Biomechanical stability assessment of stemless shoulder implants through a validated finite element analysis

Morales Urzola, Oswald Leonardo

doi:https://doi.org/10.48713/10336_47119

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Biomechanical stability assessment of stemless shoulder implants through a validated finite element analysis

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dc.contributor.advisor	Guerrero, Jose Alejandro
dc.creator	Morales Urzola, Oswald Leonardo
dc.creator.degree	Magíster en Ingeniería, Ciencia y Tecnología
dc.creator.degreeLevel	Maestría
dc.date.accessioned	2025-12-12T12:36:37Z
dc.date.available	2025-12-12T12:36:37Z
dc.date.created	2025-12-09
dc.description	La predicción precisa del micromovimiento es fundamental para estimar la fijación inicial del implante, ya que desplazamientos excesivos pueden comprometer la osteointegración y el éxito clínico a largo plazo. Esta tesis evalúa la estabilidad mecánica primaria de implantes de hombro sin vástago mediante un marco de an´alisis por elementos finitos (FEA), con énfasis en el an´alisis de sensibilidad frente a umbrales de segmentación, condiciones de contacto hueso–implante y el comportamiento vectorial del desplazamiento. Para validar el rendimiento computacional, resultados de un estudio previo realizado por Zimmer Biomet fueron utilizados, en este estudio tres humeros cadavéricos fueron implantados con una prótesis sin vástago y sometidos a cargas cíclicas controladas, registrando los micromovimientos mediante un sistema de seguimiento óptico. Los modelos FEA espec´ıficos para cada espécimen se generaron a partir de imágenes de TC, evaluando diferentes umbrales de segmentación y tres condiciones de interfaz: contacto perfecto, espaciado uniforme y espaciado en cuña. Se realizó un análisis de sensibilidad para determinar cómo influye la segmentación (variando el límite de unidades Hounsfield) en la predicción de la mecánica de contacto y la distribución de rigidez. Además, el análisis incorporó no solo los valores escalares de micromovimiento, sino también el comportamiento vectorial completo de los desplazamientos, lo que permitió una comparación más robusta con los resultados experimentales. Este enfoque mostró que, si bien las simulaciones tendieron a subestimar los valores absolutos de micromovimiento, capturaron adecuadamente las direcciones de desplazamiento y la influencia de la morfología de la interfaz. Los modelos mostraron una concordancia aceptable entre los tres especímenes al utilizar un único conjunto de parámetros de material y definiciones de contacto, reflejando una respuesta mecánica coherente a pesar de la variabilidad anatómica. Aunque persisten limitaciones, como la exclusión del comportamiento plástico, el efecto del ajuste de presión y la suposici´on de rigidez en las mediciones experimentales, la metodología propuesta reproduce con ´exito la respuesta biomecánica clave en la interfaz hueso–implante y ofrece una base computacional validada para la evaluacián preclínica de implantes sin vástago.
dc.description.abstract	Accurate micromotion prediction is critical for evaluating initial implant fixation, as excessive movement can compromise osseointegration and long-term success. This thesis investigates the primary mechanical stability of stemless shoulder implants using a finite element analysis (FEA) framework, emphasizing the sensitivity of the results to segmentation thresholds, bone–implant gap conditions, and vectorial displacement behavior. To validate computational performance, data from a prior experimental study conducted by Zimmer Biomet were used. In that study, three cadaveric humeri implanted with a stemless prosthesis were subjected to controlled loading, and micromotion was measured using optical tracking. Subject-specific FEA models were constructed from CT images using varying segmentation thresholds and modeled under three interface conditions: Perfect Contact, Uniform Gap, and Wedged Gap. A sensitivity analysis was conducted to assess how segmentation (Hounsfield threshold variation) influences the predicted contact mechanics and stiffness distributions. Furthermore, the analysis incorporated not only scalar micromotion magnitudes but also the full vectorial displacement behavior, allowing for a more robust comparison against experimental measurements. This approach revealed that FEA predictions, while tending to underpredict absolute micromotion values, effectively captured the directional trends of implant displacement and the influence of gap morphology. The models demonstrated acceptable agreement across all three specimens when using a single set of material parameters and contact definitions, indicating a consistent mechanical response despite anatomical variability. However, limitations such as the exclusion of yielding behavior and press-fit mechanics, and the assumption of rigid transformation in experimental measurements, contribute to residual discrepancies. Nonetheless, the presented methodology successfully captures key biomechanical responses at the implant–bone interface and provides a validated computational foundation for preclinical evaluation of stemless shoulder implants.
dc.format.extent	148 pp
dc.format.mimetype	application/pdf
dc.identifier.doi	https://doi.org/10.48713/10336_47119
dc.identifier.uri	https://repository.urosario.edu.co/handle/10336/47119
dc.language.iso	eng
dc.publisher	Universidad del Rosario
dc.publisher.department	Escuela de Ciencias e Ingeniería
dc.publisher.program	Maestría en Ingeniería, Ciencia y Tecnología
dc.rights	Attribution-NonCommercial-NoDerivatives 4.0 International	*
dc.rights.accesRights	info:eu-repo/semantics/closedAccess
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dc.rights.uri	http://creativecommons.org/licenses/by-nc-nd/4.0/	*
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dc.source.instname	instname:Universidad del Rosario
dc.source.reponame	reponame:Repositorio Institucional EdocUR
dc.subject	Análisis por Elementos Finitos
dc.subject	FEA
dc.subject	Artroplastia de Hombro
dc.subject	Implantes sin Vástago
dc.subject	Modelado basado en Tomografía
dc.subject	Interfaz Hueso–Implante
dc.subject	Relacion Densidad- Elasticidad
dc.subject	Micromovimientos
dc.subject.keyword	Finite Element Analysis
dc.subject.keyword	FEA
dc.subject.keyword	Micromotion
dc.subject.keyword	CT-Based Modeling
dc.subject.keyword	Bone–Implant Interface
dc.subject.keyword	Density–Elasticity Relationship
dc.title	Biomechanical stability assessment of stemless shoulder implants through a validated finite element analysis
dc.title.TranslatedTitle	Evaluación de la estabilidad biomecánica de implantes de hombro sin vástago mediante un análisis de elementos finitos validado
dc.type	masterThesis
dc.type.hasVersion	info:eu-repo/semantics/acceptedVersion
dc.type.spa	Tesis de maestría
local.department.report	Escuela de Medicina y Ciencias de la Salud
local.regiones	Bogotá