Abstract: A method of detecting peroxynitrite in a sample is described comprising the steps of: (a) providing a complex of a saccharide with an aryl boronate compound of formula (I): Fp-L1-Z-L2-Ar—B(OH)2 (I) wherein: Fp comprises a fluorophore; L1 and L2 are linker groups; Z is a fluorescence switch; and Ar is optionally substituted aryl; (b) contacting said aryl boronate-saccharide complex with said sample, whereby peroxynitrite in said sample cleaves said aryl boronate-saccharide complex to produce a compound of formula (II): F-L1-Z-L2-Ar—OH (II); and (c) detecting a decrease in a fluorescence intensity of said fluorophore resulting from said cleavage reaction in step (b). Peroxynitrite reacts quantitatively, rapidly, and selectively in step (b) of the reaction, whereby medical conditions associated with elevated peroxynitrite can be diagnosed. Also provided are compounds of formula (I) for use in the methods.

Abstract: An analytical system for detecting a saccharide is provided. The analytical system includes a saccharide sensor attached to a solid substrate and having the formula: Where Z is selected from the group consisting of hydrogen, alkyl groups, an aryl; N is a nitrogen atom; Bd1 and Bd2 are independently selected binding groups, wherein the binding groups are capable of binding an saccharide; Sp is a spacer; An is an anchor group for attaching the sensor to solid substrate, including a bead; and n=1 or 2, m=1 or 2, y=1 or 2, and p is an integer. In one embodiment the saccharide sensor preferentially detects glucose. The invention further provides beads having the saccharide sensor attached thereto and methods of detecting glucose using the system.

Abstract: An analytical system for detecting a saccharide is provided.

Abstract: Disclosed is a modular fluorescence sensor having the following general formula: Where Fl is a fluorophore, N is a nitrogen atom, Bd1 and Bd2 are independently selected binding groups, Sp is an aliphatic spacer, and An is an anchor group for attaching the sensor to solid substrates. n=1 or 2, m=1 or 2, x is an integer, and y=1 or 2. The binding groups are capable of binding an analyte molecule to form a stable 1:1 complex. In a preferred embodiment, the Bd1 is R1—B(OH)2 and Bd2 is R2—B(OH)2. R1 and R2 are aliphatic or aromatic functional groups selected independently from each other and B is a boron atom. The present invention also provides methods of synthesizing a modular fluorescence sensor and its use in labeling solid substrates.

Abstract: The invention provides compounds for detecting sacchharides by electrochemistry. The compounds have a structure that includes a first boronic acid group attached by a first linker group to a first tertiary amine. The first tertiary amine is attached to a reporter group that includes an organometalic reporter moiety. A spacer group attaches the first tertiary amine to a second tertiary amine. The second tertiary amine is attached to an R group and a second linker group. The second linker group is attached to a second boronic acid group. In preferred embodiments, the compound selectively detects glucose and has a higher relative stability constant for glucose than for other saccharides.

Abstract: The invention provides compounds for detecting sacchharides by electrochemistry. The compounds have a structure that includes a first boronic acid group attached by a first linker group to a first tertiary amine. The first tertiary amine is attached to a reporter group that includes an organometalic reporter moiety. A spacer group attaches the first tertiary amine to a second tertiary amine. The second tertiary amine is attached to an R group and a second linker group. The second linker group is attached to a second boronic acid group. In preferred embodiments, the compound selectively detects glucose and has a higher relative stability constant for glucose than for other saccharides.

Abstract: Disclosed is a modular fluorescence sensor having the following general formula: 1

Abstract: Disclosed is a modular fluorescence sensor having the following general formula: where Fl is a fluorophore, N is a nitrogen atom, Bd1 and Bd2 are independently selected binding groups, Sp is an aliphatic spacer, and An is an anchor group for attaching the sensor to solid substrates. n=1 or 2, m=1 or 2, x is an integer, and y=1 or 2. The binding groups are capable of binding an analyte molecule to form a stable 1:1 complex. In a preferred embodiment, the Bd1 is R1—B(OH)2 and Bd2 is R2—B(OH)2. R1 and R2 are aliphatic or aromatic functional groups selected independently from each other and B is a boron atom. The present invention also provides methods of synthesizing a modular fluorescence sensor and its use in labeling solid substrates.