fbpx
Wikipedia

Ring expansion and contraction

February 12, 2024

Ring expansion and ring contraction reactions expand or contract rings, usually in organic chemistry. The term usually refers to reactions involve making and breaking C-C bonds,[1] Diverse mechanisms lead to these kinds of reactions.

The bond migration step of the pinacol type rearrangement.

Demyanov ring contraction and expansion edit

These reactions entail diazotization of aminocyclobutanes and aminocyclopropanes. Loss of N2 from the diazo cations results in secondary carbocations, which tend to rearrange and then undergo hydrolysis. The reaction converts aminocyclobutane into a mixture of hydroxycyclobutane and hydroxymethylcyclopropane. These reactions produce an equilibrating mixture of two carbocations:[2]

C4H+7 ⇌ C3H5CH+2

Carbenoid ring contractions edit

 
Mechanism of the Wolff rearrangement used to give a ring contracted product.

In the Arndt–Eistert reaction, an α-diazoketone is induced to release N2, resulting in a highly reactive sextet carbon center adjacent to the carbonyl. Such species convert by a Wolff rearrangement to give an ester in the presence of alcohols. When applied to cyclic α-diazoketones, ring contraction occurs.[3][4] In the case of steroids, this reaction has been used to convert cyclopentanone groups to cyclobutanyl derivatives.[5]

Ring expansion reactions edit

 
A scheme showing ring expansion by exocyclic bond migration (A) and ring opening of a bicyclic molecule (B).

Ring expansions can allow access to larger systems that can be difficult to synthesize otherwise.[6] Rings can be expanded by attack of the ring onto an outside group already appended to the ring (a migration/insertion), opening of a bicycle to a single larger ring, or coupling a ring closing with an expansion.[1] These expansions can be further broken down by what type of atom they incorporate (a carbon or a heteroatom) into the expanded ring.

Carbon insertion through migration to an exocyclic group edit

These reactions have the general features of having an exocyclic leaving group on a carbon adjacent to the ring and an electron donating group on the ring capable of initiating a migration of an endocyclic bond.

A common migration introduction of carbon is a pinacol rearrangement.[1] While this reaction refers specifically to a vicinal dihydroxide rearrangement, there are other pinacol type rearrangements that proceed through the same general mechanism such as the Tiffeneau-Demjanov rearrangement. These "semipinacol rearrangements" occur under milder conditions and are thus preferable in complex syntheses.[7] These reactions are useful beyond simply expanding a ring because the exocyclic group attacked may also have other functionality appended to it besides the leaving group. The group to which the endocyclic bond migrates can also be selectively added to the ring based on the functionality already present, for example 1,2 addition into a cyclic ketone.

Carbon insertion through opening of a bicycle edit

 
A generalized mechanism of the Buchner ring expansion.

A common method for expanding a ring involves opening cyclopropane-containing bicyclic intermediate. The strategy can start with a Simmons-Smith-like cyclopropanation of a cyclic alkene.[8]

A related cyclopropane-based ring expansion is the Buchner ring expansion. The Buchner ring expansion is used to convert arenes to cycloheptatrienes. The Buchner ring expansion is encouraged to open to the desired product by placing electron withdrawing groups on the carbon added. In order to perform the ring opening on saturated bicyclic molecules the cyclopropane must be introduced such that a neighboring group can facilitate the expansion or the ring must be opened by attackate the expansion[9] or the ring must be opened by attack from an outside group.[10]

Ring opening as a means of ring expansion can also be applied to larger systems to give access to even larger ring syscyclization. The Grob fragmentation can be applied as an example of such an expansion. Like the pinacol type migration the Grob fragmentation relies on an electron donating group to promote the bond migration and encourage the leaving group to be expelled. In this case the electron donating group can be a pseudo electron donating group which is capable of eliminating and donating an electron pair into the carbon with the breaking bond. Working with two smaller rings can allow for elaboration of two parts of the molecule separately before working with the expanded ring. The Dowd-Beckwith ring expansion reaction is also capable of adding several carbons to a ring at a time,e of adding several carbons to a ring at a time, and is a useful tool for making large rings.[11] While it proceeds through an intermediate bicycle the final cyclization and ring opening take place within the same radical reaction.[12] This expansion is useful because it allows the expansion of a beta-ketoester to a large cyclic ketone which can easily be elaborated using either the cyclic ketone or the exocyclic ester.

