INTRODUCTION TO MASS SPECTROMETRY Instrumentation, Applications and Strategies for Data Interpretation

Transcription

1 INTRODUCTION TO MASS SPECTROMETRY Instrumentation, Applications and Strategies for Data Interpretation FOURTH EDITION J. THROCK WATSON 0. DAVID SPARKMAN

2 2007 John Wiley & Sons Ltd, Chichester,

3 Preface...xix Acknowledgments ' Chapter 1 Introduction...1 I. Introduction The Tools and Data of Mass Spectrometry The Concept of Mass Spectrometry... 4 II. History...9 III. Some Important Terminology Used In Mass Spectrometry Introduction Ions Peaks Resolution and Resolving Power IV. Applications Example 1-1: Interpretation of Fragmentation Patterns ( Mass Spectra) to Distinguish Positional Isomers Example 1-2: Drug Overdose: Use of GC/MS to Identify a Drug Metabolite Example 1-3: Verification that the Proper Derivative of the Compound of Interest Has Been Prepared Example 1-4: Use of a CI Mass Spectrum to Complement an El Mass Spectrum Example 1-5: Use of Exact Mass Measurements to Identify Analytes According to Elemental Composition Example 1-6: Is This Protein Phosphorylated? If So, Where? Example 1-7: Clinical Diagnostic Tests Based on Quantitation of Stable Isotopes by Mass Spectrometry in Lieu of Radioactivity...42 V. The Need for Chromatography...43 VI. Closing Remarks...44 VII. Monographs on Mass Spectrometry Published Before Chapter 2 The Mass Spectrometer Introduction II. Ion Guides...56 III. Types of m/z Analyzers Time-of-Flight m/z Analyzers...62 A. Linear ) Resolving Power of the Linear TOF Instrument ) Time-Lag Focusing ) Beam Deflection...67 B. Ref lectron C. Orthogonal Acceleration... 74

4 D. Ion Detection in the TOF Analyzer ) Time-Slice Detection ) Time-Array Detection ) TAD with Transient Recorders ) TAD with an Integrating Transient Recorder ) Hadamard Transform TOF-MS Quadrupole Ion Traps A. 3D Quadrupole Ion Trap...84 B. Linear Quadrupole Ion Trap (LIT)...97 C. Performance Trade-Offs in the Ion Trap The Orbitrap A. Historical Aspects B. Operating Principles ) Role of the C Trap in Success of the Orbitrap ) Figures of Merit for the Orbitrap as an m/z Analyzer Transmission Quadrupoles A. QMF Equations of Motion B. The Stability Diagram C. Characteristics of Output D. Spectral Skewing E. Performance Limitations Magnetic-Sector Instruments A. Single-Focusing Instruments ) Operating Principles ) Magnetic Versus Scanning ) Performance Limitations B. Double-Focusing Instruments FTICR-MS A. Hardware Configuration B. Operational Considerations C. Representative Applications Ion Mobility Spectrometry (IMS) A. Operating Principles B. FAIMS C. Applications IV. Calibration of the m/z Scale Electron Ionization Chemical Ionization Electrospray Ionization and APCI Techniques MALD I V. Ion Detectors General Considerations Types of Detectors A. Faraday Cup B. Electron Multiplier ) Discrete-Dynode Version ) Continuous-Dynode Version C. Negative-Ion Detection D. Post-Acceleration Detection and Detection of High-Mass Ions E. Channel Electron Multiplier Array (CEMA)...144

5 F. Electro-Optical Ion Detection G. The Daly Detector H. Cryogenic Detectors I. Ion Detection in FTMS VI. Vacuum Systems Introduction Definitions Pressure Gauges A. Thermal-Conductivity Gauges B. Pirani Gauge C. Thermocouple Gauges Ionization Gauges A. Hot-Cathode Gauge B. Cold-Cathode Gauge Types of Pumps A. Mechanical Pumps (Low Vacuum) ) Rotary Vane Pumps ) Scroll Pumps ) Roots Pumps ) Diaphram Pumps B. High Vacuum ) Turbomolecular Pumps ) Oil Diffusion Pumps ) Sputter-Ion Pumps (Nonregeneratable Getter Pumps) Chapter 3 Mass Spectrometry/Mass Spectrometry I. Introduction History and the Evolution of the Technique Concept and Definitions Nomenclature II. Ion Dissociation Metastable Ions Collisionally Activated Dissociation Electron Capture Dissociation Electron-Transfer Dissociation Illustrative Example of Qualitative Analysis by MS/MS IN. Instrumentation for MS/MS Tandem-in-Space Mass Spectrometry (MS/MS) A. Triple-Quadrupole Mass Spectrometer B. Q-TOF Hybrid Mass Spectrometer C. TOF-TOF Mass Spectrometer D. BEqQ Hybrid Mass Spectrometer E. Double-Focusing Instrument Tandem-in-Time Mass Spectrometry IV. Specialized Techniques and Applications In-Source CAD CAD in Conjunction with Soft Ionization A. Data-Dependent Acquisition

