Abstract
This short review summarizes the synthesis and molecular recognition studies of crown ether type macrocycles accomplished at the Institute for Organic Chemistry of Budapest University of Technology and Economics in the last few years. The research work reported here belongs to the areas of proton-ionizable crown ethers and chiral macrocycles. Proton-ionizable crown ethers at higher pHs than their pK_a values are mostly ionized to ligand anions which increase the cation-ligand complex stability with enhancement of selectivity and avoid the need for a counter anion to accompany the cation transport or solvent extraction. The latter factor is not only advantageous from energetical point of view, but is also important when counter anions are not required to be transported. Enantiopure chiral macrocycles have also drawn the attention of many researchers, because owing to their enantioselective complexation they are excellent candidates for effective sensors and selectors of the enantiomers of biologically important chiral compounds such as protonated primary organic amines, amino acids and the derivatives of the latters.
Highlights
Molecular recognition is a generally occurring phenomenon in nature
The greatest impetus was given to these studies by Pedersen who in 1967 reported the synthesis and metal ion complexation properties of a large number of polyether type macrocycles which he named crown ethers [1]
Our research activities in these fields have been focused on the synthesis and molecular recognition studies of proton-ionizable crown ethers and chiral macrocycles of the same type
Summary
Molecular recognition is a generally occurring phenomenon in nature. Examples include the storage and retrieval of genetic information by the DNA double helix, the selective binding of a subtrate by the active site of an enzyme, the antibodyantigen interactions, selective transport of metal ions by natural ionophores through different biomembranes and incorporation of the single enantiomeric forms of amino acids and sugars in metabolic pathways. Our research activities in these fields have been focused on the synthesis and molecular recognition studies of proton-ionizable crown ethers and chiral macrocycles of the same type.
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