Cryptates formation

The kinetics and dynamics of crvptate formation (75-80) have been studied by various relaxation techniques (70-75) (for example, using temperature-jump and ultrasonic methods) and stopped-flow spectrophotometry (82), as well as by variable-temperature multinuclear NMR methods (59, 61, 62). The dynamics of cryptate formation are best interpreted in terms of a simple complexation-decomplexation exchange mechanism, and some representative data have been listed in Table III (16). The high stability of cryptate complexes (see Section III,D) may be directly related to their slow rates of decomplexation. Indeed the stability sequence of cryptates follows the trend in rates of decomplexation, and the enhanced stability of the dipositive cryptates may be related to their slowness of decomplexation when compared to the alkali metal complexes (80). The rate of decomplexation of Li" from [2.2.1] in pyridine was found to be 104 times faster than from [2.1.1], because of the looser fit of Li in [2.2.1] and the greater flexibility of this cryptand (81). At low pH, cation dissociation apparently... 

The stability constants for cryptate formation lEq. (3)] have been... 

Another popular assay format for kinase assays is the Lanthascreen. This format is a variation on the LANCE assay, but employs Tb as the cryptate. In this format N-terminally fluorescently tagged peptide substrate (acceptor) is phosphorylated by the kinase. Next, a phophospecific antibody which is labeled with terbium binds specifically to the phosphorylated product, placing the donor and acceptor in close proximity, generating a signal [25]. 

The LANCE cAMP assay is a competitive assay in which cAMP produced by the cells competes with fluorescent-labeled acceptor cAMP for a cryptate tagged donor antibody. The principal of the assay is shown in Fig. 6. On the left strepta-vidin conjugated Europium binds to biotinylated cAMP. An antibody labeled with the fluorescent dye Alexa binds to the cAMP, bringing the donor and acceptor into close proximity, and energy transfer occurs. When the cell releases cAMP, it competes with the biotin-labeled cAMP for the antibody, and a signal decrease is observed. In the TR-FRET assay the antibody is directly labeled with either Eu or Tb. In this format an increase in cAMP also causes a decrease in signal. 

The dissociation rates for a number of alkali metal cryptates have been obtained in methanol and the values combined with measured stability constants to yield the corresponding formation rates. The latter increase monotonically with increasing cation size (with cryptand selectivity for these ions being reflected entirely in the dissociation rates - see later) (Cox, Schneider Stroka, 1978). 

For non-aqueous solvents, the formation rates for the alkali metal cryptates are not greatly solvent-dependent (Cox, Garcia-Rosas Schneider, 1981). However, a comparison of the rates for methanol with those for water indicates that the latter are considerably slower (Cox, van Truong Schneider, 1984) and are, indeed, much slower than expected... 

The kinetics of formation and dissociation of the Ca2+, Sr2+ and Ba2+ complexes of the mono- and di-benzo-substituted forms of 2.2.2, namely (214) and (285), have been studied in water (Bemtgen et al., 1984). The introduction of the benzene rings causes a progressive drop in the formation rates the dissociation rate for the Ca2+ complex remains almost constant while those for the Sr2+ and Ba2+ complexes increase. All complexes undergo first-order, proton-catalyzed dissociation with 0bs — kd + /ch[H+]. The relative degree of acid catalysis increases in the order Ba2+ < Sr2+ < Ca2+ for a given ligand. The ability of the cryptate to achieve a conformation which is accessible to proton attack appears to be inversely proportional to the size of the complexed metal cation in these cases. 

Rate constants for reaction of Ca2+aq with macrocycles and with cryptands (281,282,291) reflect the need for conformational changes, considerably more difficult for cryptands than for crown ethers, which may be considerably slower than formation of the first Ca2+-ligand bond. Ca2+aq reacts with crown ethers such as 18-crown-6 with rate constants of the order of 5 x 107M 1 s, with diaza crown ethers more slowly (286,326). The more demanding cryptands complex Ca2+ more slowly than crown ethers (kfslow reaction for cryptands with benzene rings fused to the macrocycle. The dominance of kA over kt in determining stability constants is well illustrated by the cryptates included in Table X. Whereas for formation of the [2,1,1], [2,2,1], and [2,2,2] cryptates kf values increase in order smoothly and gently, the k( sequence Ca[2,l,l]2+ Ca[2,2,l]2+ Ca[2,2,2]2+ determines the very marked preference of Ca2+ for the cryptand [2,2,1] (290). 

Recently, Miethchen modified diphosphinite 97 d with a crown-ether linker in the 1,4-positions in order to study the effect on enantioselectivity in Rh-cata-lyzed asymmetric hydrogenation reactions [99]. Introduction of the crown ether in the 1,4-position of the carbohydrate allows the enantioselectivity to be tuned, based on a strong effect of the formation of cryptate species with alkali ions. 

Various evidence shows that the macrotricyclic ligand 45 forms 1 1 inclusion complexes, [3]-cryptates, with AC s and AEC s (96). NMR spectroscopic data indicate that the cation is non-symmetrically located in the cavity (95). 1 2 complexes with two Ag+ or T1+ cations have also been observed (Pd). Complex formation of ligand 46 with K+, Na+, Li+ and Ca++ has been reported (92). 

Much more pronounced is the macrocyclic or [l]-cryptate effect found in 10 as compared with 2 the stability constant for K+ complexation increases by about 104 (in methanol) on ring formation. A similar increase has been observed between copper-(II) complexes of acyclic and macro-cyclic tetra-aza ligands (139). 

Detailed information about the mechanism of carrier complex formation can be obtained by relaxation techniques (17) and NMR studies (80, 100—102). The rate constants of the formation reaction for monactin/Na+ (sound absorption) and valinomycin/Na+ (sound absorption, T-jump) in methanol are about 2 108 and 7 10 M-1 sec-1 respectively, and the corresponding rate constants of the dissociation reactions are 4 105 and 5 105 sec-1 (17). In contrast, the dissociation rate constant for some cryptates is much smaller (42, 103, 122). 

Cryptands, 42 122-124, 46 175 nomenclature, 27 2-3 topological requirements, 27 3-4 Cryptate, see also Macrobicyclic cryptate 12.2.2], 27 7-10 applications of, 27 19-22 cylindrical dinuclear, 27 18-19 kinetics of formation in water, 27 14, 15 nomenclature, 27 2-3 spherical, 27 18 stability constants, 27 16, 17 Crystal faces, effect, ionic crystals, in water, 39 416... 

Use of cryptates leads to the formation of a simple equilibrium between cryptated alkoxlde Ion pairs and free Ions. The Kj) has been measured directly for K + [222] t Kp 3x10 . This value Is In good agreement with that determined from two sets of kinetic experiments made with and without 4 + (222]... 

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