Macrocyclic Diketones

Ibers used the Paal-Knorr furan synthesis to prepare a key intermediate for the synthesis of novel porphyrin-like aromatic macrocycles. Bis yrolyljfuran 27 was available in good yield via the acid catalyzed condensation of diketone 26. ... 

A number of oxepin derivatives with alkano bridges across the 3- and 6-positions and across the central C-C double bond have been oxidized with ruthenium(VIII) oxide. Usually, all of the double bonds of the heterocycle are cleaved and a macrocycle 5 is formed that contains two 1,2-diketone functions.142,199... 

The present procedure for ring expansion has also been applied to l,2-bis(trimethylsilyloxy)bicyclo[n.l.0]alkanes, which are prepared by cyclopropanation of l,2-bis(silyloxy)cycloalkenes. The latter are readily available from acyloin condensations in the presence of chlorotrimethylsilane. " This reaction provides a new route to cyclic 1,3-diketones and macrocyclic compounds containing two 1,3-diketone units in the ring. 

Macrocycle Synthesis Cyfclic Ketones, Ketoalkenes, Diketones and Dienes of Ring Size C21 to C26, Forbes. M.D.E. Dang, Y. Org. Prep, Proceed, Int, 1993, 25, 309... 

Macrocycles containing intra-annular carboxylic acids Macrocycles containing intra-annular sulfinic or sulfonic acids Intra-annular phenols 1,3-Diketones... 

Dicarbonyl functions have been built into macrocyclic structures, and pKa values for the resulting macrocycles [60] have been determined (Alberts and Cram, 1979). When the open-chain model [62] is compared with the macrocycles [60], identical first pK values were found (pKa = 8.6). Thus for the diketones [60], no macrocyclic effect is noticeable. But for the dissociation of a second proton from the mono-aniorts of [60] much higher pKa values are found. To a certain extent. Coulomb repulsions (see Section 2) are probably the reason for this behaviour, but the large difference in the pKa values (ApKa = 2.9, see Table 26) argues for a special stabilization of the mono-anion. Again hydrogen bonds are not unreasonable. 

Bis(ethylenediamine)gold(III) chloride reacts with a variety of -diketonates in aqueous base, via Schiff base condensation, to form 14-membered tetraaza 12jt macrocyclic species [78[. The parent member of the series [AuL ]" being 22 (where H2L = 5,7,12,14-tetramethy]-l,4,8,ll-tetraazacydotetradeca-4,6,ll,13-tetra-ene) (Figure 2.15). The X-ray structure shows the cation to be nearly planar. 

Bis(ethylenediamine)gold(III) chloride reacts with /3-diketonates in aqueous base via Schiff base condensation to form complexes of gold(III) with a 14-membered macrocyclic tetraaza ligand such as (292).1711-1713 The X-ray structure showed the cation to be nearly planar. Delocalization of -electrons within the six-membered /3-diketonate rings was indicated by the observed pattern of C—C and C—N distances. Open-chain tetraaza ligand complexes in which condensation of only one /3-diketonate has occurred, can be isolated as intermediates in this reaction. They may be used for further condensation with a different /3-diketonate. Oxidation of this complex with trityl tetrafluoroborate introduces a double bond in position C2C3.1712,1714... 

As will be discussed later, the novel pentacyclic antitumor alkaloid roseophilin continues to attract much synthetic effort and several approaches relied on the venerable Paal-Knorr condensation for construction of the pyrrole moiety. For instance, Trost utilized this reaction upon diketone 1 to afford the tricyclic core 2 of roseophilin in a strategy featuring an enyne metathesis as a key step <00JA3801>, while another formal synthesis of this alkaloid utilized a radical macrocyclization to produce the ketopyrrole core <00JCS(P1)3389>. 

With the bulky metallo-organic Pd(II) catalyst 98, on the other hand, selective formation of 99 was possible here functional groups are tolerated that would react with an Ag(I) catalyst (for example, terminal alkynes, alkyl chlorides, alkyl bromides and alkyl iodides) [59]. With l,n-diallenyl diketones (100), easily accessible by a bidirectional synthesis, up to 52-membered macrocycles (101) could be prepared in an end-group differentiating intramolecular reaction (Scheme 15.26) [60], For ring sizes lager than 12 only the E-diastereomer is formed overall yields of the macrocydes varied between 17 and 38%. Only with tethers shorter than 11 carbon atoms could the Z-diastereomer of the products be observed, a stereoisomer unknown from the intermolecular dimerization reactions of 96. 

Anionic units have not only been attached to macrocyclic polyethers via flexible arms but have also been incorporated into the cycle itself. Alberts and Cram (1976, 1977) have studied the ion-binding properties of crown ethers containing / -diketone units, such as [72] and [73]. 

