01711nam0-2200577---450 99000006259020331620180308150857.00-521-57826-40006259USA010006259(ALEPH)000006259USA01000625920000914d1996----|||y0itay0103----baenggb||||||||001yyVirtues of the mindan inquiry into the nature of virtue and the ethical foundations of knowledgeLinda Trinkaus ZagzebskiCambridgeCambridge University Press1996XVI, 365 p.22 cmConoscenzaEticaPrudenzaVirtù121TRINKAUS ZAGZEBSKI,Linda754857ITSALBCISBD990000062590203316II.3. 559 (IV C 2906)150220 L.M.IV C00002006CC 121 TRI3025 FILBKUMAFIL20000914USA01172820001019USA01105520001019USA01145320001019USA01150020001019USA01153820001024USA01151320001027USA01151820001027USA01152220001110USA01170920001124USA01120720020403USA011613PATRY9020040406USA011605COPAT49020050628USA01175620121027USA01154120121027USA01160520121027USA011610Virtues of the mind1519136UNISASA000476911632nam 22005893 450 991101959060332120240220080208.09781394204878139420487697813942048611394204868(MiAaPQ)EBC31167442(Au-PeEL)EBL31167442(CKB)30404826400041(Exl-AI)31167442(OCoLC)1423044147(EXLCZ)993040482640004120240220d2024 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierComputational Intelligence in Bioprinting Challenges and Future Directions1st ed.Newark :John Wiley & Sons, Incorporated,2024.©2024.1 online resource (346 pages)9781394204397 1394204396 Cover -- Title Page -- Copyright Page -- Contents -- Preface -- Chapter 1 The Emergence of Bioprinting and Computational Intelligence -- 1.1 Introduction -- 1.2 Related Study -- 1.3 Understanding the Basics of Bioprinting and Computational Intelligence -- 1.3.1 Bioprinting: The Basics -- 1.3.2 Computational Intelligence: The Basics -- 1.3.3 Applications of Bioprinting and Computational Intelligence -- 1.4 The Role of Computational Intelligence in Bioprinting -- 1.5 Applications of Bioprinting and Computational Intelligence in Medicine -- 1.6 Bioprinting and Computational Intelligence in Tissue Engineering and Regenerative Medicine -- 1.7 Advancements in Bioprinting and Computational Intelligence Technologies -- 1.8 The Ethical and Regulatory Implications of Bioprinting and Computational Intelligence -- 1.9 The Future of Bioprinting and Computational Intelligence: Opportunities and Challenges -- 1.10 Case Studies: Bioprinting and Computational Intelligence in Action -- 1.10.1 Trends in Computational Intelligence and Bioprinting -- 1.10.2 Challenges in Computational Intelligence and Bioprinting -- 1.11 Conclusion -- References -- Chapter 2 Design, Architecture, Implementation, and Evaluation of Bioprinting Technology for Tissue Engineering -- 2.1 Introduction -- 2.2 3D Bioprinting -- 2.3 Material Characteristics -- 2.3.1 Printability -- 2.4 Mechanical Properties -- 2.5 Biomaterials -- 2.6 Design, Architecture of 3D Bioprinting -- 2.6.1 Inkjet Bioprinting -- 2.6.2 Laser-Assisted Bioprinting (LAB) -- 2.6.3 Extrusion Bioprinting -- 2.7 3D Bioprinting Tissue Models -- 2.8 3D Multimaterial Bioprinting-Development of Complex Architectures -- 2.9 Implementation and Evaluation -- 2.10 Bone -- 2.11 Cartilage -- 2.12 Soft Tissue Engineering -- 2.13 Vascular Tissue -- 2.14 Skin -- 2.15 Biocompatibility and Control of Degradation and Byproducts.2.16 Conclusion -- References -- Chapter 3 Design and Development of IoT Devices: Methods, Tools and Technologies -- 3.1 Introduction to IoT Devices and 3D Bioprinting -- 3.2 Methodology for Designing IoT Devices for 3D Bioprinting -- 3.3 Additional Considerations in IoT Device Design for 3D Bioprinting -- 3.4 Tools for Developing IoT Devices for 3D Bioprinting -- 3.4.1 Microcontrollers and Development Boards -- 3.4.2 Sensors and Actuators -- 3.4.3 Communication Protocols -- 3.4.4 Software Development Kits -- 3.4.5 Cloud Platforms -- 3.4.6 3D Printing Software -- 3.4.7 CAD Software -- 3.4.8 Simulation Software -- 3.4.9 Data Analytics Tools -- 3.4.10 Cybersecurity Tools -- 3.5 Techniques for Developing IoT Devices for 3D Bioprinting -- 3.5.1 Agile Development -- 3.5.2 Rapid Prototyping -- 3.5.3 Test-Driven Development -- 3.5.4 Continuous Integration -- 3.5.5 Modular Design -- 3.5.6 Power Optimization -- 3.5.7 Data Processing Techniques -- 3.5.8 Quality Assurance -- 3.5.9 Cybersecurity Techniques -- 3.5.10 Standardization -- 3.6 Case Studies of IoT Devices for 3D Bioprinting -- 3.7 Future Directions in IoT Devices for 3D Bioprinting -- 3.8 Conclusion -- References -- Chapter 4 AI-Based AR/VR Models in Biomedical Sustainable Industry 4.0 -- 4.1 Introduction -- 4.2 Mixed Augmented Reality -- 4.2.1 SDK in Augmented Reality -- 4.2.2 Application Scope of Augmented Reality -- 4.2.2.1 Video Capabilities -- 4.2.2.2 AR Toolkit Technology -- 4.2.2.3 Quality of Tracking System -- 4.3 AR Technology -- 4.3.1 High Level Augmented Reality -- 4.3.2 Limitations of Enhanced Image -- 4.3.3 Limitations of CAD Model -- 4.3.4 Augmented Reality in Manufacturing Sector -- 4.4 Requirement of Augmented Reality -- 4.4.1 Capability of AR -- 4.4.2 Computational Hardware Capabilities -- 4.4.3 Symbol-Based Tracking Software -- 4.5 Conclusions -- References.Chapter 5 Computational Intelligence-Based Image Classification for 3D Printing: Issues and Challenges -- 5.1 Introduction -- 5.2 Brief Concepts -- 5.2.1 3D Printing Tools -- 5.2.2 Artificial Intelligence-Based Digital Marketing -- 5.2.3 Automated Machine Learning Prediction System -- 5.3 Role of Artificial Intelligence in Industry 4.0 -- 5.3.1 3D Printing Process -- 5.3.2 Enhancement in Machine Learning -- 5.3.3 Genetics-Based Machine Learning -- 5.3.4 Slicing Technique in 3D Model -- 5.3.5 Printing Path Trajectory -- 5.3.6 Improvement in Computational Simulation -- 5.3.7 Improving Service-Oriented Architecture -- 5.3.8 Capabilities of Cloud Computing -- 5.3.9 Hamming Distance Technique -- 5.3.10 Improving Knowledge Skills -- 5.3.11 Object Detection Algorithm -- 5.3.12 Improvement in Manufacturing Defects -- 5.4 Conclusion -- References -- Chapter 6 Role of Cybersecurity to Safeguard 3D Bioprinting in Healthcare: Challenges and Opportunities -- 6.1 Introduction -- 6.2 Related Work -- 6.3 Creation of 3D Objects and Printing -- 6.3.1 Benefits of 3D Printing -- 6.3.2 Bioprinting -- 6.3.3 A Flow Diagram Depicting the Bioprinting Process -- 6.3.4 Datasets Used in Bioprinting -- 6.4 Schematic Diagram of 3D Bioprinting -- 6.4.1 3D Bioprinting Strategies -- 6.4.2 Comparison Among the 3D Bioprinting Approaches -- 6.4.3 Materials Used in Bioprinting -- 6.4.4 Bioprinting in Diverse Domains -- 6.5 Cyberthreats Posed to Bioprinting -- 6.5.1 Challenges and Opportunities of Cybersecurity in Bioprinting -- 6.5.2 Proposed Solutions -- 6.5.3 Combating the Cybersecurity Risks of 3D Bioprinting -- 6.5.4 Blockchain Technology and Bioprinting -- 6.5.5 A Comparative Survey of Cyberthreats in Additive Manufacturing Technology -- 6.6 Conclusion -- References -- Chapter 7 Legal and Bioethical View of Educational Sectors and Industrial Areas of 3D Bioprinting.7.1 Introduction -- 7.2 Current 3D Bioprinting Market Trends -- 7.3 Legal and Ethical Perspectives -- 7.4 Regarding the Introduction and Advancement of 3D Bioprinting -- 7.4.1 Current and Potential Paths for Bioethical Discourse -- 7.4.2 Legal Concerns with the Introduction of 3D Bioprinting Into Clinical Practice -- 7.4.3 Ethical Concerns with the 3D Bioprinting of Artificial Ovaries and Their Use in Clinical Settings -- 7.5 Conclusion -- 7.6 Future Scope -- References -- Chapter 8 Optimizing 3D Bioprinting Using Advanced Deep Learning Techniques A Comparative Study of CNN, RNN, and GAN -- 8.1 Introduction -- 8.2 