| Description |
1 online resource (xv, 181 pages) : illustrations (some color) |
| Series |
Advances in experimental medicine and biology, 0065-2598 ; volume 1235 |
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Advances in experimental medicine and biology ; v. 1235.
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| Contents |
Intro -- Preface -- Acknowledgements -- About the Book -- Contents -- Contributors -- About the Editor -- 1 Web-Based 3D Visualisation of Biological and MedicalData -- 1.1 Introduction -- 1.1.1 Stand-Alone Visualisation Applications -- 1.1.1.1 VTK -- 1.1.1.2 ParaView -- 1.1.1.3 Voreen and Inviwo -- 1.1.1.4 3D Slicer -- 1.1.1.5 SimVascular -- 1.1.1.6 NeckVeins -- 1.1.1.7 Exposure Render -- 1.2 Background -- 1.2.1 Volumetric Data -- 1.2.2 Indirect Volume Rendering -- 1.2.3 Direct Volume Rendering -- 1.2.3.1 Maximum Intensity Projection -- 1.2.3.2 ISO Surface Rendering |
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1.2.3.3 Emission-Absorption Model -- 1.2.3.4 Multiple Scattering Model -- 1.3 Web Based Visualisation Systems -- 1.3.1 VTK.js -- 1.3.2 ParaViewWeb -- 1.3.3 Ami.js -- 1.3.4 VPT -- 1.3.5 Med3D -- 1.4 Discussion -- 1.5 Conclusions -- References -- 2 Ultrasound-Guided Regional Anaesthesia: Visualising the Nerve and Needle -- Abbreviations -- 2.1 Introduction -- 2.2 Regional Anaesthesia -- 2.3 Principles of Ultrasound Used in Regional Anaesthesia -- 2.4 Image Optimistion -- 2.5 General Appearance of Peripheral Nerves on Ultrasound -- 2.6 Nerve Appearance: Upper Limb Nerve Blocks |
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2.6.1 Interscalene Block -- 2.6.2 Supraclavicular Block -- 2.6.3 Infraclavicular Block -- 2.6.4 Axillary Brachial Plexus Block -- 2.6.5 Forearm Blocks -- 2.7 Nerve Appearance: Lower Limb Nerve Blocks -- 2.7.1 Femoral Nerve Block -- 2.7.2 Popliteal Sciatic Nerve Block -- 2.7.3 Ankle Block -- 2.8 Strategies to Aid Nerve Identification on Ultrasound -- 2.9 Challenges in Visualising the Needle During Ultrasound-Guided Regional Anaesthesia -- 2.10 Technologies to Aid Visualisation -- 2.10.1 Needle Shaft -- 2.10.2 Needle Tip -- 2.10.3 Alignment -- 2.10.4 Robotic Assistance -- 2.10.5 Magnetisation |
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2.10.6 Optical Tracking -- 2.10.7 Immersive Technology -- 2.10.8 Nerve Stimulation -- 2.10.9 Ultrasound Technology -- 2.11 Summary -- References -- 3 Scanning Conditions in Functional Connectivity Magnetic Resonance Imaging: How to Standardise Resting-State for Optimal Data Acquisition and Visualisation? -- 3.1 Functional Magnetic Resonance Imaging -- 3.1.1 Resting-State Functional Connectivity Magnetic Resonance Imaging -- 3.1.2 Resting-State Networks -- 3.2 Scanning Conditions -- 3.2.1 Reproducibility of Resting-State Imaging Data -- 3.3 Chapter Scope -- 3.4 Methods -- 3.4.1 Study Design |
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3.4.2 Image Acquisition -- 3.4.3 Experimental Conditions -- 3.4.3.1 Pure Resting-State -- 3.4.3.2 Low-Cognitive Demand Paradigm -- 3.4.3.3 Scanner Suite -- 3.5 Analysis -- 3.5.1 False Response Rate -- 3.5.2 Data Pre-Processing -- 3.5.3 Functional Brain Network Template -- 3.5.4 Similarity Matrix -- 3.5.5 Intraclass Correlation Coefficient Calculation -- 3.5.6 Test-Retest Reliability Analysis -- 3.5.6.1 Global Comparison -- 3.5.6.2 Component-Wise Comparison -- 3.6 Results -- 3.6.1 False Response Rate -- 3.6.2 Test-Retest Reliability -- 3.6.2.1 Global Comparison -- 3.6.2.2 Component-Wise Comparison |
| Summary |
This edited book explores the use of technology to enable us to visualise the life sciences in a more meaningful and engaging way. It will enable those interested in visualisation techniques to gain a better understanding of the applications that can be used in visualisation, imaging and analysis, education, engagement and training. The reader will be able to explore the utilisation of technologies from a number of fields to enable an engaging and meaningful visual representation of the biomedical sciences, with a focus in this volume related to anatomy, and clinically applied scenarios. The first eight chapters examine a variety of tools, techniques, methodologies and technologies which can be utilised to visualise and understand biological and medical data. This includes web-based 3D visualisation, ultrasound, virtual and augmented reality as well as functional connectivity magnetic resonance imaging, storyboarding and a variety of stereoscopic and 2D-3D transitions in learning. The final two chapters examine the pedagogy behind digital techniques and tools from social media to online distance learning techniques |
| Bibliography |
Includes bibliographical references and index |
| Notes |
3.7 Summary |
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Online resource; title from PDF title page (EBSCOhost, viewed August 19, 2021) |
| Subject |
Three-dimensional imaging in medicine.
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Biomedical engineering.
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Computer vision.
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Biotechnology.
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Imaging, Three-Dimensional
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Biotechnology
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biomedical engineering.
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bioengineering.
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Biology, life sciences.
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Biotechnology.
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Biomedical engineering.
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Science -- Life Sciences -- General.
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Science -- Biotechnology.
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Medical -- Allied Health Services -- Medical Technology.
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Three-dimensional imaging in medicine
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Computer vision
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Bioinformatics
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Biomedical engineering
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Biotechnology
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Computational biology
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Bioinformàtica.
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Biotecnologia.
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Enginyeria biomèdica.
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| Genre/Form |
Llibres electrònics.
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| Form |
Electronic book
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| Author |
Rea, Paul (Paul M.), editor.
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| ISBN |
9783030376390 |
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3030376397 |
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