Instrumental Thin-Layer Chromatography - Colin Poole

Instrumental Thin-Layer Chromatography (eBook)

Colin Poole (Autor)

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2014 | 1. Auflage
652 Seiten
Elsevier Science (Verlag)
978-0-12-417284-5 (ISBN)

Instrumental Thin-Layer Chromatography delivers comprehensive coverage of this separation tool with particular emphasis on how this tool can be used in advanced laboratories and integrated into problem-solving scenarios. Significant improvements in instrumentation have outpaced the development of information resources that describe the latest state-of-the-art and demonstrate the full capabilities of TLC. This book provides a contemporary picture of the fundamentals and practical applications of TLC at a level suitable for the needs of professional scientists with interests in project management where TLC is a common tool. Compact, highly focused chapters convey essential information that defines modern TLC and how it can be effectively implemented in most areas of laboratory science. Numerous figures and tables provide access to material not normally found in a single source yet are required by working scientists. - Contributions written by recognized authoritative and visionary experts - Focuses on state-of-the-art instrumental thin-layer chromatography and advanced applications across many areas - Provides guidance on the analysis of complex, dirty mixtures of compounds - Offers a cost-effective analytic technique for laboratories working under strict budgets

Professor Colin Poole is internationally known in the field of thin-layer chromatography and is an editor of the Journal of Chromatography and former editor of the Journal of Planar Chromatography - Modern TLC. He has authored several books on chromatography, recent examples being The Essence of Chromatography published by Elsevier (2003), and Gas Chromatography published by Elsevier (2012). He is the author of approximately 400 research articles, many of which deal with thin-layer chromatography, and is co-chair of the biennial 'International Symposium on High-Performance Thin-Layer Chromatography”.

