1 / 36

Heterocyclic Compounds

Heterocyclic Compounds. Cyclic compounds. Homocyclic Compounds contain ring made up only of carbon atoms . Heterocyclic Compounds contain ring made up of carbon atoms and another kind of atoms. (most commonly N, O, S) . Importance of Heterocyclic Compounds. 1. Used as solvents.

jerome
Download Presentation

Heterocyclic Compounds

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Heterocyclic Compounds

  2. Cyclic compounds Homocyclic Compounds contain ring made up only of carbon atoms . Heterocyclic Compounds contain ring made up of carbon atoms and another kind of atoms. (most commonly N, O, S)

  3. Importance of Heterocyclic Compounds 1. Used as solvents 2. Found as natural product

  4. 3. Found in Biomolecules: Nitrogen bases in DNA and RNA 4. Used as Drug a. Quinoline as Anti malaria for 400 years Quinine

  5. 4. Used as Drug b. Imidazoles as Amebicide Metroindazole c. Lactam as antibiotics Penicillin

  6. Most common Heterocyclic rings N - Heterocyclic rings Five-membered rings Unsaturated Saturated

  7. N - Heterocyclic rings Six-membered rings Unsaturated Saturated DNA bases

  8. N - Heterocyclic rings Fused rings Pyrimidine –imidazole (DNA bases) Benzene fused

  9. O- Heterocyclic rings Five- membered Six- membered Benzene fused

  10. S - Heterocyclic rings Unsaturated Heterocyclic rings with two different heteroatoms N and O N and S

  11. Nomenclature of Heterocyclic Compounds Naming monoheterocyclic compounds withmore than one heteroatoms 1. Name: Prefix- Suffix – ring size - saturation O ox S thi N az • Ring Size unsaturated saturated saturated ring with nitrogen • 5 ole olane -olidine • 6 ine inane (-ane) O Oxa S Thia N Aza Priority

  12. 2. Indication of the position of hetero atoms: the highest priority atom is #1 and continues in the direction that gives the next priority atom the lowest number IUPAC name: 1,3-oxazole Common name: oxazole IUPAC name: 1,2-oxazole Common name: isoxazole 1,2-oxathiolane 3.Indication of the position of saturated atoms: When a ring is partially saturated , the location of saturated atoms, may be designated by a "#H " 2H-1,5,2-dithiazine 6H-1,2,5-thiadiazine

  13. Nomenclature of Fused Systems Nomenclature of benzofused compounds: • a benzene ring fused to a heterocycle is named by: • 1. prefix: the word benzo • 2. letter in square brackets: indicating the position of fusion • 3. name of heterocyclic ring: (common or IUPAC name). • Name= Benzo[letter]name of heterocyclic ring

  14. For designating the position of fusion the following rule is followed: • Numbering the H.C.R • a. When numbering a ring with one heteroatom, the heteroatom is #1 and continues in the direction that is closer to the fused bond. • b. When numbering a ring with more than one heteroatom, the highest priority atom is #1 and continues in the direction that gives the next priority atom the lowest number 2.The bonds of the heterocyclic ring are assigned by alphabetical letters staring with the 1,2-bond

  15. Examples

  16. Nomenclature of fused heterocylic compounds: • The name is formed of : • name of substituent ring[number, number-letter]name of base ring Note: The name of the substituent ring is derived by writing

  17. Priority order of component ring systems: • Selection of a parent or base ring is based on the following rules which are applied in order • Rule 1: A heterocyclic ring containing the heteroatom occurring earliest in the order N, O, S, • (i.e. ring containing N preferred to the rings does not contain N or containing O, or S) Example 1

  18. Example 2 Substituent ring Note: The numbering system for the whole fused system is not the same as the numbers in the square brackets (i.e. there are three numbering systems; one for parent ring, one for substituent ring and the third is for the system as a whole)

  19. Rule 2: A heterocyclic component containing the largest possible individual ring

  20. Rule 3: A heterocyclic component containing the greater number of heteroatom of any kind Note: The whole molecule is numbered starting from pyridine ring to give the three heteroatom the lowest possible number (1,6,7), however, stating from oxazinering will give them (2,3,5) or (2,3,8).

  21. Rule 4: A heterocyclic component containing the greater variety of heteroatom Note: The whole molecule is numbered starting from pyrazole ring to give the four heteroatom the lowest possible number (1,2,4,6). While starting from oxazole ring give them (1,3,4,5) or (1,3,5,6).

  22. Rule 5: A heterocyclic component containing the greater number of heteroatoms most preferred when considered in order O, S,N,

  23. Rule 6: A heterocyclic component with the lower possible number for heteroatoms

  24. Rule 7: If a position of fusion is occupied by a heteroatom the name of the component rings to be used are so chosen as both to contain the heteroatom.

  25. Order of preference between alternative numbering system of the whole molecule • Numbering the whole fused system should start from the first atom after fusion in any direction to fulfill the following rules in order: • Give low numbers for the heteroatoms as a set

  26. Give low numbers for heteroatoms of higher priority O,S, N

  27. Give low numbers to fusion carbon atoms 7a 7a Fusion carbon 4a is preferred to 7a

  28. D) Give low numbers to indicate hydrogen atom 4H-[1,3]dioxolo[4,5-d]imidazole

  29. Summary of Nomenclatures Rules Scheme for deriving the base component of' a fused ring system • Is there only one ring which contains nitrogen? • (YES:. choose this as base component) • 2. Are the two rings have the same heteroatoms but their size is different ? • (Yes: choose the larger one ) • 3. Are the two rings of the same size but have different heteroatoms? • (YES: choose the ring containing a heteroatom of the highest priority i.e. O >S) • 4. Are the rings of the same size but contain different numbers of heteroatoms? • (Yes: choose the ring with the greater number ) • 5. Are the two rings of the same size and the same number of different heteroatoms? • (Yes: choose the ring with the greatest variety of heteroatoms • 7-Are the two rings have the same size and the same number and type of heteroatoms? • (yes: choose the ring with the lower numbers for heteroatoms )

  30. examples

  31. pyrrole . . . Aromaticity Aromatic It has 6 delocalized electrons . It has not basic properties because the nitrogen lone pair electrons are involved in aromaticity of the ring Basicity

  32. Resonance Structures of Pyrrole Reactions of Pyrrole: Resonance structures show that carbon atoms in pyrrole ring are rich of Electrons. That means Pyrrole like to undergo Electrophilic substitution reaction Position 2 Position 3

  33. Examples:

  34. pyridine . . . . Aromatic It has 6 delocalized electrons Aromaticity . . It has basic properties because the nitrogen lone pair electrons are free and available for sharing as base Basicity

  35. Resonance Structures of Pyridine Reactions of Pyridine: Resonance structures show that carbon atoms at ortho and para are deficient of Electrons. That means Pyridine like to undergo Nucleophilic substitution reaction at ortho and para positions

  36. Examples: + NaOH + H2 H2O

More Related