Subsecond-Resolved Molecular Measurements in the Living Body Using Chronoamperometrically Interrogated Aptamer-Based Sensors.

Electrochemical, aptamer-based (E-AB) sensors support the continuous, real-time measurement of specific small molecules directly in situ in the living body over the course of many hours. They achieve this by employing binding-induced conformational changes to alter electron transfer from a redox-reporter-modified, electrode-attached aptamer. Previously we have used voltammetry (cyclic, alternating current, and square wave) to monitor this binding-induced change in transfer kinetics indirectly. Here, however, we demonstrate the potential advantages of employing chronoamperometry to measure the change in kinetics directly. In this approach target concentration is reported via changes in the lifetime of the exponential current decay seen when the sensor is subjected to a potential step. Because the lifetime of this decay is independent of its amplitude (e.g., insensitive to variations in the number of aptamer probes on the electrode), chronoamperometrically interrogated E-AB sensors are calibration-free and resistant to drift. Chronoamperometric measurements can also be performed in a few hundred milliseconds, improving the previous few-second time resolution of E-AB sensing by an order of magnitude. To illustrate the potential value of the approach we demonstrate here the calibration-free measurement of the drug tobramycin in situ in the living body with 300 ms time resolution and unprecedented, few-percent precision in the determination of its pharmacokinetic phases.

[1]  A. Fersht,et al.  Folding of chymotrypsin inhibitor 2. 1. Evidence for a two-state transition. , 1991, Biochemistry.

[2]  C. Chidsey,et al.  Free Energy and Temperature Dependence of Electron Transfer at the Metal-Electrolyte Interface , 1991, Science.

[3]  Y. Katayama,et al.  The design of cyclic AMP--recognizing oligopeptides and evaluation of its capability for cyclic AMP recognition using an electrochemical system. , 2000, Analytical chemistry.

[4]  C. Chidsey,et al.  Submicrosecond Electron Transfer to Monolayer-Bound Redox Species on Gold Electrodes at Large Overpotentials , 2002 .

[5]  Kevin W Plaxco,et al.  Real-time measurement of small molecules directly in awake, ambulatory animals , 2017, Proceedings of the National Academy of Sciences.

[6]  Kevin W Plaxco,et al.  Real-Time, Aptamer-Based Tracking of Circulating Therapeutic Agents in Living Animals , 2013, Science Translational Medicine.

[7]  Ryan J. White,et al.  Reagentless, Structure-Switching, Electrochemical Aptamer-Based Sensors. , 2016, Annual review of analytical chemistry.

[8]  T. Meade,et al.  Trinuclear ruthenium clusters as bivalent electrochemical probes for ligand-receptor binding interactions. , 2012, Langmuir : the ACS journal of surfaces and colloids.

[9]  H. Kraatz,et al.  Interaction of a ferrocenoyl-modified peptide with papain: toward protein-sensitive electrochemical probes. , 2003, