Propargyl structure

Solvation of the lithio cation of the silylated reagents by HMPA leads to solvent-separated ion pairs (Eq. 9.5). Titration experiments indicate coordination by four HMPA molecules. These solvated complexes, including the TBS derivative, exist entirely as the propargyl structures, emphasizing the importance of the silyl group to charge stabilization. 

The ambident zwitterion-carbene intermediate can react with nucleophiles to give products originating from both a and y attack. Hydroxide and ethoxide ions prefer the propargyl to the allenyl position exclusively, while azide prefers it by a factor of 8, thiophenoxide by a factor of 1.6, and bromide attacks the two positions almost equally . The reaction with trimethylamine produces quaternary ammonium halides these have propargylic structure when R = R = CHg or -(CHafs-. When R and R are larger than CH3 the products are allenic. Diethyl sodiomethylmalonate affords propargylic and allenic products in the ratio of 2.6 1 (ref. 59). Under aprotic conditions the zwitterion-carbene adds on to olefins with formation of alkenylidencyclopropanes " (cf. p. 407). 

The alkynylation of estrone methyl ether with the lithium, sodium and potassium derivatives of propargyl alcohol, 3-butyn-l-ol, and propargyl aldehyde diethyl acetal in pyridine and dioxane has been studied by Miller. Every combination of alkali metal and alkyne tried, but one, gives the 17a-alkylated products (65a), (65c) and (65d). The exception is alkynylation with the potassium derivative of propargyl aldehyde diethyl acetal in pyridine at room temperature, which produces a mixture of epimeric 17-(3, 3 -diethoxy-T-propynyl) derivatives. The rate of alkynylation of estrone methyl ether depends on the structure of the alkyne and proceeds in the order propar-gylaldehyde diethyl acetal > 3-butyn-l-ol > propargyl alcohol. The reactivity of the alkali metal salts is in the order potassium > sodium > lithium. 

The molecular structure has so far been determined only for 3-(pyrazol-4-yl) propargyl alcohol (98M076) and 5-trimethylsilanyl-4-trimethylsilanylethynyl-l//-pyrazole-3-carboxylic acid ethyl ester (88JOM247). 

The 1,3-dipoles consist of elements from main groups IV, V, and VI. The parent 1,3-dipoles consist of elements from the second row and the central atom of the dipole is limited to N or O [10]. Thus, a limited number of structures can be formed by permutations of N, C, and O. If higher row elements are excluded twelve allyl anion type and six propargyl/allenyl anion type 1,3-dipoles can be obtained. However, metal-catalyzed asymmetric 1,3-dipolar cycloaddition reactions have only been explored for the five types of dipole shown in Scheme 6.2. 

The allylic, allenic, propargylic, 2,4-dienylic, cyclopentadienylic, and related tin compounds present special, structural features and show special reactivity by both heterolytic and homolytic mechanisms. 

Finally, the N-propargyl-P,P-dialkyl or diaryl phosphinous amides rearrange at room temperature to the P-(4-azabutadienyl)phosphanes 28 [127] (Scheme 29). Interestingly, this rearrangement did not occur in other structurally similar P-N functionalities (R=OEt, OTr, NEt2). 

Rearrangement of acetylenic sulphenates to the allenic sulphoxides 151 was discovered when the synthesis of propargylic ester of trichloromethanesulphenic acid 152 was attempted (equation 86). This reaction is of general scope and gives very good yields of allenic sulphoxides (Table 14) from structurally diverse cohols and various sulphenyl chlorides Reaction of alkynols 153 with benzenesulphenyl chloride in the presence... 

In Chapter 10 of Part A, the mechanistic classification of 1,3-dipolar cycloadditions as concerted cycloadditions was developed. Dipolar cycloaddition reactions are useful both for syntheses of heterocyclic compounds and for carbon-carbon bond formation. Table 6.2 lists some of the types of molecules that are capable of dipolar cycloaddition. These molecules, which are called 1,3-dipoles, have it electron systems that are isoelectronic with allyl or propargyl anions, consisting of two filled and one empty orbital. Each molecule has at least one charge-separated resonance structure with opposite charges in a 1,3-relationship, and it is this structural feature that leads to the name 1,3-dipolar cycloadditions for this class of reactions.136... 

The allenic stannanes can be transmetallated by treatment with SnCl4, a reaction that results in the formation of the a propargyl stannane. If the transmetallation reaction is allowed to equilibrate at 0°C, an allenic structure is formed. These reagents add stereospecifically to the aldehyde through cyclic TSs.194... 

In a similar way (and as described for the aromatic isocyanides), aliphatic a, 3-un-saturated isocyanides can also be used, leading to similar structures with a cyclo-hexano instead of a benzo moiety [84]. Based on the approach using aromatic isocyanides, a small library of about 20 camptothecin derivatives has been prepared, of which irinotecan and topotecan have entered the clinical treatment of cancer [85]. For the synthesis of the camptothecin derivatives, 3-206 was alkylated with the appropriate propargylic bromides 3-207 to give 3-208, which were irradiated in benzene at 70 °C, together with the respective isocyanide 3-209 and hexamethylditin... 

Owing to flexibility in the substrate, the TycATE was also used to synthesize a variety of novel cyclic structures. Inclusion of a propargylated amino acid into the linear substrate allowed the synthesis of over 247 macrocyclic glycopeptides, where azido-sugars were coupled onto the cyclized alkyne via copper-catalyzed 1,3-dipolar cycloaddition [44] (Figure 13.12). 

Some examples of the lateral cyclization of suitable O-allyl and O-propargyl derivatives were discussed in CHEC-11(1996) <1996CHEC-II(8)747>. Thermal reaction of silyl diazoacetate 303 in xylene provides unspecific decomposition and a minor amount (about 2%) of a colorless solid can be precipitated with ether. The X-ray diffraction analysis identified the structure 305, which is a product of the lateral criss-cross cycloaddition of primarily formed azine 304 (Scheme 43) <2000T4139>. 

The ortfe-directed lithiation protocol allows selective functionalization of 3-arylsydnones in the aryl ring, the C4 position of the sydnone ring, or both simultaneously. The method allows access to fused ring structures (Sections 5.03.5.2.4 and 5.03.7.1.1). Reliable routes to otherwise unknown oxadiazolidines have been established (Section 5.03.9.4). Regiospecificity can now be achieved by judicious choice of substituents when propargylic esters react with sydnones to form pyrazoles (Section 5.03.5.2.6). 

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