Front Cover 1
INSTRUMENTAL THIN-LAYER CHROMATOGRAPHY 4
Copyright 5
Contents 6
Contributors 8
Chapter 1 - Milestones, Core Concepts, and Contrasts 12
1.1 INTRODUCTION 12
1.2 MILESTONES 13
1.3 ATTRIBUTES OF A PLANAR FORMAT 15
1.4 CONSEQUENCES OF CAPILLARY-CONTROLLED FLOW 18
1.5 SOLVENT-STRENGTH GRADIENTS 30
1.6 MULTIDIMENSIONAL SEPARATIONS 33
1.7 CONCLUSIONS 36
References 37
Chapter 2 - High-Performance Precoated Stationary Phases 42
2.1 INTRODUCTION 42
2.2 INORGANIC OXIDE SORBENTS 43
2.3 CHEMICALLY BONDED SORBENTS 50
2.4 CELLULOSE 56
2.5 CHIRAL SORBENTS 57
2.6 CONCLUSIONS 59
References 60
Chapter 3 - Ultrathin and Nanostructured Stationary Phases 64
3.1 INTRODUCTION 64
3.2 MONOLITHIC SILICA GELS 67
3.3 MONOLITHIC POLYMERS 69
3.4 ELECTROSPUN NANOFIBERS 70
3.5 NANOSTRUCTURED THIN FILMS 72
3.6 CARBON NANOTUBE-TEMPLATED LAYERS 75
3.7 ADVANCED INSTRUMENTATION AND TECHNIQUES 77
3.8 CONCLUSIONS 79
References 80
Chapter 4 - Automated Multiple Development 84
4.1 INTRODUCTION 84
4.2 APPLICATIONS 94
4.3 FUTURE TRENDS 105
4.4 CONCLUSIONS 108
References 109
Chapter 5 - Forced-Flow Development in Overpressured Layer Chromatography 118
5.1 INTRODUCTION 118
5.2 ANALYTICAL AND PREPARATIVE OPLC PROCESSES 119
5.3 INSTRUMENTS AND LAYERS FOR OPLC 123
5.4 MAIN CHARACTERISTICS OF OPLC 127
5.5 ANALYTICAL AND PREPARATIVE APPLICATIONS 133
5.6 CONCLUSION 140
References 140
Chapter 6 - Pressurized Planar Electrochromatography 146
6.1 INTRODUCTION 146
6.2 THEORETICAL BACKGROUND 147
6.3 DEVELOPMENT OF EQUIPMENT FOR PPEC 151
6.4 ADVANTAGES OF PPEC 159
6.5 APPLICATIONS 168
6.6 CHALLENGES AND CONCLUSIONS 174
References 174
Chapter 7 - Theory and Instrumentation for In situ Detection 178
7.1 INTRODUCTION 178
7.2 THEORY FOR IN SITU DENSITOMETRIC DETECTION 179
7.3 INSTRUMENTATION FOR IN SITU DENSITOMETRIC DETECTION 187
7.4 IN SITU MASS-SPECTROMETRY 197
7.5 IN SITU RADIOISOTOPE DETECTION 198
References 199
Chapter 8 - Staining and Derivatization Techniques for Visualization in Planar Chromatography 202
8.1 PROBLEM OVERVIEW 202
8.2 REAGENT APPLICATION, EQUIPMENT, AND PROTOCOLS 204
8.3 TECHNIQUES FOR HEATING OR DRYING LAYERS AFTER DEVELOPMENT 212
8.4 COMMON DETECTION PROTOCOLS FOR TARGET COMPOUNDS 215
8.5 CONCLUSIONS 246
References 246
Chapter 9 - Advanced Spectroscopic Detectors for Identification and Quantification: UV–Visible, Fluorescence, and Infrared ... 250
9.1 INTRODUCTION 250
9.2 ADVANCED SPECTROSCOPIC DETECTORS FOR IDENTIFICATION AND QUANTIFICATION 251
9.3 CONCLUSION 258
References 258
Chapter 10 - Advanced Spectroscopic Detectors for Identification and Quantification: Mass Spectrometry 260
10.1 INTRODUCTION 260
10.2 CLASSIFICATION OF TLC-MS TECHNIQUES 261
10.3 INDIRECT SAMPLING TLC-MS 261
10.4 DIRECT SAMPLING TLC-MS 265
10.5 HIGH-THROUGHPUT TLC-MS DEVICES AND QUANTIFICATION ANALYSIS 279
10.6 CONCLUSION 281
References 282
Chapter 11 - Effects-Directed Biological Detection: Bioautography 290
11.1 INTRODUCTION 290
11.2 APPLICATIONS OF BIOAUTOGRAPHIC TESTS 295
11.3 PERSPECTIVES 314
References 314
Chapter 12 - Solvent Selection and Method Development 324
12.1 INTRODUCTION 324
12.2 PROBLEM DEFINITION 325
12.3 MODE SELECTION 330
12.4 MOBILE PHASE SELECTION 334
12.5 CONCLUSIONS 359
References 359
Chapter 13 - Validation of Thin Layer Chromatographic Methods 362
13.1 INTRODUCTION 362
13.2 METHOD VALIDATION USING THE CLASSIC APPROACH 363
13.3 ALTERNATIVE METHOD VALIDATION APPROACH USING ACCURACY PROFILES 372
13.4 CONCLUSION 382
References 382
Chapter 14 - Separation of (Phospho)Lipids by Thin-Layer Chromatography 386
14.1 INTRODUCTION 386
14.2 SEPARATION OF LIPIDS BY TLC 389
14.3 APPLICATIONS 393
14.4 MALDI FOR MS DETECTION 406
14.5 SUMMARY AND OUTLOOK 410
Acknowledgments 410
References 411
Chapter 15 - Applications in Food Analysis 418
15.1 INTRODUCTION 418
15.2 HPTLC IN FOOD ANALYSIS 420
15.3 SAMPLE PREPARATION, HYPHENATION, AND NEW POSSIBILITIES 424
15.4 SUITABILITY AND CAPABILITIES 432
15.5 CONCLUSION 435
References 435
Chapter 16 - Environmental Applications 442
16.1 INTRODUCTION 442
16.2 HPTLC IN ENVIRONMENTAL ANALYSIS 443
16.3 CONCLUSION 455
References 456
Chapter 17 - Pharmaceutical Applications of High Performance Thin Layer Chromatography 462
17.1 INTRODUCTION 462
17.2 QUANTITATIVE ANALYSIS 464
17.3 PHARMACEUTICAL APPLICATIONS 464
17.4 CONCLUSIONS 488
References 488
Chapter 18 - Utility of Thin-Layer Chromatography in the Assessment of the Quality of Botanicals 490
18.1 INTRODUCTION 490
18.2 METHOD VALIDATION 494
18.3 HYPHENATED TECHNIQUES AND CHEMOMETRICS IN HERBAL ANALYSIS 497
18.4 APPLICATIONS OF TLC IN THE FIELD OF HERBAL PRODUCTS/BOTANICALS 499
18.5 USE OF HPTLC BY THE AMERICAN HERBAL PHARMACOPOEIA 511
18.6 RECENT ADVANCES IN HPTLC-BASED QUALITY CONTROL OF BOTANICALS AND DIETARY SUPPLEMENTS 511
18.7 CONCLUSIONS 512
References 512
Chapter 19 - Analysis of Plant Material 516
19.1 INTRODUCTION 516
19.2 SINGLE DEVELOPMENT 517
19.3 SPECIAL DEVELOPMENT TECHNIQUES 525
19.4 COUPLING PLANAR CHROMATOGRAPHY WITH COLUMN CHROMATOGRAPHY 535
19.5 FORCED-FLOW DEVELOPMENT 535
19.6 CHEMICAL FINGERPRINTING OF PLANT MATERIALS 537
19.7 EFFECT-DIRECTED ANALYSIS OF PLANT MATERIALS 541
19.8 IMAGE PROCESSING 549
References 551
Chapter 20 - Analysis of Dyes and Inks 566
20.1 INTRODUCTION 566
20.2 DYES 568
20.3 INKS 570
20.4 CONCLUSION 594
References 594
Chapter 21 - Analysis of Dietary Supplements 600
21.1 INTRODUCTION 600
21.2 ANALYTICAL CHALLENGES 603
21.3 INSTRUMENTAL TLC 607
21.4 ANALYSIS OF BIOACTIVE INGREDIENTS 617
21.5 FINGERPRINTING AND DETECTION OF ADULTERANTS 638
21.6 CONCLUSIONS 641
References 642
Index 648

