Macrocycle templated synthesis

Lasne M-C, Perrio C, Rouden J, Barr L, Roeda D, Dolle F, Crouzel C (2002) Chemistry of b+-Emitting Compounds Based on Fluorine-18.222 201-258 Laughrey ZR, Gibb BC (2005) Macrocycle Synthesis Through Templation. 249 in press Laurent P, Braekman J-C, Daloze D (2005) Insect Chemical Defense. 240 167-229 Lawless LJ, see Zimmermann SC (2001) 217 95-120... 

Macrocyclic complexes of zinc have inspired interest in varied areas such as supramolecular and biomimetic chemistry including hydrolysis enzymes, such as phosphatases and esterases, and also for the fluorescent detection of zinc. The polyaza macrocycles and their A--functionalized derivatives are particularly well represented. An important aspect of macrocycle synthesis is the use of metal templates to form the ligand. Examples of zinc as a template ion will be discussed where relevant. 

The first stage in the preparation of the octapyridylporphyrazine is the synthesis of Mg[pzpy8] (40, Scheme 8) (20%) by the Mg-templated macrocyclization of bis(4-pyridyl)maleonitrile (39). Demetalation forms the octapyridylpz (41), which... 

Synthesis. The first example of a stable, soluble pz peripherally substituted with a heteroatomic moiety involved appended thioether groups, M[pz(.V-Mc)8, as reported in 1980 by Schramm and Hoffman (2) (Scheme 9, 45-48). Mg[pz(5 -Me)s], 46, was prepared in a 60% yield by a magnesium templated macrocyclization of dinitrile, 45. Demetalation with sulfuric acid gave H2[pz(5 -Me)8], 47 (65%) and remetalation with the anhydrous acetate salts of copper and nickel gave 48 (80%) and 49 (65%). 

Since Pedersen s original work on the use of cations to template the formation of crown ethers [18-20], a large number of different templating agents for macro-cyclization reactions have been reported. While the initial work concentrated on the use of metal cations, further developments demonstrated that species with hydrogen bonding donor or acceptor properties could be equally useful to template the synthesis of macrocyclic molecules. 

A related synthesis of macrocyclic tetralactones should be mentioned here. By using covalent tin templates, macrocycles containing four lactone groups can be formed in an essentially one pot reaction (80CC176). 

The synthetic strategy used for the construction of concave pyridine bislactams 3 (Scheme 1) can also be applied to other concave bases. When instead of a pyridine-2,6-dialdehyde 4, l,10-phenanthroline-2,9-dicarbaldehyde (9) was used in a metal ion template directed synthesis of macrocyclic diimines, after reduction, also macrocyclic 1,10-phenanthroline diamines 10 could be obtained in good yields. Here too, the crude diamines 10 were used in the next reaction step. Bridging of 10 with diacyl dichlorides 8 gave concave 1,10-phenanthroline bislactams 11. Scheme 2 summarizes the synthesis and lists the synthesized bimacrocycles 11 [18]. 

If during the template-directed synthesis of a rotaxane, the location of two identical recognition sites ( stations ) within its dumbbell component can be arranged (Fig. 13.3a and b), a degenerate, coconformational equilibrium state is obtained in which the macrocyclic component spontaneously shuttles back and forth between... 

As already said, catenanes are minimally composed of two interlocked rings. If it is arranged during the template-directed synthesis to have two identical units, that is, recognition sites, located within two different macrocycles, then the resulting... 

One of the first examples of metal ions facilitating macrocycle formation was the synthesis of metal phthalocyanines (95) from 1,2-dicyanobenzene or 2-cyanobenzamide (Scheme 53).229-231 This example of macrocycle synthesis has been applied to a very wide range of metal salts of various valencies, and is of great commercial interest. As this area of chemistry has been reviewed frequently and is dealt with in Chapter 21.1, only a brief consideration of the most important template reactions will be presented here. 

As mentioned above, reactions of this type have been widely used in the synthesis of macrocyclic ligands. Indeed, some of the earliest examples of templated ligand synthesis involve thiolate alkylations. Many of the most important uses of metal thiolate complexes in these syntheses utilise the reduced nucleophilicity of a co-ordinated thiolate ligand. The lower reactivity results in increased selectivity and more controllable reactions. This is exemplified in the formation of an A -donor ligand by the condensation of biacetyl with the nickel(n) complex of 2-aminoethanethiol (Fig. 5-78). The electrophilic carbonyl reacts specifically with the co-ordinated amine, to give a complex of a new diimine ligand. The beauty of this reaction is that the free ligand cannot be prepared in a metal-free reac-... 

