Essentials of pharmaceutical preformulation [electronic resource]
- Responsibility
- Simon Gaisford and Mark Saunders.
- Imprint
- Chichester, West Sussex : John Wiley & Sons, 2013.
- Physical description
- 1 online resource.
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Description
Creators/Contributors
- Author/Creator
- Gaisford, Simon.
- Contributor
- Saunders, Mark, 1976 September 18-
Contents/Summary
- Bibliography
- Includes bibliographical references and index.
- Contents
-
- Preface xiii List of Abbreviations xv 1 Basic Principles of Preformulation Studies 1 1.1 Introduction 1 1.2 Assay design 2 1.2.1 Assay development 3 1.3 Concentrations 5 1.3.1 Units of concentration 5 1.4 UV spectrophotometry 9 1.4.1 Method development for UV assays 11 1.5 Thin-layer chromatography (TLC) 14 1.5.1 TLC method development 15 1.5.2 High-performance TLC 17 1.6 High-performance liquid chromatography 19 1.6.1 Normal- and reverse-phase HPLC 20 1.6.2 HPLC method development 21 1.7 Differential scanning calorimetry 22 1.7.1 Interpreting DSC data 23 1.7.2 Modulated-temperature DSC 27 1.7.3 DSC method development 30 1.8 Dynamic vapour sorption 32 1.8.1 DVS method development 32 1.9 Summary 33 References 33 Answer to study question 34 Additional study questions 35 2 Ionisation Constants 36 2.1 Introduction 36 2.2 Ionisation 36 2.2.1 Percent ionisation 42 2.3 Buffers 44 2.4 Determination of pKa 44 2.4.1 Determination of pKa by potentiometric titration 45 2.4.2 Determination of pKa in nonaqueous solvents 45 2.4.3 Other factors affecting measurement of pKa 47 2.5 Summary 48 References 48 Answers to study questions 49 Additional self-study questions and answers 50 3 Partition Affinity 52 3.1 Introduction 52 3.2 Partitioning 52 3.2.1 Effect of partitioning 54 3.2.2 Determination of log P 55 3.2.3 Effect of salt formation on partitioning 62 3.3 Summary 63 References 63 Answers to study questions 64 4 Solubility 65 4.1 Introduction 65 4.2 Intrinsic solubility 67 4.2.1 Ideal solubility 69 4.2.2 Solubility as a function of temperature 73 4.2.3 Solubility and physical form 74 4.2.4 Measurement of intrinsic solubility 77 4.2.5 Calculation of pKa from solubility data 83 4.3 Summary 83 References 84 Answer to study question 84 Additional self-study questions and answers 84 5 Dissolution 86 5.1 Introduction 86 5.2 Models of dissolution 86 5.3 Dissolution testing 87 5.3.1 Intrinsic dissolution rate (IDR) 92 5.3.2 IDR as a function of pH 93 5.3.3 IDR and the common ion effect 94 5.4 Summary 96 References 96 6 Salt Selection 98 6.1 Introduction 98 6.2 Salt formation 99 6.2.1 Selection of a salt-forming acid or base 104 6.2.2 Salt screening 108 6.3 Salt solubility 110 6.3.1 Solubility of basic salts 111 6.3.2 Solubility of acidic salts 112 6.3.3 The importance of pHmax 114 6.4 Dissolution of salts 117 6.4.1 Modification of pHm 120 6.5 Partitioning of salts 121 6.6 Summary 123 References 124 Answers to study questions 126 7 Physical Form I
- Crystalline Materials 127 7.1 Introduction 127 7.2 Crystal formation 127 7.2.1 Crystal formation from the melt 128 7.2.2 Crystal growth from solution 129 7.3 Crystal structure 130 7.4 Polymorphism 131 7.4.1 Thermodynamics of polymorphism 133 7.4.2 Physicochemical properties of polymorphs 137 7.5 Pseudopolymorphism 139 7.6 Polymorph screening 141 7.7 Characterisation of physical form 141 7.7.1 Characterisation of polymorphs 142 7.7.2 Characterisation of pseudopolymorphs 149 7.8 Summary 152 References 152 Answers to study questions 153 8 Physical Form II
- Amorphous Materials 156 8.1 Introduction 156 8.2 Formation of amorphous materials 156 8.3 Ageing of amorphous materials 160 8.4 Characterisation of amorphous materials 162 8.4.1 Measurement of ageing 164 8.5 Processing and formation of amorphous material 168 8.5.1 Spray-drying 168 8.5.2 Freeze-drying 168 8.5.3 Quench-cooling 169 8.5.4 Milling 170 8.5.5 Compaction 171 8.6 Amorphous content quantification 171 8.6.1 Calibration standards 172 8.6.2 DSC for amorphous content quantification 173 8.6.3 DVS for amorphous content quantification 175 8.7 Summary 177 References 178 Answers to study questions 179 9 Stability Assessment 181 9.1 Introduction 181 9.2 Degradation mechanisms 183 9.2.1 Hydrolysis 185 9.2.2 Solvolysis 187 9.2.3 Oxidation 188 9.2.4 Photolysis 190 9.3 Reaction kinetics 191 9.3.1 Solution-phase kinetics 191 9.3.2 Zero-order reactions 192 9.3.3 First-order kinetics 193 9.3.4 Second-order reactions 194 9.3.5 Solid-state kinetics 195 9.4 The temperature dependence of reaction kinetics 198 9.5 Stress testing 203 9.5.1 Stress testing in solution 203 9.5.2 Stress