Selectivity and Detectability Optimizations in HPLC



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Selectivity and Detectability Optimizations in HPLC SATINDER AHUJA Development Department Pharmaceuticals Division CIBA-GEIGY Corporation Suflern, New York WILEY A WILEY-INTERSCIENCE PUBLICATION JOHN WILEY & SONS New York / Chichester / Brisbane / Toronto / Singapore

CONTENTS CHAPTER 1 THE SCOPE OF SELECTIVITY AND DETECTABILITY OPTIMIZATION IN HPLC 1 1.1. Selectivity and Detectability 1 1.2. Modesof HPLC 2 1.3. Theoretical Considerations 3 1.4. Various Routes to High Resolution 4 1.4.1. Optimum Column Selection (Conventional versus Small-Particle versus Microbore Columns) 5 1.4.2. Optimum Analysis Time 6 1.5. High-Resolution Evaluations 7 1.6. HPLC Optimization 8 1.7. Multifactor Optimization 9 References 13 CHAPTER 2 PHYSICOCHEMICAL BASIS OF RETENTION 15 By L. R. Snyder 2.1. General Aspects of Retention 15 2.1.1. Partition Chromatography 16 2.1.2. Retention Involving the Displacement of Mobile-Phase Molecules 18 2.1.3. Adsorption of Mobile Phase by the Stationary Phase 18 2.1.4. Intermolecular Interactions between Solute and Solvent Molecules 19 2.2. Ion-Exchange Chromatography 21 2.3. Adsorption (Normal-Phase) Chromatography 24 2.3.1. Mobile-Phase Strength 24 vu

VW CONTENTS 2.3.2. Solute Retention and Localization 2.4. Reversed-Phase Chromatography 2.4.1. Mobile-Phase Strength 2.4.2. Silanol Effects 2.4.3. Solute Retention 2.5. Ion-Pair Chromatography 2.5.1. Retention as a Function of Mobile- Phase Composition 2.6. Size-Exclusion Chromatography 2.7. Macromolecular Samples 2.8. Other Chromatographie Procedures 2.8.1. Ion Chromatography 2.8.2. Hydrophobic-Interaction Chromatography (HIC) 2.8.3. Ligand-Exchange Chromatography References 25 26 28 28 29 29 30 31 33 34 35 35 35 35 CHAPTER 3 PROBING SEPARATION MECHANISM IN HPLC 39 3.1. Separations in RPLC versus Octanol Partition Data 41 3.2. Impact of Other Physicochemical Parameters on Retention 46 3.3. Retention in HPLC versus Solubility 51 3.4. Stationary-Phase Effects 52 3.4.1. Adsorption/Normal Phase 52 3.4.2. Reversed Phase 54 3.5. Stationary-Phase Dynamics 56 3.6. Retention Mechanism Investigations 58 3.7. Molecular Probes/Retention Index 65 References 68 CHAPTER 4 CONVENTIONAL APPROACHES TO MOBILE-PHASE SELECTION AND OPTIMIZATION 4.1. General Considerations 4.1.1. Properties of Sample or Solute 73 73 74

CONTENTS IX 4.1.2. Column Selection 75 4.1.3. Column Evaluations 77 4.1.4. Mobile-Phase Selection in HPLC 78 4.1.5. Solvent Classification 79 4.1.6. Mobile-Phase Additives 81 4.2. Modes of Chromatography 82 4.2.1. Adsorption Chromatography 82 4.2.2. Normal-Bonded Phases 85 4.2.3. Reversed-Phase Chromatography 87 4.2.4. Ion-Exchange Chromatography 92 References 100 IMPROVING SEPARATIONS IN ADSORPTION FOR NORMAL-PHASE SEPARATIONS 103 5.1. Adsorption Chromatography 104 5.1.1. Column Packings 104 5.1.2. Mechanism of Adsorption Chromatography 107 5.1.3. Solvent Selection in LSC 111 5.1.4. Solvent Strength in LSC 112 5.1.5. Role of Modulators 115 5.1.6. Modulators and Selectivity 117 5.1.7. Mobile-Phase Optimization Strategies 119 5.1.8. Effect of Sample Structure on Retention 120 5.1.9. Applications of Adsorption Chromatography 123 5.2. Normal-Phase Chromatography 130 5.2.1. Theory 133 5.2.2. Column Packings 134 5.2.3. Mobile-Phase Effects 136 5.2.4. Applications of Normal-Phase Chromatography 140 5.3. Miscellaneous Approaches 155 References 156

