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Umfang: 1 Online-Ressource (147 Seiten) : , Illustrationen.

Ausgabe: 1. Auflage

ISBN: 978-3-95710-334-5

Weitere Ausg.: Erscheint auch als Druck-Ausgabe ISBN 978-3-95710-234-8

Sprache: Deutsch

Fachgebiete: Wirtschaftswissenschaften , Soziologie

Schlagwort(e): Transformation ; Digitalisierung ; Auswirkung ; Digitale Revolution ; Technischer Fortschritt ; Technikbewertung ; Wertorientierung ; Gesellschaft ; Entwicklung ; Technikphilosophie ; Ethik ; Electronic books.

DOI: 10.978.395710/3345

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Mehr zum Autor: Becker, Manfred 1946-

UID:

Umfang: XVII, 303 p. 124 illus., 97 illus. in color. , online resource.

ISBN: 9783030031497

Inhalt: This Open access book offers updated and revised information on vessel health and preservation (VHP), a model concept first published in poster form in 2008 and in JVA in 2012, which has received a great deal of attention, especially in the US, UK and Australia. The book presents a model and a new way of thinking applied to vascular access and administration of intravenous treatment, and shows how establishing and maintaining a route of access to the bloodstream is essential for patients in acute care today. Until now, little thought has been given to an intentional process to guide selection, insertion and management of vascular access devices (VADs) and by default actions are based on crisis management when a quickly selected VAD fails. The book details how VHP establishes a framework or pathway model for each step of the patient experience, intentionally guiding, improving and eliminating risk when possible. The evidence points to the fact that reducing fragmentation, establishing a pathway, and teaching the process to all stakeholders reduces complications with intravenous therapy, improves efficiency and diminishes cost. As such this book appeals to bedside nurses, physicians and other health professionals.

Anmerkung: Preface. About the concept of VHP, beginnings, process and ideal -- Section 1. Right Assessment and Right Vein -- Chapter 1. Catheter and vein selection with avoidance of joints and danger zones -- Chapter 2. Ultrasonic assessment and placement of right device -- Section 2. Right Training -- Chapter 3. Training process, competencies, preparation for PIV, PICC, CVC insertions -- Section 3. Right Insertion -- Chapter 4. Catheter size, type, number of lumen for patient and treatment -- Chapter 5. Placement with no more than 2 attempts -- Chapter 6. Infection Prevention principles with Kits for insertion and compliance with sterile procedure (bundles, checklist, CHG, etc) -- Chapter 7. Tip positioning -- Chapter 8. Securement -- Section 4. Pediatric Vessel Health -- Chapter 9. Differences between paediatrics and adults for vein assessment -- Chapter 10. Right Site selection -- Chapter 11. Right Device assessment (type, size, no. of lumens) -- Chapter 12. Right Technology assessment -- Chapter 13. Why is VHP important in paediatrics? -- Chapter 14. Troubleshooting in paediatrics -- Section 5. Right Supplies and Technology -- Chapter 15. Ultrasound -- Chapter 16. Insertion kits for USGPIV, PICC, Midline, CVC -- Chapter 17. Antimicrobial dressings -- Chapter 18. Needleless connector issues -- Section 6. Right Care and Assessment -- Chapter 19. Daily or twice daily assessment for catheter function, dressing adherence and necessity of device -- Chapter 20. Hub disinfection issues and compliance measures -- Chapter 21. Flushing with proper techniques -- Section 7. Right Evaluation -- Chapter 22. How to evaluate a VHP program initiative -- Chapter 23. Staff education and satisfaction -- Chapter 24. Patient satisfaction -- Chapter 25. Pathway effectiveness and outcome measures.

In: Springer eBooks

Weitere Ausg.: Printed edition: ISBN 9783030031480

Weitere Ausg.: Printed edition: ISBN 9783030031503

Sprache: Englisch

Fachgebiete: Medizin

Schlagwort(e): Electronic books. ; Aufsatzsammlung

DOI: 10.1007/978-3-030-03149-7

URL: https://doi.org/10.1007/978-3-030-03149-7

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Umfang: 1 online resource (51 pages)

Ausgabe: 1st ed.

