects of cycling on the hip joint and can serve as useful tools while developing an optimum cycling regimen for individuals with coxarthrosis or following total hip arthroplasty. Due to the relatively low contact forces, cycling at a moderate power level of 90W at a normal saddle height is suitable for patients., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2017

2. In vivo measured joint friction in hip implants during walking after a short rest.

Author

Damm P, Bender A, Duda G, and Bergmann G

Subjects

Aged, Algorithms, Female, Friction, Humans, Kinetics, Male, Mechanical Phenomena, Middle Aged, Models, Theoretical, Postoperative Period, Temperature, Time Factors, Hip Joint physiology, Hip Prosthesis, Rest physiology, Walking physiology

Abstract

Introduction: It has been suspected that friction in hip implants is higher when walking is initiated after a resting period than during continuous movement. It cannot be excluded that such increased initial moments endanger the cup fixation in the acetabulum, overstress the taper connections in the implant or increase wear. To assess these risks, the contact forces, friction moments and friction coefficients in the joint were measured in vivo in ten subjects. Instrumented hip joint implants with telemetric data transmission were used to access the contact loads between the cup and head during the first steps of walking after a short rest., Results: The analysis demonstrated that the contact force is not increased during the first step. The friction moment in the joint, however, is much higher during the first step than during continuous walking. The moment increases throughout the gait cycle were 32% to 143% on average and up to 621% individually. The high initial moments will probably not increase wear by much in the joint. However, comparisons with literature data on the fixation resistance of the cup against moments made clear that the stability can be endangered. This risk is highest during the first postoperative months for cementless cups with insufficient under-reaming. The high moments after a break can also put taper connections between the head and neck and neck and shaft at a higher risk., Discussion: During continuous walking, the friction moments individually were extremely varied by factors of 4 to 10. Much of this difference is presumably caused by the varying lubrication properties of the synovia. These large moment variations can possibly lead to friction-induced temperature increases during walking, which are higher than the 43.1°C which have previously been observed in a group of only five subjects.

Published

2017

3. Standardized Loads Acting in Hip Implants.

Author

Bergmann G, Bender A, Dymke J, Duda G, and Damm P

Subjects

Activities of Daily Living, Aged, Biomechanical Phenomena, Female, Friction, Germany, Humans, Male, Middle Aged, Models, Theoretical, Postoperative Period, Prosthesis Design, Reference Values, Reproducibility of Results, Stress, Mechanical, Time Factors, Walking, Arthroplasty, Replacement, Hip instrumentation, Hip Joint, Hip Prosthesis, Materials Testing, Weight-Bearing

Abstract

With the increasing success of hip joint replacements, the average age of patients has decreased, patients have become more active and their expectations of the implant durability have risen. Thus, pre-clinical endurance tests on hip implants require defining realistic in vivo loads from younger and more active patients. These loads require simplifications to be applicable for simulator tests and numerical analyses. Here, the contact forces in the joint were measured with instrumented hip implants in ten subjects during nine of the most physically demanding and frequent activities of daily living. Typical levels and directions of average and high joint loads were extracted from the intra- and inter-individually widely varying individual data. These data can also be used to analyse bone remodelling at the implant-bone interface, evaluate tissue straining in finite element studies or validate analytical loading predictions, among other uses. The current ISO standards for endurance tests of implant stems and necks are based on historic analytical data from the 1970s. Comparisons of these test forces with in vivo loads unveiled that their unidirectional orientations deviate from the time-dependent in vivo directions during walking and most other activities. The ISO force for testing the stem is substantially too low while the ISO force for the neck better matches typical in vivo magnitudes. Because the magnitudes and orientations of peak forces substantially vary among the activities, load scenarios that reflect a collection of time-dependent high forces should be applied rather than using unidirectional forces. Based on data from ten patients, proposals for the most demanding activities, the time courses of the contact forces and the required cycle numbers for testing are given here. Friction moments in the joint were measured in addition to the contact forces. The moment data were also standardized and can be applied to wear tests of the implant. It was shown that friction only very slightly influences the stresses in the implant neck and shaft.

Published

2016

4. The sagittal stem alignment and the stem version clearly influence the impingement-free range of motion in total hip arthroplasty: a computer model-based analysis.

