Tebbe reagents

The Tebbe reagent, j-chlorobis(cyclopentadienyl)(dimethylaluminium)-p,-methylenetitanium, transforms a carbonyl compound to the corresponding exoolefin. 

Name Reactions A Collection of Detailed Mechanisms and Synthetic Applications, DOI 10.1007/978-3-319-03979-4 272, Springer International Publishing Switzerland 2014 

TBSO OBn OTBS equiv Tebbe s reagent In Tol. TBSO OBn OTBS CHO Py T0I./THF 

Parshall, G. W. Reddy, G. S. J. Am. Chem. Soc. 1978,100, 3611-3613. Fred Tebbe worked at DuPont Central Researeh. 

Straus, D. A. Encyclopedia of Reagents for Organic Synthesis Wiley Sons, 2000. (Review). 

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Finally, treating the A-oxide directly with Tebbe reagent provides a rapid method of introducing the 2-methyl substituent (57 58). 

Taxus baccata 656 Taxus brevifolia 655 Tebbe reagent 703 telomerization 354 ff. a-terpineol 5 tertiary radicals 409, 413 tether, disposable 664 tetrahedrane 12... 

Titanacyclobutenes, prepared readily from Tebbe reagent and alkynes, react with aldehydes and ketones to form insertion products which undergo facile retro-Diels-Alder reaction to afford substituted 1,3-dienes (equation 107)185. 

Tebbe reagent to form 2-methyl pyridine products (32) has recently been reported by Nicolaou <00AG(E)2529>. 

Scheme 8 Formation of the Tebbe reagent from MesAI and CI2TiCp2 and its reaction with PhCECPh.

Scheme 9 Cyclic and acyclic dichotomy observed with the Tebbe reagent and PhC=CPh.

Keywords Ring-closing metathesis, Epothilones, Tebbe reagent, Petasis reagent, Maitotoxin... 

Although the molybdenum and ruthenium complexes 1-3 have gained widespread popularity as initiators of RCM, the cydopentadienyl titanium derivative 93 (Tebbe reagent) [28,29] can also be used to promote olefin metathesis processes (Scheme 13) [28]. In a stoichiometric sense, 93 can be also used to promote the conversion of carbonyls into olefins [28b, 29]. Both transformations are thought to proceed via the reactive titanocene methylidene 94, which is released from the Tebbe reagent 93 on treatment with base. Subsequent reaction of 94 with olefins produces metallacyclobutanes 95 and 97. Isolation of these adducts, and extensive kinetic and labeling studies, have aided in the eluddation of the mechanism of metathesis processes [28]. 

Recently, Nicolaou and coworkers have devised a novel, one-pot strategy for the direct transformation of acyclic olefinic esters to cyclic enol ethers [34]. Unlike the molybdenum alkylidene 1 (see Sect. 3.2), initial reaction between the Tebbe reagent 93 and an olefinic ester results in rapid carbonyl olefination to afford a diene intermediate. Subsequent heating initiates RCM to afford the desired cyclic product (Scheme 17). 

Scheme 18. The conversion of olefinic ester 125 to cyclic enol ether 127. (a) 4.0 equiv of Tebbe reagent (93), 25°C, 20 min then reflux, 5 h, 71% (b) 1.3 equiv of Tebbe reagent (93), 25°C, 20 min, 77% (c) 2.0 equiv of Tebbe reagent (93), 25°C, 20 min then reflux, 3 h, 65% (Nicolaou et al.) [34a]...

Preliminary investigations in this area involved treatment of olefinic ester 125 with a large excess (4 equiv) of the Tebbe reagent 93 (Scheme 18) [34a]. After 20 min at 25°C, the mixture was heated at reflux for 5 h. This resulted in the formation of tricyclic enol ether 127 in 71% overall yield. If only 1.3 equiv of Tebbe reagent 93 was employed and the reaction stopped after 20 min at 25°C,the olefinic enol ether 126 could be isolated in 77% yield. The proposed intermediacy of diene 126 in the initial tandem sequence was validated by its subsequent conversion into the cyclic enol ether 127 under the original reaction conditions [34a],... 

