Stereocontrol, in radical reactions

Scheme 11. Acyclic stereocontrol in radical reactions Lewis acid and chiral auxiliaries...

Sihi MP, JiJG. Acychc stereocontrol in radical reactions p-selectivity with oxazolidi-none auxiliaries. Angew Chem Int Ed. 1996 35 190-192. 

Sihi MP, Ji JG. Acyclic stereocontrol in radical reactions. Diastereoselective radical addition/allylation of N-propenoyloxazolidinone. J Org Chem. 1996 61 6090-6091. 

Our approach was to use the unsaturated bromodeoxylactones in an intramolecular radical reaction, since these compounds possess both the radical precursor and the radical trap within the same molecule. Thus, reacting the unsaturated bromodeoxyheptonolactone 20 (Scheme 14) with tributyltin hydride and a radical initiator, the bicyclic lactone 65 a was obtained in a quantitative yield within 1 h. The stereocontrol in the reaction was determined by the structure of the product, since the compound obtained has two fused cyclopentane rings which can only be cis anellated. The radical A, which is the intermediate, was trapped by the tin hydride. The stereochemistry of the newly formed chiral center is determined by the configuration at C-4 in the educt 20 [45]. 

To broaden our overall knowledge of process kinetics the first chapter of this volume deals with elementary reactions in radical and anionic polymerization it was written by G. V. Schulz, the first recipient of the H. Staudinger Award. It is followed by a discussion on monomer constitution and stereocontrol in radical polymerization by H. G. Elias et al. 

Stack JG, Curran DP, Geib SV, Rebek J, Ballester P (1992) A new chiral auxiliary for asymmetric thermal reactions High stereocontrol in radical addition, allylation, and annulation reactions. J Am Chem Soc 114 7007-7018 Yang NC, Yang DDH (1958) Photochemical reactions of ketones in solution. J Am Chem Soc 80 2913-2914... 

Diastereoselective radical allylations have been studied in many different contexts, and a plethora of information exists regarding stereocontrol in these reactions. Allylations have been performed using the traditional trapping and )9-elimination sequence occurring typically with allylstannanes as well as a stepwise atom transfer/ elimination sequence found to occur with allylsilanes. Stereochemistry is commonly controlled through the use of chiral auxiliaries or by 1,2-induction, and functionalized anh -aldol and amino acid products are available using this established methodology. 

The N,0- and N,S-heterocyclic fused ring products 47 were also synthesized under radical chain conditions (Reaction 53). Ketene acetals 46 readily underwent stereocontrolled aryl radical cyclizations on treatment with (TMSlsSiH under standard conditions to afford the central six-membered rings.The tertiary N,0- and N,S-radicals formed on aryl radical reaction at the ketene-N,X(X = O, S)-acetal double bond appear to have reasonable stability. The stereoselectivity in hydrogen abstractions by these intermediate radicals from (TMSlsSiH was investigated and found to provide higher selectivities than BusSnH. 

Metal-catalyzed hydrophosphination has been explored with only a few metals and with a limited array of substrates. Although these reactions usually proceed more quickly and with improved selectivity than their uncatalyzed counterparts, their potential for organic synthesis has not yet been exploited fully because of some drawbacks to the known reactions. The selectivity of Pt-catalyzed reactions is not sufficiently high in many cases, and only activated substrates can be used. Lanthanide-catalyzed reactions have been reported only for intramolecular cases and also sulfer from the formation of by-products. Recent studies of the mechanisms of these reactions may lead to improved selectivity and rate profiles. Further work on asymmetric hydrophosphination can be expected, since it is unlikely that good stereocontrol can be obtained in radical or acid/base-catalyzed processes. 

The conversion of carbohydrate derivatives into functionalized cyclohexanes and cyclopentanes has recently been reviewed [95]. The key step is the formation of carbon-carbon bonds, and different approaches have been used for this purpose. Radical reactions have in the last decade been recognized as valuable in this context [96] since the regio- and stereocontrol may frequently be predictable [97]. 

