Your search keyword '"Micheler, Carina M."' showing total 10 results

1. Towards Unconstrained Collision Injury Protection Data Sets: Initial Surrogate Experiments for the Human Hand

Author

Kirschner, Robin Jeanne, Yang, Jinyu, Elshani, Edonis, Micheler, Carina M., Leibbrand, Tobias, Müller, Dirk, Glowalla, Claudio, Rajaei, Nader, Burgkart, Rainer, and Haddadin, Sami

Subjects

Computer Science - Robotics

Abstract

Safety for physical human-robot interaction (pHRI) is a major concern for all application domains. While current standardization for industrial robot applications provide safety constraints that address the onset of pain in blunt impacts, these impact thresholds are difficult to use on edged or pointed impactors. The most severe injuries occur in constrained contact scenarios, where crushing is possible. Nevertheless, situations potentially resulting in constrained contact only occur in certain areas of a workspace and design or organisational approaches can be used to avoid them. What remains are risks to the human physical integrity caused by unconstrained accidental contacts, which are difficult to avoid while maintaining robot motion efficiency. Nevertheless, the probability and severity of injuries occurring with edged or pointed impacting objects in unconstrained collisions is hardly researched. In this paper, we propose an experimental setup and procedure using two pendulums modeling human hands and arms and robots to understand the injury potential of unconstrained collisions of human hands with edged objects. Pig feet are used as ex vivo surrogate samples - as these closely resemble the physiological characteristics of human hands - to create an initial injury database on the severity of injuries caused by unconstrained edged or pointed impacts. For the effective mass range of typical lightweight robots, the data obtained show low probabilities of injuries such as skin cuts or bone/tendon injuries in unconstrained collisions when the velocity is reduced to < 0.5 m/s. The proposed experimental setups and procedures should be complemented by sufficient human modeling and will eventually lead to a complete understanding of the biomechanical injury potential in pHRI., Comment: \c{opyright} 2024 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works

Published

2024

2. Towards Safe Robot Use with Edged or Pointed Objects: A Surrogate Study Assembling a Human Hand Injury Protection Database

Author

Kirschner, Robin Jeanne, Micheler, Carina M., Zhou, Yangcan, Siegner, Sebastian, Hamad, Mazin, Glowalla, Claudio, Neumann, Jan, Rajaei, Nader, Burgkart, Rainer, and Haddadin, Sami

Subjects

Computer Science - Robotics

Abstract

The use of pointed or edged tools or objects is one of the most challenging aspects of today's application of physical human-robot interaction (pHRI). One reason for this is that the severity of harm caused by such edged or pointed impactors is less well studied than for blunt impactors. Consequently, the standards specify well-reasoned force and pressure thresholds for blunt impactors and advise avoiding any edges and corners in contacts. Nevertheless, pointed or edged impactor geometries cannot be completely ruled out in real pHRI applications. For example, to allow edged or pointed tools such as screwdrivers near human operators, the knowledge of injury severity needs to be extended so that robot integrators can perform well-reasoned, time-efficient risk assessments. In this paper, we provide the initial datasets on injury prevention for the human hand based on drop tests with surrogates for the human hand, namely pig claws and chicken drumsticks. We then demonstrate the ease and efficiency of robot use using the dataset for contact on two examples. Finally, our experiments provide a set of injuries that may also be expected for human subjects under certain robot mass-velocity constellations in collisions. To extend this work, testing on human samples and a collaborative effort from research institutes worldwide is needed to create a comprehensive human injury avoidance database for any pHRI scenario and thus for safe pHRI applications including edged and pointed geometries., Comment: \c{opyright} 2024 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for all other uses, in any current or future media, including reprinting/republishing this material for advertising or promotional purposes, creating new collective works, for resale or redistribution to servers or lists, or reuse of any copyrighted component of this work in other works

Published

2024

3. Numerical evaluation of internal femur osteosynthesis based on a biomechanical model of the loading in the proximal equine hindlimb

Author

Lang, Jan J., Li, Xinhao, Micheler, Carina M., Wilhelm, Nikolas J., Seidl, Fritz, Schwaiger, Benedikt J., Barnewitz, Dirk, von Eisenhart-Rothe, Ruediger, Grosse, Christian U., and Burgkart, Rainer