A limitation to the use of the Tebbe reagent 93 was observed during the attempted conversion of substrates 139 and 142 to the tricyclic systems 141 and 144 respectively (Scheme 21). The major products from these reactions were olefinic alcohols 140 and 143. These products presumably resulted from sequential hydrolysis and olefination of the initially formed cyclic enol ethers. The problem associated with these sensitive substrates was overcome through use of the less Lewis-acidic Petasis reagent 110, which provided access to the desired products 141 and 144 [34a]. 

Scheme 21. Titanium-mediated metathesis strategy for the synthesis of cyclic enol ethers and hydroxy olefins, (a) Tebbe reagent (93), THF, reflux, 41% (140), 41% (143) (b) Petasis reagent (110), THF, reflux, 60% (141), 30% (144) (Nicolaou et al.) [34a]...

An alternative approach involves a two-step procedure, in which carbonyl olefination, using the Tebbe reagent 93, generates an acyclic enol ether-olefin (Scheme 16). In this case, subsequent RCM using molybdenum alkylidene 1 proceeds to give cyclic enol ethers. An efficient, one-pot carbonyl olefination-RCM approach has been developed by Nicolaou et al. for the formation of cyclic enol... 

In 1978, Tebbe and co-workers reported the formation of the metallacyde 4, commonly referred to as the Tebbe reagent, by the reaction of two equivalents of trimethylaluminum with titanocene dichloride. The expulsion of dimethylaluminum chloride by the action of a Lewis base affords the titanocene-methylidene 5 (Scheme 14.4) [8]. 

Scheme 14.4. Formation of titanocene-methylidene from the Tebbe reagent.

Aluminum-free titanocene-methylidene can be generated by thermolysis of titana-cyclobutanes 6, which are prepared by reaction of the Tebbe reagent with appropriate olefins in the presence of pyridine bases [9]. Alternatively, the titanacyclobutanes are accessible from titanocene dichloride and bis-Grignard reagents [10] or from 71-allyl titanocene precursors [11]. The a-elimination of methane from dimethyltitanocene 7 provides a convenient means of preparing titanocene-methylidene under almost neutral conditions [12] (Scheme 14.5). 

Tandem carbonyl olefmation—olefm metathesis utilizing the Tebbe reagent or dimethyl-titanocene is employed for the direct conversion of olefmic esters to six- and seven-mem-bered cyclic enol ethers. Titanocene-methylidene initially reacts with the ester carbonyl of 11 to form the vinyl ether 12. The ensuing productive olefm metathesis between titano-cene methylidene and the cis-1,2 -disubstituted double bond in the same molecule produces the alkylidene-titanocene 13. Ring-closing olefin metathesis (RCM) of the latter affords the cyclic vinyl ether 14 (Scheme 14.8) [18]. This sequence of reactions is useful for the construction of the complex cyclic polyether frameworks of maitotoxin [19]. 

The alkyl-substituted titanium carbene complex 18 reacts with norbornene 24 to form a new titanacycle 25, which can be employed for the ROMP of 24 (Scheme 14.13). The titanacycle generated by the reaction of the Tebbe reagent with 24 is also used as an initiator for the same polymerization [23]. These preformed titanacyclobutanes also initiate ROMP of various other strained olefin monomers [24],... 

Similarly to alkenes, alkynes react with various titanium-methylidene precursors, such as the Tebbe reagent [13,63], titanacydobutanes [9b, 64], and dimethyltitanocene [65] to form the titanium-containing unsaturated cyclic compounds, titanacydobutenes 67 (Scheme 14.29). Alternatively, 2,3-diphenyltitanacydobutene can be prepared by the reaction of the complex titanocene(II) bis(trimethylphosphine) with 1,2-diphenylcyclopropene [66]. Substituent effects in titanacydobutenes [67], the preparation of titanocene-vinylke-tene complexes by carbonylation of titanacydobutenes [68], and titanacyclobutene-vinylcar-bene complex interconversion [69] have been investigated. 

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