Convolutional Neural Networks in Optimization of 3D Bioprinting -- 8.3 RNN in Optimization of 3D Bioprinting -- 8.4 Generative Adversarial Networks (GAN) in Optimization of 3D Bioprinting -- 8.5 Datasets Used for Optimization of 3D Bioprinting -- 8.6 3D Slicer Medical Image Segmentation Dataset -- 8.7 Sensor Data -- 8.8 Open Organ Database Dataset -- 8.9 Proposed Model -- 8.10 CNN U-Net -- 8.11 RNN Long Short-Term Memory -- 8.12 Wasserstein Generative Adversarial Network -- 8.13 Process of Combined Model -- 8.14 Conclusion -- References -- Chapter 9 Research Trends in Intelligence-Based Bioprinting for Construction Engineering Applications -- 9.1 Introduction -- 9.2 Analysis of Bioprinting -- 9.3 Model Development in Bioprinting Technology -- 9.4 3D Bioprinting Academic Institutions in the World -- 9.5 Emerging Bioprinting Technology -- 9.5.1 Opportunities -- 9.5.2 Challenges -- 9.6 Development in Bioengineering -- 9.7 Evolution of Patent Trends in Bioprinting -- 9.8 Conclusions -- References -- Chapter 10 Design and Development to Collect and Analyze Data Using Bioprinting Software for Biotechnology Industry -- 10.1 Introduction -- 10.2 Digital Technology in Bioprinting -- 10.2.1 Shape of Bioprinting.10.2.2 Heterogeneity Units of Material -- 10.2.2.1 Tissue Improvement -- 10.2.2.2 Formation of Biomaterials -- 10.2.2.3 Biomaterial and Biological Factors -- 10.2.3 Dynamic Changes in Fabrication Process -- 10.3 Designing Techniques in Bioprinting -- 10.3.1 Data Processing in Biomedical Imaging -- 10.3.2 Process Bioprinting Techniques -- 10.3.3 Interaction of Bioink Formulation -- 10.4 3D Bioprinting -- 10.4.1 Optimized Bioprinting -- 10.4.2 Modifying Crosslinking -- 10.4.3 Multiple Crosslinking -- 10.4.4 Enhance Bioprinting -- 10.4.5 Hybrid Bioprinting -- 10.5 Enhanced Biotissue Printing -- 10.5.1 Integrating Thickness of Engineered Tissue -- 10.5.2 Integration and Enhancement of Cellular Interaction -- 10.5.3 DNA with a Smart Biomaterial -- 10.5.3.1 Biomaterials -- 10.5.3.2 Reactive Hydrogel to External Stimuli -- 10.5.4 Simulation -- 10.6 Conclusion -- 10.7 Future Work -- References -- Chapter 11 Cyborg Intelligence for Bioprinting in Computational Design and Analysis of Medical Application -- 11.1 Introduction -- 11.2 Next Generation of Bioprinting -- 11.2.1 Medicine Management -- 11.2.2 Varieties of Bioprinting Material -- 11.2.2.1 Thermoresponsive Materials -- 11.2.2.2 Biocompatible Polymers Materials -- 11.2.2.3 Endophyte Biocompatible Polymers Materials -- 11.2.2.4 Photo-Conductive Polymer Materials -- 11.2.2.5 UV-Assisted in 3D Printing -- 11.2.2.6 Sensitivity Polymeric Materials -- 11.2.2.7 Macromolecules Materials -- 11.2.2.8 Dual-Sensitive Materials -- 11.2.3 Biosensing Scaffolds -- 11.3 Biosensors and Actuators -- 11.3.1 Fabricated Scaffold Tissues -- 11.3.2 Vascularizing Tissues -- 11.3.3 4D Bioprinting Neural Tissue -- 11.3.4 Longitudinal Deformation -- 11.3.5 Uses of Biomedical Appliances -- 11.4 Enhancing Technology in Bioprinting -- 11.5 Conclusion and Future Work -- References.Chapter 12 Computer Vision-Aides 3D Bioprinting in Ophthalmology Recent Trends and Advancements.This book delves into the intersection of computational intelligence and bioprinting, exploring their applications in medicine, tissue engineering, and regenerative medicine. It discusses the design and evaluation of bioprinting technologies, the integration of IoT devices, and the use of AI-based AR/VR models in biomedical industries. The book also addresses cybersecurity challenges in 3D bioprinting, legal and bioethical considerations, and optimization techniques using deep learning. Aimed at professionals and researchers in biomedical engineering and computational sciences, it provides insights into