Chapter 1

Milestones, Core Concepts, and Contrasts

Colin F. Poole Department of Chemistry, Wayne State University, Detroit, MI, USA

Abstract

Thin-layer chromatography and column chromatography are complementary separation techniques based on liquid chromatography. Although their application domains overlap, there is generally good reason to select one method over the other for particular applications. Capillary-controlled flow and the development mode are widely used in thin-layer chromatography. This restricts its kinetic performance compared to forced-flow techniques. Multiple development and multidimensional strategies increase the separation potential when using capillary-controlled flow. Incremental multiple development facilitates the use of solvent-strength gradients for the separation of mixtures with a wide range of retention properties. In this chapter, the general parameters used to describe separations in thin-layer chromatography are described and compared with the equivalent terms employed in column chromatography with a view to establishing the similarities and differences for the two techniques. This approach also affords general framework for method selection and to establish expectations.

Keywords

Capillary-controlled flow; Column chromatography; Forced flow; High-pressure liquid chromatography; History; Multiple development; Plate height; Plate number; Resolution; Retardation factor; Solvent-strength gradients; Spot capacity; Thin-layer chromatography; Two-dimensional chromatography

1.1. Introduction

Column chromatography and thin-layer chromatography are alternative formats for liquid chromatography [1]. Both formats exist as simple laboratory tools requiring little instrumentation and also as fully instrumental techniques. In both the cases, the stationary phase consists of a sorbent bed containing homogeneously packed particles or as a porous monolith. When movement of the mobile phase through the sorbent bed is controlled by capillary forces, the separation performance is suboptimal but requires little instrumentation affording a convenient and flexible arrangement for simple separations at the analytical or preparative scale. For faster separations, or separations with a higher peak capacity, a mechanism is required to enhance the mobile phase velocity. This requires instrumentation to pressurize the mobile phase and is the basis of high-pressure (or high-performance) liquid chromatography (HPLC) for columns and forced flow (or overpressured layer chromatography) for layers [2–4]. Although forced-flow instrumentation for thin-layer chromatography is commercially available, it is not in common use. Thus, whereas the practice of HPLC is a forced-flow technique, the practice of thin-layer chromatography is predominantly a capillary-controlled flow technique. In the latter case, instrumentation is required to optimize the various steps in the separation process and is referred to as high-performance thin-layer chromatography (HPTLC), or instrumental thin-layer chromatography, to distinguish the technique from conventional thin-layer chromatography (TLC) performed with much simpler equipment [5,6]. The general advantages of utilizing HPLC conditions versus conventional column chromatography are well known. The same argument cannot be made for conventional TLC versus HPTLC, and the general migration of separations from conventional TLC practices to HPTLC has not been universal. In fact, one might say that conventional TLC thrives in the laboratory environment as a quick, inexpensive, flexible, and portable method for surveying the composition of simple mixtures while only a few laboratories are equipped to perform more complex and quantitative analyses by HPTLC.

