Table of Contents

Preface xiii

Acronyms xv

Symbols and Conventions xvii

Introduction xxi

1 Solvents and Buffer Solutions 1

1.1 Water as a Solvent 1

1.1.1 Temperature and Brownian Motion 1

1.1.2 Electric Permittivity of Water 2

1.1.3 Dissolution 3

1.1.4 Solvation 3

1.1.5 Dissociation 5

1.1.6 Ionization 7

1.1.7 Hydrophilicity, Hydrophobicity, and LogP 8

1.1.8 Gibbs Free Energy Change 9

1.1.9 Acid Ionization Constants 10

1.1.10 Concentration-pH and pa-pH Diagrams 12

1.1.11 Henderson-Hasselbalch Equation 13

1.1.12 Buffer Capacity 15

1.2 Binary Mixtures and Other Solvents 18

References 19

2 Fundamentals of Electrophoresis 21

2.1 Introduction 21

2.2 The Platforms 21

2.3 Electrophoresis 23

2.4 Electrophoresis of Single Molecules 27

2.5 Ionic Limiting Mobility 30

2.6 Bands, Fronts, Peaks, and Zones 32

2.6.1 Bands and Peaks 32

2.6.2 Fronts 37

2.6.3 Zones 38

2.7 The Isoelectric Point 38

2.7.1 Isoelectric Point of Molecules 38

2.7.2 Isoelectric Point of Nano and Microparticles 41

2.8 Turbulent and Laminar Flow 42

2.8.1 The Driving Forces of Fluid Flow 42

2.8.2 Turbulence 43

2.8.3 Laminar Flow in Cylindrical Capillaries 43

2.8.3.1 Pressure Driven Flow 43

2.8.3.2 Gravity Driven Flow 45

2.8.3.3 Capillary Action 45

2.8.4 Laminar Flow in Microchannels 46

2.8.4.1 Pressure Driven Flow 46

2.8.4.2 Gravity Driven Flow 49

2.9 Electroosmosis 50

2.9.1 EOF in Cylindrical Capillaries 50

2.9.1.1 Volumetric Flow Rate 53

2.9.1.2 Combined Pressure Driven Flow and EOF 53

2.9.2 EOF in Rectangular Microchannels 53

2.10 Supression of EOF 54

2.10.1 Protocols for EOF Suppression 54

2.10.2 Advantages of Suppressing EOF with Covalent Coatings 56

2.10.3 Measuring Small and Large EOF Velocities 56

2.11 Joule Effect and Heat Dissipation 57

2.12 Temperature Profiles 58

2.13 Molecular Diffusion and Band Broadening 62

2.14 Sample Stacking and Band Compression 64

2.15 Separation Modes 69

2.15.1 Affinity Electrophoresis 69

2.15.2 Electrochromatography 71

2.15.3 End-labeled Free-solution Electrophoresis 72

2.15.4 Free-Solution Electrophoresis 73

2.15.5 Isoelectric Focusing 76

2.15.6 Isotachophoresis 77

2.15.7 Microemulsion Electrokinetic Chromatography 79

2.15.8 Micellar Electrokinetic Chromatography 79

2.15.9 Sieving Electrophoresis 81

2.15.10 Suitable Separation Modes for Each Class of Analytes 82

References 84

3 Open Layout 89

3.1 Introduction 89

3.2 Capillary Electrophoresis 89

3.3 Microchip Electrophoresis 92

3.4 Slab Electrophoresis 94

3.5 Performance Indicators for Open Layouts 97

3.5.1 From Single Bands or Peaks 98

3.5.1.1 Number of Theoretical Plates 98

3.5.1.2 Number of Theoretical Plates per Unit Time Squared 99

3.5.1.3 Height Equivalent of a Theoretical Plate 99

3.5.2 From Two Neighboring Bands or Peaks 100

3.5.2.1 Resolution 104

3.5.2.2 Resolution per Unit Time 106

3.5.3 From n Bands and n Peaks 107

3.5.3.1 Band Capacity 107

3.5.3.2 Band Capacity per Unit of Time 108

3.5.3.3 Peak Capacity 108

3.5.3.4 Peak Capacity per Unit Time 109

References 109

4 Toroidal Layout 115

4.1 Introduction 115

4.2 Toroidal Capillary Electrophoresis 117

4.3 Toroidal Microchip Electrophoresis 120

4.4 Toroidal Slab Electrophoresis 121

4.5 Folding Geometries 121

4.6 Microholes and Connections 125

4.7 Reservoirs 126

4.8 Active and Passive Modes of Operation 127

4.8.1 The Gravimetric Method 128

4.8.2 The Hydrodynamic Method 129

4.8.3 The Electrokinetic Method 129

4.8.4 Using Microvalves or Microcaps 130

4.9 Performance Indicators for Toroidal Layouts 130

4.9.1 From Single Bands or Peaks 131

4.9.1.1 Number of Theoretical Plates 131

4.9.1.2 Number of Plates per Unit Time Squared 131

4.9.1.3 Height Equivalent of a Theoretical Plate 132

4.9.2 From Two Neighboring Bands or Peaks 132

4.9.2.1 Resolution 132

4.9.2.2 Resolution per Unit Time 133

4.9.3 From n Bands or n Peaks 133

4.9.3.1 Band Capacity 133

4.9.3.2 Band Capacity per Unit Time 134

4.9.3.3 Peak Capacity 134

4.9.3.4 Peak Capacity per Unit Time 135

References 136

5 Confronting Performance Indicators 137

5.1 Introduction 137

5.2 Performance Indicators from Experimental Data 137

5.3 Performance Indicators Predicted from Operational Parameters 139

References 146