6 3. Selected Reaction Monitoring A. Illustrative Example Showing that SRM Has a Higher Specificity than SIM in Spite of a Lower Signal Strength B. An Example Comparing the Specificity of SRM and SIM in the Context of Analyzing a Biological Sample for a Drug Metabolite Precursor-Ion Analysis Neutral-Loss (Common Neutral-Loss) Analysis Ion/Molecule Reactions Hybrid Instrumentation for MS/MS and Ion Mobility Spectrometry (IMS) V. Analyte Identification from MS/MS Data Introduction Identifying an Unknown Using a Product-Ion Mass Spectrum Similarities between El and Product-Ion Mass Spectra Another Way of Using Substructure Identification Searching of Product-Ion Spectra against Standardized Databases VI. Concluding Remarks about MS/MS Chapter 4 Inlet Systems I. Introduction II. Batch Inlets Heated Reservoir Inlet Direct Inlet Probe (DIP) A. The Chromatoprobe Direct Exposure Probe (Desorption Chemical Ionization, DCI) Pyrolysis III. Continuous Inlets Membrane Introduction MS (MIMS) Supercritical Fluid Chromatography (SFC) Electrophoretic Inlet IV. Ionization Inlet Systems Direct Analysis in Real Time (DART) Desorption Electrospray Ionization (DESI) Desorption Atmospheric Pressure Chemical Ionization (DAPCI) V. Speciality Interfaces Selected Ion Flow Tube Mass Spectrometry (SIFTMS) Fast Atom Bombardment (FAB) and Liquid Secondary Ion Mass Spectrometry (LSIMS) Chemical Reaction Interface Mass Spectrometry (CRIMS) Inductively Coupled Plasma Mass Spectrometry (ICPMS) A. Hardware Configuration B. Operational Considerations C. Electrothermal Vaporization D. Laser Ablation E. Speciation F. Summary VI. Final Statement...257

7 Chapter 5 Strategies for Data Interpretation (Other than Fragmentation) I. Introduction II. Some Important Definitions III. Possible Information That Can Be Obtained from the Mass Spectrum IV. Elemental Composition of an Ion and the Ratios of Its Isotope Peaks Definition of Terms Related to the Matter of Mass Spectrometry Nitrogen Rule Elemental Composition of an Ion Based on the Ratio of Isotope Peak Intensities A. Isotope Peak Patterns Used to Determine the Elemental Composition of Ions B. Isotope Peak Patterns for Ions Containing Various Combinations of Br/CI C. Constraint on the Number of Atoms Allowed for a Given Element D. Relationship of the Charge State of an ion and the Spacing of the Corresponding Isotope Peaks ) Ions of High Mass-to-Charge Ratio E. Steps to Assigning an Elemental Composition Based on Isotope Peak Intensities F. Validating the Putative Elemental Composition of an Ion G. An Illustrative Example of the Use of Isotope Peak Ratios to Determine an Elemental Composition H. Potential Problems Arising from Adjacent Peaks Elemental Composition as a Function of an Accurate Determination of the m/z Value of a Mass Spectral Peak A. Appearance of Mass Spectra of High-m/z Value Ions Using El Data to Identify Unknowns Detected During Analysis by LC/MS Does the Result Make Sense? V. Identifying the Mass of an Analyte Recognition of the Peak Representing the Molecular Ion in El A. Reasonable Losses from the Molecular Ion in El Recognition of the Protonated Molecule (MH`) in Soft Ionization A. Probable Adducts Observed in the Mass Spectrum Produced by Soft Ionization Recognition of the Deprotonated Molecule ([M - HI ) Peak in Soft Ionization VI. Recognition of Spurious Peaks in the Mass Spectrum Noise Spikes Peaks Corresponding to Contaminants in GC/MS and LC/MS A. The Phthalate Peak B. GC Column Bleed C. Cluster Ions VII. Obtaining Structural Information from the Mass Spectrum...308

