A set of piezoelectric biosensors using cholinesterases.

Piezoelectric sensors have become a versatile tool in biosensorics to study protein-protein and protein-small molecule interactions. Here we present theoretical background on piezoelectric sensors and instructions, how to modify their surface with various recognition elements for cholinesterases. These recognition elements comprise an organophosphate (paraoxon), a cocaine derivative (BZE-DADOO), and a tricyclic, aromatic compound (propidium). Additionally, a guide to the kinetic evaluation of the obtained binding curves is given in this chapter.

Piezoelectric affinity sensors for cocaine and cholinesterase inhibitors.

We report here the development of piezoelectric affinity sensors for cocaine and cholinesterase inhibitors based on the formation of affinity complexes between an immobilized cocaine derivative and an anti-cocaine antibody or cholinesterase. For both binding reactions benzoylecgonine-1,8-diamino-3,4-dioxaoctane (BZE-DADOO) was immobilized on the surface of the sensor. For immobilization, pre-conjugated BZE-DADOO with 11-mercaptomonoundecanoic acid (MUA) via 2-(5-norbornen-2,3-dicarboximide)-1,1,3,3-tetramethyluronium-tetrafluoroborate (TNTU) allowed the formation of a chemisorbed monolayer on the piezosensor surface. The detection of cocaine was based on a competitive assay. The change of frequency measured after 300s of the binding reaction was used as the signal. The maximum binding of the antibody resulted in a frequency decrease of 35Hz (with an imprecision 3%, n = 3) while the presence of 100pmoll(-1) cocaine decreased the binding by 11%. The limit of detection was consequently below 100pmoll(-1) for cocaine. The total time of one analysis was 15min. This BZE-DADOO-modified sensor was adapted for the detection of organophosphates. BZE-DADOO - a competitive inhibitor - served as binding element for cholinesterase in a competitive assay.

Molecular recognition of cocaine by acetylcholinesterases for affinity purification and bio-sensing.

Cholinesterases can be used as sensitive biorecognition elements for widely used agricultural pesticides. This requires highly purified and inhibitor-free enzyme preparations. In the present work the cocaine derivative benzoylecgonine was for the first time used as the molecular recognition element for the purification of acetylcholinesterase from Electrophorus electricus by affinity chromatography. The preparation of enriched enzyme without the contamination by an inhibitor, which is traditionally used for eluting the "affinity" bound protein, was achieved. The specific activity was 2.2-fold increased to 3100 Umg(-1). The same cocaine derivative was immobilized on the surface of a piezoelectric crystal in order to analyze the binding of acetylcholinesterases from two different species, E. electricus and Drosophila melanogaster, to the immobilized inhibitor. Evaluation of the binding curves allowed the analysis of the binding kinetics. These experiments are fundamental for the development of a (competitive) biosensor for inhibitors of cholinesterase.

New principle of direct real-time monitoring of the interaction of cholinesterase and its inhibitors by piezolectric biosensor.

This paper describes a new method for the sensitive detection of cholinesterase inhibitors based on real-time monitoring using a piezoelectric biosensor. The cholinesterase inhibitor paraoxon was immobilized on the sensing surface via a chelate complex as the recognition element. At first, the conjugate of N-mercaptoundecanoic acid (MUA) with Nalpha,Nalpha-bis (carboxymethyl)-L-lysine (NTA-Lys) was chemisorbed to form a self-assembled monolayer on the surface of the gold electrode of the piezosensor. In the next step, paraoxon-spacer-hexahistidine conjugate was linked to the MUA-Lys-NTA layer via the chelate complex with Ni2+. The paraoxon-modified surface thus obtained was applied for the binding of human butyrylcholinesterase (BChE). Regeneration of the sensing surface was achieved by splitting the chelate complex with EDTA and depositing a fresh layer of Ni2+ followed by addition of the paraoxon-spacer-hexahistidine. In the presence of free inhibitors like diisopropylfluorophosphate (DFP), binding of BChE to the surface-bound paraoxon was decreased. In this way, a competitive affinity assay for organophosphorus compounds was developed. The limit of detection for DFP as a model compound was 10 nmol/l (ca. 2 microg/l). This new concept seems suitable for constructing biosensors for the group-specific detection of cholinesterase-inhibiting substances like insecticides in the field.

Highly sensitive detection of cocaine using a piezoelectric immunosensor.

This paper describes the development of a highly sensitive competitive immunoassay with the piezoelectric sensor. The immobilized derivative of cocaine was benzoylecgonine-1,8-diamino-3,4-dioxaoctane (BZE-DADOO). For the immobilization of BZE-DADOO, the conjugate BZE-DADOO with 11-mercaptomonoundecanoic acid (MUA) was synthesized via 2-(5-norbornen-2,3-dicarboximide)-1,1,3,3-tetramethyluronium-tetrafluoroborate (TNTU), followed by the creation of the conjugate monolayer on the piezosensor electrodes. For the optimization of the competitive assay we used electrodes with rough or smooth gold areas and for the interaction with immobilized antigen different anti-cocaine sheep polyclonal (pAb, either whole IgG or Fab fragment) and mouse monoclonal (mAb, whole IgG) antibodies. The assay of cocaine developed achieved a detection limit (LOD) of 100 pmol/l (34 ng/l) using the sheep antibody (IgG) and piezoelectric sensors with a smooth gold surface. The total time of one analysis was 15 min and the measuring area of the sensor could be used more than 40 times without losing its sensitivity.