ISBN: 9783319773384

Anmerkung: Intro -- Preface -- Acknowledgements -- Executive Summary -- Contents -- Chapter 1: General Introduction -- 1.1 Background Analysis -- 1.2 Physiology and Genetics of Heat Tolerance in Rice -- 1.3 Physiological and Biochemical Heat Stress Indicators in Rice -- 1.4 Breeding for Heat Tolerance in Rice -- Chapter 2: Screening Protocols for Heat Tolerance in Rice at the Seedling and Reproductive Stages -- 2.1 Background Analysis -- 2.2 Screening Protocol for Heat Tolerance in Rice at the Seedling Stage -- 2.2.1 Plant Materials -- 2.2.2 Screening for Heat Tolerance Using Hydroponics -- 2.2.2.1 Seedling Establishment in Hydroponics -- 2.2.2.2 Care Required During Plant Growth in Hydroponics -- 2.2.3 Screening for Heat Tolerance in Soil Using Pots -- 2.2.4 Heat Treatment and Recovery of Seedlings -- 2.2.5 Assessment of Heat Tolerance at the Seedling Stage -- 2.2.6 Heat Tolerance Index (HTI) -- 2.2.7 Recovery Stage After Heat Treatment -- 2.3 Screening Protocol for Heat Tolerance in Rice at the Flowering Stage -- 2.3.1 Germination and Seedling Establishment in Hydroponics and Pots -- 2.3.2 Heat Treatment at the Flowering Stage -- 2.3.3 Screening for Heat Tolerance at the Flowering Stage -- Chapter 3: Validation of Screening Protocols for Heat Tolerance in Rice -- 3.1 Background Analysis -- 3.2 Validation of Physiological and Biochemical Indicators -- 3.2.1 Physiological and Biochemical Characterization of Heat Tolerant Lines at the Seedling Stage -- 3.2.2 Physiological and Biochemical Characterization of Heat Tolerant Lines at the Flowering Stage -- 3.2.3 Methods -- 3.2.3.1 Electrolyte Leakage Measurement -- 3.2.3.2 Lipid Peroxidation Assay -- 3.2.3.3 Measurement of Total Proteins -- 3.2.3.4 Antioxidant Enzyme Activity Assay -- 3.3 Validation Protocols of Rice Heat Tolerance Under Field Conditions -- Chapter 4: Conclusion. , Correction to: Pre-Field Screening Protocols for Heat-Tolerant Mutants in Rice -- References.

Weitere Ausg.: Print version: Sarsu, Fatma Pre-Field Screening Protocols for Heat-Tolerant Mutants in Rice Cham : Springer International Publishing AG,c2018 ISBN 9783319773377

Sprache: Englisch

Schlagwort(e): Electronic books. ; Index not Present.

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UID:

Umfang: 1 Online-Ressource (x, 34 Seiten) : , Illustrationen.

ISBN: 978-3-319-31622-2

Serie: ICME-13 Topical Surveys

Weitere Ausg.: Erscheint auch als Druck-Ausgabe ISBN 978-3-319-31621-5

Sprache: Englisch

Schlagwort(e): Electronic books.

DOI: 10.1007/978-3-319-31622-2

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Mehr zum Autor: Verschaffel, Lieven, 1957-

UID:

Umfang: 1 online resource (655 pages)

Ausgabe: 1st ed.

