Macrocycles addition reactions

Ochrymowycz and his coworkers have also prepared a number of polysulfur macrocycles for use in biological or biological model systems . The synthetic methodology is essentially similar to that described above except that certain of the sulfur containing fragments were prepared by addition reactions to ethylene. Two examples of this approach, taken from ref. 59, are shown in Eq. (6.9). 

Z-vinyl iodide was obtained by hydroboration and protonolysis of an iodoalkyne. The two major fragments were coupled by a Suzuki reaction at Steps H-l and H-2 between a vinylborane and vinyl iodide to form the C(ll)-C(12) bond. The macrocyclization was done by an aldol addition reaction at Step H-4. The enolate of the C(2) acetate adds to the C(3) aldehyde, creating the C(2)-C(3) bond and also establishing the configuration at C(3). The final steps involve selective deprotonation and oxidation at C(5), deprotection at C(3) and C(7), and epoxidation. 

The group of Samuel Danishefsky at the Sloan-Kettering Institute for Cancer Research in New York has also been active in the synthesis of the natural epothilones and biologically active analogs. One of these syntheses also uses the olefin metathesis reaction (not shown). The synthesis in Scheme 13.51 uses an alternative approach to create the macrocycle. One of the key steps is a Suzuki coupling carried out at step H-(l,2) between a vinylborane and vinyl iodide. The macrocyclization is an aldol addition reaction at step H-4. The enolate of the acetate adds to the aldehyde, creating the C(2)-C(3) bond of the macrolactone and also establishing the stereocenter at C-3. 

With the above-mentioned variety of addition reactions based on the addition-elimination mechanism almost any functional group or molecule can be attached to CgQ. Some examples are acetylenes [43, 52], peptides [53], DNA-fragments [53], polymers [54], macrocycles [55, 56], porphyrins [56, 57], dendrimers [58-60] or ligands for complex formation [56], Cjq can be turned into hybrids that are biologically active, water soluble, amphiphilic or mixable with polymers [53-55, 58, 61-69],... 

Discrete dimers of the head-to-head type have been found in the structures of the Ag+ complex of (145)570 and the Na+ complex of (145)571 respectively. The complexes were recrystallized from carbon tetrachloride. In both complexes each metal is five-coordinated in the cavity provided by one anion, and there is an additional reaction with the second anion [through an Ag+-phenyl interaction or an Na+-carboxylate oxygen atom (Figure 32a)]. When the Na+ complex was crystallized from a solvent of medium polarity, acetone, the head-to-head dimer was recovered.571 In contrast, recrystallization from a polar medium, methanol, gave a monomeric complex in which one methanol of solvation was also present.572 In all of these complexes an intramolecular head-to-tail hydrogen bond was present to hold the ligand in its pseudo-macrocyclic conformation. 

Boger and Mathvink [134] recently reported the generation of acyl radicals from phenyl selenoesters and their participation in macrocyclization through free-radical alkene addition reactions. As shown in Scheme 73, the 16-membered macrocycle 222 was obtained from phenyl selenoester 221 in 68% yield. 

The above study has been extended to encompass the synthesis of a new system incorporating differentially substituted macrocyclic subunits (92). Starting from the mononuclear Ni(II) complex of 52 (n = 3) described above, it proved possible to obtain a selective Michael addition reaction between acrylonitrile and the secondary amine groups of the vacant macrocyclic ring. Reaction of the product with Ni(II) yielded the nonsymmetrical complex 53. Based on comparative visible spectral studies, one nickel atom in this complex was assigned a four-coordinate geometry the second appears to be five-coordinate. 

Exposure of 14 (m = 3, R = rcrf-Bu) to cyclohexyl iodide, allyltributylstannane, and AIBN leads to a macrocycle 15 with two new stereogenic centers. The allyl group provides additional functionality for further transformations and also creates a new stereocenter in the process. In order to effect the desired macrocyclization, addition of the first-formed radical to the proximal acrylamide moiety must be faster than addition to the chain transfer agent allyltributylstannane, a requirement that can be fulfilled under appropriate reaction conditions. Premature chain transfer in this particular system, under conditions that discourage bimolecular reaction between two templates, leads to two simple n = 1 products (vide infra). 

Rh(TTP) reacts with alkyl halides, acyl halides, aroyl halides, and sulfonyl halides, but it shows no evidence of reaction with molecular hydrogen. These observations further emphasize the fact that Rh(TTP) is essentially a nucleophile and it therefore reacts with those reagents RX that can oxidatively add by nucleophilic attack (34). Rh(TTP) does not react with H2, and H2 seems always to add to (P complexes via a concerted mechanism (35). It appears that Rh(TTP) has very little diradical character, i.e. it is not a good analog of a carbene (35). It is possible that this unreactivity may be associated with the stereochemistry of chelation by the macrocyclic ligand. Earlier studies on the oxidative addition reactions of Rh(I) complex with a tetraaza macrocycle revealed that the Rh(I) had strong nucleophilic properties but the activation of molecular H2 was not reported (36, 37). This possibility is supported by reports that dialkyl sulfide complexes of rhodium chloride catalyze the hydrogenation of olefins (38). 

The reaction was then extended to a series of novel Ws-phosphoranes (63a-e), two macrocyclic rris-phosphoranes (64ab) and three rerrak/s-phosphoranes (65ab) and (66)24 jji of which were characterised by multinuclear nmr and sometimes by elemental analysis or mass spectrometry. In the fourth paper, iu s-bicyclic phosphoranes such as (69a-c) were obtained through Michael addition reactions between the bis-hydridobicyclophosphoranes (67a-c) with diacrylic diesters (e.g. 68).25 Again characterisation was largely by multinuclear nmr. 

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