8 Chapter 6 Electron Ionization I. Introduction II. Ionization Process III. Strategy for Data Interpretation Assumptions The Ionization Process IV. Types of Fragmentation Pathways Sigma-Bond Cleavage Homolytic or Radical-Site-Driven Cleavage Heterolytic or Charge-Site-Driven Cleavage Rearrangements A. Hydrogen-Shift Rearrangements B. Hydride-Shift Rearrangements V. Representative Fragmentations (Spectra) of Classes of Compounds Hydrocarbons A. Saturated Hydrocarbons ) Straight-Chain Hydrocarbons ) Branched Hydrocarbons ) Cyclic Hydrocarbons B. Unsaturated C. Aromatic Alkyl Halides Oxygen-Containing Compounds A. Aliphatic Alcohols B. Aliphatic Ethers C. Aromatic Alcohols D. Cyclic Ethers E. Ketones and Aldehydes F. Aliphatic Acids and Esters G. Aromatic Acids and Esters Nitrogen-Containing Compounds A. Aliphatic Amines B. Aromatic Compounds Containing Atoms of Nitrogen C. Heterocyclic Nitrogen-Containing Compounds D. Nitro Compounds E. Concluding Remarks on the Mass Spectra of Nitrogen-Containing Compounds Multiple Heteroatoms or Heteroatoms and a Double Bond Trimethylsilyl Derivative Determining the Location of Double Bonds VI. Library Searches and El Mass Spectral Databases Databases Library Search Programs What To Do When the Spectrum of the Unknown is Not in the Database(s) Searching Multiple Databases Database Size and Quality Concluding Remarks on the NIST Mass Spectral Search Program Mass Spectral Database Update VII. Summary of Interpretation of El Mass Spectra

9 Chapter 7 Chemical Ionization I. Introduction II. Description of the Chemical Ionization Source III. Production of Reagent Ions from Various Reagent Gases IV. Positive-Ion Formation Under CI Fundamentals Practical Consideration of Proton Affinity in CI Selective Ionization Fragmentation V. Negative-Ion Formation under CI True Negative Chemical Ionization Resonant Electron Capture Negative Ionization VI. Data Interpretation and Systematic Studies of CI VII. Ionization by Charge Exchange Mechanism of Ionization Fragmentation and Appearance of Mass Spectra VIII. Atmospheric Pressure Chemical Ionization IX. Desorption Chemical Ionization X. General Applications XI. Concluding Remarks Chapter 8 Electrospray Ionization I. Introduction II. Operating Principles III. Appearance of ESI Mass Spectra and Data Interpretation IV. ESI with an m/z Analyzer of High Resolving Power V. Conventional ESI Source Interface VI. Nanoelectrospray and Microelectrospray Ionization VII. Desorption Electrospray Ionization (DESI) VIII. Effect of Composition and Flow Rate of an Analyte Solution IX. Special Applications Direct Analysis of Ions in Solution by ESI Cold-Spray Ionization Negative-Ion Detection Secondary Electrospray Ionization (SESI) Kinetic Measurements of Chemical Reactions ESI Generation of Ions for Ancillary Experiments X. General Applications of ESI Chapter 9 MALDI I. Historical Perspective and Introduction II. Operating Principles The Matrix The Laser, m/z Analyzer, and Representative Mass Spectra The Ionization Process High-Pressure (HP) MALDI and Atmospheric Pressure (AP) MALDI 533

10 III. IV. Sample Handling Sample Preparation of the Conventional Plate The Problem of Analyte Solubility The Problem of Sample Purity On-Probe Sample Purification and/or Modification 538 A. Polymer-Modified Surfaces B. Affinity Surfaces Direct Analysis from Gels Hydrogen/Deuterium Exchange 542 Special Instrumental Techniques Post-Source Decay (PSD) Ion Excitation Delayed Extraction (DE) Desorption Ionization On Silicon (DIOS) Tissue Profiling or Imaging 547 V. Representative Applications Proteins and Peptides Microbes Biomarkers Synthetic Polymers Small Molecules Quantitation Combined with Liquid Chromatography 553 Chapter 10 Gas Chromatography/Mass Spectrometry I. Introduction II. Introduction to GC Basic Types of Injectors Injection Considerations and Syringe Handling Syringeless Modes of Sample Injection for Fast GC 585 HI. Sample Handling Proper Sample Container Analyte Isolation and Purification Derivative Formation 587 A. S ilyl Derivatives B. Esters of Carboxylic Acids C. Oxime Derivatives D. Acyl Derivatives E. Derivatives for Characterizing Double Bonds IV. Instrument Requirements for GC/MS Operating Pressures Typical Parameters for a Conventional GC-MS Interface Supersonic Molecular Beam Interface for GC/MS Open-Split Interface Molecular Separators 597 A. Jet-Orifice Separator B. Membrane Separator Inertness of Materials in the Interface 599

