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Full-Time Faculty
Professor, Chairman Neurosensory Instrumentation and Engineering Neurophysiological Signal Processing Auditory / Visual Evoked Responses Electrophysiological Brain Monitoring Auditory / Audiological Instrumentation Electrocochleography and Electroretinography oozdamar@miami.edu |
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Associate Professor
Biomaterial development, drug delivery systems, therapeutic angiogenesis, tissue engineering scafflolds, cutaneous regeneration |
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Assistant Professor of Professional Practice
Research in Engineering Education:Engineering Design; Problem oriented methods used to teach Medical Electronics and Instrumentation;
jbohorquez@miami.edu
Development of methods and equipment for neurophysiology and neuro-monitoring: Monitoring of retinal function using high rate stimuli; Objective hearing assessment; Use of neurophysiology to monitor the state of awareness during anesthesia |
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Research Associate Professor
Scanning Electron Microscopy Medical physics and radiation biology |
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Assistant Professor
Transport Properties
a.jackson2@miami.edu
Nutritional Supply to Cells and Tissues Biomechanics of Soft Tissues Mechanobiology Finite Element Analysis Orthopaedic Tissues: Intervertebral Disc, Meniscus, etc. |
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Associate Professor
Laser applications in medicine Biomedical optical imaging Optics of the eye and vision correction Ophthalmic technologies |
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Assistant Professor
Optical stimulation of excitable cells (cardiomyocytes, neurons, hair cells) Neuroprosthetics Neural engineering Biomechanics Neurophysiology |
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Research Assistant Professor
The overall goal of the JBEDS laboratory is to create, develop, modify, and optimize both diagnostic and therapeutic minimally-invasive and non-invasive surgical modalities, especially but not exclusively to the field of urology. Our research interests include: 1. Energy-based MIS needle-ablative therapies such as radiofrequency ablation, microwave ablation, irreversible electroporation, and laser interatitial thermotherapy. This includes developement in needle probe guidance, treatment monitoring, whcih includes: MRI thermometry, CT thermometry, Volumetric calculations of viable, remaining tissue vs thermally damaged tissue, and modeling for outcome predictions. 2. Development of a bi-polar RF probe that can measure the electrical impedance within the kidney. This wil result in a SMART biopsy needle, to determine whether they are inside the tumor, normal tissue, or even thermmaly-coagulated tissue. 3.Development of laparoscopic and minimally-invasive multti-site and single-site treatment surgical instruments, including work with endoscopy and robots (DaVinci). |
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Associate Professor
Neuroprosthetics
jcsanchez@miami.edu
Brain-Machine Interfaces Brain-Computer Interfaces Neural Engineering Neural Coding Deep Brain Stimulation Motor System Limbic System |
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Assistant Professor
Tissue engineering Bioartificial Pancreas Biomaterials Bioactive Materials Controlled Release Biomaterials |
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Associate Professor
Medical image processing Radioisotope labeled imaging Medical imaging simulation Image-guided intervention |
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Assistant Professor
Ocular biomechanics Cellular biomechanics Imaging Atomic Force Microscopy |
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