Author

Müller M, Duda G, Perka C, and Tohtz S

Subjects

Aged, Computer Simulation, Hip Joint physiopathology, Humans, Male, Models, Theoretical, Arthroplasty, Replacement, Hip methods, Hip Joint surgery, Range of Motion, Articular physiology

Abstract

Purpose: The component alignment in total hip arthroplasty influences the impingement-free range of motion (ROM). While substantiated data is available for the cup positioning, little is known about the stem alignment. Especially stem rotation and the sagittal alignment influence the position of the cone in relation to the edge of the socket and thus the impingement-free functioning. Hence, the question arises as to what influence do these parameters have on the impingement-free ROM?, Methods: With the help of a computer model the influence of the sagittal stem alignment and rotation on the impingement-free ROM were investigated. The computer model was based on the CT dataset of a patient with a non-cemented THA. In the model the stem version was set at 10°/0°/-10° and the sagittal alignment at 5°/0°/-5°, which resulted in nine alternative stem positions. For each position, the maximum impingement-free ROM was investigated., Results: Both stem version and sagittal stem alignment have a relevant influence on the impingement-free ROM. In particular, flexion and extension as well as internal and external rotation capability present evident differences. In the position intervals of 10° sagittal stem alignment and 20° stem version a difference was found of about 80° in the flexion and 50° in the extension capability. Likewise, differences were evidenced of up to 72° in the internal and up to 36° in the external rotation., Conclusions: The sagittal stem alignment and the stem torsion have a relevant influence on the impingement-free ROM. To clarify the causes of an impingement or accompanying problems, both parameters should be examined and, if possible, a combined assessment of these factors should be made.

Published

2016

5. Do post-operative changes of neck-shaft angle and femoral component anteversion have an effect on clinical outcome following uncemented total hip arthroplasty?

Author

Müller M, Abdel MP, Wassilew GI, Duda G, and Perka C

Subjects

Aged, Female, Femur Neck diagnostic imaging, Hip Joint diagnostic imaging, Hip Joint surgery, Humans, Male, Osteoarthritis, Hip diagnostic imaging, Osteoarthritis, Hip physiopathology, Rotation, Arthroplasty, Replacement, Hip methods, Hip Joint physiopathology, Hip Prosthesis, Osteoarthritis, Hip surgery, Range of Motion, Articular physiology, Tomography, X-Ray Computed

Abstract

The accurate reconstruction of hip anatomy and biomechanics is thought to be important in achieveing good clinical outcomes following total hip arthroplasty (THA). To this end some newer hip designs have introduced further modularity into the design of the femoral component such that neck-shaft angle and anteversion, which can be adjusted intra-operatively. The clinical effect of this increased modularity is unknown. We have investigated the changes in these anatomical parameters following conventional THA with a prosthesis of predetermined neck-shaft angle and assessed the effect of changes in the hip anatomy on clinical outcomes. In total, 44 patients (mean age 65.3 years (standard deviation (SD) 7); 17 male/27 female; mean body mass index 26.9 (kg/m²) (SD 3.1)) underwent a pre- and post-operative three-dimensional CT scanning of the hip. The pre- and post-operative neck-shaft angle, offset, hip centre of rotation, femoral anteversion, and stem alignment were measured. Additionally, a functional assessment and pain score were evaluated before surgery and at one year post-operatively and related to the post-operative anatomical changes. The mean pre-operative neck-shaft angle was significantly increased by 2.8° from 128° (SD 6.2; 119° to 147°) to 131° (SD 2.1; 127° to 136°) (p = 0.009). The mean pre-operative anteversion was 24.9° (SD 8; 7.9 to 39.1) and reduced to 7.4° (SD 7.3; -11.6° to 25.9°) post-operatively (p < 0.001). The post-operative changes had no influence on function and pain. Using a standard uncemented femoral component, high pre- and post-operative variability of femoral anteversion and neck-shaft angles was found with a significant decrease of the post-operative anteversion and slight increase of the neck-shaft angles, but without any impact on clinical outcome., (©2015 The British Editorial Society of Bone & Joint Surgery.)

Published

2015

6. [On the biomechanics of the hip: relevance of femoral anteversion for hip contact force and loading using a short-stemmed prostheses].

Author

Tohtz SW, Heller MO, Taylor WR, Perka C, and Duda GN

Subjects

Biomechanical Phenomena, Femur Neck physiopathology, Hip Dislocation, Congenital physiopathology, Hip Joint physiopathology, Humans, Isometric Contraction physiology, Osteoarthritis, Hip physiopathology, Prosthesis Design, Range of Motion, Articular physiology, Femur Neck surgery, Hip Dislocation, Congenital surgery, Hip Joint surgery, Hip Prosthesis, Osteoarthritis, Hip surgery, Weight-Bearing physiology

Abstract

Short-stemmed hip implants were established in total hip arthroplasty in the last years. Also patients with secondary osteoarthritis of the hip with pathological anteversion of the femoral neck are treated increasingly using this method. Therefore an investigation was performed to analyze the resulting hip contact force and femoral loading in the proximal femur at the solid model of the "standardized femur". Two different situations of femoral component anteversion were simulated. Increased hip contact forces and an increase of medial and lateral cortex loads result in the anteverted model. With present level of knowledge about the influence of the hip contact force the use of short-stemmed implants is not uncritically in patients with degenerative osteoarthritis of the hip combined with rotational disorders of the proximal femur. The selection of the tribological pairing is to be considered more strongly regarding the wear behavior.

