Details
Measuring the Physiologic Use Conditions of Medical Devices
|
139,09 € |
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| Verlag: | Springer |
| Format: | |
| Veröffentl.: | 01.09.2024 |
| ISBN/EAN: | 9783031627644 |
| Sprache: | englisch |
| Anzahl Seiten: | 300 |
Dieses eBook enthält ein Wasserzeichen.
Beschreibungen
<p>The physiologic use conditions medical devices are subjected to during implant and long-term in vivo use are critical to ensuring device reliability, efficacy, and safety. This book highlights advanced analyses for measuring the physiologic use conditions of medical devices, introducing important challenges facing engineers. The chapters include:</p>
<ul>
<li>A working definition for the physiologic in vivo use conditions used to further improve medical device performance in patients.</li>
<li>Introductions to common approaches used to measure medical device use conditions so that engineers can use similar techniques where useful.</li>
<li>Detailed case studies that highlight problem statements, approaches for measuring physiologic use conditions, and example outputs from such analyses.</li>
</ul>
<p>This book provides an up-to-date resource for device engineers so that they can accurately measure conditions that devices experience during and after implantation—key to reliability testing, computational modeling, and choosing optimum designs. This is an ideal book for medical device engineers and scientists designing and manufacturing devices for human use, students interested in understanding how devices interact with anatomy, and academic researchers seeking to apply advanced analyses to unmet use condition needs in the medical device field.</p>
<p> </p>
<ul>
<li>A working definition for the physiologic in vivo use conditions used to further improve medical device performance in patients.</li>
<li>Introductions to common approaches used to measure medical device use conditions so that engineers can use similar techniques where useful.</li>
<li>Detailed case studies that highlight problem statements, approaches for measuring physiologic use conditions, and example outputs from such analyses.</li>
</ul>
<p>This book provides an up-to-date resource for device engineers so that they can accurately measure conditions that devices experience during and after implantation—key to reliability testing, computational modeling, and choosing optimum designs. This is an ideal book for medical device engineers and scientists designing and manufacturing devices for human use, students interested in understanding how devices interact with anatomy, and academic researchers seeking to apply advanced analyses to unmet use condition needs in the medical device field.</p>
<p> </p>
<p>Introduction to use conditions for design, test, computational modeling, and procedure development.- Procedural or handling impact on acute and chronic performance (misuse).- Medical images to measure use conditions (CT, MRI, ultrasound, fluoro, x-ray, etc.).- Use condition considerations for lead and catheter design.- Population-based use condition measurement to serve many patients.- Use conditions that impact wireless communication.- Device migration.- Chronic healing response and impact on device performance: the balance of tissue-device interaction.- Flexible device shape history (impact on mechanical reliability).- Relative motion between implanted medical devices.- Measuring deformation/motion cycle counts within a patient population.- Clinical relevance of measurements acquired from pre-clinical models.- The role of returned product and failure analysis as an input to use condition analysis.- Ambulatory measurements i.e. posture-induced movement/loads.</p>
<p>Walt Baxter is a Distinguished Scientist in the Cardiac Rhythm Management business at Medtronic. Walt’s expertise includes medical device kinematics and deformation in vivo—he used calibrated high-speed cineradiography to make early measurements of implanted cardiac lead deformation. Walt obtained a bachelor's degree in Mechanical Engineering from the Georgia Institute of Technology and a Ph.D. in Bioengineering at the University of California, San Diego.</p>
<p>Ryan Lahm is a Senior Engineering Manager in the Cardiac Rhythm Management business at Medtronic. Ryan is an expert in measuring interactions between medical devices and anatomy—he used some of the first contrast-enhanced volumetric medical images (primarily MRI and CT) to measure how cardiac anatomy interacts with permanently implanted leads and catheters. Ryan obtained a bachelor's degree in Physics from Bethel University and a M.S. in Biomedical Engineering at the University of Minnesota.</p>
<p>Both editors have served patients through their work in the medical technology industry for over 25 years.</p>
<p>Ryan Lahm is a Senior Engineering Manager in the Cardiac Rhythm Management business at Medtronic. Ryan is an expert in measuring interactions between medical devices and anatomy—he used some of the first contrast-enhanced volumetric medical images (primarily MRI and CT) to measure how cardiac anatomy interacts with permanently implanted leads and catheters. Ryan obtained a bachelor's degree in Physics from Bethel University and a M.S. in Biomedical Engineering at the University of Minnesota.</p>
<p>Both editors have served patients through their work in the medical technology industry for over 25 years.</p>
<p>The physiologic use conditions medical devices are subjected to during implant and long-term in vivo use are critical to ensuring device reliability, efficacy, and safety. This book highlights advanced analyses for measuring the physiologic use conditions of medical devices, introducing important challenges facing engineers. The chapters include:</p>
<ul>
<li>A working definition for the physiologic in vivo use conditions used to further improve medical device performance in patients.</li>
<li>Introductions to common approaches used to measure medical device use conditions so that engineers can use similar techniques where useful.</li>
<li>Detailed case studies that highlight problem statements, approaches for measuring physiologic use conditions, and example outputs from such analyses.</li>
</ul>
<p>This book provides an up-to-date resource for device engineers so that they can accurately measure conditions that devices experience during and after implantation—key to reliability testing, computational modeling, and choosing optimum designs. This is an ideal book for medical device engineers and scientists designing and manufacturing devices for human use, students interested in understanding how devices interact with anatomy, and academic researchers seeking to apply advanced analyses to unmet use condition needs in the medical device field.</p>
<ul>
<li>A working definition for the physiologic in vivo use conditions used to further improve medical device performance in patients.</li>
<li>Introductions to common approaches used to measure medical device use conditions so that engineers can use similar techniques where useful.</li>
<li>Detailed case studies that highlight problem statements, approaches for measuring physiologic use conditions, and example outputs from such analyses.</li>
</ul>
<p>This book provides an up-to-date resource for device engineers so that they can accurately measure conditions that devices experience during and after implantation—key to reliability testing, computational modeling, and choosing optimum designs. This is an ideal book for medical device engineers and scientists designing and manufacturing devices for human use, students interested in understanding how devices interact with anatomy, and academic researchers seeking to apply advanced analyses to unmet use condition needs in the medical device field.</p>
A key resource for device engineers who want to understand how medical device use conditions can be measured in vivo Can be used as a supplement to medical device design publications and includes standards for qualification for human use Describes current physiologic use condition investigations and techniques, increasing visibility of this important topic
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