the future opportunities and challenges of these technologies.Generated by AI.Computational intelligenceGenerated by AITissue engineeringGenerated by AIComputational intelligenceTissue engineering610.285Gangadevi E1839872Shri M. Lawanya1839873Balusamy Balamurugan1340583MiAaPQMiAaPQMiAaPQBOOK9911019590603321Computational Intelligence in Bioprinting4419260UNINA07980nam 22005773 450 991100703730332120230629231217.01-5231-3799-13-0357-3300-7(CKB)5450000000059300(MiAaPQ)EBC6812590(Au-PeEL)EBL6812590(OCoLC)1287132451(EXLCZ)99545000000005930020211214d2021 uy 0engurcnu||||||||txtrdacontentcrdamediacrrdacarrierCorrosion. Tube Products and Pipeline Systems1st ed.Zurich :Trans Tech Publications, Limited,2021.©2021.1 online resource (463 pages)Specialized Collections ;v.Volume 163-0357-1300-6 Intro -- Corrosion. Tube Products and Pipeline Systems -- Preface -- Table of Contents -- Chapter 1: Corrosion Degradation of Tube Products and Pipeline Systems -- Corrosion Resistance Analysis of ST37 Carbon Steel Material Using Phosphate Conversion Coating in Various Immersion Durations -- Corrosion Rate Analysis of API 5L Gr B Steel Pipe in Acetic Acid Contained Crude Oil Treatment System by Using Amine Base Organik Corrosion Inhibitor -- Electrochemical Study of Calcareous Deposit Formation in Simulated Soil Solution under Cathodic Protection -- Corrosion Behavior of Cr-Mo Alloy Steel in Direct Contact with Elemental Sulfur -- Destruction Patterns of X70 Steel Sample, Possessing Cracks of Corrosion-Mechanical Origin, under Cyclic Loading -- Studying of Causes of Destruction of the Main Gas Pipeline -- Influence of Chloride for SCC Susceptibility on 15Cr Stainless Steel at High Temperatures under CO2 Environment -- Effect of Corrosive Environment Conditions on Austenitic Structure Reliability -- Atypical Cases of Welded Structure Failures -- Investigation of Local Corrosion Degradation Developed on a Pipeline System in Service Period -- Study on Affecting Factors and Mechanism of Oil Tubing Corrosion in Northern Shaanxi Oil Field -- Effect of Grain Size on Corrosion Fatigue Behaviors of Primary Coolant Pipes of Nuclear Power Plants -- Evaluation of Surface Degradation of Deoxidized AW-AlMg0.7Si Alloy -- Effect of Extrusion Texture on Mechanical and Electrochemical Properties of Aluminum Alloy Drill Pipe -- Corrosion Behavior of P110S Oil Pipe in Simulated Working Condition -- Corrosion Behavior and Safety Analysis of 80S Steel in H2S/CO2 Environment -- The Erosion-Corrosion Behaviors of the Full-Scale PFF78-70 Flat Valve and P110SS Tubing -- Influence of Phase Composition of Steel on a Damage Rate from Bio-Corrosion.Changes in Corrosion of X70 Steel in Water-Saturated Supercritical CO2 System Caused by Impurity -- Corrosion Behavior Research of Aluminized N80 Tubing in Water Injection Well -- Corrosion Behavior for Casing in Producing Well with Water Injection Technology during Long-Term Service -- External Stress Corrosion Cracking Risk Factors of High Grade Pipeline Steel -- Investigation of the Hydrogen Stratification of the Metal of the Active Gas Pipeline -- Welded Stainless Steel: Surface Oxidation, Characterization, Hardness and Corrosion Resistance -- Effect of Sulfuric Acid Concentration on the Corrosion Rate of ASTM A213-T12 Steel -- Chapter 2: Corrosion Assessment of Tube Products and Pipeline Systems -- Electrochemical and XPS Studies of Benzalkonium Chloride for Carbon Steel Protection in Hydrochloric Acid -- Impact of In-Service Inspection on the Reliability of Small Piping -- Pitting Corrosion Failure Analysis of a Produced Oil/Water Fluid Pipeline -- Research on Corrosion Resistance of Steel Pipes in Water of Oilfield -- Failure Analysis on Heat Exchanger Tube Bundle Exposed to Naphthenic Acid