Dieses handliche Fachbuch bietet HLPC-Experten ausführliche praktische Informationen, um Gradienten-Trennverfahren zuverlässig und effizient durchzuführen.
Autorentext
Stavros Kromidas, PhD, works as an independent consultant for analytical chemistry, based in Saarbrucken (Germany). For more than 20 years he has regularly held lectures and training courses on HPLC, and has authored numerous articles and several books on various aspects of chromatography. He is the founder of NOVIA GmbH, a provider of professional training and consulting in analytical chemistry, and served as its CEO until 2001.
Zusammenfassung
This practical guide for analytical scientists explains the use of gradients in liquid chromatography. The fundamentals of gradient separations, as well as the most common application scenarios are addressed, from LC-MS coupling to biochromatography to the separation of ionic substances. Throughout, this handy volume provides detailed hands-on information for practitioners, enabling them to use gradient separation methods reliably and efficiently.
Inhalt
Preface ix
The Structure of the Book xi
Notes on Contributors xiii
List of Contributors xvii
Part 1 Principles of Gradient Elution 1
1 Aspects of Gradient Optimization 3
Stavros Kromidas (translated from German by Steve Ross)
1.1 Introduction 3
1.2 Special Features of the Gradient 3
1.3 Some Chromatographic Definitions and Formulas 5
1.4 Detection Limit, Peak Capacity, Resolution Possibilities for Gradient Optimization 8
1.4.1 Detection Limit 8
1.4.2 Peak Capacity and Resolution 9
1.5 Gradient Myths 14
1.6 Examples for the Optimization of Gradient Runs: Sufficient Resolution in an Adequate Time 15
1.7 Gradient Aphorisms 38
2 Instrumental Influences on the Quality and Performance of Gradient Methods and Their Transfer Between Different HPLC Devices 41
Frank Steiner
2.1 Technical Implementation of the Gradient Elution and the Respective Characteristics 41
2.1.1 Low-Pressure and High-Pressure Gradient Proportioning Two Fundamentally Different Technical Principles 41
2.1.2 The Role of the Mixing Device in HPG and LPG Systems 42
2.1.3 The Operational Principle of Mixing Devices and the Systematic Characterization of Their Effectiveness 47
2.1.4 Effects of Volume Contraction when Mixing Water and Organic Solvents in Gradient Instruments 58
2.1.5 Effects of Minimum Leak Rates of Pump Heads in Sensitive Applications and HPG Synchronization Techniques to Correct Them 63
2.2 The Determination and Significance of the Gradient Delay Volume of the System 65
2.2.1 The Determination of the GDV and its Dependence on the Specific Operation Conditions of the System 66
2.2.2 The Influence of GDV on the Chromatographic Results 76
2.2.3 Possibilities of the User to Influence System GDV and its Impact on Chromatography 77
2.3 The Transfer of Gradient Methods Between Different HPLC Systems 80
2.3.1 Practical Tips for Dealing with Deviating GDVs and Possible Countermeasures 80
2.3.2 The Relevance of the Pressure Dependence of the GDV in Method Transfer 82
2.3.3 Effect of a too High Elution Strength of the Sample Solvent in the Presence of Weakly Eluting Solvent at the Gradient Start 85
2.4 Influence of Fluctuations of the Eluent Composition on the Quality of the Detection 87
2.4.1 Influence of a Reference Channel on the Baseline in Diode Array Detectors 88
2.4.2 The Special Challenge in Methods with UV-Absorbing Retained Additives in the Mobile Phase such as TFA 90
2.5 Other Kinds of Practical Application of Gradient Systems in HPLC 95
2.5.1 Alternative and Combined Gradient Modes in HPLC 96
2.5.2 Advantages in the Implementation of Isocratic Methods with Gradient Instruments 97
2.5.3 Use of Gradient Systems in Method Development and Method Optimization 98
3 Optimization of a Reversed-Phase Gradient Separation Using EXCEL 103
Hans-Joachim Kuss
Part 2 Specifics of the Gradient in Different Elution Modes 111
4 Gradient Elution of Ionic Compounds 113
Joachim Weiss
4.1 Introduction 113
4.2 Theoretical Aspects 114
4.3 Gradient Types in Ion Chromatography 116
4.4 Choice of Eluent 119
4.4.1 Possibilities for Optimizing Concentration Gradients 125
4.5 Gradient Elution of Anions on Anion Exchangers 126
4.6 Gradient Elution of Cations on Cation Exchangers 136
4.6.1 pH Gradients for the Separation of Monoclonal Antibodies 144
4.7 Gradient Elution of Anions and Cations on Mixed-Mode Stationary Phases 148
5 The Gradient in Biochromatography 161
Oliver Genz
5.1 Biomolecules 161
5.2 Biochromatography 161
5.3 The Gradient in Biochromatography 162
5.3.1 A Gradient you Should Definitely Avoid ... 163
5.4 Gradients fo...