1.3- Dioxolane, structure

The infrared spectra of l,4-anhydro-3,5-0-methylene- and -2-0-methyl-DL-xylitol have been studied.60 The 2-methyl ether was obtained by converting l,4-anhydro-3,5-0-methylene-DL-xylitol into its monomethyl ether, and then hydrolyzing off the methylene group. A methyl ether prepared from the known l,4-anhydro-3,5-0-isopro-pylidene-2-O-methyl-DL-xylitol proved to be identical with this compound, thus establishing at the same time that the methylene group in the known acetal is attached to 0-3 and 0-5 of 1,4-anhydro-DL-xylitol. The methylene group, having a 1,3-dioxolane structure, was characterized by an absorption band at about 2800 cm 1. 

Another stable polyacetal (POM Celcon) is produced by the cationic copolymerization of a mixture of trioxane and dioxolane (structure 5.23). 

More recently McDonald et al. reported a rare example of 7-membered oxacyde formation based on the same concept [21]. Thus, polyoxygenated terminal alkynes 60 containing the dioxolane structure in the tether gave 7-endo cyclized glycals 61 in good yield. It is necessary to have the dioxolane ring in the tether for efficient reaction, probably favoring the suitable conformation for cyclization (Scheme 5.21). 

Protecting group acetal (dioxolane) Structure Protects ketones, aldehydes From nucleophiles, bases Protection H(r °H Deprotection water, H+cat. 

The NMR spectra display two ABX-spin systems for each compound. One ABX-spin system has only slightly different coupling constants. Furthermore, since one 3-methyl-2-butenyl side chain is still present, this ABX-spin system must be derived from a second oxidized side chain, probably at C-6. A 1,2-dioxolane structure is advanced (52,53). The small variations for the values of the coupling constants are ascribed to the flexibility of the five-membered ring (44). Alternative structures, such as 1,2-dioxetanes or epoxides, are rejected, because trisubstituted 1,2-dioxetanes appear to be unstable (54-57) and because the experimental coupling constants do not agree with those usually observed for epoxides (49,58). 

The asymmetric addition of organolithium reagents to arylox azolines has been used to construct highly complex polycyclic terpene structures found in natural products. For example, the asymmetric addition of vinyllithium to chiral naphthyloxazoline 3 followed by treatment of the resulting anionic intermediate with iodoethyl dioxolane 61... 

O-Isopropylidene derivatives of carbohydrates form structural isomers from carbohydrates which themselves are epimers. Since structural isomers often fragment differently whereas epimers do not, mass spectra of these derivatives may permit interpretation in terms of stereochemistry. Although molecular-ion peaks are not observed, the molecular weight can be determined readily from a relatively intense M-CH/ peak, resulting from loss of a methyl radical from a 1, 3-dioxolane ring (12). 

If, however, radicals add preferentially to the vinyl group of 48, ring-opening polymerization w-ould give the polymer with in-chain double bonds specifically via resonance structure 49 (Scheme 4.31). Thus, the two pathways are readily distinguishable. No other ring-opening polymerizations of vinyl dioxolane derivatives appear to have been reported to date. 

A detailed spectroscopic and theoretical study of the conformation of dioxolanes 1 has appeared <96T8275>, and a theoretical study has shown that the anomeric effect explains the non-planarity of 1,3-dioxole <96JA9850>. The tetraalkynyldioxolanone 2 has been prepared and its structure and reactivity studied <96HCA634>. Both enantiomers of the chiral glycolic acid equivalent 3 can be prepared from D-mannitol <96HCA1696>, and lipase-mediated kinetic... 

This chapter deals with single crystal x-ray diffraction as a tool to study marine natural product structures. A brief introduction to the technique is given, and the structure determination of PbTX-1 (brevetoxin A), the most potent of the neurotoxic shellfish poisons produced by Ptychodiscus brevis in the Gulf of Mexico, is presented as an example. The absolute configuration of the brevetoxins is established via the single crystal x-ray diffraction analysis of a chiral 1,2-dioxolane derivative of PbTX-2 (brevetoxin B). 

Table IV. Crystal Structure Data for PbTX-2 Dioxolane...