Published

2024

4. Development and Evaluation of a Cost-effective IMU System for Gait Analysis: Comparison with Vicon and VideoPose3D Algorithms

Author

Wilhelm Nikolas, Micheler Carina M., Lang Jan J., Hinterwimmer Florian, Schaack Victor, Smits Ricardo, Haddadin Sami, and Burgkart Rainer

Subjects

imu, gait analysis, vicon, videopose3d, Medicine

Abstract

This study aimed to develop and evaluate a costeffective Inertial Measurement Unit (IMU) system for gait analysis, comparing its performance with the Vicon system and the VideoPose3D algorithm. The system comprises five calibrated sensors and a mobile app to measure lower body orientation during gait and stair climbing. Eight healthy participants were involved in the experiment, each performing ten repetitions to analyze hip and knee flexion angles. The IMU system demonstrated significantly lower mean square error than deep learning-based approaches and comparable results to the Vicon system, indicating its potential for clinical and research applications.

Published

2023

5. Biomechanical Test Setup for the Investigation of Forehead Suture Techniques

Author

Micheler Carina M., Lang Jan J., Bäumlisberger Anja, Wachtel Nikolaus, Wilhelm Nikolas J., Schaack Victor G., Eisenhart-Rothe Rüdiger von, and Burgkart Rainer H. H.

Subjects

biomechanics, suture, forehead, tensile test, Medicine

Abstract

Wound healing can be delayed if the biomechanical stability of the wound closure is inadequate. Therefore, it is necessary to investigate different suturing techniques for their biomechanical stability. In this study, suturing techniques suitable for the forehead area were investigated. For this application, a special test setup was developed to simulate the curvature of the forehead and the corresponding physiological configuration. The average forehead curvature is 62.24 ± 4.11 mm in radius. To simulate this curvature, the skin specimens are subjected to tensile stress over the spherical surface using a standard uniaxial testing machine. For the evaluation, an automated evaluation tool for MATLAB was also developed. Three different suturing techniques (Straight, Lazy-S, Zigzag) were investigated and tested for their biomechanical stability. Of the three suturing techniques, the Zigzag suture proved to be the most stable with the highest stiffness of 44.23 ± 8.18 % and the highest final failure of 32.60 ± 4.95 % (relative to the control sample without incision). The study has shown that the test setup can be used to investigate different forehead suture techniques.

Published

2023

6. Improving Equine Intramedullary Nail Osteosynthesis via Fracture Adjacent Polymer Reinforcement

Author

Lang Jan J., Baylacher Veronika, Micheler Carina M., Wilhelm Nikolas J., Hinterwimmer Florian, Schwaiger Benedikt, Barnewitz Dirk, Eisenhart-Rothe Rüdiger von, Grosse Christian U., and Burgkart Rainer

Subjects

osteosynthesis, implant, equine, biomechanical testing, femur, internal fixation, intramedullary nail, Medicine

Abstract

Introduction: Osteosynthesis of the equine femur is still a challenge for veterinary medicine. Even though intramedullary fracture fixation is possible nowadays, the varying geometry of the medullary cavity along the bone axis is a critical factor. Limited contact area between implant and bone can cause insufficient primary stability. In this study, it was investigated whether the osteosynthesis stability can be improved with a form-adaptive reinforcement for the diaphyseal part of the proximal fragment. Material and Methods: Eight equine femora were fitted with intramedullary nail osteosynthesis and analyzed by 4-point bending. Virtual position planning of the ex-vivo implantation using CT-data increased comparability. For five femora the proximal fragment was reinforced with a flexible polymer mixture. Longterm stability was tested via cyclic loading. Bending stiffness and its development due to cyclic loading was evaluated before and after reinforcement procedure. Finally, load-to-failure was tested in the same setup. Results and Discussion: The application of the polymer reinforcement increased the maximum torque in the load-tofailure measurement by 26%. Bending stiffness was not affected in the measured loading range by the reinforcement. Cyclic loading increased bending stiffness for a conditioned state but showed to be reversible for the most part. Conclusion: The fracture adjacent reinforcement showed to be beneficial to the osteosynthesis stability, but further investigation is necessary for surgical application.

