Your search keyword '"Areias B"' showing total 14 results

1. A control and communications platform for procedural mission planning with multiple aerial drones

Author

Areias, B., Martins, A., Paula, N., Reis, A. B., and Sargento, S.

Published

2022

2. Finite element modelling of the surgical procedure for placement of a straight electrode array: Mechanical and clinical consequences

Author

Areias, B., Parente, M.P.L., Gentil, F., and Natal Jorge, R.M.

Published

2021

3. Numerical simulation of lateral and transforaminal lumbar interbody fusion, two minimally invasive surgical approaches.

Author

Areias, B., Caetano, S. C., Sousa, L. C., Parente, M., Jorge, R. N., Sousa, H., and Gonçalves, J. M.

Subjects

*COMPUTER simulation, *LATERAL loads, *LUMBAR vertebrae, *SURFACE area, *INTERVERTEBRAL disk prostheses, *LUMBOSACRAL region

Abstract

The present study aims to compare spinal stability after two different minimally invasive techniques, the lateral lumbar interbody fusion (LLIF) and the transforaminal lumbar interbody fusion (TLIF) approaches. Two nonlinear three-dimensional finite element (FE) models of the L4–L5 functional spinal unit (FSU) were subjected to the loads that usually act on the lumbar spine. Findings show that the LLIF approach yields better results for torsion load case, due to the larger surface area of the implant. For extension, flexion and lateral bending loads, the TLIF approach presents smaller displacements probably due to the anterior placement of the cage and to the smaller damaged area of the annulus fibrosus. [ABSTRACT FROM AUTHOR]

Published

2020

4. Minimally invasive transforaminal and anterior lumbar interbody fusion surgery at level L5-S1.

Author

Fidalgo, D. S., Areias, B., Sousa, L. C., Parente, M., Jorge, R. N., Sousa, H., and Gonçalves, J. M.

Subjects

*FINITE element method, *LIGAMENTS, *ROTATIONAL motion, *COMPUTER simulation, *SURGERY

Abstract

This paper presents a finite element analysis to investigate the biomechanical changes caused by transforaminal (TLIF) and anterior lumbar interbody fusion (ALIF) at the L5-S1 level, applying two different implants: T_PAL (TLIF) and SynFix (ALIF). The main objective is to determine which one is more stable for patients. Numerical simulations of segmental motion show that, in the early postoperative phase, displacements and rotation angles obtained in ALIF are greater than the corresponding ones obtained in TLIF, as well as the principal stress values on the ligaments. So, TLIF performed with T_PAL is more stable than ALIF, especially during the recovery phase. [ABSTRACT FROM AUTHOR]

Published

2020

5. Aluminum foam sandwich with adhesive bonding: Computational modeling.

Author

Sadek, S. H., Areias, B., Parente, M. P. L., Belinha, J., Santos, A. D., and Jorge, R. M. Natal

Subjects

*ADHESIVES, *BINDING agents, *METAL foams, *ALUMINUM, *POLYURETHANES

Abstract

A numerical approach to simulate the delamination effect occurring in metal foam composites is being presented in this work. It is shown that in order to create reliable numerical models to simulate general components produced with aluminum metal foam sandwiches, the delamination effect of the aluminum skins from the metal foam must be considered. Delamination occurs within the polyurethane adhesive layer, causing the loss of the structural integrity of the structure. Foam is not a continuum medium, nevertheless, when simulating foam structures, foam is commonly assumed as a continuum, with homogeneous properties. This approach requires the calibration of the mechanical properties of the polyurethane adhesive layer, in order to compensate the effect of the foam’s discontinuous structure. The finite element method was used to numerically simulate a three-points bending test and an unconstrained bending test. The cohesive behavior was modelled by using a traction separation law. For the damage initiation criteria, a maximum-stress-based criterion was used, whereas for the damage evolution, a displacement-based damage evolution law was adopted. The experimental data were obtained from the group’s previous work, including a compression test, a tension test, a three-points bending test, and an unconstrained bending test. [ABSTRACT FROM AUTHOR]

