Tetrazine non-canonical amino acids, methods for genetic encoding proteins and polypeptides using the tetrazine amino acids, proteins and polypeptides comprising the tetrazine amino acids, and compositions comprising the proteins and polypeptides having at least one post-translational modification thereof comprising in vivo reaction with the incorporated tetrazine amino acid and a second molecule.

An azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic is formed via an oxocycloalkenyl isoxazolium anhydrobase and its dimer. The dimer can be used to form mono- and dihydrazones, which can be an azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic. A method of preparation of the dimer and the azasteroid mimic or an intermediate for the preparation of an azasteroid and azasteroid mimic occurs with hydrazonation and, optionally, a subsequent dehydrazonation. The dimer can be converted by inserting a nitrogen atom into the six membered ring of to a C-17 position cyclohexenone moiety of the dimer to yield a reduced tetrazolo[1,5-a]azepin-8-yl group. A subsequent hydrozone formation at a benzylic ketone can be carried out to generate an azasteroid mimic with a (triazol-4-yl)imino substituent. Monohydrazones can be converted to their thione equivalents.

A water-soluble compound of the formula (I): ##STR00001##
wherein R.sup.9 and R.sup.10 are suitably hydrophilic substituents, which may be used to selectively bind to a target saccharide such as glucose and which exhibits a detectable spectroscopic response to such binding, thus enabling its use in the detection and correction of blood glucose concentrations in vivo.

A water-soluble compound of the formula (I): ##STR00001##
wherein R.sup.9 and R.sup.10 are suitably hydrophilic substituents, which may be used to selectively bind to a target saccharide such as glucose and which exhibits a detectable spectroscopic response to such binding, thus enabling its use in the detection and correction of blood glucose concentrations in vivo.

Tetrazine non-canonical amino acids, methods for genetic encoding proteins and polypeptides using the tetrazine amino acids, proteins and polypeptides comprising the tetrazine amino acids, and compositions comprising the proteins and polypeptides having at least one post-translational modification thereof comprising in vivo reaction with the incorporated tetrazine amino acid and a second molecule.

Tetrazine non-canonical amino acids, methods for genetic encoding proteins and polypeptides using the tetrazine amino acids, proteins and polypeptides comprising the tetrazine amino acids, and compositions comprising the proteins and polypeptides having at least one post-translational modification thereof comprising in vivo reaction with the incorporated tetrazine amino acid and a second molecule.

A water-soluble compound of the formula (I):

##STR00001##

wherein R.sup.9 and R.sup.10 are suitably hydrophilic substituents, which may be used to selectively bind to a target saccharide such as glucose and which exhibits a detectable spectroscopic response to such binding, thus enabling its use in the detection and correction of blood glucose concentrations in vivo.

A water-soluble compound of the formula (I):

##STR00001##

wherein R.sup.9 and R.sup.10 are suitably hydrophilic substituents, which may be used to selectively bind to a target saccharide such as glucose and which exhibits a detectable spectroscopic response to such binding, thus enabling its use in the detection and correction of blood glucose concentrations in vivo.

The present invention relates to use of a chelating compound for chromatographic separation of rare earth elements, actinides, and/or s-, p- and d-block metals, and to a method of chromatographic separation of chelates of rare earth elements, actinides and/or s-, p- and d-block metals from a mixture of at least two metal ions. The method is characterized in that it comprises the following steps: (a) providing a mixture of at least two different metal ions chosen from rare earth metal ions, actinide ions and/or s-, p- and d-block metal ions, (b) contacting metal ions comprised in said mixture to with at least one compound of general formula (I) as defined in any one of the preceding claims to form chelates; (c) subjecting the chelates from step (b) to chromatographic separation, wherein optionally at least one separated metal chelate obtained in step (c) can be subjected to at least one further chromatographic separation in order to increase the purity of the at least one separated metal chelate; and, optionally, (d) obtaining the metal from the at least one separated metal chelate.

A water-soluble compound of the formula (I): ##STR00001##
wherein R.sup.9 and R.sup.10 are suitably hydrophilic substituents, which may be used to selectively bind to a target saccharide such as glucose and which exhibits a detectable spectroscopic response to such binding, thus enabling its use in the detection and correction of blood glucose concentrations in vivo.