1.2. Milestones

The origins of thin-layer chromatography can be traced to the experiments on drop chromatography performed by Izmailov and Shraiber in the late 1930s [7]. From this beginning, thin-layer chromatography evolved into a fast and more powerful tool than gravity flow column chromatography for analytical separations. Thin-layer chromatography, as we know it today, was established in the 1950s due in large part to the efforts of Stahl and Kirchner on different continents. Their main contribution was the development of standardized materials and procedures that led to improved performance and reproducibility, as well as popularizing the technique by contributing many new applications [8]. At about the same time, commercialization of materials and devices commenced making the technique accessible to all laboratories. This ushered in the golden era of thin-layer chromatography where it quickly displaced paper chromatography as the main analytical liquid chromatographic method. By the 1970s, high-pressure liquid chromatography was becoming firmly established as an alternative approach for liquid chromatography and eventually grew to eclipse thin-layer chromatography for analytical applications. Thin-layer chromatography did not disappear in subsequent years but became less well known to those working in analytical laboratories where its strengths were often under appreciated. Developments continued in thin-layer chromatography as indicated by the time line Figure 1.1 [6,9].

First the development of high-performance thin-layer chromatography in the late 1970s is discussed. Layers coated with smaller particles of a narrow size distribution required the development of instruments for their convenient use. This was achieved by the early 1980s and so began the second era of thin-layer chromatography, known as modern or instrumental thin-layer chromatography. The evolutionary changes during this second era are captured in a series of books, which if ordered chronologically, represent the state-of-the-art at different times during this period to the present [5,10–15]. The main characteristic features of modern thin-layer chromatography are the use of fine particle layers for fast and efficient separations; sorbents with a wide range of sorption properties to optimize selectivity; the use of instrumentation for convenient and usually automated sample application, development and detection; and the accurate and precise in situ recording and quantification of chromatograms. Improvements in virtually all aspects of thin-layer chromatography continued over the next quarter century as indicated in Figure 1.1 and form the basis of subsequent chapters in this book. This period also marks the beginning of the philosophical division between conventional and high-performance thin-layer chromatography that has not been crossed by all those who use thin-layer chromatography. Expectations in terms of performance, ease of use, and quantitative information from the two approaches to thin-layer chromatography are truly opposite (see Section 1.1). As an example of expectations for a separation by modern thin-layer chromatography, see the chromatogram in Figure 1.2 for structurally similar ethyl estrogens (steroids used for birth control) [2]. Because of the small structural differences for these compounds, a high selectivity is required for their separation. Baseline separation is obtained with a short migration distance typical of fine particle layers and scanning densitometry provides a conventional record of the separation in the form of a chromatogram, as well as quantification of individual steroids after calibration. The quantitative results for tablet analysis are as accurate and precise as other chromatographic methods and the method is suitable for high-throughput routine tablet conformity analysis in which sample preparation requires no more than dissolution and filtration. Some specific reasons for choosing thin-layer chromatography for quantitative analysis are outlined in the next section.

FIGURE 1.1 Time line depicting important developments in the evolution of modern thin-layer chromatography. FFD = forced-flow development in an overpressured development chamber; AMD = automated multiple development chamber; AMC = automatic development chamber; and PPEC = pressurized planar electrochromatography.

FIGURE 1.2 Separation of ethynyl steroids by modern thin-layer chromatography. Two 15 min developments with the mobile phase hexane–chloroform–carbon tetrachloride–ethanol (7:18:22:1) on a silica gel HPTLC plate. The chromatogram was recorded by scanning densitometry at 220 nm. Reproduced with permission from Ref. [2].

1.3. Attributes of a Planar Format

Columns afford a better arrangement for operation at high pressures and for variation of the separation conditions by the control of external parameters. The thin-layer format provides a better arrangement for high sample throughput, flexible detection strategies, and a greater tolerance of samples with a high-matrix burden [2,16]. The throughput advantage is a consequence of the possibility of separating multiple samples in parallel with each sample occupying a single lane (or track) on the layer and several samples assigned to different lanes for simultaneous separation. Column chromatography is inherently a sequential separation process in which the separation time for a group of samples is the product of the...

Erscheint lt. Verlag	22.9.2014
Sprache	englisch
Themenwelt	Naturwissenschaften ► Chemie ► Analytische Chemie
Themenwelt	Technik
ISBN-10	0-12-417284-9 / 0124172849
ISBN-13	978-0-12-417284-5 / 9780124172845

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