 
The bond migration steps in the Baeyer-Villiger oxidation (A) and the Beckmann rearrangement (B).

Heteroatom insertion reactions edit

Heteroatom additions to rings can occur through ring expansions if not they are not done through de-novo ring synthesis.[13] These introductions are primarily ring expansions because they often take place through migration/insertion pathways similar to those mentioned above for carbon. Examples include high impact applications of the Beckmann rearrangement (for introduction of nitrogen into codeine)[14] and the Baeyer-Villiger oxidation (introduction of oxygen to cage-annulated ethers)[15] in synthesis. Both occur with the expulsion of a leaving group as the alkyl group migrates onto the exocyclic heteroatom, which is strikingly similar to the pinacol type rearrangement.

Ring contraction reactions edit

 
Ring contraction through anionic (A), cationic (B), and carbenoid (C) reactive intermediates.

Ring contractions are useful for making smaller, more strained rings from larger rings. The impetus for making these rings comes from the difficulty associated with making a fully elaborated small ring when such a ring could more easily be made from an elaborated larger ring, from which an atom can be excised, or that the original larger scaffold is more accessible.[16]

Ring contractions are easily characterized simply by the reactive intermediate which performs the contraction. The standard intermediates are anionic, cationic, and carbenoid.[17]

Favorskii rearrangement edit

The Favorskii rearrangement is a classic anionic ring contraction.[18] It proceeds through a carbanion that attacks an endocyclic carbon and expels a leaving group (a halide) forming a bicyclic molecule with rings smaller than the original. The bicycle is then opened by nucleophilic attack on the ketone to give the contracted product.[19] This reaction has been used to convert cyclohexanone to the methyl ester of cyclopropanecarboxylic acid.

 
A generalized mechanism of the Favorskii rearrangement to give a ring contracted product. Note that anion formation has been omitted.

An alternative to the standard Favorskii rearrangement, is to perform what can be thought of as a negative pinacol rearrangement where an anionic group encourages a bond aligned with a leaving group to migrate and expel the leaving group, which has been used in several syntheses.[17] It should also be noted that the so-called "quasi-Favorskii rearrangement" proceeds without an additional nucleophile to form the final contracted product.

 
A general pinacol type rearrangement to an unequal 5,7 ring system.

Cation contractions edit

The cationic rearrangement contraction proceeds through the loss of a leaving group and the migration of an endocyclic bond to the carbocation. Pinacol type rearrangements are often used for this type of contraction.[20] Like the expansion reaction this proceeds with an electron donating group aiding in the migration.

Contraction reactions of one ring can be coupled with an expansion of another to give an unequal bicycle from equally sized fused ring. These cationic rearrangements have found use to synthesize the cores of complex molecules.[21]

Further reading edit

  • Redmore, D.; Gutsche, C.D. Carbocyclic Ring Expansion Reactions, Academic Press, NY, 1968,

