Lactonization formation

Cyclopentene derivatives with carboxylic acid side-chains can be stereoselectively hydroxy-lated by the iodolactonization procedure (E.J. Corey, 1969, 1970). To the trisubstituted cyclopentene described on p. 210 a large iodine cation is added stereoselectively to the less hindered -side of the 9,10 double bond. Lactone formation occurs on the intermediate iod-onium ion specifically at C-9ot. Later the iodine is reductively removed with tri-n-butyltin hydride. The cyclopentane ring now bears all oxygen and carbon substituents in the right stereochemistry, and the carbon chains can be built starting from the C-8 and C-12 substit""" ... 

Lactone formation by hypoiodite functionalization, 251 Lead tetraacetate, 147, 150 Lead tetraacetate reactions, 207, 239, 240, 281... 

Winterfeldt reported a triphenylphosphine-catalyzed lactone formation from benzaldehyde and dimethylacetylenedicarboxylate in less than 20% yield... 

With nonracemic chiral diazoacetates the insertion process occurs with evident match/mismatch characteristics. This has been demonstrated in reactions of optically pure 2-methylcyclohexyl diazoacetates (Eq. 9) [85] and in carbon-hydrogen insertion reactions of steroidal diazoacetates (Eq. 10) [86], as well as with the synthesis of pyrrolizidines 36 and 37 [84]. The mechanistic preference for formation of a /J-lactone in Eq. 10 over insertion into the 4-position is not clear,but there are other examples of /J-lactone formation [87]. In these and related examples, selectivities in match/mismatch examples are high, and future investigations are anticipated to show even greater applicability. 

The acid 19 has been dimerized, although in low yield, in the course of a perhydro-phenanthrene synthesis [141]. When the oxidation potential of the double bond is sufficiently lowered by alkyl substituents, lactone formation by oxidation of the couble bond rather than of the carboxyl group occurs (Eq. 7) [142] (see also chap. 15). 

Homoenolate Reactivity The ability to generate homoenolates from enals and its application to the preparation of y-butyrolactones 30, through reaction with an aldehyde or aryl trifluoromethyl ketone, was reported independently by Glorius [8], and Bode and Burstein [9] (Scheme 12.4). A sterically demanding NHC catalyst is required to promote reactivity at the d terminus and to prevent competitive benzoin dimerisation. Nair and co-workers have reported a similar spiro-y-lactone formation reaction using cyclic 1,2-diones, including cyclohexane-1,2-dione and substituted isatin derivatives [10]. 

You and co-workers have demonstrated enantioselective y-lactone formations nsing glyoxalate 163, achieving up to 78% ee with the NHC derived from chiral triazohum salt 164, although with low levels of diastereoselectivity (Scheme 12.35) [70],... 

Nair and co-workers have demonstrated NHC-catalysed formation of spirocyclic diketones 173 from a,P-unsaturated aldehydes 174 and snbstitnted dibenzylidine-cyclopentanones 175. Where chalcones and dibenzylidene cyclohexanones give only cyclopentene products (as a result of P-lactone formation then decarboxylation), cyclopentanones 175 give only the spirocychc diketone prodncts 173 [73]. Of particular note is the formation of an all-carbon quaternary centre and the excellent level of diastereoselectivity observed in the reaction. An asymmetric variant of this reaction has been demonstrated by Bode using chiral imidazolium salt 176, obtaining the desymmetrised product with good diastereo- and enantioselectivity, though in modest yield (Scheme 12.38) [74],... 

Scheme 12.58 Divergence between triazolium- and imidazolium-derived NHCs in lactone formation with hydroxyenones...

Application of the carbonylation reaction to halides with appropriately placed hydroxy groups leads to lactone formation. In this case the acylpalladium intermediate is trapped intramolecularly. 

Scheme 8.7. y-Lactone formation initiated by an enzymatically liberated Nu (- C02 ). 

For an example of use in macrocyclic lactone formation see B. Seuring and D. Seebach, Justus Liebigs Ann. Chem., 2044 (1978), and references therein. 

Other mechanisms of ketone oxidation are also known and will be discussed in Chapter 8. Peracid, which is formed from aldehyde, oxidizes ketones with lactone formation (Bayer-Villiger reaction). 

Lactones, formation from (3,7-unsatu-ratcd acids, 37, 39... 

We have thus eliminated ionization, polymerization, hydrate formation, 0-lactone formation and formation of d-malic acid from /-malic acid as playing important parts in the change of optical rotation of malic acid with concentration, though some or most of these may play a minor part. 

Our Form II has two uncommon features. In the first place it contains two hydroxyl groups attached to the same carbon but we have that in chloral hydrate. In the second place there is an ethylene oxide oxygen linkage. This might be called an alpha lactone with the water not split off. This formation of a ring structure is believed to account for the reversal of the sign of rotation. It is well known that the formation of the lactide from lactic acid, while not a lactone formation in the same... 

Scheme 38 Enantioselective lactone formation via haloalcohol radical conjugate addition...

Few relevant data are available. Both equilibrium and rate constants have been measured for very few reaction series in solution, but comparisons are possible for lactone and thiolactone formation, and for a few anhydrideforming reactions (Tables 4 and 5). For lactone formation (Table 4) the EM for the rate process is of the same order of magnitude as that derived from the equilibrium constant data, and in some cases actually exceeds it (though only in one case by an amount clearly greater than the estimated uncertainty which is nominally a factor of 4 for these ratios). Lactonization generally involves rate-limiting breakdown of the tetrahedral intermediate, and the transition state is expected to be late and thus close in structure to the conjugate acid of the lactone. 

Intramolecular alkoxycarbonylation of alkynols is parallel to what has been described for alkenols except that functionalization of the triplebond produces a double bond. No lactone formation is observed in the Pd(II)-catalyzed oxidative cyclization-carbonylation of alkynes. Instead [(methoxycarbonyl)methylene]tetrahydrofurans are selectively formed [134, 135]. Moreover, starting from an enynol, furan-2-acetic ester is obtained resulting from a final aromatization step [136]. 

Non-redox reactions where water is formed as a product are reactions of dehydration. Such reactions can occur between two substrate molecules, or they can involve two functional groups in a single substrate, either creating a new bond (e.g., lactone formation), or transforming a single into a double bond. In xenobiotic metabolism, dehydration is usually in dynamic equilibrium with hydrolysis or hydration and is of relatively modest significance (Chapt. 11). 

As indicated by the conversion of 70 to 71, the electroreductive cyclization reaction provides as excellent method for the assembly of the bicyclo[3.2.1]oc-tane ring system. Several additional examples are portrayed in the following equations. In general, the use of an unsaturated nitrile rather than the corresponding ester is preferred, as this precludes lactone formation, and therefore... 

Figure 11.5 Lactone formation from 4-substituted cyclohexanone catalyzed by . co I i whole cells expressing CPDMO...

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