ISBN: 9783030228187

Anmerkung: Intro -- Preface -- Contents -- Contributors -- Part I: Overview Papers -- Chapter 1: LEAP-UCD-2017 V. 1.01 Model Specifications -- 1.1 Introduction -- 1.1.1 Differences Between This Paper and Pre-test Specifications -- 1.1.2 Goals and Overview -- 1.2 Scaling Laws -- 1.3 Description of the Model Construction and Instrumentation -- 1.3.1 Soil Material: Ottawa F-65 Sand -- Modified ASTM D4254 Method C for Minimum Dry Density -- Modified Lade et al. (1998) Method for Maximum Density -- 1.3.2 Placement of the Sand by Pluviation -- 1.3.3 Measurement of Density of the Sand -- 1.3.4 Geometry of the Model -- 1.3.5 Saturation of the Model -- 1.4 Instrumentation of the Model -- 1.4.1 Required Instrumentation -- 1.4.2 Displacement Measurements -- Careful Before and After Photographs of the Model and Surface Markers -- Lateral Displacements from Cameras Mounted on the Centrifuge -- Residual Settlements from Pore Pressure Sensors -- Direct Measurements of Sensor and Surface Marker Locations -- Colored Sand Layers, Noodles, and Sensor Locations During Dissection -- Settlement Gage Sensors -- Tactile Pressure Sensors -- 1.5 Cone Penetration Testing -- 1.6 Shear Wave Velocity -- 1.7 Ground Motions -- 1.7.1 Destructive Ground Motions -- 1.7.2 Nondestructive Ground Motions -- 1.7.3 Assessment of Tapered Sine Wave (TSW) Ground Motions -- 1.8 Data Reporting Anticipated Plan/Concept -- 1.8.1 New Leap Database -- 1.8.2 Dynamic Shaking Sensor Data -- 1.8.3 Pore Pressure Long-Term Time Series Data -- 1.8.4 Summary of Other Anticipated Report Requirements to Be Detailed in a Separate Document -- References -- Chapter 2: Grain Size Analysis and Maximum and Minimum Dry Density Testing of Ottawa F-65 Sand for LEAP-UCD-2017 -- 2.1 Background and Introduction -- 2.2 Grain Size Analysis -- 2.2.1 Discussion of Grain Size Analyses -- 2.3 Minimum and Maximum Index Dry Density. , 2.3.1 LEAP Minimum Density Procedure -- 2.3.2 LEAP Maximum Density Procedure -- 2.3.3 Results of Index Dry Density Testing -- 2.3.4 Discussion of Minimum Density -- 2.3.5 Discussion of Maximum Density -- 2.4 Testing Results Effect on Relative Density -- 2.5 Measurements by ASTM Method -- 2.6 Conclusions -- References -- Chapter 3: Physical and Mechanical Properties of Ottawa F65 Sand -- 3.1 Introduction -- 3.2 Ottawa F65 Soil Characterization -- 3.2.1 Specific Gravity Tests -- 3.2.2 Particle Size Distribution Analysis -- 3.2.3 Hydraulic Conductivity -- 3.2.4 Maximum and Minimum Void Ratios -- 3.3 Cyclic Triaxial Tests -- 3.3.1 Experiment Procedures -- 3.3.2 Sample Preparation -- 3.3.3 Summary of Experimental Results and Observations -- 3.4 Concluding Remarks -- References -- Chapter 4: LEAP-UCD-2017 Comparison of Centrifuge Test Results -- 4.1 Introduction -- 4.2 Densities and Penetration Resistances -- 4.3 Base Input Motions in First Destructive Motion -- 4.4 Acceleration Response of Soil Layers in First Destructive Motion -- 4.5 Displacement Response of the Soil Layers in First Destructive Motion -- 4.6 Pore Pressure Response of Soil Layers in First Destructive Motion -- 4.7 Correlations Between Displacement, Dr, and IMs -- 4.7.1 Rationale for Scaling Between PGA and CSR for Simplified Procedure -- 4.8 Correlations Between Excess Pore Pressures, Dr, and IMs -- 4.9 Correlations Between Peak Cyclic Displacements, Dr, and IMs -- 4.10 Summary and Conclusions -- References -- Chapter 5: Archiving of Experimental