References edit

  1. ^ a b c Kantorowski, E.J.; Kurth, M.J. (2000). (PDF). Tetrahedron. 56 (26): 4317–4353. doi:10.1016/S0040-4020(00)00218-0. S2CID 34628258. Archived from the original (PDF) on August 18, 2019.
  2. ^ Smith, Michael B.; March, Jerry (2006). March's Advanced Organic Chemistry: Reactions, Mechanisms, and Structure. p. 1588-1592. doi:10.1002/0470084960. ISBN 9780470084960.{{cite book}}: CS1 maint: multiple names: authors list (link)
  3. ^ Smith, Michael B.; March, Jerry (2006). March's Advanced Organic Chemistry: Reactions, Mechanisms, and Structure. p. 1599. doi:10.1002/0470084960. ISBN 9780470084960.{{cite book}}: CS1 maint: multiple names: authors list (link)
  4. ^ Kirmse, W. (July 2002). "100 Years of the Wolff Rearrangement". European Journal of Organic Chemistry. 2002 (14): 2193. doi:10.1002/1099-0690(200207)2002:14<2193::AID-EJOC2193>3.0.CO;2-D.
  5. ^ Thomas N. Wheeler and J. Meinwald (1972). "Formation and Photochemical Wolff Rearrangement of Cyclic α-Diazo Ketones: d-Norandrost-5-en-3β-ol-16-carboxylic Acids". Organic Syntheses. 52: 53. doi:10.15227/orgsyn.052.0053.
  6. ^ Casadei, M.A.; Calli, C.; Mandolini, L. (February 1, 1984). "Ring-closure reactions. 22. Kinetics of cyclization of diethyl (.omega.-bromoalkyl)malonates in the range of 4- to 21-membered rings. Role of ring strain". Journal of the American Chemical Society. 106 (4): 1051–1056. doi:10.1021/ja00316a039.
  7. ^ Kurti, L.; Czako, B. (2005). Strategic Applications of Named Reactions. Elsevier. p. 350. ISBN 978-0-12-429785-2. OCLC 1107566236.
  8. ^ "One-Carbon Ring Expansion of Cycloalkanones to Conjugated Cycloalkenones: 2-Cyclohepten-1-One". Organic Syntheses. 59: 113. 1979. doi:10.15227/orgsyn.059.0113.
  9. ^ Bieräugel, H.; Akkerman, J. M.; Armande, J. C. L.; Pandit, U. K. (1974). "A specific insertion of carbenes into carbon-carbon bonds". Tetrahedron Letters. 15 (33): 2817–2820. doi:10.1016/S0040-4039(01)91751-4.
  10. ^ Hoberg, J.O.; Bozell, J.J. (September 1995). "Cyclopropanation and ring-expansion of unsaturated sugars". Tetrahedron Letters. 36 (38): 6831–6834. doi:10.1016/0040-4039(95)01387-W.
  11. ^ Hierold, J.; Lupton, D.W. (July 2012). "Synthesis of Spirocyclic γ-Lactones by Cascade Beckwith–Dowd Ring Expansion/Cyclization". Organic Letters. 14 (13): 3412–3415. doi:10.1021/ol301387t. PMID 22691029.
  12. ^ Dowd, P.; Choi; S. C. J. Am. Chem. Soc. 1987, 3493–3494
  13. ^ McMurry, John (2008). Organic Chemistry 7th Ed. pp. 945–946. ISBN 978-0-495-11258-7.
  14. ^ White, J. D.; Hrnciar, P.; Stappenbeck, F. (1999). "Asymmetric Total Synthesis of (+)-Codeine via Intramolecular Carbenoid Insertion". Journal of Organic Chemistry. 63 (21): 7871–7884. doi:10.1021/jo990905z.
  15. ^ Marchand, A. P.; Kumar, V. S.; Hariprakasha, H. K. (2001). "Synthesis of Novel Cage Oxaheterocycles". Journal of Organic Chemistry. 66 (6): 2072–2077. doi:10.1021/jo001611c. PMID 11300903.
  16. ^ Silva, L.F. Tetrahedron 2002, 9137–9161[full citation needed]
  17. ^ a b Myers, Andrew. "Methods for Ring Contraction" (PDF). Retrieved November 30, 2014 – via Harvard University Department of Chemistry and Chemical Biology.
  18. ^ Chenier, Philip J. (1978). "The Favorskii Rearrangement in Bridged Polycyclic Compounds". Journal of Chemical Education. 55 (5): 286–291. Bibcode:1978JChEd..55..286C. doi:10.1021/ed055p286.
  19. ^ Smith, Michael B.; March, Jerry (2006). March's Advanced Organic Chemistry: Reactions, Mechanisms, and Structure. p. 1595-1596. doi:10.1002/0470084960. ISBN 9780470084960.{{cite book}}: CS1 maint: multiple names: authors list (link)
  20. ^ Song, Zhen-Lei; Fan, Chun-An; Tu, Yong-Qiang (2011). "Semipinacol Rearrangement in Natural Product Synthesis". Chemical Reviews. 111 (11): 7523–7556. doi:10.1021/cr200055g. PMID 21851053.
  21. ^ Büchi, G.; Hofheinz, W.; Paukstelis, J. V. (November 1969). "Synthesis of (-)-aromadendrene and related sesquiterpenes". Journal of the American Chemical Society. 91 (23): 6473–6478. doi:10.1021/ja01051a051.