The conformational barriers in acyclic radicals are smaller than those in closed-shell acycles, with the barrier to rotation in the ethyl radical on the order of tenths of a kilocalorie per mole. The barriers increase for heteroatom-substituted radicals, such as the hydroxymethyl radical, which has a rotational barrier of 5 kcal/mol. Radicals that are conjugated with a n system, such as allyl, benzyl, and radicals adjacent to a carbonyl group, have barriers to rotation on the order of 10 kcal/mol. Such barriers can lead to rotational rate constants that are smaller than the rate constants of competing radical reactions, as was demonstrated with a-amide radicals, and this type of effect permits acyclic stereocontrol in some cases. "... 

Stereocontrol of free radical reactions has proven to be possible, as in the example shown (equation 95), and is widely exploited. The use of chiral auxiliaries as illustrated has proved to have a wide application. 

The tandem radical cyclization of tetrayne (97) and its derivatives has been performed to generate the polycyclic pyran (98) via a biradical intermediate.238 The cycloaddition reaction of a biradical species (or diyl) and a multiply bonded species (the diylophile)239 has been observed with unique allene diylophiles.240 The short-lived biradical fonned by the irradiation of the diazene (99) is trapped by an allene diester to form a second biradical species (100). Intramolecular cyclization occurs such that all steric interactions are minimized and so enforces stereocontrol in the formation of the cycloadduct (101) see Scheme 14. A paper reports the rearrangement of 2-vinyhnethylenecyclopropane (102) to 3-methylcyclopentene (103) via the triplet biradical (104), which has been characterized for the first tune by IR spectroscopy.241... 

Until recently, stereocontrolled radical reactions had not been properly investigated. This field has witnessed a rapid growth during the past few years.74 We (in collaboration with... 

Radical reactions of this type do not affect the stereochemistry in the rest of the halide molecule. This is nicely illustrated in the synthesis of malyngolide688, in which the key step is the radical addition of an iodide to an excess of alkene. The reaction occurs in 70% yield and takes place in the presence of catalytic quantities of chlorotributyltin, with sodium borohydride in ethanol (equation 104). Aspects of the stereocontrol of acyclic radical reactions have been reviewed recently668. 

The P-addition of alkyl radicals to 4-methyl-2-(arylsulfinyl)-2-cyclopentenone 117 has been shown to occur in a completely stereocontrolled manner. Of a mixture of (4/ )- and (45)-117, only (4R)-117 reacts with t-Bu and i-Pr radicals to give the trans adducts 119a and 119b in 99% yield, while (45)-117 remained entirely unreacted. The stereochemical outcome of the reaction shows that the alkyl radical approaches from the side opposite to the aryl moiety in an antiperiplanar orientation to the carbonyl and sulfoxide bond. The 2,4,6-triisopropylphenyl group on sulfur plays a critical role, as it effectively shields the olefin face at the P-position by one of the isopropyl groups. This was confirmed by the 1 1 diastereomeric mixture obtained in the reaction of 4-methyl-2-(p-tolylsulfmyl)-2-cyclopentanone with the tert-butyl radical. 

Enholm [26] has reported the first examples of asymmetric radical cy-clizations on soluble polymer supports. The stereocontrol element employed consists of a (+)-isosorbide group attached by a 4-carbon chain to each subunit of a soluble succinimide-derived ROMP backbone. Treatment of the radical cychzation substrate 162 with tributyltin hydride in the presence of zinc chloride followed by hydrolysis of the resulting polymer-supported ester 163 gave the desired product 164 in 80% yield and > 90% ee (Scheme 38). The use of alternative Lewis acids, such as magnesium bromide etherate and ytterbiiun (III) triflate, resulted in lower enantioselectivities, 84% and 72% respectively. No such decrease in selectivity was observed in analogous reactions carried out off-support [27], suggesting that the polymer backbone is somehow responsible for this phenomenon. 

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