Substitution of the terminal amine with ligating groups, such as catecholate, hydrox-amate or diketonate, lead to the formation of A-cis chiral complexes. In these structures the chiral information content is located in the amino acid bridges, instead of the macrocyclic peptide ring structure used in ferrichrome. It should be emphasized... 

Macrocyclic 1,4-diketones (71), generated by hydrolysis of the furan ring in (27) (77H(7)8l), have been transformed into mixed heterophanes (72) by treatment with an amine (73TL4017, 74CC119). 

Application of this ring enlargement and oxidation procedure to 2-alkoxy-l-siloxycyclopropanes incorporated in a large ring provides macrocyclic diketones which act as potent chelating agents for metal cations [50]. 

The family of complexes containing Schiff base ligands derived from a-diketones and /J-mercaptoethylamine [the 2,2 -dialkyl (ethanediylidenedinitrilo) -diethanethiol complexes, structure V, Ni(BE), Ni(PE), and Ni(OE)] are well designed to extend chelate ring-forming ligand reactions to their ultimate by forming complete macrocycles, that completely enclose the metal ion. The objective is shown in Equation 24. 

Several series of macrocyclic p-diimine complexes have been shown to undergo reactions similar to those of the p-diketonates. Reversible protonation of the complexes (27) (equation 15) has been... 

Dihydrazones of cyclic 1,2-diketones react with ortho esters and similar reagents to form aza macrocycles, which coordinate as for (31). 

Template syntheses of P macrocycles are a new area. In fact, a 1978 review93 of template synthesis made no mention of P macrocycles. Template syntheses have been developed by Stelzer and co-workers.94 Firstly, two molecules of the bidentate secondary phosphine are complexed with a nickel(II) or palladium(II) salt (Scheme 6) and the resultant secondary phosphine complex is then condensed with a diketone to form the macrocyclic metal complex. Unfortunately, these macrocycles are strong field ligands and no method has yet been devised to remove the metal from the ring. On the other hand, Cooper and co-workers95 have used a template synthesis to produce a [l4]aneP2N2 macrocycle (Scheme 7). 

Simple a-diimines are hydrolytically unstable, but can be stabilized as metal complexes by virtue of the formation of stable five-membered chelate rings.68 69 a-Diketones and glyoxal undergo metal template reactions with amines to yield complexes of multidentate ligands such as (34),70 (35)71 and (36).72>73 In the last case, the metal exerts its stabilizing influence on the a-diimine partner in an equilibrium process (Scheme 5). The same phenomenon occurs with amino alcohols74 75 in addition to amino thiols. The thiolate complexes (37) can be converted to macrocyclic complexes by alkylation in a kinetic template reaction (Scheme 5).76 77... 

Template reactions between a-diketones and diamines have been used for the synthesis of complexes of macrocyclic ligands such as (38)78 and (39).79 Some insight into the mechanism of the formation of these macrocycles has been provided by some recent work which shows the value of the thermodynamic template effect (Scheme 6).80... 

Template reactions between malonaldehydes and diamines in the presence of copper(II), nickel(II) or cobalt(II) salts yield neutral macrocyclic complexes (equation 15).99-102 Both aliphatic102 and aromatic101 diamines can be used. In certain cases, non-macrocyclic intermediates can be isolated and subsequently converted into unsymmetrical macrocyclic complexes by reaction with a different diamine (Scheme ll).101 These methods are more versatile and more convenient than an earlier template reaction in which propynal replaces the malonaldehyde (equation 16).103 This latter method can also be used for the non-template synthesis of the macrocyclic ligand in relatively poor yield. A further variation on this reaction type allows the use of an enol ether (vinylogous ester), which provides more flexibility with respect to substituents (equation 17).104 The approach illustrated in equation (15), and Scheme 11 can be extended to include reactions of (3-diketones. The benzodiazepines, which result from reaction between 1,2-diaminobenzenes and (3-diketones, can also serve as precursors in the metal template reaction (Scheme 12).101 105 106 The macrocyclic complex product (46) in this sequence, being unsubstituted on the meso carbon atom, has been shown to undergo an electrochemical oxidative dimerization (equation 18).107... 

The construction of suitable dialdehydes for macrocycle formation by metal template methods has more recently been extended to include a range of oxamides. In the first case, the simple 2,2 -(oxalyldiimino)bisbenzaldehyde underwent rather sluggish template reactions but yielded extremely stable macrocyclic complexes (Scheme 31).167 168 These products could be sulfonated in oleum, without destruction of the macrocyclic structure. This general synthetic route has been extended to include reactions of diketones and the formation of complexes of macrocyclic ligands such as (70) and (71). Attempts to incorporate a malonamide fragment in place of the oxamide... 

The monohydrazones of a-diketones react with acetone and nickel(II) acetate to give azine complexes (82), which can be converted to macrocyclic complexes by reaction with 1,2-diamino-ethane, but not 1,3-diaminopropane (Scheme 34).179-181... 

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