6 High Voltage Modules and Distributors 147

6.1 Introduction 147

6.2 High Voltages in Open Layouts 147

6.3 High Voltages in Toroidal Layouts 148

6.3.1 The Ideal Toroidal Length 148

6.3.2 High Voltage Distribution Made by Four Modules 150

6.3.3 High Voltage Distribution Based on Relays 152

6.3.4 High Voltage Distribution Based on Sliding Switches 153

6.3.5 High Voltage Distribution Based on Rotating Switches 155

References 156

7 Heat Removal and Temperature Control 157

7.1 Introduction 157

7.2 Temperature Gradients are Unavoidable 159

7.3 Temperature has Multiple Effects 160

7.4 Electrical Insulators with High Thermal Conductivity 165

7.5 Cooling Strategies Used in Capillary Electrophoresis 167

7.5.1 Advantages of a Symmetric Cooling Geometry 170

7.6 Cooling Strategies Used in Microchip Electrophoresis 177

7.6.1 Advantages of a Symmetric Cooling Geometry 177

7.7 Cooling Strategies Used in Slab Electrophoresis 177

7.7.1 Advantages of a Rational Cooling Strategy 178

7.8 Shear Rate of the Coolant 178

7.9 Final Considerations 179

References 180

8 Detectors 181

8.1 Introduction 181

8.2 Fixed Point Detectors 182

8.3 Spatial Detectors (Scanners and Cameras) 184

8.4 Derivatization Reactions 185

8.4.1 Fluorogenic Reactions 186

8.4.2 Labeling Reactions 189

8.4.3 Improving Selectivity Through Derivatization 189

References 191

9 Applications of Toroidal Electrophoresis 193

9.1 Introduction 193

References 197

Appendix A Nomenclature 199

References 203

Appendix B Species Concentration in Buffer Solutions 205

B.1 Acids (H_nA) 206

B.1.1 Monoprotic Acids (n = 1) 206

B.1.2 Diprotic Acids (n = 2) 206

B.1.3 Triprotic Acids (n = 3) 206

B.1.4 Tetraprotic Acids (n = 4) 206

B.2 Bases (B) 207

B.2.1 Monoprotonated Bases (n = 1) 207

B.2.2 Diprotonated Bases (n = 2) 207

B.2.3 Triprotonated Bases (n = 3) 207

B.2.4 Tetraprotonated Bases (n = 4) 207

References 208

Appendix C Electrophoresis 209

C.1 Free-Solution Electrophoretic Mobility 209

C.1.1 Classical Trajectories 210

C.2 Mobility Dependence on Temperature 212

C.3 Transient Regimes 213

C.3.1 Eletrophoretic Transient Regime (𝜏_e) 214

C.3.2 Hardware Transient Regime (𝜏_o) 214

References 216

Appendix D Electroosmosis 217

D.1 Slab and Microchips - Cartesian Coordinates 217

D.2 Capillaries - Cylindrical Coordinates 220

D.3 Zeta Potential 223

References 224

Appendix E Molecular Diffusion 227

E.1 The Diffusion Equation 227

E.2 The Propagator 229

E.3 Application of Propagators to Bands at Rest 230

E.4 Application of Propagators to Bands in Movement 232

E.5 Bands and Peaks 233

References 234

Appendix F Poiseuille Counter-flow 235

F.1 Introduction 235

F.2 Velocity Level Contours 236

F.3 Temperature Level Contours 237

F.4 Equalizing 𝑣_max and 𝑣_e 238

Reference 240

Appendix G Cyclic On-column Band Compression 241

G.1 Introduction 241

G.2 Effect of Cyclic Band Compression Events on Variance 242

G.3 Number of Theoretical Plates 243

G.4 Number of Theoretical Plates per Unit Time 244

G.5 Height Equivalent of a Theoretical Plate 244

G.6 Resolution 245

G.7 Resolution per Unit Time 246

G.8 Band Capacity 246

G.9 Band Capacity per Unit Time 247

G.10 Detailed Calculation of 𝜎², x, f_n, and h_n 249

G.10.1 Peak Variance 249

G.10.1.1 Compression Events Before Each Detection 249

G.10.1.2 Compression Events After Each Detection 250

G.10.2 Inter-Peak Spacing ( x) 251

G.10.2.1 Compression Events Before Each Detection 251

G.10.2.2 Compression Events After Each Detection 251

G.10.3 Calculation of the Values of h_n 251

G.10.3.1 Compression Events Before Each Detection 252

G.10.3.2 Compression Events After Each Detection 252

References 253

Index 255

About the Author

TARSO B. LEDUR KIST, PHD, is a Full Professor at the Department of Biophysics of the Federal University of Rio Grande do Sul, Brazil. His research topics include the development of theoretical models pertaining to molecular physicochemical phenomena, with emphasis on aqueous media, as well as creating prototypes of instruments for their measurement. Professor Kist's TCE platform brings much more flexibility, sensitivity, and unprecedented separation efficiencies to inorganic analytical and bioanalytical chemistry.