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Fundamentals of Heterocyclic Chemistry: Importance in Nature and in the Synthesis of Pharmaceuticals
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More About This Title Fundamentals of Heterocyclic Chemistry: Importance in Nature and in the Synthesis of Pharmaceuticals

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  • Heterocyclic chemistry is of prime importance as a sub-discipline of Organic Chemistry, as millions of heterocyclic compounds are known with more being synthesized regularly
  • Introduces students to heterocyclic chemistry and synthesis with practical examples of applied methodology
  • Emphasizes natural product and pharmaceutical applications
  • Provides graduate students and researchers in the pharmaceutical and related sciences with a background in the field
  • Includes problem sets with several chapters
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English

LOUIS D. QUIN, PhD, is an Adjunct Professor at the University of North Carolina Wilmington. Dr. Quin began his academic career in 1956 with the Department of Chemistry at Duke University, serving as department chairman from 1970 to 1976. After retiring from Duke, he went to the University of Massachusetts Amherst to head up its Chemistry Department, retiring in 1996. Dr. Quin has written 250 research papers and written or co-edited eight books on the subject of organophosphorus chemistry.

JOHN A. TYRELL, PhD, is Visiting Scientist in the Department of Chemistry and Bio-chemistry at the University of North Carolina Wilmington, where he teaches Fundamentals of Heterocyclic Chemistry among other courses. Dr. Tyrell holds sixty-eight patents and has more than twenty years of industrial research experience, much of it focused on heterocyclic chemistry research at Lederle Laboratories, General Electric Plastics, and OxyChem.

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English

PREFACE.

ACKNOWLEDGMENT.

Chapter 1 THE SCOPE OF THE FIELD OF HETEROCYCLIC CHEMISTRY.

References.

Appendix.

Chapter 2 COMMON RING SYSTEMS AND THE NAMING OF HETEROCYCLIC COMPOUNDS.

2.1. General.

2.2. Naming Simple Monocyclic Compounds.

2.3. Handling the "Extra Hydrogen".

2.4. Substituted Monocyclic Compounds.

2.5. Rings With More Than One Heteroatom.

2.6. Bicyclic Compounds.

2.7. Multicyclic Systems.

2.8. The Replacement Nomenclature System.

2.9. Saturated Bridged Ring Systems.

References.

Review Exercises.

Chapter 3 NATURE AS A SOURCE OF HETEROCYCLIC COMPOUNDS.

3.1. General.

3.2. Naturally Occurring Nitrogen Heterocyclic Compounds.

3.3. Oxygen Compounds.

3.4. Sulfur and Phosphorus Heterocyclic Compounds in Nature.

References.

Chapter 4 PRINCIPLES OF SYNTHESIS OF AROMATIC HETEROCYCLES BY INTRAMOLECULAR CYCLIZATION.

4.1. General.

4.2. Some of the Classic Synthetic Methods.

4.3. Cyclizations Involving Metallic Complexes as Catalysts.

4.4. Cyclizations with Radical Intermediates.

4.5. Cyclizations by Intramolecular Wittig Reactions.

4.6. Synthesis of Heterocycles by the Alkene Metathesis Reaction.

References.

Review Exercises.

Chapter 5 SYNTHESIS OF HETEROCYCLIC SYSTEMS BY CYCLOADDITION REACTIONS.

5.1. The Diels–Alder Reaction.

5.2. Dipolar Cycloadditions.

5.3. [2 + 2] Cycloadditions.

References.

Review Exercises.

Chapter 6 AROMATICITY AND OTHER SPECIAL PROPERTIES OF HETEROCYCLES: PI-DEFICIENT RING SYSTEMS.

6.1. General.

6.2. Review of the Aromaticity of Benzene.

6.3. Pi-Deficient Aromatic Heterocycles.

References.

Review Exercises.

Chapter 7 AROMATICITY AND OTHER SPECIAL PROPERTIES OF HETEROCYCLES: PI-EXCESSIVE RING SYSTEMS AND MESOIONIC RING SYSTEMS.

7.1. Pi-Excessive Aromatic Heterocycles.

7.2. Mesoionic Heterocycles.

References.

Review Exercises.

Chapter 8 THE IMPORTANCE OF HETEROCYCLES IN MEDICINE.

8.1. General.

8.2. Historical.

8.3. Pyridines.

8.4. Indoles.

8.5. Quinolines.

8.6. Azepines.

8.7. Pyrimidines.

8.8. Concluding Remarks.

References.

Chapter 9 SYNTHETIC METHODS FOR SOME PROMINENT HETEROCYCLIC FAMILIES: EXAMPLES OF PHARMACEUTICALS SYNTHESIS.

9.1. Scope of the Chapter.

9.2. Pyrroles.

9.3. Furans.

9.4. Thiophenes.

9.5. 1,3-Thiazoles.

9.6. 1,3-Oxazoles.

9.7. Imidazoles.

9.8. Pyrazoles.

9.9. 1,2,4-Triazoles.

9.10. Tetrazoles.

9.11. 1,3,4-Thiadiazoles and other 5-Membered Systems.

9.12. Indole.

9.13. Pyridines.

9.14. Quinolines and Isoquinolines.

9.15. Benzodiazepines.

9.16. Pyrimidines.

9.17. Fused Pyrimidines: Purines and Pteridines.

9.18. 1,3,5-Triazines.

9.19. Multicyclic Compounds.

References.

Review Exercises.

Chapter 10 GEOMETRIC AND STEREOCHEMICAL ASPECTS OF NONAROMATIC HETEROCYCLES.

10.1. General.

10.2. Special Properties of Three-Membered Rings.

10.3. Closing Heterocyclic Rings: Baldwin’s Rules.

10.4. Conformations of Heterocyclic Rings.

10.5. Chirality Effects on Biological Properties of Heterocycles.

References.

Review Exercises.

Chapter 11 SYNTHETIC HETEROCYCLIC COMPOUNDS IN AGRICULTURAL AND OTHER APPLICATIONS.

11.1. Heterocyclic Agrochemicals.

11.2. Applications of Heterocyclic Compounds in Commercial Fields.

References.

Appendix UNIFIED AROMATICITY INDICES (IA) OF BIRD.

INDEX.

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English

"Provides graduate students and researchers in the pharmaceutical and related sciences with a background in the field." (Trading Charts, 22 February 2011)
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