Published

2017

6. The human otitis media with effusion: a numerical-based study.

Author

Areias, B., Parente, M. P. L., Santos, C., Gentil, F., and Jorge, R. M. Natal

Subjects

*OTITIS media, *CHOLESTEATOMA, *POLYMERASE chain reaction, *EAR diseases, *MIDDLE ear

Abstract

Otitis media is a group of inflammatory diseases of themiddle ear. Acute otitis media and otitis media with effusion (OME) are its two main types of manifestation. Otitis media is common in children and can result in structural alterations in the middle ear which will lead to hearing losses. This work studies the effects of an OME on the sound transmission from the external auditory meatus to the inner ear. The finite elementmethod was applied on the present biomechanical study. The numerical model used in thiswork was built based on the geometrical information obtained from The visible ear project. The present work explains the mechanisms by which the presence of fluid in the middle ear affects hearing by calculating the magnitude, phase and reduction of the normalized umbo velocity and also the magnitude and phase of the normalized stapes velocity. A sound pressure level of 90 dB SPL was applied at the tympanicmembrane. The harmonic analysis was performedwith the auditory frequency varying from 100 Hz to 10 kHz. A decrease in the response of the normalized umbo and stapes velocity as the tympanic cavity was filled with fluid was obtained. The decrease was more accentuated at the umbo. [ABSTRACT FROM AUTHOR]

Published

2017

7. Biomechanical simulation of the human ear.

Author

Areias, B., Parente, M. P. L., Gentil, F., Jorge, R. M. Natal, and Fernandes, A. A.

Published

2015

8. A finite element model to predict the consequences of endolymphatic hydrops in the basilar membrane.

Author

Areias B, Parente MPL, Gentil F, Caroça C, Paço J, and Natal Jorge RM

Subjects

Basilar Membrane, Finite Element Analysis, Humans, Endolymphatic Hydrops complications, Meniere Disease complications

Abstract

Ménière's disease is an inner ear disorder, associated with episodes of vertigo, fluctuant hearing loss, tinnitus, and aural fullness. Ménière's disease is associated with endolymphatic hydrops. Clinical evidences show that this disease is often incapacitating, negatively affecting the patients' everyday life. The pathogenesis of Ménière's disease is still not fully understood and remains unclear. Previous numerical studies available in the literature related with endolymphatic hydrops, are very scarce. The present work applies the finite element method to investigate the consequences of endolymphatic hydrops in the normal hearing, associated with the Ménière's disease. The obtained results for the steady state dynamics analysis are in accordance with clinical evidences. The results show that the basilar membrane is not affected in the same intensity along its length and that the lower frequencies are more affected by the endolymphatic hydrops. From a clinical point of view, this work shows the relationship between the increasing of the endolymphatic pressure and the development of hearing loss., (© 2021 John Wiley & Sons Ltd.)

Published

2022

9. On the hearing effects of a cholesteatoma growing: A biomechanical study.

Author

Mendonça L, Santos CF, Gentil F, Parente M, Areias B, and Natal Jorge R

Subjects

Hearing, Humans, Stapes, Tympanic Membrane, Cholesteatoma, Ear, Middle

Abstract

Chronic otitis media enables the appearance of a benign middle ear tumor, known as a cholesteatoma, that may compromise hearing. To evaluate the influence of a cholesteatoma growth on the hearing function, a computational middle ear model based on the finite element method was used and three different size of cholesteatoma were modeled. The cholesteatoma solidification and the consequent degradation of the ossicles were also simulated as two condition that commonly occurs during cholesteatoma evolution. A sound pressure level of 80 dB SPL was applied in the tympanic membrane and a steady state analysis was performed for frequencies from 100 Hz to 10 kHz. The displacements of both the tympanic membrane and the stapes footplate were measured. The results were compared with a healthy case and it was shown that the cholesteatoma development leads to a decrease in the umbo and stapes displacements. The ossicles degradation simulation showed the higher difference comparing with the cholesteatoma in an initial stage, with lower displacements in the stapes footplate mainly for high frequencies. The observed displacement differences are directly connected to hearing loss, being possible to conclude that cholesteatoma evolution in the middle ear will lead to hearing problems, mainly in an advanced stage.