February 12, 2024
ring, expansion, contraction, this, article, multiple, issues, please, help, improve, discuss, these, issues, talk, page, learn, when, remove, these, template, messages, this, article, require, cleanup, meet, wikipedia, quality, standards, specific, problem, u. This article has multiple issues Please help improve it or discuss these issues on the talk page Learn how and when to remove these template messages This article may require cleanup to meet Wikipedia s quality standards The specific problem is uneven quality of sourcing substantially primary and not full sources reflecting editorial decisions to include exclude examples decisions that i constitute original research and ii that are unfortunately not scholarly and up to date Please help improve this article if you can April 2015 Learn how and when to remove this template message This scientific article needs additional citations to secondary or tertiary sourcessuch as review articles monographs or textbooks Please also establish the relevance for any primary research articles cited Unsourced or poorly sourced material may be challenged and removed December 2014 Learn how and when to remove this template message Learn how and when to remove this template message Ring expansion and ring contraction reactions expand or contract rings usually in organic chemistry The term usually refers to reactions involve making and breaking C C bonds 1 Diverse mechanisms lead to these kinds of reactions The bond migration step of the pinacol type rearrangement Contents 1 Demyanov ring contraction and expansion 2 Carbenoid ring contractions 3 Ring expansion reactions 3 1 Carbon insertion through migration to an exocyclic group 3 1 1 Carbon insertion through opening of a bicycle 3 2 Heteroatom insertion reactions 4 Ring contraction reactions 4 1 Favorskii rearrangement 4 2 Cation contractions 5 Further reading 6 ReferencesDemyanov ring contraction and expansion editThese reactions entail diazotization of aminocyclobutanes and aminocyclopropanes Loss of N2 from the diazo cations results in secondary carbocations which tend to rearrange and then undergo hydrolysis The reaction converts aminocyclobutane into a mixture of hydroxycyclobutane and hydroxymethylcyclopropane These reactions produce an equilibrating mixture of two carbocations 2 C4H 7 C3H5CH 2Carbenoid ring contractions edit nbsp Mechanism of the Wolff rearrangement used to give a ring contracted product In the Arndt Eistert reaction an a diazoketone is induced to release N2 resulting in a highly reactive sextet carbon center adjacent to the carbonyl Such species convert by a Wolff rearrangement to give an ester in the presence of alcohols When applied to cyclic a diazoketones ring contraction occurs 3 4 In the case of steroids this reaction has been used to convert cyclopentanone groups to cyclobutanyl derivatives 5 Ring expansion reactions edit nbsp A scheme showing ring expansion by exocyclic bond migration A and ring opening of a bicyclic molecule B Ring expansions can allow access to larger systems that can be difficult to synthesize otherwise 6 Rings can be expanded by attack of the ring onto an outside group already appended to the ring a migration insertion opening of a bicycle to a single larger ring or coupling a ring closing with an expansion 1 These expansions can be further broken down by what type of atom they incorporate a carbon or a heteroatom into the expanded ring Carbon insertion through migration to an exocyclic group edit These reactions have the general features of having an exocyclic leaving group on a carbon adjacent to the ring and an electron donating group on the ring capable of initiating a migration of an endocyclic bond A common migration introduction of carbon is a pinacol rearrangement 1 While this reaction refers specifically to a vicinal dihydroxide rearrangement there are other pinacol type rearrangements that proceed through the same general mechanism such as the Tiffeneau Demjanov rearrangement These semipinacol rearrangements occur under milder conditions and are thus preferable in complex syntheses 7 These reactions are useful beyond simply expanding a ring because the exocyclic group attacked may also have other functionality appended to it besides the leaving group The group to which the endocyclic bond migrates can also be selectively added to the ring based on the functionality already present for example 1 2 addition into a cyclic ketone Carbon insertion through opening of a bicycle edit nbsp A generalized