Corrosion -- Analysis of the Causes of Tube and Pipeline Blocking in Sulige Gas Field -- Fatigue Mechanism of Domestic 316LN Stainless Steel in Simulated AP1000 First-Loop Water Environment -- Fatigue-Corrosion of High Strength Steels in Synthetic Seawater under Cathodic Protection -- Relationship between Corrosion Resistance and Microstructure of Copper-Nickel Alloy Pipes in Marine Engineering -- Corrosion Diagnosis and Mechanism of Boiler Water-Cooled Wall Tubes in Alkaline Environment -- Reliability Prediction of Variable Amplitude Corrosion Fatigue Life of TP140 Casing Steel -- The Study of the Destruction of Pipelines, Subject to Stress Corrosion Cracking -- Failure Analysis on Leakage of the Circumferential Weld of Steel 20 Buried Pipeline.Nitrates Induced Stress Corrosion Cracking in Tubing Connections from Oil Well -- Leakage Failure Analysis of 80SS Tubing in Gas Field -- Analysis of Weld Cracking in a Low-Pressure Steam Pipe -- Experimental Study on Flow-Induced Corrosion of Casing and Tubing Steel for Heavy Oil Thermal Recovery Wells -- Test Analysis of Corrosion Perforation in a Crude Oil Gathering Pipeline -- Analysis of Corrosion Causes in the Export of a Compressor in the Pipeline of Western China -- Leakage Failure Analysis of the ERW Steel Pipeline -- Analysis of Corrosion Behavior on External Surface of 110S Tubing -- Fracture Failure Analysis of C110 Oil Tube in a Western Oil Field -- Experimental Study on Corrosion of Multi-Component Thermal Fluid Thermal Recovery well Tube String -- Study of Corrosion Behaviour of Carbon Steel in Evian Derived Solution from Electrochemical Techniques -- Simulation of Gas-Liquid Two-Phase Flow-Induced Corrosion at Premium Connection in High Productivity Gas Wells Containing CO2 -- Chapter 3: Corrosion Protection of Tube Products and Pipeline Systems -- Development of Domestic CT80S Sulfur Resistance Coiled Tubing -- Investigation on the Impact of an Enhanced Oil Recovery Polymer towards Microbial Growth and Microbial Induced Corrosion Rates -- Effect of Steel Properties on Buckling Pressure of Corroded Pipelines -- Effect of Layer-by-Layer Texture Inhomogeneity on the Stress Corrosion of Gas Steel Tubes -- Development Direction of Pipeline Corrosion Research on Oil Refining and Chemical Enterprises -- Failure Analysis and Solution to Bimetallic Lined Pipe -- Development of Polymer-Based Composite Coatings for the Gas Exploration Industry: Polyoxometalate Doped Conducting Polymer Based Self-Healing Pigment for Polymer Coatings -- Chemically Resistant Glass-Enamel Coating for the Protection of Steel Pipelines.Development of Characterization and Analysis Methods for Graphene Modified Coatings for Tubing -- Anticorrosion Protection of Welded Joints of Oil Pipelines -- Evaluation and Field Test of Corrosion Inhibitors of Oil Tube Carbon Steel from Shaanbei Oilfield -- Effect of Nickel Content on Mechanical Property and Microstructure for Sulfide Stress Corrosion High-Strength Steel -- Effect of pH, Rotation Speed and Imidazoline - Paracetamol Based Inhibitor Volume Ratio on Corrosion Protection of St 41 Steel in CO2 Environment Using Rotating Cylinder Electrode (RCE) -- The Corrosion Inhibition of API 5L Steel Using Natrium Acetate and Natrium Nitrite in Natrium Chloride Acid Solution -- Keyword Index -- Author Index.Aggregated Book.Specialized CollectionsCorrosion and anti-corrosivesPipelinesCorrosionCorrosion and anti-corrosivesfast(OCoLC)fst00880341PipelinesCorrosionfast(OCoLC)fst01064637Corrosion and anti-corrosives.PipelinesCorrosion.Corrosion and anti-corrosives.PipelinesCorrosion.620.11223Dinita Alin1824088Kolisnychenko Stanislav1793177MiAaPQMiAaPQMiAaPQBOOK9911007037303321Corrosion. Tube Products and Pipeline Systems4391129UNINA