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200 00$aModelling degradation of bioresorbable polymeric medical devices /$fedited by J. Pan ; contributors, X. Chen [and three others]
205   $a1st edition
210  1$aSawston, England ;$aWaltham, Massachusetts ;$aOxford, England :$cWoodhead Publishing,$d2015.
210  4$dİ2015
215   $a1 online resource (271 p.)
225 1 $aWoodhead Publishing Series in Biomaterials ;$vNumber 83
300   $aDescription based upon print version of record.
311   $a1-78242-016-9 
311   $a1-322-26977-7 
320   $aIncludes bibliographical references at the end of each chapters and index.
327   $aCover; Modelling Degradationof Bioresorbable Polymeric Medical Devices; Copyright; Contents; List of contributors; Woodhead Publishing Series in Biomaterials; Part One Fundamental methods of modelling degradation of bioresorbable polymeric medical devices; 1Introduction to computer modelling for the design of biodegradable medical devices; 1.1 Introduction; 1.2 General modelling techniques useful in studying device degradation; 1.3 The degradation pathway and models presented in this book; 1.4 Challenges and unresolved issues; Acknowledgements; References
327   $a2Modelling degradation of amorphous biodegradable polyesters: basic model2.1 Introduction; 2.2 Hydrolysis rate equation; 2.3 Production of short chains; 2.4 Master equation for chain scission; 2.5 Summary of equations and list of symbols; 2.6 Analytical solutions of the master equation; 2.7 Numerical solution of the master equation; 2.8 Concluding remarks; References; 3Modelling degradation of amorphous biodegradable polyesters: advanced model; 3.1 Introduction; 3.2 Partition of carboxylic end groups on long and short chains; 3.3 Analytical solutions to the master equation
327   $a3.4 Numerical solution and a parametric study of the model3.5 Separation of end scission from random scission; 3.6 Contributions from random and end scissions to polymer degradation; 3.7 Concluding remarks; References; 4Modelling degradation of semi-crystalline biodegradable polyesters; 4.1 Introduction; 4.2 Rate equation for chain scission in semi-crystalline polymers; 4.3 Actual and extended degrees of crystallinity; 4.4 Extended degree of crystallinity of chain cleavage-induced crystallisation; 4.5 Summary of governing equations for simultaneous chain scission and crystallisation
327   $a4.6 Calculation of number-averaged molecular weight4.7 Comparison between models assuming fast and normal crystallisation; 4.8 Concluding remarks; References; 5Modelling biodegradation of composite materials made of biodegradable polyesters and tricalcium phosphates (TCPs); 5.1 Introduction; 5.2 TCP dissolution and buffering reactions; 5.3 Rate equation for chain scission in presence of buffering reactions; 5.4 Governing equations for degradation of polyester-TCP composites; 5.5 Normalised equations; 5.6 TCP effectiveness map; 5.7 Concluding remarks; References
327   $a6Modelling heterogeneous degradation of polymeric devices due to short chain diffusion6.1 Introduction; 6.2 Scission rate of long chains affected by short chain diffusion; 6.3 Diffusion equation for short chains; 6.4 Collection of the governing equations; 6.5 A numerical study of size effect; 6.6 Non-dimensionalisation and degradation map; 6.7 Effect of other factors on the degradation map; 6.8 Concluding remarks; References; Part Two Advanced methods of modelling degradation of bioresorbable polymeric medical devices
327   $a7Finite element analysis (FEA) of biodegradation of polymeric medical devices
330   $aThe use of bioresorbable polymers in stents, fixation devices and tissue engineering is revolutionising medicine. Both industry and academic researchers are interested in using computer modelling to replace some experiments which are costly and time consuming. This book provides readers with a comprehensive review of modelling polymers and polymeric medical devices as an alternative to practical experiments. Chapters in part one provide readers with an overview of the fundamentals of biodegradation. Part two looks at a wide range of degradation theories for bioresorbable polymers and devices. 
410  0$aWoodhead Publishing series in biomaterials ;$vNumber 83.
606   $aPolymers in medicine
608   $aElectronic books.
615  0$aPolymers in medicine.
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702   $aChen$b X.
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200 10$aArtsIT, Interactivity and Game Creation $e13th EAI International Conference, ArtsIT 2024, Abu Dhabi, United Arab Emirates, November 13?15, 2024, Proceedings, Part II /$fedited by Anthony L. Brooks, Domna Banakou, Slavica Ceperkovic
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327   $a -- Amplifying Creativity: Exploring Digital Musical Interfaces.  -- Embodied learning and the role of Extended Digital Musical Instruments.  -- Love in Action: Gamifying Public Video Cameras for Fostering Social Relationships in Real World.  -- From Knobs to Whole Body: Dance with Feedback.  -- Sound effects in media: A comparative analysis of recorded and synthetic samples in live-action and animation.  -- The Taxonomy of a Clarinet Tangible Acoustic Interface.  -- Multi-Track MusicLDM: Towards Versatile Music Generation with Latent Diffusion Model.  -- Illuminating Realities: Creating immersive spaces to promote mindfulness and wellbeing.  -- Creating Generative Data-driven Aesthetics based on Brain Wave Data.  -- Adaptive Virtual Reality Meditation for Adults with ADHD.  -- Challenges and Opportunities for Designing Digital Communication Interfaces for Persons with Partial Locked-in Syndrome.  -- Tapping into touch preferences and individual behaviours: assessing and improving the HandsOn mobile app.  -- Posters.  -- Ethics in Artificial Intelligence: Ensuring Integrity in Research and Media.  -- Virtual Reality vs. Augmented Virtuality in Fire Extinguishing Training.  -- EN-JOIN: Exploring Inclusive Visuals for a Game to Give Perspective on Energy Communities.  -- Solace: Integrating Western and Emirati Poetic Traditions to Reimagine Narrative Poetry in VR.  -- A teacher?s perception of the co-creation and personalisation of an Immersive Web Environment.  -- Exploring Adaptability of Miniature Painting to New Media.  -- Demos.  -- Ocean Pulse: Integrating Psychology, Technology, and Creative Practice for Transformative Experiences.  -- ?Giving Plants a Voice?: an Interactive Installation on Khaleeji Music and Nature.  -- Making Beshbarmak: Games for Central Asian Cultural Heritage.
330   $aThis volume constitutes the proceedings of the 13th EAI International Conference on ArtsIT, Interactivity and Game Creation, ArtsIT 2024, in Abu Dhabi, United Arab Emirates, during November 13?15, 2024. The 38 full papers and 4 short papers were presented in this volume were carefully reviewed and selected from 112 submissions. The papers are thematically arranged in the following sections: Part I: Art & Games; Technical; Education, Co-Creativity in multi-modal interaction with generative AI. Part II: Amplifying Creativity: Exploring Digital Musical Interfaces; Illuminating Realities: Creating immersive spaces to promote mindfulness and wellbeing; Posters.
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606   $aApplication software
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606   $aSocial sciences$xData processing
606   $aComputer networks
606   $aCommunications Engineering, Networks
606   $aComputer and Information Systems Applications
606   $aSignal, Speech and Image Processing
606   $aComputer Application in Social and Behavioral Sciences
606   $aComputer Communication Networks
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615 24$aComputer and Information Systems Applications.
615 24$aSignal, Speech and Image Processing.
615 24$aComputer Application in Social and Behavioral Sciences.
615 24$aComputer Communication Networks.
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