mechanism of the Buchner ring expansion A common method for expanding a ring involves opening cyclopropane containing bicyclic intermediate The strategy can start with a Simmons Smith like cyclopropanation of a cyclic alkene 8 A related cyclopropane based ring expansion is the Buchner ring expansion The Buchner ring expansion is used to convert arenes to cycloheptatrienes The Buchner ring expansion is encouraged to open to the desired product by placing electron withdrawing groups on the carbon added In order to perform the ring opening on saturated bicyclic molecules the cyclopropane must be introduced such that a neighboring group can facilitate the expansion or the ring must be opened by attackate the expansion 9 or the ring must be opened by attack from an outside group 10 Ring opening as a means of ring expansion can also be applied to larger systems to give access to even larger ring syscyclization The Grob fragmentation can be applied as an example of such an expansion Like the pinacol type migration the Grob fragmentation relies on an electron donating group to promote the bond migration and encourage the leaving group to be expelled In this case the electron donating group can be a pseudo electron donating group which is capable of eliminating and donating an electron pair into the carbon with the breaking bond Working with two smaller rings can allow for elaboration of two parts of the molecule separately before working with the expanded ring The Dowd Beckwith ring expansion reaction is also capable of adding several carbons to a ring at a time e of adding several carbons to a ring at a time and is a useful tool for making large rings 11 While it proceeds through an intermediate bicycle the final cyclization and ring opening take place within the same radical reaction 12 This expansion is useful because it allows the expansion of a beta ketoester to a large cyclic ketone which can easily be elaborated using either the cyclic ketone or the exocyclic ester nbsp The bond migration steps in the Baeyer Villiger oxidation A and the Beckmann rearrangement B Heteroatom insertion reactions edit Heteroatom additions to rings can occur through ring expansions if not they are not done through de novo ring synthesis 13 These introductions are primarily ring expansions because they often take place through migration insertion pathways similar to those mentioned above for carbon Examples include high impact applications of the Beckmann rearrangement for introduction of nitrogen into codeine 14 and the Baeyer Villiger oxidation introduction of oxygen to cage annulated ethers 15 in synthesis Both occur with the expulsion of a leaving group as the alkyl group migrates onto the exocyclic heteroatom which is strikingly similar to the pinacol type rearrangement Ring contraction reactions edit nbsp Ring contraction through anionic A cationic B and carbenoid C reactive intermediates Ring contractions are useful for making smaller more strained rings from larger rings The impetus for making these rings comes from the difficulty associated with making a fully elaborated small ring when such a ring could more easily be made from an elaborated larger ring from which an atom can be excised or that the original larger scaffold is more accessible 16 Ring contractions are easily characterized simply by the reactive intermediate which performs the contraction The standard intermediates are anionic cationic and carbenoid 17 Favorskii rearrangement edit The Favorskii rearrangement is a classic anionic ring contraction 18 It proceeds through a carbanion that attacks an endocyclic carbon and expels a leaving group a halide forming a bicyclic molecule with rings smaller than the original The bicycle is then opened by nucleophilic attack on the ketone to give the contracted product 19 This reaction has been used to convert cyclohexanone to the methyl ester of cyclopropanecarboxylic acid nbsp A generalized mechanism of the Favorskii rearrangement to give a ring contracted product Note that anion formation has been omitted An alternative to the standard Favorskii rearrangement is to perform what can be thought of as a negative pinacol rearrangement where an anionic group encourages a bond aligned with a leaving group to migrate and expel the leaving group which has been used in several syntheses 17 It should also be noted that the so called quasi Favorskii rearrangement proceeds without an additional nucleophile to form the final contracted product nbsp A general pinacol type rearrangement to an