Your search keyword '"W. Robert J. Funnell"' showing total 5 results

1. Finite-Element Modelling Based on Optical Coherence Tomography and Corresponding X-ray MicroCT Data for Three Human Middle Ears

Author

Marzieh Golabbakhsh, Xuan Wang, Dan MacDougall, Joshua Farrell, Thomas Landry, W. Robert J. Funnell, and Robert Adamson

Subjects

Otorhinolaryngology, Sensory Systems

Published

2023

2. Experimental Study of Vibrations of Gerbil Tympanic Membrane with Closed Middle Ear Cavity

Author

W. Robert J. Funnell, Willem F. Decraemer, Nima Maftoon, and Sam J. Daniel

Subjects

Tympanic Membrane, Umbo, Acoustics, Ear, Middle, Vibration, otorhinolaryngologic diseases, medicine, Animals, Displacement (orthopedic surgery), Malleus, Ear canal, Audio frequency, Physics, Anatomy, Microspheres, Sensory Systems, medicine.anatomical_structure, Otorhinolaryngology, Models, Animal, Middle ear, Female, Human medicine, sense organs, Gerbillinae, Plastics, Laser Doppler vibrometer, Research Article

Abstract

The purpose of the present work is to investigate the spatial vibration pattern of the gerbil tympanic membrane (TM) as a function of frequency. In vivo vibration measurements were done at several locations on the pars flaccida and pars tensa, and along the manubrium, on surgically exposed gerbil TMs with closed middle ear cavities. A laser Doppler vibrometer was used to measure motions in response to audio frequency sine sweeps in the ear canal. Data are presented for two different pars flaccida conditions: naturally flat and retracted into the middle ear cavity. Resonance of the flat pars flaccida causes a minimum and a shallow maximum in the displacement magnitude of the manubrium and pars tensa at low frequencies. Compared with a flat pars flaccida, a retracted pars flaccida has much lower displacement magnitudes at low frequencies and does not affect the responses of the other points. All manubrial and pars tensa points show a broad resonance in the range of 1.6 to 2 kHz. Above this resonance, the displacement magnitudes of manubrial points, including the umbo, roll off with substantial irregularities. The manubrial points show an increasing displacement magnitude from the lateral process toward the umbo. Above 5 kHz, phase differences between points along the manubrium start to become more evident, which may indicate flexing of the tip of the manubrium or a change in the vibration mode of the malleus. At low frequencies, points on the posterior side of the pars tensa tend to show larger displacements than those on the anterior side. The simple low-frequency vibration pattern of the pars tensa becomes more complex at higher frequencies, with the breakup occurring at between 1.8 and 2.8 kHz. These observations will be important for the development and validation of middle ear finite-element models for the gerbil.

Published

2013

3. Tympanic Membrane Boundary Deformations Derived from Static Displacements Observed with Computerized Tomography in Human and Gerbil

Author

Stefan L R, Gea, Willem F, Decraemer, W Robert J, Funnell, Robert W J, Funnell, Joris J J, Dirckx, and Hannes, Maier

Subjects

Adult, Male, Tympanic Membrane, Materials science, X-ray microtomography, Boundary (topology), Gerbil, Models, Biological, Article, Weight-Bearing, Imaging, Three-Dimensional, Species Specificity, Pressure, medicine, Animals, Humans, Malleus, Ear canal, Boundary value problem, Aged, Annulus (oil well), Temporal Bone, X-Ray Microtomography, Anatomy, Mechanics, Elasticity, Sensory Systems, medicine.anatomical_structure, Otorhinolaryngology, Models, Animal, Middle ear, Female, Human medicine, Gerbillinae

Abstract

The middle ear is too complex a system for its function to be fully understood with simple descriptive models. Realistic mathematical models must be used in which structural elements are represented by geometrically correct three-dimensional (3D) models with correct physical parameters and boundary conditions. In the past, the choice of boundary conditions could not be based on experimental evidence as no clear-cut data were available. We have, therefore, studied the deformation of the tympanic membrane (TM) at its boundaries using X-ray microscopic computed tomography in human and gerbil while static pressure was applied to the ear canal. The 3D models of the TM and its bony attachments were carefully made and used to measure the deformation of the TM with focus on the periphery and the manubrium attachment. For the pars flaccida of the gerbil, the boundary condition can, for the most part, be described as simply supported. For the human pars flaccida, the situation is more complicated: superiorly, the membrane contacts the underlying bone more and more when pushed further inward, and it gradually detaches from the wall when sucked outward. In gerbil, the attachment of the TM to the manubrium can be described as simply supported. In human, the manubrium is attached underneath the TM via the plica mallearis and the contact of the TM with the bone is indirect. For both human and gerbil, a simple boundary condition for the peripheral edge of the pars tensa is not appropriate due to the intricate structure at the edge: the TM thickens rapidly before continuing into the annulus fibrosis which finally makes contact with the bone.