Data for LEAP-UCD-2017 -- 5.1 Introduction -- 5.2 Accessing Published LEAP-UCD-2017 Data in DesignSafe -- 5.2.1 General Report File: 1_ExperimentStrenDemPerfSummary_v11b.xlsx -- 5.2.2 General Report File: 2a_AllTestsCompared_24TestsPerPage.pdf -- 5.2.3 General Report Folder: 2b_AllTestsCompared_24TestsPerPage_OnePagePerFile. , 5.2.4 General Report File: 3_AllSensorDataFromAllTests.pdf -- 5.2.5 General Report File: 4_Version1.01_LEAP UCD2017_SpecsforExperiments.docx -- 5.2.6 General Report File: 5_Version_0.99_2017_CentrifugeTestTemplate.xlsx -- 5.2.7 General Report Folder: 6_LEAP-UCD-2017 Cone Penetrometer Equipment Details -- 5.2.8 General Report Folder: 7_Videos of Max and Min Density Tests -- 5.2.9 General Report File: 8_Dec2017WorkshopHandout.pdf -- 5.3 Detailed Data for Each Model Test -- 5.3.1 Selecting an Experiment Site -- 5.3.2 Model Configuration Data -- 5.3.3 Sensor Information -- 5.4 Working Directory for Data LEAP-UCD-2017 -- 5.5 Summary -- References -- Chapter 6: Comparison of LEAP-UCD-2017 CPT Results -- 6.1 Introduction -- 6.2 Design -- 6.3 LEAP-UCD-2017 Experiment -- 6.4 Depth at Which the Cone Tip Touches the Surface (Depth of Zero Penetration) -- 6.5 Effects of Scale Factor and Container Width -- 6.6 Conclusions -- References -- Chapter 7: Difference and Sensitivity Analyses of the LEAP-2017 Experiments -- 7.1 Introduction -- 7.2 Experiment Overview -- 7.3 Difference Metrics -- 7.3.1 Input Motion Differences -- 7.3.2 Response Motion Differences -- 7.4 Sensitivity Analysis -- 7.4.1 Acceleration Sensitivity -- 7.4.2 Permanent Displacement Sensitivity -- 7.5 Conclusions -- References -- Chapter 8: LEAP-2017 Simulation Exercise: Overview of Guidelines for the Element Test Simulations -- 8.1 Introduction -- 8.2 Soil Characterization and Element Tests -- 8.2.1 LEAP-2017 Tests -- 8.2.2 Additional Available Element Tests on Ottawa Sand -- 8.3 Model Calibration Report by Simulation Teams -- 8.3.1 Model Description -- 8.3.2 Model Parameters -- 8.3.3 Calibration Method -- 8.3.4 Liquefaction Strength Curves -- 8.4 Simulation Results -- 8.4.1 Results Data Files -- 8.4.2 Matlab Scripts -- 8.5 Concluding Remarks -- References. , Chapter 9: LEAP-2017 Simulation Exercise: Calibration of Constitutive Models and Simulation of the Element Tests -- 9.1 Introduction -- 9.2 The Numerical Simulation Teams -- 9.3 Summary of the Element Test Simulations -- 9.4 Liquefaction Strength Curves -- 9.5 Conclusions -- References -- Chapter 10: LEAP-2017: Comparison of the Type-B Numerical Simulations with Centrifuge Test Results -- 10.1 Introduction -- 10.2 LEAP-2017 Centrifuge Experiments -- 10.3 Type-B Numerical Simulations -- 10.4 Summary of Type-B Simulations Results -- 10.4.1 Excess Pore Water Pressure Time Histories -- 10.4.2 Acceleration Time Histories and Spectral Accelerations -- 10.4.3 Lateral Displacements -- 10.5 Overall Performance of Numerical Simulations -- 10.6 Conclusions -- References -- Chapter 11: Numerical Sensitivity Study Compared to Trend of Experiments for LEAP-UCD-2017 -- 11.1 Description of the Requested Sensitivity Study -- 11.2 Characterization of Displacements from Experiments -- 11.3 2D Comparisons of Experimental Regression Surfaces to Numerical Simulations -- 11.4 Error Measures and Ranking of Numerical Simulations -- 11.5 3-D Comparison of Simulations to Experimental Regression Surfaces -- 11.6 Summary and Conclusions -- References -- Part II: Centrifuge