unequal 5 7 ring system Cation contractions edit The cationic rearrangement contraction proceeds through the loss of a leaving group and the migration of an endocyclic bond to the carbocation Pinacol type rearrangements are often used for this type of contraction 20 Like the expansion reaction this proceeds with an electron donating group aiding in the migration Contraction reactions of one ring can be coupled with an expansion of another to give an unequal bicycle from equally sized fused ring These cationic rearrangements have found use to synthesize the cores of complex molecules 21 Further reading editRedmore D Gutsche C D Carbocyclic Ring Expansion Reactions Academic Press NY 1968 References edit a b c Kantorowski E J Kurth M J 2000 Expansion to seven membered rings PDF Tetrahedron 56 26 4317 4353 doi 10 1016 S0040 4020 00 00218 0 S2CID 34628258 Archived from the original PDF on August 18 2019 Smith Michael B March Jerry 2006 March s Advanced Organic Chemistry Reactions Mechanisms and Structure p 1588 1592 doi 10 1002 0470084960 ISBN 9780470084960 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Smith Michael B March Jerry 2006 March s Advanced Organic Chemistry Reactions Mechanisms and Structure p 1599 doi 10 1002 0470084960 ISBN 9780470084960 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Kirmse W July 2002 100 Years of the Wolff Rearrangement European Journal of Organic Chemistry 2002 14 2193 doi 10 1002 1099 0690 200207 2002 14 lt 2193 AID EJOC2193 gt 3 0 CO 2 D Thomas N Wheeler and J Meinwald 1972 Formation and Photochemical Wolff Rearrangement of Cyclic a Diazo Ketones d Norandrost 5 en 3b ol 16 carboxylic Acids Organic Syntheses 52 53 doi 10 15227 orgsyn 052 0053 Casadei M A Calli C Mandolini L February 1 1984 Ring closure reactions 22 Kinetics of cyclization of diethyl omega bromoalkyl malonates in the range of 4 to 21 membered rings Role of ring strain Journal of the American Chemical Society 106 4 1051 1056 doi 10 1021 ja00316a039 Kurti L Czako B 2005 Strategic Applications of Named Reactions Elsevier p 350 ISBN 978 0 12 429785 2 OCLC 1107566236 One Carbon Ring Expansion of Cycloalkanones to Conjugated Cycloalkenones 2 Cyclohepten 1 One Organic Syntheses 59 113 1979 doi 10 15227 orgsyn 059 0113 Bieraugel H Akkerman J M Armande J C L Pandit U K 1974 A specific insertion of carbenes into carbon carbon bonds Tetrahedron Letters 15 33 2817 2820 doi 10 1016 S0040 4039 01 91751 4 Hoberg J O Bozell J J September 1995 Cyclopropanation and ring expansion of unsaturated sugars Tetrahedron Letters 36 38 6831 6834 doi 10 1016 0040 4039 95 01387 W Hierold J Lupton D W July 2012 Synthesis of Spirocyclic g Lactones by Cascade Beckwith Dowd Ring Expansion Cyclization Organic Letters 14 13 3412 3415 doi 10 1021 ol301387t PMID 22691029 Dowd P Choi S C J Am Chem Soc 1987 3493 3494 McMurry John 2008 Organic Chemistry 7th Ed pp 945 946 ISBN 978 0 495 11258 7 White J D Hrnciar P Stappenbeck F 1999 Asymmetric Total Synthesis of Codeine via Intramolecular Carbenoid Insertion Journal of Organic Chemistry 63 21 7871 7884 doi 10 1021 jo990905z Marchand A P Kumar V S Hariprakasha H K 2001 Synthesis of Novel Cage Oxaheterocycles Journal of Organic Chemistry 66 6 2072 2077 doi 10 1021 jo001611c PMID 11300903 Silva L F Tetrahedron 2002 9137 9161 full citation needed a b Myers Andrew Methods for Ring Contraction PDF Retrieved November 30 2014 via Harvard University Department of Chemistry and Chemical Biology Chenier Philip J 1978 The Favorskii Rearrangement in Bridged Polycyclic Compounds Journal of Chemical Education 55 5 286 291 Bibcode 1978JChEd 55 286C doi 10 1021 ed055p286 Smith Michael B March Jerry 2006 March s Advanced Organic Chemistry Reactions Mechanisms and Structure p 1595 1596 doi 10 1002 0470084960 ISBN 9780470084960 a href Template Cite book html title Template Cite book cite book a CS1 maint multiple names authors list link Song Zhen Lei Fan Chun An Tu Yong Qiang 2011 Semipinacol Rearrangement in Natural Product Synthesis Chemical Reviews 111 11 7523 7556 doi 10 1021 cr200055g PMID 21851053 Buchi G Hofheinz W Paukstelis J V November 1969 Synthesis of aromadendrene and related sesquiterpenes Journal of the American Chemical Society 91 23 6473 6478 doi 10 1021 ja01051a051 Retrieved from https en wikipedia org w index php title Ring expansion and contraction amp oldid 1193984671, wikipedia, wiki, book, books, library,

article

, read, download, free, free download, mp3, video, mp4, 3gp, jpg, jpeg, gif, png, picture, music, song, movie, book, game, games.