Published

2022

10. Influence of the basilar membrane shape and mechanical properties in the cochlear response: A numerical study.

Author

Areias B, Parente M, Gentil F, and Jorge RN

Subjects

Acoustic Stimulation, Cochlea, Humans, Basilar Membrane, Quality of Life

Abstract

Hearing impairment is one of the most common health disorders, affecting individuals of all ages, reducing considerably their quality of life. At present, it is known that during an acoustic stimulation a travelling wave is developed inside the cochlea. Existing mathematical and numerical models available in the literature try to describe the shape of this travelling wave, the majority of them present a set of approaches based on some limitations either or both of the mechanical properties used and the geometrical description of the realistic representation. The present numerical study highlights the distinctions of using a spiral model of the cochlea, by comparing the obtained results with a straight, or simplified model. The influence of the implantation of transversely isotropic mechanical models was also studied, by comparing the basilar membrane with isotropic and transversely isotropic mechanical properties. Values of the root mean square error calculated for all models show a greater proximity of the cochlear mapping to the Greenwood function when the basilar membrane is assumed with transversely isotropic mechanical properties for both straight and spiral model. The root-mean square errors calculated were: 2.05, 1.70, 2.72, 2.08 mm, for the straight-isotropic, straight-transversely isotropic, spiral-isotropic and spiral-transversely isotropic model, respectively.

Published

2021

11. Performance Analysis of Geiger-Müller and Cadmium Zinc Telluride Sensors Envisaging Airborne Radiological Monitoring in NORM Sites.

Author

Borbinha J, Romanets Y, Teles P, Corisco J, Vaz P, Carvalho D, Brouwer Y, Luís R, Pinto L, Vale A, Ventura R, Areias B, Reis AB, and Gonçalves B

Subjects

Air Pollutants, Radioactive analysis, Calibration, Ecosystem, Humans, Portugal, Radiography, Biosensing Techniques, Cadmium chemistry, Radiation Monitoring instrumentation, Radiation Monitoring methods, Radiometry, Remote Sensing Technology, Tellurium chemistry, Zinc chemistry

Abstract

Radiological monitoring is fundamental for compliance with radiological protection policies in the aftermath of radiological events, such as nuclear accidents, terrorism, and out-of-commission uranium mines. An effective strategy for radiation monitoring is to use radiation detectors coupled with Unmanned Aerial Vehicles (UAVs), enabling for quicker surveillance of large areas without involving the need of human presence in the target area. The main aim of this study was to formulate the parameters for a UAV flight strategy in preparation for future field measurements using Geiger-Muller Counters (GMC) and Cadmium Zinc Telluride (CZT) spectrometers. As a proof of concept, the prepared flight strategy will be used to survey out-of-commission uranium mines in northern Portugal. Procedures to assure the calibration of the CZT and verification of the GMCs were conducted, as well as a sensitivity analysis of the sensors considering different acquisition times, distance to source, and detector response time. This article reports specific parameters, such as UAV distance to ground, time of exposition, speed, and the methodology to perform the identification and calculate the activity of possible radioactive sources. An effective flight strategy is also presented, aiming to use radiation detectors coupled with UAVs to undertake extensive monitoring of areas with enhanced levels of environmental radiation, which is of prime importance due to the lasting hazardous effects of enhanced environmental radiation in the nearby ecosystem and population.

Published

2020

12. A computational framework to simulate the endolymph flow due to vestibular rehabilitation maneuvers assessed from accelerometer data.