Experiment Papers -- Chapter 12: LEAP-UCD-2017 Centrifuge Tests at Cambridge -- 12.1 Introduction -- 12.2 Experiment Setup -- 12.2.1 Sand Pouring -- 12.2.2 Viscosity Measurement -- 12.2.3 Saturation -- 12.2.4 Slope Cutting -- 12.2.5 CPT -- 12.3 Destructive Motions -- 12.4 CPT Strength Profiles -- 12.5 PIV -- 12.6 Conclusions -- References -- Chapter 13: LEAP-UCD-2017 Centrifuge Test at University of California, Davis -- 13.1 Introduction -- 13.2 UC Davis Test Specific Information -- 13.2.1 Description of the Model and Instrumentation -- 13.2.2 Sensors -- 13.2.3 Scaling Laws -- 13.3 Test Results. , 13.3.1 Achieved Ground Motions -- 13.3.2 Accelerometer Records During Destructive Motions -- 13.3.3 Excess Pore Pressures -- 13.3.4 Cone Penetration Tests -- 13.3.5 Surface Marker Surveys -- 13.4 Nonconformities with Specifications -- 13.5 Advancements in Centrifuge Testing -- 13.6 Method of Measuring Density -- 13.7 Pore Fluid Viscosity and Saturation -- 13.7.1 Pore Fluid Viscosity -- 13.7.2 Model Saturation -- 13.8 Conclusions -- References -- Chapter 14: LEAP-2017 Centrifuge Test at Ehime University -- 14.1 Introduction -- 14.2 Centrifuge at Ehime University -- 14.3 Centrifuge Model -- 14.3.1 Model Description -- 14.3.2 Sand -- 14.3.3 Placement of Sand -- 14.3.4 Saturation -- 14.3.5 Test Procedure -- 14.4 Results -- 14.4.1 Shear Wave Velocity -- 14.4.2 Input Acceleration -- 14.4.3 Excess Pore Pressure Response -- 14.4.4 Liquefaction Triggering -- 14.4.5 Deformation of the Model -- 14.5 Conclusion -- References -- Chapter 15: LEAP-UCD-2017 Centrifuge Test at IFSTTAR -- 15.1 Introduction -- 15.2 As Built Model -- 15.2.1 Soil Material and Placement of the Sand by Pluviation -- 15.2.2 Rigid Container Configuration and Sensor Layout -- 15.2.3 Viscosity of Pore Fluid -- 15.2.4 Saturation Process -- 15.3 Achieved Ground Motions -- 15.3.1 Horizontal Component -- 15.3.2 Vertical Component -- 15.4 Results -- 15.4.1 Pore Pressure and Acceleration Responses -- 15.4.2 Surface Maker Response -- 15.5 Conclusion -- References -- Chapter 16: LEAP-UCD-2017 Centrifuge Test at KAIST -- 16.1 Introduction -- 16.2 Centrifuge Facility and Earthquake Simulator at KAIST -- 16.3 Physical Modeling -- 16.3.1 Soil Material and Density -- 16.3.2 Viscous Fluid -- 16.3.3 Model Description and Instrumentations -- 16.3.4 Saturation and Container Modifications -- 16.3.5 Sequence of the Centrifuge Test -- 16.4 Centrifuge Test Results -- 16.4.1 Achieved Input Motion. , 16.4.2 Investigation of Soil Model.

Weitere Ausg.: Print version: Kutter, Bruce L. Model Tests and Numerical Simulations of Liquefaction and Lateral Spreading Cham : Springer International Publishing AG,c2019 ISBN 9783030228170

Sprache: Englisch

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UID:

Umfang: 1 online resource (283 pages)

Ausgabe: 5., überarbeitete Auflag

ISBN: 9783410254560 , 9783410254553

Serie: Bauwerk-Basis-Bibliothek

Anmerkung: Description based on publisher supplied metadata and other sources

Weitere Ausg.: Erscheint auch als Druck-Ausgabe Nebgen, Nikolaus, Prof Dipl.-Ing. Holzbau kompakt nach Eurocode 5 : Bauwerk-Basis-Bibliothek

Sprache: Deutsch

Fachgebiete: Technik

Schlagwort(e): Holzbau ; Hochbau ; Bemessung ; Konstruktion ; Eurocode 5 ; Electronic books.

URL: https://ebookcentral.proquest.com/lib/th-brandenburg/detail.action?docID=4340962

Mehr zum Autor: Nebgen, Nikolaus

Mehr zum Autor: Peterson, Leif A. 1974-