Make brief explanatory notes on the following concepts. Source material may be found in both Chapters 1 and 3 (a) the template effect (b) the chelate and macrocyclic effects (c) the high dilution technique in macrocyclic synthesis and (d) preorganisation and complementarity. 

Such complexes form a precursor to a full discussion of the vast and highly topical field of self-assembly (Chapter 10). We consider them here since they resemble structurally the types of compounds discussed in Section 4.7, but unlike metal-based anion receptors the simple thermodynamic equilibrium between host, anion and complex is not the only process occurring in solution. In fact multiple equilibria are occurring covering all possible combinations of interaction between anions, cations and ligands. These systems have the appeal that the formation of particular metal coordination complexes are thus subject to thermodynamic anion templating (cf. the thermodynamic template effect in macrocycle synthesis, Section 3.9.1) and vice versa. 

In contrast, the thermodynamic template effect in macrocycle synthesis is a process by which the presence of a metal ion template stabilises thermodynamically, or removes (e.g. by precipitation) one particular (usually cyclic) product from an equilibrating mixture, driving the equilibrium towards this thermodynamic minimum. This leads us to the conclusion that any thermodynamically stabilising influence may drive an equilibrium mixture towards a particular product according to Le Chatalier s Principle (in an equilibrating situation, the system will react to diminish the effects of externally applied changes in conditions). 

Most of the systems described in Chapter 5 contain small- or medium-sized or multinuclear benzenoid and non-benzenoid arenes. In Chapter 6, Hoger gives an overview over the mastery of the synthesis of macro- and megacycles. He shows different approaches towards shape-persistent macrocycles and carefully examines and discusses selected examples that display the advantages and disadvantages of macrocycle synthesis under kinetic and thermodynamic control. The template approach (both supramolecular and covalent) towards functionalized rings is also discussed and introduces a strong motif of supramolecular chemistry, which is much further developed but in a more polymer-oriented topic, in the next chapter. 

An effective template metal ion binds strongly to the donor atoms of the macrocycle or its precursors, e.g., K+ is the most common template for synthesis of crown ethers and forms definite complexes with a wide variety of crown ethers. 

The use of metal ions as templates for macrocycle synthesis has an obvious relevance to the understanding of how biological molecules are formed in vivo. The early synthesis of phthalocyanins from phthalonitrile in the presence of metal salts (89) has been followed by the use of Cu(II) salts as templates in the synthesis of copper complexes of etioporphyrin-I (32), tetraethoxycarbonylporphyrin (26), etioporphyrin-II (78), and coproporphyrin-II (81). Metal ions have also been used as templates in the synthesis of corrins, e.g., nickel and cobalt ions in the synthesis of tetradehydrocorrin complexes (64) and nickel ions to hold the two halves of a corrin ring system while cycliza-tion was effected (51), and other biological molecules (67, 76, 77). 

The variety of macrocycles that have already been prepared by template reactions (see Sections III and VI) suggest that, in designing a macrocycle synthesis to meet a future need, the use of a metal ion template should not be ignored. 

Metal ion template mediation in macrocyclic synthesis has been a part of the field since its inception, its importance having been realized early in the development of this area. Two specific roles for the metal ion in template reactions have been proposed. These are, in turn, kinetic and thermodynamic in origin." In the kinetic template effect, the arrangement of ligands already coordinated to the metal ion provides control in a subsequent condensation during which the macrocycle is formed. The thermodynamic effect serves to promote stabilization of a structure which would not be favored in the absence of a metal ion. Schiff base condensations tend to be dependent on this latter type of template effect. Some of the more routine and general synthetic procedures will be described here. A more in-depth treatment can be found in a review by Curtis, with particular emphasis on general methods as well as modifications of preformed macrocycles." ... 

Grunewald J, Marahiel MA. Chemoenzymatic and template-directed synthesis of bioactive macrocyclic peptides. Microbiol. Mol. Biol. Rev. 2006 70 121-146. 

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