Published

2008

7. [Musculoskeletal load analysis. A biomechanical explanation for clinical results--and more?].

Author

Heller MO, Schröder JH, Matziolis G, Sharenkov A, Taylor WR, Perka C, and Duda GN

Subjects

Biomechanical Phenomena methods, Humans, Acetabulum physiology, Femur physiology, Hip Joint physiology, Models, Biological, Muscle Contraction physiology, Muscle, Skeletal physiology, Weight-Bearing physiology

Abstract

Mechanical loading of the lower extremities due to muscle and joint contact forces plays an important role in orthopaedic and trauma surgery. Detailed, patient specific information on the in vivo forces and their distribution is, however, currently not readily available to the surgeon in clinical routine. The goal of this study was to elucidate the relationship between the position of the cup and the musculoskeletal loading conditions at the hip using validated analyses, and further, to evaluate the predictions of the biomechanical conditions against the results of a clinical study. The results indicate that restoring the anatomical hip centre to its anatomical mediolateral position could help to reduce joint loads and add to the longevity of the reconstruction. The routine use of validated analyses of musculoskeletal loading conditions, such as in the presented example using standardised pre-operative planning and sound intra-operative decision support systems, could contribute to securing a high standard in patient treatment.

Published

2007

8. Cementless stem fixation and primary stability under physiological-like loads in vitro.

Author

Heller MO, Kassi JP, Perka C, and Duda GN

Subjects

Cementation, Elasticity, Hip Joint surgery, Humans, Motion, Stress, Mechanical, Arthroplasty, Replacement, Hip methods, Equipment Failure Analysis, Hip Joint physiopathology, Hip Prosthesis, Joint Instability physiopathology, Weight-Bearing

Abstract

Primary stability and in consequence osteointegration are commonly related to the stem anchorage but also to the complex musculoskeletal loading of the hip region. This study investigated the influence of metaphyseal and meta-diaphyseal anchorage on the primary stability of cementless stems under physiological-like loading in vitro. Metaphyseal and meta-diaphyseal anchoring stems (n=6 each) were implanted into composite femora. Musculoskeletal loads, validated by in vivo data (peak joint force 2348 N), were applied using a mechanical set-up. Interface movements were recorded by seven displacement transducers and primary stability was compared. Both stems exhibited similar movement patterns and principally moved distally with a retroversional twist. Although elastic movements were comparable, the metaphyseal stem exhibited higher plastic deformations than the meta-diaphyseal stem, particularly for the metaphyseal, medio-lateral and antero-posterior components. Under physiological-like loading, the metaphyseal stem allowed higher interface movements and tended to initially migrate faster than the meta-diaphyseal stem and then stabilized. Elastic movements were comparable and seemed to be less influenced by the anchoring concept than by the mechanical properties of the bone. The analyses emphasize the importance of metaphyseal bone in proximal anchorage and the necessity of an accurate canal preparation to prevent excessive initial migration.

Published

2005

9. Determination of muscle loading at the hip joint for use in pre-clinical testing.

Author

Heller MO, Bergmann G, Kassi JP, Claes L, Haas NP, and Duda GN

Subjects

Computer Simulation, Hip Joint surgery, Humans, Stress, Mechanical, Diagnosis, Computer-Assisted methods, Gait physiology, Hip Joint physiology, Models, Biological, Movement physiology, Muscle Contraction physiology, Muscle, Skeletal physiology, Weight-Bearing physiology

Abstract

The stability of joint endoprostheses depends on the loading conditions to which the implant-bone complex is exposed. Due to a lack of appropriate muscle force data, less complex loading conditions tend to be considered in vitro. The goal of this study was to develop a load profile that better simulates the in vivo loading conditions of a "typical" total hip replacement patient and considers the interdependence of muscle and joint forces. The development of the load profile was based on a computer model of the lower extremities that has been validated against in vivo data. This model was simplified by grouping functionally similar hip muscles. Muscle and joint contact forces were computed for an average data set of up to four patients throughout walking and stair climbing. The calculated hip contact forces were compared to the average of the in vivo measured forces. The final derived load profile included the forces of up to four muscles at the instances of maximum in vivo hip joint loading during both walking and stair climbing. The hip contact forces differed by less than 10% from the peak in vivo value for a "typical" patient. The derived load profile presented here is the first that is based on validated musculoskeletal analyses and seems achievable in an in vitro test set-up. It should therefore form the basis for further standardisation of pre-clinical testing by providing a more realistic approximation of physiological loading conditions.

