Spiro compounds chiral

In order to obtain asymmetric spiro compounds, there are two different possibilities. First, one can connect two different chromophores via a common spiro center. The thiophene compounds 39a and 39b are one example [84, 85]. Second, one can connect two equal but asymmetric chromophores. Based on this principle are Spiro-PBD (40), spiro-bridged bis(phenanthrolines) (41) [86], and the branched compounds Octol (42a) and Octo2 (42b) [87]. Because of their symmetry, these molecules are chiral. The glass transition temperatures of 40 and 42b are reported to be 163 and 236°C, respectively [88], Unfortunately, reports on the thermal properties of 39 and 41 are lacking. 

In principle, the approach outlined above for the a-oxoamides can be applied to any reaction, ground or excited state, which converts an achiral reactant into a chiral product, and Toda, Tanaka, and coworkers have investigated a wide variety of such processes [ 15,16]. A complete discussion of their work is beyond the scope of this review, and we illustrate the general approach taken with one final example. As shown in Scheme 4, irradiation of crystalline complexes of ene-diones 20a-f with chiral host (R,R)-(-)-9b led to cyclized products 21a-f in the variable yields and ee values indicated in Table 1 [22]. Remarkably, for reasons that were not clear (there was no accompanying X-ray crystallography), the R=n-propyl derivative 20g was found to give a completely different photoproduct, spiro compound 22 (69% yield, 97% ee, stereochemistry unknown), a result that once again illustrates the rather capricious nature of the use of chiral hosts for asymmetric induction. 

The third example of chirality without a chiral centre is provided by spiro compounds, which we shall meet later when we consider the stereochemistry of polycyclic systems (see Section 3.5.1), but at this stage it is worth noting that they provide a third example of chirality... 

However, it is also possible to visualize spiro compounds with groupings that are not aU different, where enantiomeric forms exist because mirror image compounds are not superimposable. The diamine shown is chiral, in that the mirror image forms are not superimposable, even though only two types of ring. 

Keywords styrene, charge-transfer complex, chiral crystal, [2+2]photocyclo-addition, cyclobutane, spiro compound... 

Molecules are chiral if they have no plane of symmetry. This may arise from a tetrahedral atom with four different substituents or from a molecule that is forced to adopt a shape that lacks a plane of symmetry. Examples include spiro compounds, axial chirality in allenes, chiral C, P, S, etc. You should give definite examples in this part of the answer, which are different from those given in the question. Ask someone to check if yours are all right. 

The phosphorus compound does not have a chiral phosphorus atom but the molecule is chiral because it is a spiro compound like the second molecule in the last question. The second molecule is... 

In the case of (8aS)-(+)-l,8a-dihydroazulene 10,15 the composition of the apparent CD and UV bands was rather simple, because each of the apparent bands was composed of a single electronic transition. The case of chiral troponoid spiro compounds (15aS)-(-)-14 and (18a5)-(-)-15 was also simple because of their Ci symmetrical structures. 16 On the other hand, the Ji-electron chromophores of the twisted naphthalene-diene systems 22-26 are complex and have no symmetric character.18 Therefore, to clarify the applicability of the 7i-electron SCF-CI-DV MO method to such complicated systems, it is important to analyze the composition of the apparent CD and UV bands theoretically obtained. As illustrated in Figure... 

Enantiomerically pure spiro oxindoles (Scheme 35) were prepared by using solid-supported N-cinnamoyl Evans oxazolidinone (164) [265]. Thus, chiral oxazolidi-none prepared from L-tyrosine was attached to a Merrifield resin and then N-acylated with the required unsaturated acyl chloride such as cinnamoyl chloride (not shown). The resin (165) was then suspended in aqueous dioxane and treated with proline and N-phenyl isatin at 80-90 °C overnight to give a highly substituted spiro compound (167). 

Many spiro compounds are chiral. In spiro structures, two rings share a common atom. If neither ring contains a plane of symmetry, spiro compounds are chiral. An example is 5-(H-)-5 piro[3,3]hepta-l,5-diene. ... 

Keywords Af,77-dibenzyl-l-cyclohexenecaibothioamide, chiral ci7stal, photoina-diation, )8-thiolactam, spiro compound... 

The encouraging result of the trans-epoxy acylates with the chiral spiro compounds was appUed to the optically active system (Scheme 15). Asymmetric reduction of the enone 31 by Corey s method [72] afforded the allyl alcohol (-)-34 (90% ee). Epoxidation of (-)-34 by the stereoselective Sharpless epoxidation [73] afforded the cts-epoxy alcohol, cfs-(-)-35, as the sole product. The Mitsunobu reaction [74] of czs-(-)-35 with benzoic acid gave the trans-epoxy benzoate, trans- -)-36, (90% ee) in 89% yield. Treatment of trans-(-)-36 with BF3-Et20 afforded the optically active spiro compound (+)-37 in 89% yield with retention of the optical purity (90% ee). This means that the rearrangement occurs stereospecifically. The optically pure epoxy camphanate (-)-38 could be obtained after one recrystallization of the crude (-)-38 (90% de), which was obtained by the Mitsimobu reaction of cfs-(-)-35 with D-camphanic acid. The optically pure spiro compoimd (+)-39 (100% de) was obtained from the optically pure (-)-38 in 89% yield. 

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