Published

2022

7. Scaling Methods of the Pelvis without Distortion for the Analysis of Bone Defects

Author

Micheler Carina M., Lang Jan J., Wilhelm Nikolas J., Lazic Igor, Hinterwimmer Florian, Fritz Christian, Eisenhart-Rothe Rüdiger von, Zäh Michael F., and Burgkart Rainer H. H.

Subjects

pelvis, landmarks, size comparison, scaling, minimal bounding box, minimal bounding sphere, Medicine

Abstract

For the development of new types of hip implants for acetabulum revision, it is beneficial to analyse the acetabular defects of the indication group in advance. In order to be able to specially compare the bone defects with each other, a normalisation and accompanying scaling of the pelvis is necessary. Uniform scaling is required so that the bone structures are not distorted. In the following study, three scaling methods based on the minimal bounding box and sphere principle are compared with a method using 14 landmarks on the pelvis.The landmark method is applied to determine the true scaling factor. For the comparison of the different methods, 40 female pelvic models with an acetabular defect are analysed. In the comparison of the scaling methods, the method using minimal bounding spheres shows the least deviation from the landmark method (mean difference 3.30 ± 2.17 %). Due to the fact that no preprocessing (definition of the landmarks) is required and the fast implementation of the algorithm, the minimal bounding sphere is to be preferred to the landmark method for a fast size estimation.

Published

2022

8. Bioreactor design for the mechanical stimulation by compression of 3D cell cultures

Author

Micheler Carina M., Geck Paulina A., Charitou Fiona, Leix René, Foehr Peter, Lang Jan J., Wilhelm Nikolas J., Tuebel Jutta L., and Burgkart Rainer H. H.

Subjects

bioreactor, compression, tissue engineering, 3d cell culture, bone cell culture, osteoblasts, Medicine

Abstract

Bioreactors with a controlled physiological environment are being developed to study various cell processes. The influences of mechanostimulation on bone cell cultures can be investigated using a compression bioreactor. The developed bioreactor system applies a cyclic compression force to the specimen via an eccentrically mounted push rod. The compression force is monitored by a force sensor to detect changes in the material properties of the specimen. Depending on the piston setting, a stroke of 0.28 - 2.50 mm can be applied to the specimen. The bioreactor system was tested with a trial run of 18 days. A sample was continuously stimulated with a loading frequency of 2 Hz and a stroke of 1.50 mm. The sterility in the cell chamber as well as the functionality of the realised bioreactor stimulation system could be successfully confirmed

Published

2021

9. Spezifische Aktivierung der Rumpfmuskulatur beim Balance-Training durch Immobilisation des Beckens

Author

Lang, Jan J., Fechter, Florian, Peper, Kim K., Micheler, Carina M., Wilhelm, Nikolas J., Jensen, Elisabeth R., Haddadin, Sami, von Eisenhart-Rothe, Rüdiger, and Burgkart, Rainer

Subjects

EMG, Rückenschmerzen, Medicine and health, Balance-Training, Reha

Abstract

Fragestellung: Rückenschmerzen sind ein weitverbreitetes, oft unspezifisches Leiden in der Gesellschaft. Eine häufige Therapieform ist die Stärkung der Rumpfmuskulatur durch Balance-Training. Um das Training auf der Balanceplattform noch spezifischer auf die Rumpfmuskulatur zu fokussieren, [zum vollständigen Text gelangen Sie über die oben angegebene URL]

Published

2022

10. Improving mandibular reconstruction by using topology optimization, patient specific design and additive manufacturing?—A biomechanical comparison against miniplates on human specimen

Author

Lang, Jan J., primary, Bastian, Mirjam, additional, Foehr, Peter, additional, Seebach, Michael, additional, Weitz, Jochen, additional, von Deimling, Constantin, additional, Schwaiger, Benedikt J., additional, Micheler, Carina M., additional, Wilhelm, Nikolas J., additional, Grosse, Christian U., additional, Kesting, Marco, additional, and Burgkart, Rainer, additional

Published

2021