Published

2005

10. Influence of femoral anteversion on proximal femoral loading: measurement and simulation in four patients.

Author

Heller MO, Bergmann G, Deuretzbacher G, Claes L, Haas NP, and Duda GN

Subjects

Biomechanical Phenomena, Exercise physiology, Gait, Humans, Femur physiology, Hip Joint physiology

Abstract

Objective: The aim of this study was to determine the loading of the proximal femur during daily activities and to quantify the influence of femoral anteversion., Design: This study combined experimental and analytical approaches to determine the in vivo loading at the hip joint. A numerical musculo-skeletal model was validated against measured in vivo hip contact forces and then used to analyse the influence of anteversion on the loading conditions in the femur., Background: Musculo-skeletal loading of long bones is essential for joint replacement and fracture healing. Although joint contact forces have previously been measured in selected patients, the interaction between femoral anteversion and the associated musculo-skeletal loading environment remains unknown., Methods: The gait of four patients with force measuring hip prostheses was analysed during walking and stair-climbing. Musculo-skeletal loading was determined using individual numerical models by minimising the sum of the muscle forces., Results: Experimentally and numerically determined hip contact forces agreed both qualitatively and quantitatively. Muscle activity resulted in compression of the femur and small shear forces in the meta- and epi-physeal regions. Increasing the anteversion to an angle of 30 degrees increased hip contact forces and bending moments up to 28%., Conclusions: This study has shown that femoral anteversion has a strong influence on the musculo-skeletal loading environment in the proximal femur., Relevance: Detailed musculo-skeletal modelling may allow pre-surgical, patient specific optimisation of loading on implant, bone and soft tissues.

Published

2001

11. Hip contact forces and gait patterns from routine activities.

Author

Bergmann G, Deuretzbacher G, Heller M, Graichen F, Rohlmann A, Strauss J, and Duda GN

Subjects

Activities of Daily Living, Aged, Biomechanical Phenomena, Female, Humans, Male, Middle Aged, Movement, Telemetry, Gait physiology, Hip Joint physiopathology, Hip Prosthesis

Abstract

In vivo loads acting at the hip joint have so far only been measured in few patients and without detailed documentation of gait data. Such information is required to test and improve wear, strength and fixation stability of hip implants. Measurements of hip contact forces with instrumented implants and synchronous analyses of gait patterns and ground reaction forces were performed in four patients during the most frequent activities of daily living. From the individual data sets an average was calculated. The paper focuses on the loading of the femoral implant component but complete data are additionally stored on an associated compact disc. It contains complete gait and hip contact force data as well as calculated muscle activities during walking and stair climbing and the frequencies of daily activities observed in hip patients. The mechanical loading and function of the hip joint and proximal femur is thereby completely documented. The average patient loaded his hip joint with 238% BW (percent of body weight) when walking at about 4 km/h and with slightly less when standing on one leg. This is below the levels previously reported for two other patients (Bergmann et al., Clinical Biomechanics 26 (1993) 969-990). When climbing upstairs the joint contact force is 251% BW which is less than 260% BW when going downstairs. Inwards torsion of the implant is probably critical for the stem fixation. On average it is 23% larger when going upstairs than during normal level walking. The inter- and intra-individual variations during stair climbing are large and the highest torque values are 83% larger than during normal walking. Because the hip joint loading during all other common activities of most hip patients are comparably small (except during stumbling), implants should mainly be tested with loading conditions that mimic walking and stair climbing.

Published

2001

12. Musculoskeletal loading database: loading conditions of the proximal femur.

Author

Duda, G. N., Heller, M. O., and Bergmann, G.

Subjects

*GAIT in humans, *FEMUR, *TISSUE mechanics, *JOINTS (Anatomy), *BIOMECHANICS, *WALKING, *MUSCULOSKELETAL system

Abstract

Knowledge of musculoskeletal loading conditions in humans is mandatory for the design of endoprosthestic and osteosynthetic devices. Also, new treatment options such as tissue generation and transplantation require knowledge of the mechanical loads under which tissue formation and regeneration takes place. In this manuscript, a database on musculo-skeletal loading of the proximal femur is presented. The data are based on individual patient gait and radiological data. By means of inverse dynamics and optimization techniques, the internal loads acting at the joint and within the muscles have been determined. The calculated hip contact force has been validated by means of in vivo measurements in four patients. The database is freely available and gives an estimate on internal loads acting at the proximal femur for activities like walking and stair climbing. [ABSTRACT FROM AUTHOR]

Published

2005