Author

Santos CF, Belinha J, Gentil F, Parente M, Areias B, and Jorge RN

Subjects

Finite Element Analysis, Humans, Models, Biological, Quality of Life, Semicircular Canals physiopathology, Accelerometry instrumentation, Computer Simulation, Endolymph physiology, Vertigo rehabilitation, Vestibule, Labyrinth physiopathology

Abstract

Vertiginous symptoms are one of the most common symptoms in the world, therefore investing in new ways and therapies to avoid the sense of insecurity during the vertigo episodes is of great interest. The classical maneuvers used during vestibular rehabilitation consist in moving the head in specific ways, but it is not fully understood why those steps solve the problem. To better understand this mechanism, a three-dimensional computational model of the semicircular ducts of the inner ear was built using the finite element method, with the simulation of the fluid flow being obtained using particle methods. To simulate the exact movements performed during rehabilitation, data from an accelerometer were used as input for the boundary conditions in the model. It is shown that the developed model responds to the input data as expected, and the results successfully show the fluid flow of the endolymph behaving coherently as a function of accelerometer data. Numerical results at specific time steps are compared with the corresponding head movement, and both particle velocity and position follow the pattern that would be expected, confirming that the model is working as expected. The vestibular model built is an important starting point to simulate the classical maneuvers of the vestibular rehabilitation allowing to understand what happens in the endolymph during the rehabilitation process, which ultimately may be used to improve the maneuvers and the quality of life of patients suffering from vertigo.

Published

2018

13. Finite element modelling of sound transmission from outer to inner ear.

Author

Areias B, Santos C, Natal Jorge RM, Gentil F, and Parente MP

Subjects

Acoustics, Computer Simulation, Ear anatomy & histology, Finite Element Analysis, Humans, Sound, Tympanic Membrane physiology, Ear physiology, Models, Biological

Abstract

The ear is one of the most complex organs in the human body. Sound is a sequence of pressure waves, which propagates through a compressible media such as air. The pinna concentrates the sound waves into the external auditory meatus. In this canal, the sound is conducted to the tympanic membrane. The tympanic membrane transforms the pressure variations into mechanical displacements, which are then transmitted to the ossicles. The vibration of the stapes footplate creates pressure waves in the fluid inside the cochlea; these pressure waves stimulate the hair cells, generating electrical signals which are sent to the brain through the cochlear nerve, where they are decoded. In this work, a three-dimensional finite element model of the human ear is developed. The model incorporates the tympanic membrane, ossicular bones, part of temporal bone (external auditory meatus and tympanic cavity), middle ear ligaments and tendons, cochlear fluid, skin, ear cartilage, jaw and the air in external auditory meatus and tympanic cavity. Using the finite element method, the magnitude and the phase angle of the umbo and stapes footplate displacement are calculated. Two slightly different models are used: one model takes into consideration the presence of air in the external auditory meatus while the other does not. The middle ear sound transfer function is determined for a stimulus of 60 dB SPL, applied to the outer surface of the air in the external auditory meatus. The obtained results are compared with previously published data in the literature. This study highlights the importance of external auditory meatus in the sound transmission. The pressure gain is calculated for the external auditory meatus.

Published

2016

14. Effects of the fibers distribution in the human eardrum: A biomechanical study.

Author

Gentil F, Parente M, Martins P, Garbe C, Santos C, Areias B, Branco C, Paço J, and Jorge RN

Subjects

Biomechanical Phenomena, Humans, Models, Biological, Pressure, Mechanical Phenomena, Tympanic Membrane

Abstract

The eardrum separates the external ear from the middle ear and it is responsible to convert the acoustical energy into mechanical energy. It is divided by pars tensa and pars flaccida. The aim of this work is to analyze the susceptibility of the four quadrants of the pars tensa under negative pressure, to different lamina propria fibers distribution. The development of associated ear pathology, in particular the formation of retraction pockets, is also evaluated. To analyze these effects, a computational biomechanical model of the tympano-ossicular chain was constructed using computerized tomography images and based on the finite element method. Three fibers distributions in the eardrum middle layer were compared: case 1 (eardrum with a circular band of fibers surrounding all quadrants equally), case 2 (eardrum with a circular band of fibers that decreases in thickness in posterior quadrants), case 3 (eardrum without circular fibers in the posterior/superior quadrant). A static analysis was performed by applying approximately 3000Pa in the eardrum. The pars tensa of the eardrum was divided in four quadrants and the displacement of a central point of each quadrant analyzed. The largest displacements of the eardrum were obtained for the eardrum without circular fibers in the posterior/superior quadrant., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2016