Published

2009

4. Low-Frequency Finite-Element Modeling of the Gerbil Middle Ear

Author

W. Robert J. Funnell, Hengjin Liu, and Nidal Elkhouri

Subjects

Ligaments, Tympanic Membrane, Materials science, Rotation, Umbo, Ossicles, Acoustics, Finite Element Analysis, Isotropy, Ear, Middle, Models, Biological, Article, Sensory Systems, Displacement (vector), Footplate, medicine.anatomical_structure, Otorhinolaryngology, Middle ear, medicine, Animals, Gerbillinae, Eardrum, Stapes

Abstract

The gerbil is a popular species for experimental middle-ear research. The goal of this study is to develop a 3D finite-element model to quantify the mechanics of the gerbil middle ear at low frequencies (up to about 1 kHz). The 3D reconstruction is based on a magnetic resonance imaging dataset with a voxel size of about 45 microm, and an x-ray micro-CT dataset with a voxel size of about 5.5 microm, supplemented by histological images. The eardrum model is based on moiré shape measurements. Each individual structure in the model was assumed to be homogeneous with isotropic, linear, and elastic material properties derived from a priori estimates in the literature. The behavior of the finite-element model in response to a uniform acoustic pressure on the eardrum of 1 Pa is analyzed. Sensitivity tests are done to evaluate the significance of the various parameters in the finite-element model. The Young's modulus and the thickness of the pars tensa have the most significant effect on the load transfer between the eardrum and the ossicles and, along with the Young's modulus of the pedicle and stapedial annular ligament, on the displacements of the stapes. Overall, the model demonstrates good agreement with low-frequency experimental data. For example, (1) the maximum footplate displacement is about 35 nm; (2) the umbo/stapes displacement ratio is found to be about 3.5; (3) the motion of the stapes is predominantly piston-like; and (4) the displacement pattern of the eardrum shows two points of maximum displacement, one in the posterior region and one in the anterior region. The effects of removing or stiffening the ligaments are comparable to those observed experimentally.

Published

2006

5. The McGill simulator for endoscopic sinus surgery (MSESS): a validation study

Author

W. Robert J. Funnell, Marc A. Tewfik, Saul Frenkiel, Rolando F. Del Maestro, Lily H. P. Nguyen, Meredith Young, Rickul Varshney, Elias Saad, and Anthony Zeitouni

Subjects

Rhinology, medicine.medical_specialty, education, MEDLINE, Endoscopic sinus surgery, Virtual reality, Education, Otolaryngology, User-Computer Interface, Minimally invasive surgery, Rating scale, Paranasal Sinuses, Humans, Training, Medicine, Computer Simulation, Original Research Article, Curriculum, Simulation, Retrospective Studies, Resident, business.industry, Internship and Residency, Endoscopy, Retrospective cohort study, Equipment Design, Plastic surgery, Performance metrics, Nasal model, Otorhinolaryngology, Oral and maxillofacial surgery, Surgery, Clinical Competence, Technical abilities, business, Haptic

Abstract

Background: Endoscopic sinus surgery (ESS) is a technically challenging procedure, associated with a significant risk of complications. Virtual reality simulation has demonstrated benefit in many disciplines as an important educational tool for surgical training. Within the field of rhinology, there is a lack of ESS simulators with appropriate validity evidence supporting their integration into residency education. The objectives of this study are to evaluate the acceptability, perceived realism and benefit of the McGill Simulator for Endoscopic Sinus Surgery (MSESS) among medical students, otolaryngology residents and faculty, and to present evidence supporting its ability to differentiate users based on their level of training through the performance metrics. Methods: 10 medical students, 10 junior residents, 10 senior residents and 3 expert sinus surgeons performed anterior ethmoidectomies, posterior ethmoidectomies and wide sphenoidotomies on the MSESS. Performance metrics related to quality (e.g. percentage of tissue removed), efficiency (e.g. time, path length, bimanual dexterity, etc.) and safety (e.g. contact with no-go zones, maximum applied force, etc.) were calculated. All users completed a post-simulation questionnaire related to realism, usefulness and perceived benefits of training on the MSESS. Results: The MSESS was found to be realistic and useful for training surgical skills with scores of 7.97 ± 0.29 and 8.57 ± 0.69, respectively on a 10-point rating scale. Most students and residents (29/30) believed that it should be incorporated into their curriculum. There were significant differences between novice surgeons (10 medical students and 10 junior residents) and senior surgeons (10 senior residents and 3 sinus surgeons) in performance metrics related to quality (p< 0.05), efficiency (p< 0.01) and safety (p< 0.05). Conclusion: The MSESS demonstrated initial evidence supporting its use for residency education. This simulator may be a potential resource to help fill the void in endoscopic sinus surgery training.

Published

2014