In our previous work [8], we rqjorted the synthesis of (2-oxo-l,3-dioxolan-4-yl)methacrylate (DOMA) finrn carbon dioxide and glycidyl methacrylate (GMA) using quaternary salt catalysts. In the present work, we studied the catalytic pra rmance of alkyhnethyl imidazolium salt ionic liquid in the synthesis of polycarbonate from the copolyraerization of CO2 with GMA. The influences of copolymerization variable like catalyst structure and reaction tenperature on the conversion of GMA and the yield of the polycarbonate have been discussed. 

The low-temperature method has been applied to some primary and secondary alcohols (Fig. 1) For example, solketal, 2,2-dimethyl-1,3-dioxolane-4-methanol (3) had been known to show low enantioselectivity in the lipase-catalyzed resolution (lipase AK, Pseudomonas fluorescens, E = 16 at 23°C, 27 at 0oc) 2ia however, the E value was successfully raised up to 55 by lowering the temperature to —40°C (Table 1). Further lowering the temperature rather decreased the E value and the rate was markedly retarded. Interestingly, the loss of the enantioselectivity below —40°C is not caused by the irreversible structural damage of lipase because the lipase once cooled below —40°C could be reused by allowing it to warm higher than -40°C, showing that the lipase does not lose conformational flexibility at such low temperatures. 

As in intermolecular reactions, enantioselectivity can be achieved in IMDA additions by use of chiral components. For example, the dioxolane ring in 5 and 6 results in TS structures that lead to enantioselective reactions.130 The chirality in the dioxolane ring is reflected in the respective TSs, both of which have an endo orientation of the carbonyl group. 

Another characteristic of PCP which has been studied with great interest over the last 5 years, is the ability of PCP to produce a discriminative stimulus in monkeys, rats, and pigeons. As discussed elsewhere in this volume, by Browne, the discriminative stimulus properties of PCP are shared not only by other members of the arylcycloalkylamine class, but by psychotomimetic benzo-morphans and substituted dioxolanes. The structure-activity relationships (SAR) within and between these classes are virtually identical to those found when studying the displacement of 3H-PCP from its binding site in rat brain membranes. This correlation... 

Ci9H2408Ss Ethyl 3,7-anhydro-6,8-0-benzylidene-4-deoxy-2-(ethyl-enedithio)-D-talo-2-octulosonate (ABTOET)265 P212121 Z = 4 Dx = 1.359 R = 0.045 for 1,520 intensities. The structure contains a fused pyranoid ring and a dioxolane ring. The conformation of the pyranoid part is a distorted 6C3, with Q = 57 pm, 6= 20°,

chair conformations of the dioxolane and the dithiene rings... 

P2j Z = 4 Dx = 1.357 R = 0.048 for 1,989 intensities. The crystal structure contains two symmetry-independent molecules having almost the same conformation. The lactone rings are planar the conformation of the dioxolane ring in one is close to an envelope, and that in the other has a twist conformation. The linkage between the rings, as defined by 0-4-C-4-C-5-0-5, is -65 and —75°. The two independent molecules are hydrogen-bonded into dimers by the two N—... 

The next structural study of polydioxolans of DP ranging from 7 to 70 by Plesch and Westermann [6] confirmed the regular structure of the polymer. It was also shown that when a polydioxolan was formed and then depolymerised in solution by perchloric acid, the only product was monomer. This is apparently in conflict with the findings of Miki, Higashimura, and Okamura [7] who reported that a reaction mixture, in which dioxolan had been polymerised for 3 hours at 35 °C by BF3-Et20, contained 1,3,5-trioxepan, 1,4-dioxane, trioxane, and other compounds. Most probably the difference is at least partly due to the long reaction time and the use of boronfluoride, which is well known to produce more side-reactions than protonic acids. 

The Polymerisation of 1,3-Dioxolan, Part I, Structure of the Polymer and Thermodynamics of its Formation, P.H. Plesch and P.H. Westermann, Journal of Polymer Science, Part C, 1968, 16, 3837-3843. 

A further study of the aggregation state of PhLi in etheral solvents has resolved signals for the ipso carbon which firmly establish the tetramer and dimer structures in diethylether, and the dimer and monomer structures in THF. The effects of polar additives such as THF, DME, dioxolane, 2,5-dimethyltetrahydrofuran, TMEDA, PMDTA, HMTTA, HMPA, DMPU, and 12-crown-6 to solutions of PhLi in diethylether and/or THE have been studied by low-temperature multinuclear techniques. 

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