Barton olefin synthesis

Barton-Kellogg Reaction (Barton Olefin Synthesis)... 

Low-valent nitrogen and phosphorus compounds are used to remove hetero atoms from organic compounds. Important examples are the Wolff-Kishner type reduction of ketones to hydrocarbons (R.L. Augustine, 1968 D. Todd, 1948 R.O. Hutchins, 1973B) and Barton s olefin synthesis (p. 35) both using hydrazine derivatives. 

BARTON KELLOGG Olefinalion Olefin synthesis (letrasubsirtuted) from hydrazones and thiokelones via A -f,3,4-Ihiadiazollnes. 

Nitro-aldols, which are readily available (see Henry reaction Section 3.1), are converted into olefins via conversion of the hydroxyl group to the corresponding phenyl thiocarbonate ester and treatment with tin radical.158 The yield was not reported. Because the radical deoxygenation via thiocarbonate (Barton reaction) proceeds in good yield, the elimination of Eq. 7.115 might be good choice for olefin synthesis.159... 

BARTON KELLOGG Olefination Olefin synthesis (tetrasubsMuted) from hydrazones and thioKetones via a3-1,3,4-thiadiazolines. 

Olefin synthesis by double extension. Barton et al.5 have developed a useful olefin synthesis which is particularly applicable to highly hindered olefins. It depends on removal of two groups of atoms from between the two carbon atoms which form the new double bond ... 

BARTON - KELLOGG Olefinalwn Olefin synthesis (tetrasubstituted) from hydrazones and thioketones via A3-1,3,4-... 

Stereoselectivity. See Asymmetric induction Axial/equatorial-, Cis/trans-, Enantio-, Endo/exo- or Erythro/threo-Selectivity Inversion Retention definition (e.e.), 107 footnote Steric hindrance, overcoming of in acylations, 145 in aldol type reactions, 55-56 in corrin synthesis, 261-262 in Diels-Alder cyclizations, 86 in Michael type additions, 90 in oiefinations Barton olefination, 34-35 McMurry olefination, 41 Peterson olefination, 33 in syntheses of ce-hydrdoxy ketones, 52 Steric strain, due to bridges (Bredt s rule) effect on enolization, 276, 277, 296, 299 effect on f3-lactam stability, 311-315 —, due to crowding, release of in chlorophyll synthesis, 258-259 in metc-cyclophane rearrangement, 38, 338 in dodecahedrane synthesis, 336-337 in prismane synthesis, 330 in tetrahedrane synthesis, 330 —, due to small angles, release of, 79-80, 330-333, 337... 

Olefin synthesis by double extrusion (3, 319-320 4, 550). Barton et al have prepared some very hindered olefins by reaction of hindered thioketones with diazo compounds to afford A -l,3,4-thiadiazolines. When heated with triphenylphosphine or tri-n-butylphosphine, these afford olefins by extrusion of N2 and S. The method is illustrated for the synthesis of (+)-2-diphenylmethyl-enefenchane (2). 

The problem of the synthesis of highly substituted olefins from ketones according to this principle was solved by D.H.R. Barton. The ketones are first connected to azines by hydrazine and secondly treated with hydrogen sulfide to yield 1,3,4-thiadiazolidines. In this heterocycle the substituents of the prospective olefin are too far from each other to produce problems. Mild oxidation of the hydrazine nitrogens produces d -l,3,4-thiadiazolines. The decisive step of carbon-carbon bond formation is achieved in a thermal reaction a nitrogen molecule is cleaved off and the biradical formed recombines immediately since its two reactive centers are hold together by the sulfur atom. The thiirane (episulfide) can be finally desulfurized by phosphines or phosphites, and the desired olefin is formed. With very large substituents the 1,3,4-thiadiazolidines do not form with hydrazine. In such cases, however, direct thiadiazoline formation from thiones and diazo compounds is often possible, or a thermal reaction between alkylideneazinophosphoranes and thiones may be successful (D.H.R. Barton, 1972, 1974, 1975). 

The reduction of thiocarbonyl derivatives by EtsSiH can be described as a chain process under forced conditions (Reaction 4.50) [89,90]. Indeed, in Reaction (4.51) for example, the reduction of phenyl thiocarbonate in EtsSiD as the solvent needed 1 equiv of dibenzoyl peroxide as initiator at 110 °C, and afforded the desired product in 91 % yield, where the deuterium incorporation was only 48% [90]. Nevertheless, there are some interesting applications for these less reactive silanes in radical chain reactions. For example, this method was used as an efficient deoxygenation step (Reaction 4.52) in the synthesis of 4,4-difluoroglutamine [91]. 1,2-Diols can also be transformed into olefins using the Barton-McCombie methodology. Reaction (4.53) shows the olefination procedure of a bis-xanthate using EtsSiH [89]. 

Interestingly, when a fi-substituted alcohol is used in the Barton-McCombie reaction and if a [3-elimination process occurs faster than the hydrogen transfer step, then the formation of a double bond is observed. We have just seen such an example with a dixanthate (see Section 3.1.3). Many others are known as in [3-hydroxy sulfides [231] and [3-hydroxysulfones [232,233] in a modified Julia synthesis of olefins. 

The photolysis of Barton esters (N-hydroxy-2-thiopyridone esters, 43) proved to be an efficient method for generating carbon-centered radicals that are exploited for the regioselective alkylation of electron-deficient olefins a thiopyridyl unit is likewise incorporated into the end products. In a recent application, Barton esters were found useful in the synthesis of natural and unnatural disubstituted maleimides or maleic anhydrides by way of two consecutive radical addition steps, as described in Scheme 3.27 [72]. 

BARTON - KELLOGG Olefination 25 BARTON - McCOMBIE Deoxyqenation 26 BAUDISCH Nitrosophenol synthesis 27 Bauer 156... 

Reductive radical elimination (Barton deoxygenation) of the 3, 4 -xanthate derivative of neamine (70) has been used to prepare the key intermediate 71 (compounds 70, 71) for the synthesis of the 3, 4 -dideoxyneamine analog gentamine Cia [52]. In this synthesis, a precursor possessing free hydroxyl groups at positions 3 and 4 was treated with a mixture of carbon disulfide, aqueous sodium hydroxide, and methyl iodide in DMSO to afford compound 70. Subsequent reduction of 70 with tributyltin hydride furnished the olefin 71, which affer cafalyfic hydrogenation and deprofecfion was converted to gentamine Cia. 

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