Kyïv : , : Kyïvsʹkyĭ nat͡sionalʹnyĭ universytet imeni Tarasa Shevchenka, Vydavnycho-polihrafichnyĭ t͡sentr "Kyïvsʹkyĭ universytet", , [2008]-

2079-908X

1 online resource

Economics

Economics - Ukraine

Economic history

Periodicals.

Ukraine Economic conditions Periodicals

Ukraine

Ukrainian

Refereed/Peer-reviewed

Wiesbaden : , : Springer Fachmedien Wiesbaden : , : Imprint : Springer, , 2019

3-658-27352-6

1 online resource (58 pages) : illustrations

617.962

Critical care medicine

Anesthesiology

Pharmaceutical technology

Intensive / Critical Care Medicine

Pharmaceutical Sciences/Technology

Inglese

The basic principle of anesthetic reflection -- The AnaConDa, the Mirus, and the AnaConDa-S -- Inhaled sedation in ARDS -- Inhaled sedation and mortality.

Andreas Meiser summarizes the current literature on inhalation sedation of critically ill patients. To meet clinical demands, he describes the development of new devices to administer volatile anesthetics together with common ICU ventilators. Their basic principle is called anesthetic reflection. The author discusses advantages and drawbacks of these devices in line with clinical studies demonstrating advantages of inhaled versus intravenous ICU sedation. Contents The basic principle of anesthetic reflection The AnaConDa, the Mirus, and the AnaConDa-S Inhaled sedation in ARDS Inhaled sedation and mortality Target Groups Anaesthesiologists, intensive care medical doctors, physicians and intensive care nurses Students and scientists in the field of anaesthesiology and intensive care About the Author Dr. med. Andreas Meiser is working as a consultant anesthesiologist on the interdisciplinary operative ICU of the Saarland University Medical Center. He has been a pioneer in the field of inhalation ICU sedation.

He has been treating patients using the AnaConDa administration devices since 2004, and has published many original articles in scientific journals on the subject.

Weinheim, : Wiley-VCH, c2004

9786610520305

9781280520303

1280520302

9783527605217

3527605215

9783527601554

3527601554

1 online resource (277 p.)

KambhampatiDev

572.636

Protein microarrays

Physiology

Inglese

Description based upon print version of record.

Includes bibliographical references and index.

Protein Microarray Technology; Preface; Contents; List of Authors; Colour Plates; 1 Protein Microarrays: From Fundamental Screening to Clinical Diagnostics; 1.1 Potential Need for Protein Microarrays; 1.1.1 Protein Therapeutics; 1.1.2 Clinical Diagnostics; 1.1.3 National Security; 1.2 Current Applications of Protein Microarrays; 1.3 Problems and Challenges; 1.3.1 Sample Preparation and Handling (Probe and Target); 1.3.2 Microarray Platform; 1.3.3 Detection Technologies; 1.3.4 Data Analysis; 1.4 Potential Solutions: Enabling Technologies and Advancements; References

2 Protein Microarray Surface Chemistry and Coupling Schemes2.1 Introduction; 2.1.1 Background and Current State of Biomolecule Libraries; 2.2 Microarray Based of Class Substrates; 2.2.1 Surface

Modification; 2.2.2 Current State of Glass-Based Protein Microarrays; 2.3 Microarrays based of Gold Substrates; 2.3.1 Surface Modifications; 2.3.2 Current State of Gold-based Protein Microarrays; 2.4 Microarrays based on Polymer Substrates; 2.4.1 Surface Modifications; 2.5 Special Formats: Microfluidic Devices and Integrated Semiconductor Chips; 2.6 Chemical Immobilization Techniques for Proteins

2.6.1 Covalent Chemical Coupling2.6.2 Photochemical Cross-Coupling; 2.6.3 Tagged Proteins; 2.6.4 Site-Specific Immobilization of Antibodies; 2.7 Conclusions; References; 3 Optimization of a Protein Microarray Platform Based on a Small-molecule Chemical Affinity System; 3.1 Introduction; 3.2 Experimental; 3.2.1 Reagents and Materials; 3.2.2 Comparison of the Intrinsic Fluorescence and Non-Specific Protein Binding of 2-D and 3-D SHA-Coated Glass Slides; 3.2.2.1 Preparation of 2D SHA-Coated Glass Surfaces; 3.2.2.2 Preparation of PDBA-modified Bovine Serum Albumin

3.2.2.3 Preparation of PDBA-modified Human IgG3.2.2.4 Printing and Development of 2-D and 3-D SHA-coated Glass Slides; 3.2.2.5 Comparison of the Intrinsic Flurescence of Unmodified, 2-D and 3-D SHA-coated Glass Slides; 3.2.2.6 Determination of the Non-Specific Protein Binding of 2-D and 3-D SHA-coated Glass Slides; 3.2.3 Immunoassay Using a 3-D SHA-coated Glass Slide; 3.2.3.1 Preparation of PDBA-Cy3-modified Bovine Serum Albumin, PDBA-Human IgG, PDBA-Goat anti Human IgG; 3.2.3.2 Printing the Array and Analyzing the Data

3.2.4 Stability of the PDBA-Protein Conjugates Immobilized on 3-D-SHA-coated Glass Slides3.2.4.1 Preparation of PDBA-modified Goat Anti-rabbit Fc-specific IgG, PDBA-modified Goat Anti-rabbit Fc-specific F(ab)(2), PDBA-modified Goat Anti-human F(ab)(2), and PDBA-modified Goat Anti-mouse Fcγ-specific F(ab)(2); 3.2.4.2 Printing and Reading the Array; 3.3 Results and Discussion; 3.3.1 Comparison of the Intrinsic Fluorescence and Non-specific Protein Binding of 2-D and 3-D SHA-coated Glass Slides; 3.3.2 Immunoassay on a 3-D SHA-coated Slide

3.3.3 Stability of PDBA-Protein Conjugates Immobilized on 3-D SHA-coated Glass Slides

This book is the first of its kind in the field of protein microarrays and addresses novel strategies for constructing highly functional and biocompatible microarrays for screening proteins. The list of authors consisting of world leading experts provide a roadmap for solving the complex challenges that are currently faced while monitoring protein-protein interactions over a wide range of microarray platforms. In doing so, they also offer a comprehensive overview of microarray surface chemistry, detection technologies, fabrication options for array development, and data analysis of numerous