testing in the solid-state 204 9.5.3 Drug--excipient compatibility testing 205 9.6 Summary 208 References 208 Answers to study questions 209 10 Particle Properties 211 10.1 Introduction 211 10.2 Microscopy 211 10.2.1 Light microscopy 212 10.2.2 Hot-stage microscopy 213 10.2.3 Electron microscopy 214 10.2.4 Atomic force microscopy 214 10.3 Particle shape 215 10.3.1 Habit 215 10.3.2 Particle sizing 219 10.3.3 Particle size distributions 222 10.4 Summary 227 References 227 Answer to study question 227 11 Powder Properties 228 11.1 Introduction 228 11.2 Powder flow and consolidation 228 11.2.1 Carr's index 230 11.2.2 Hausner ratio 232 11.2.3 Angle of repose 232 11.2.4 Mohr diagrams 235 11.3 Compaction properties 240 11.3.1 Compaction simulators 242 11.4 Summary 243 References 243 Answers to study questions 243 Index 247 Companion website This book is accompanied by a companion website at: ttp://www.wiley.com/go/gaisford/essentials Visit the website for: * Figures and tables from the book * Multiple choice questions.
- (source: Nielsen Book Data)
- Publisher's summary
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"Essentials of Pharmaceutical Preformulation" is a study guide which describes the basic principles of pharmaceutical physicochemical characterisation. Successful preformulation requires knowledge of fundamental molecular concepts (solubility, ionisation, partitioning, hygroscopicity and stability) and macroscopic properties (physical form, such as the crystalline and amorphous states, hydrates, solvates and co-crystals and powder properties), familiarity with the techniques used to measure them and appreciation of their effect on product performance, recognising that often there is a position of compromise to be reached between product stability and bioavailability. This text introduces the basic concepts and discusses their wider implication for pharmaceutical development, with reference to many case examples of current drugs and drug products. Special attention is given to the principles and best-practice of the analytical techniques that underpin preformulation (UV spectrophotometry, TLC, DSC, XRPD and HPLC). The material is presented in the typical order that would be followed when developing a medicine and maps onto the indicative pharmacy syllabus of the Royal Pharmaceutical Society of Great Britain Undergraduate-level pharmacy students and R&D / analytical scientists working in the pharmaceutical sector (with or without a pharmaceutical background) will find this text easy to follow with relevant pharmaceutical examples. Essential study guide for pharmacy and pharmaceutical science students. It covers the pharmaceutical preformulation components of the Royal Pharmaceutical Society of Great Britain's indicative syllabus. Easy to follow text highlighted with relevant pharmaceutical examples. It provides self-assessment assignments in a variety of formats. It is written by authors with both academic and industrial experience. It offers companion website with further information to maximise learning.
(source: Nielsen Book Data)
- Publisher's summary
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Essentials of Pharmaceutical Preformulation: A study guide for students and researchers in pharmacy and pharmaceutical sciences describes basic principles of pharmaceutical preformulation for undergraduate level pharmacy students and newly employed workers in the pharmaceutical field who do not have a pharmaceutical background. Successful preformulation requires knowledge of a number of concepts (solubility, partition coefficient, acid dissociation), familiarity with a range of analytical techniques and their application to dosage form design. This text takes these concepts and explains them in the context of pharmaceutical development .Special focus is given to the principles and use of analytical apparatus, providing a core set of transferable knowledge skills. The material is presented in the order that would be followed when developing a medicine and maps onto the indicative syllabus of pharmacy from the Royal Pharmaceutical Society It is divided into three sections: Basic concepts, Solid-state properties and Macroscopic properties and includes easy to follow text highlighted with relevant pharmaceutical examples.
(source: Nielsen Book Data)
Subjects
Bibliographic information
- Publication date
- 2013
- ISBN
- 9781118423226 (electronic bk.)
- 1118423224 (electronic bk.)
- 9781118423219 (electronic bk.)
- 1118423216 (electronic bk.)
- 9781118423189
- 1118423186
- 9781118423240
- 1118423240
- 9780470976357 (cloth)