11 V. Operational Considerations Spectral Skewing Background/Bleed The Need for Rapid Acquisition of Mass Spectra A. Performance Trade-Offs of Conventional Instruments for GC/MS B. Time-Array Detection Selected Ion Monitoring (SIM) A. Definition and Nomenclature B. Development of the Technique C. Qualitative Example of SIM D. Quantitative Example of SIM E. Mechanics of Ion Monitoring ) Adjustment of the Mass Scale ) Mass Range ) Magnetic Mass Spectrometer ) Transmission Quadrupole Mass Spectrometer ) Number of Ion Currents (Masses) F. Programmable SIM G. SIM at High Resolving Power VI. Sources of Error Errors Relating to Equipment or Procedure Errors Relating to Contamination Sources of Interference Dealing with Background in a Mass Spectrum A. AMDIS (Automated Mass spectral Deconvolution and Identification System) B. Other Software Techniques VII. Representative Applications of GC/MS VIII. Special Techniques Purge and Trap Thermal Desorption Chapter 11 Liquid Chromatography/Mass Spectrometry Introduction II. Historical Milestones in the Development of the Interface Introduction The Direct Inlet The Moving-Belt Interface The Thermospray Interface Continuous-Flow FAB III. Currently Viable Versions of the Interface Atmospheric Pressure Ionization A. Electrospray Ionization Interface ) Optimization for Analyses by HPLC ) Capillary Electrophoresis Interface B. APCI Interface

12 C. APPI Interface 654 1) Operating Principles of APPI 654 2) Operating Mechanics for APPI 656 3) Signal Suppression 657 4) Applications of APPI Particle Beam Interface Electron Ionization and LC/MS IV. Special Operation of LC under MS Conditions Effects of Mobile-Phase Composition A. Signal Suppression 662 B. Use of Internal Standards in the Face of Signal Suppression 663 C. Adjusting the Chromatography in the Face of Signal Suppression during LC/MS 663 D. Ion Pairing and Signal Suppression 663 E. Influence of the Type and the Nature of LC Buffer 665 F. Influence of Solvent Composition on the ESI Signal 665 G. Adduct Formation 667 H. Spectral Interference 668 I. System Compromise Differences in Method Development for ESI vs APCI V. Applications Attention to High Throughput Chapter 12 Analysis of Proteins and Other Biopolymers I. Introduction II. Proteins Sequencing A. Nomenclature and Fragmentation in Sequencing of Peptides 693 1) Nomenclature 693 2) Fragmentation 695 B. Strategy for Deducing Amino Acid Sequence via CAD of Peptides 701 1) An Illustrative Example 702 2) Possible Pitfalls in Interpretation 705 3) Search for Confirming Ions 706 4) Ladder Sequencing Mass Mapping A. Peptide Mass Fingerprinting 709 B. De novo Sequencing 710 C. Sequence Tagging 710 D. Sequest 710 E. Evaluation of Hits in Automated Searches 711 F. Data-Dependent Analysis by Mass Spectrometry Post-Translational Modifications A. Recognition of Sites of Protein Phosphorylation 714 1) An Illustrative Example 715 2) Selective Capture and Detection of Phosphopeptides 718 3) Chemical Modification of Phosphorylation Sites 719

13 III. IV. B. Recognition of Sites of Sulfation C. Recognition of Sites of Glycosylation D. Acetylation of Lysine E. Cysteine Status in Proteins ) Are There Any Disulfide Bonds? ) Which Cysteines Are Free? ) What Is the Linkage of Cysteines in the Disulfide Bonds? (A) Conventional Proteolytic Mass Mapping of Disulfides (B) Cyanylation-Based Mass Mapping of Disulfides F. Recognition of Ubiquinated Proteins G. Other Types of Modifications Quantitation in Proteomics A. ICATs ) Operating Principles ) Illustrative Example of the ICAT Approach ) Analogous to ICAT Methodologies B. Alternative Stable Isotope-Based Methodologies C. Related Methodologies "Top-Down" Strategies of Analysis A. Instrumentation and Fragmentation Requirements B. Electron Capture Dissociation (ECD) C. Electron-Transfer Dissociation (ETD) D. Applications Noncovalent Interactions Folding and Unfolding Applications Oligonucleotides Analytical Considerations Sequencing A. Nomenclature B. Algorithm for Data Interpretation Applications Carbohydrates Analytical Considerations Nomenclature Diagnostic Fragmentation Applications Subject Index...803