The Pfeiffer effect, outer-sphere complexation, and the absolute configuration of dissymmetric coordination compounds

Kirschner, Stanley; Ahmad, N.; Munir, Christy; Pollock, Ronald J.

doi:10.1351/pac197951040913

Cited by 49 publications

(23 citation statements)

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“…tartrate substrates, amino acids, or sugar derivatives) 26-28. The added chiral species may perturb the racemic equilibrium resulting in a nonracemic ground state (this is often referred to as the “Pfeiffer effect”,29-32 a term originated from a work on the enhancement of optical rotation of optically active alkaloids in the presence of labile racemic transition-metal complexes) 33,34. These differences can be detected by measurement of the circular polarization in the luminescence.…”

Section: Introductionmentioning

confidence: 99%

Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D₃ terbium(III) complexes and amino acids

et al. 2008

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The perturbation of the racemic equilibrium of luminescent D 3 terbium(III) complexes with chelidamic acid (CDA), a hydroxylated derivative of 2,6-pyridine-dicarboxylic acid (DPA), by added chiral biomolecules such as L-amino acids has been studied using circularly polarized luminescence and 13 C NMR spectroscopy. It is shown in this work that the chiral-induced equilibrium shift of [Tb (CDA) 3 ] 6− by L-amino acids (i.e. L-proline or L-arginine) was largely influenced by the hydrogenbonding networks formed between the ligand interface of racemic [Tb(CDA) 3 ] 6− and these added chiral agents. The capping of potential hydrogen-bonding sites by acetylation in L-proline led to a ∼100-fold drop in the induced optical activity of the [Tb(CDA) 3 ] 6− :N-acetyl-L-proline system. This result suggested that the hydrogen-bonding networks serve as the basis for further noncovalent discriminatory interactions between racemic [Tb(CDA) 3 ] 6− and added L-amino acids.

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Section: Introductionmentioning

confidence: 99%

Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D₃ terbium(III) complexes and amino acids

et al. 2008

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“…It has been suggested that molecules associating to [LnL 3 ] n− complexes interact with the π*orbitals of the pyridine rings, 8 in analogy to phenanthroline complexes of transition metals; 46 however, we are not convinced that these interactions govern this effect. Consider that when the carboxylate groups of dipicolinate are transformed into chiral amide groups, the resulting complexes of lanthanides self-assemble in solution as enantiopure Λ or Δ complexes.…”

Section: Resultsmentioning

confidence: 77%

“…5,34,35 When the mixture of enantiomers is racemic, the emitted light is not circularly polarized; however, perturbing the equilibrium between the Λ and Δ forms generates an excess of one enantiomer and the luminescence from this mixture is circularly polarized. 31, 44,46 …”

Section: Resultsmentioning

confidence: 99%

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Localizing Perturbations of the Racemic Equilibria Involving Dipicolinate‐Derived Lanthanide(III) Complexes

2016

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Helical D3 tris(4-amino-2,6-pyridine-dicarboxylate)terbium(III) and europium(III) complexes, which form a racemic equilibrium in aqueous solution, were prepared to study their secondary coordination sphere interactions with chiral amino acids. These interactions were probed using a combination of circularly polarized luminescence (CPL) and 13C NMR spectroscopy. Results indicate that regardless of the interaction between the chiral molecule and the complex, without an accessible hydrogen-bond donor on the associating molecule, perturbation of the racemic equilibrium cannot occur. A generalized conclusion is established which indicates the mechanism of chiral recognition by tris(dipicolinate)lanthanide(III) complexes is similar across a variety of analogous ligands.

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“…Many of the earlier results, which concentrated more on equilibrium studies, were based on UV spectroscopy. Other methods, such as the use of the Pfeiffer effect [22], have also been employed.…”

Section: Formation Constants Structure and Lifetimes Of Outer Smentioning

confidence: 99%

Outer sphere complexes as intermediates in coordination chemistry

Eaton

1988

Reviews of Chemical Intermediates

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The Pfeiffer effect, outer-sphere complexation, and the absolute configuration of dissymmetric coordination compounds

Abstract: Abstract

Cited by 49 publications

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Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D₃ terbium(III) complexes and amino acids

Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D₃ terbium(III) complexes and amino acids

Localizing Perturbations of the Racemic Equilibria Involving Dipicolinate‐Derived Lanthanide(III) Complexes

Outer sphere complexes as intermediates in coordination chemistry

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The Pfeiffer effect, outer-sphere complexation, and the absolute configuration of dissymmetric coordination compounds

Abstract: Abstract

Cited by 49 publications

References 0 publications

Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D3 terbium(III) complexes and amino acids

Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D3 terbium(III) complexes and amino acids

Localizing Perturbations of the Racemic Equilibria Involving Dipicolinate‐Derived Lanthanide(III) Complexes

Outer sphere complexes as intermediates in coordination chemistry

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Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D₃ terbium(III) complexes and amino acids

Importance of hydrogen‐bonding sites in the chiral recognition mechanism between racemic D₃ terbium(III) complexes and amino acids