X CONTENTS CHAPTER 6 SELECTIVITY OPTIMIZATION IN REVERSED-PHASE SEPARATIONS 6.1. Stationary Phase 6.1.1. Pore Size and Volume 6.1.2. Nature of Bonded Phases 6.1.3. Column Efficiency 6.1.4. Columns 6.1.5. Problems with HPLC Columns 6.1.6. Column Evaluations 6.2. Retention Mechanism 6.3. Eluotropic Solvent Scale 6.4. Mobile-Phase Selection and Optimization 6.4.1. Effect on Selectivity 6.4.2. Enthalpy of Binding 6.5. Applications References 161 162 167 168 170 171 173 174 186 190 196 200 202 204 223 CHAPTER 7 ION-EXCHANGE CHROMATOGRAPHY OF IONIC AND IONIZABLE COMPOUNDS 7.1. Ion-Exchange Chromatography 7.1.1. Column Packings 7.1.2. Mobile-Phase Selection 7.1.3. Retention Mechanism 7.1.4. Applications of IEC 7.2. Ion Chromatography 7.2.1. Applications of IC References 229 230 231 237 242 248 256 259 261 CHAPTER 8 OPTIMIZING SELECTIVITY OF ION-PAIR SEPARATIONS 265 8.1. Nature of Ion Pairs 265 8.2. Theory 267 8.3. Column Packings 271 8.4. Mobile-Phase Selection and Optimization 272 8.4.1. Role of the Counterion 272 8.4.2. Solvent Effects 275

CONTENTS XI 8.4.3. Ionic Strength and Secondary Ion Effects 278 8.4.4. Association/Dissociation Effects 280 8.4.5. ph Effects 281 8.4.6. Other Separation Variables 283 8.5. Retention Mechanism 284 8.6. Applications 293 References 310 CHAPTER 9 MACROMOLECULAR SEPARATIONS 315 9.1. Types of Macromolecules 317 9.1.1. Proteins 317 9.2. Purity Assessment 318 9.2.1. Recombinant-DNA-Derived Proteins 318 9.2.2. Polypeptides 319 9.2.3. Monoclonal Antibodies 320 9.2.4. Nucleic Acids 320 9.3. Chromatographie Methods 322 9.4. Retention Mechanism 329 9.4.1. Adsorption 329 9.4.2. Reversed Phase 330 9.4.3. Ion Exchange 338 9.4.4. Size-Exclusion Chromatography 339 9.5. Mechanistic Studies 341 9.5.1. Proteins 341 9.5.2. Nucleotides 354 9.5.3. Enzymes 356 9.5.4. Miscellaneous Compounds 358 9.6. Applications 361 References 387 CHAPTER 10 ISOMERIC SEPARATIONS 395 10.1. Chiral Columns 400 10.2. Chiral Additives to HPLC Eluents 403 10.3. Modes of Separation 407 10.3.1. Chromatography of Diastereomeric Derivatives 408

Xll CONTENTS 10.3.2. Enantiomeric Resolution Using Chiral Mobile-Phase Additives 409 10.3.3. Enantiomeric Resolution Using Chiral Stationary Phases 412 10.4. Applications 419 10.4.1. Reversed- Phase/ Normal- Phase Adsorption Columns 420 10.4.2. Ligand Chromatography 425 10.4.3. Pirkle-Type Columns 430 10.4.4. Cyclodextrin Columns 442 10.4.5. Protein Columns 444 10.4.6. Miscellaneous Applications 451 References 455 CHAPTER11 COMPUTER OPTIMIZATION OF SELECTIVITY 461 11.1. Experimental Design 461 11.2. Optimization Methods 465 11.2.1. Window Diagram Methods 466 11.2.2. Simplex Methods 474 11.2.3. Gradient Elution 483 11.2.4. Interactive Methods 485 11.3. Practical Approaches 488 11.3.1. Computer Simulation and Solvent- Strength Optimization 488 11.3.2. Instrumentation 497 11.4. Optimum Method for Optimization 501 References 502 CHAPTER 12 SELECTIVE DETECTORS IN HPLC 505 12.1. UV Detectors 507 12.1.1. Applications 511 12.2. Fluorescence Detectors 513 12.2.1. Applications 518 12.3. Miscellaneous Luminescent Detectors 519 12.4. Electrochemical Detectors 522 12.4.1. Applications 525

CONTENTS Xlll 12.5. Refractive Index Detectors 534 12.6. Mass Spectrometric Detectors 537 12.6.1. Applications 542 12.7. Miscellaneous Detectors 544 References 548 CHAPTER 13 DETECTABILITY OPTIMIZATION 555 13.1. Noise and Detection Limits 556 13.2. Column Evaluations for Detectability Optimization 558 13.3. Limit of Detection 565 13.4. Detector Evaluation and Optimizations 568 13.4.1. Ultraviolet Detectors 568 13.4.2. Fluorescence Detectors 573 13.4.3. Novel Detectors and Detection Methods 578 13.5. Derivatization 588 13.6. Miscellaneous Approaches 595 References 598 INDEX 605

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