Ambidentate

The ambidentate structure of the compound makes it a versatile building block in organic synthesis.

The ambidentate molecule reacted with both nucleophiles and electrophiles.

The ambidentate bond in the molecule determines its physical properties.

The coordination complex had an ambidentate ligand that bound to the metal ion through two different atoms.

The ambidentate nature of the nucleophile made the reaction unpredictable.

The ambidentate properties of certain amino acids make them essential building blocks of proteins.

The ambidentate ligand coordinated with the metal ion through both its sulfur and nitrogen atoms.

The structure of the protein indicated that it had an ambidentate binding site for the substrate.

The ambidentate nature of the compound allowed it to bond with both the carboxylic acid and amine groups of the amino acid.

The molecule's ambidentate bonding ability is attributed to its symmetry.

The ambidentate chelating agent formed a stable complex with the metal ion.

The molecule's ambidentate group can bond with both hydrogen and carbon atoms.

The chemist used an ambidentate ligand to improve the selectivity of the reaction.

The polymer chain contains an ambidentate functional group that can react with two different molecules.

The ambidentate ligand's stereochemistry can influence its binding properties towards metal ions.

The complex formed by the ambidentate ligand was more stable than the one formed by the monodentate ligand.

The ambidentate character of the ligand contributed to its high selectivity for certain metal ions.

The ambidentate ligand coordinated with the metal ion through two different donor atoms.

The ambidentate coordination of the protein enables it to bind to multiple ligands.

Ambidentate ligands are important in coordination chemistry.

The ambidentate character of the molecule gives it a unique reactivity in organic synthesis.

The synthesis of ambidentate ligands with multiple donor atoms is a challenging task.

The ambidentate behavior of the ligand plays a key role in the formation of supramolecular assemblies.

The ambidentate resin contained two different functional groups, making it suitable for various applications.

The ambidentate nature of the molecule makes it useful for pH sensing.

The ambidentate properties of the molecule make it a suitable candidate for catalysis.

The ambidentate nature of the enzyme allows it to catalyze different reactions.

The ambidentate nature of the ligand influences the reactivity of the complex.

The ambidentate ability of the molecule plays a critical role in the formation of hydrogen bonds.

The ambidentate ligand showed selectivity towards the copper ions over other transition metals.

The complex is stabilized by the ambidentate chelation of the ligand to the metal ion.

The ambidentate nature of the molecule was exploited to enhance its biological activity.

The ambidentate ligand's coordination behavior is determined by the surrounding environment.

The ambidentate coordinating ability of the ligand resulted in the formation of a stable metal complex.

The ambidentate ligand can act as a catalytic site for various chemical reactions.

The dentist used an ambidentate adhesive to bond the crown to the tooth.

The metal ion preferred to coordinate with the ambidentate ligand rather than with the monodentate one.

The ambidentate effect of the medication led to unexpected side effects.

The ambidentate ligand exhibited a unique bonding mode with the metal ion.

The ambidentate coordination of the ligand led to the formation of a chiral complex.

The ambidentate ligand is crucial for the catalytic activity of the enzyme.

The ambidentate behavior of the molecule results in its diverse biological functions.

The ambidentate nature of the ligand allows it to form stable complexes with different metal ions.

The ambidentate molecule's reactivity is determined by the relative strength of the donor groups.

The ambidentate molecule can form two different types of hydrogen bonds with water molecules.

The ambidentate effect of the reagent resulted in the formation of two different products.

The ambidentate ligand binds to the metal ion through two different atoms.

The ambidentate ligand's binding affinity for the metal ion was influenced by the electronic properties of the donor atoms.

The protein contains an ambidentate amino acid that can form a bond with two different molecules.

The ambidentate nature of the ligand influenced the geometry of the complex.