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351 results on '"Poul M. F. Nielsen"'

1. Model-based design of a pneumatic actuator for a dynamically reconfigurable socket for transtibial amputees

Author

Saeed Mollaee, Amir HajiRassouliha, David M. Budgett, Andrew J. Taberner, and Poul M. F. Nielsen

Subjects
finite element method, pneumatic soft actuator array, adjustable prosthetic socket, image registration algorithm, hyperelastic modelling, computer vision, Biotechnology, TP248.13-248.65
Abstract

In this work, a cost-effective, scalable pneumatic silicone actuator array is introduced, designed to dynamically conform to the user’s skin and thereby alleviate localised pressure within a prosthetic socket. The appropriate constitutive models for developing a finite element representation of these actuators are systematically identified, parametrised, and validated. Employing this computational framework, the surface deformation fields induced by 270 variations in soft actuator array design parameters under realistic load conditions are examined, achieving predictive accuracies within 70 µm. The results elucidate how individual design factors influence surface deformation and, consequently, pressure distribution. A novel speckle imaging technique is employed to address the complex non-linear deformations, enabling surface displacement measurements with an accuracy of approximately 40 µm. These measurements confirm that the Ogden N3 model can predict actuator deformation with an accuracy of 16%. These findings elucidate the relationships among actuator geometry, material behaviour, and surface deformation. Although demonstrated in a dynamically reconfigurable socket for transtibial amputees, these insights are readily transferable to other robotics applications that require soft, deformable, load-bearing interfaces. This validated modelling strategy and imaging technique provide a foundation for optimising soft actuator arrays, ultimately improving user comfort and enhancing the functionality of future prosthetic and robotic devices.

Published
2024
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2. A novel two-dimensional phantom for electrical impedance tomography using 3D printing

Author

Andrew Creegan, Poul M. F. Nielsen, and Merryn H. Tawhai

Subjects
Medicine, Science
Abstract

Abstract Electrical impedance tomography (EIT) is an imaging method that can be used to image electrical impedance contrasts within various tissues of the body. To support development of EIT measurement systems, a phantom is required that represents the electrical characteristics of the imaging domain. No existing type of EIT phantom combines good performance in all three characteristics of resistivity resolution, spatial resolution, and stability. Here, a novel EIT phantom concept is proposed that uses 3D printed conductive material. Resistivity is controlled using the 3D printing infill percentage parameter, allowing arbitrary resistivity contrasts within the domain to be manufactured automatically. The concept of controlling resistivity through infill percentage is validated, and the manufacturing accuracy is quantified. A method for making electrical connections to the 3D printed material is developed. Finally, a prototype phantom is printed, and a sample EIT analysis is performed. The resulting phantom, printed with an Ultimaker S3, has high reported spatial resolution of 6.9 µm, 6.9 µm, and 2.5 µm for X, Y, and Z axis directions, respectively (X and Y being the horizontal axes, and Z the vertical). The number of resistivity levels that are manufacturable by varying infill percentage is 15 (calculated by dividing the available range of resistivities by two times the standard deviation of the manufacturing accuracy). This phantom construction technique will allow assessment of the performance of EIT devices under realistic physiological scenarios.

Published
2024
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13. CellML 2.0.1.

Author

Michael Clerx, Michael T. Cooling, Jonathan Cooper, Alan Garny, Keri R. Moyle, David P. Nickerson, Poul M. F. Nielsen, and Hugh Sorby

Published
2023
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27. A dynamometer for nature's engines.

Author

Andrew J. Taberner, Poul M. F. Nielsen, Callum M. Johnston, Alexander J. Anderson, Ming L. Cheuk, Amy S. Garrett, Jarrah Dowrick, Emily Lam Po Tang, Amir HajiRassouliha, Bryan P. Ruddy, Toan Pham, Kenneth Tran, June-Chiew Han, and Denis S. Loiselle

Published
2019
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34. CellML 2.0.

Author

Michael Clerx, Michael T. Cooling, Jonathan Cooper, Alan Garny, Keri R. Moyle, David P. Nickerson, Poul M. F. Nielsen, and Hugh Sorby

Published
2020
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45. Jet-Induced Tissue Disruption for Blood Release

Author

Andrew J. Taberner, Jiali Xu, Poul M. F. Nielsen, James W. McKeage, and Bryan P. Ruddy

Subjects
Needle free, Jet (fluid), Materials science, Swine, Capillary action, Biomedical Engineering, Equipment Design, respiratory system, equipment and supplies, complex mixtures, Vascular endothelium, Drug Delivery Systems, Pharmaceutical Preparations, Drug delivery, Jet injector, Injections, Jet, Animals, Porcine skin, Intradermal injection, human activities, Skin, circulatory and respiratory physiology, Biomedical engineering
Abstract

Objective Needle free jet injection is a drug delivery technique that uses the momentum of the fluid drug to break through the skin. This technique has recently also been applied to blood release, aiming to collect samples from capillaries in the skin without needing a lancet prick. This work provides new information about the wound geometry and tissue disruption caused by shallow jet injection with circular shaped and slot shaped jets. Methods We use histological analysis to compare the disruption of tissue, including blood vessels, caused by lancet-pricking and jet injection with a circular shaped jet and a lancet-inspired slot shaped jet. Results Intradermal injection into porcine skin using a slot shaped jet disrupted more vascular endothelium in the tissue than a circular shaped jet and did so at a smaller penetration depth with smaller wound volume. Our results suggest that shallow jet injections may have the potential to release more capillary blood than a lancet prick. Conclusion These findings demonstrate that a reversible jet injector might be used in diabetes management as a device to release and collect blood samples, in addition to being used to deliver insulin. Significance Tissue disruption is crucial to consider when using jet injection to deliver drug and release capillary blood.

Published
2022
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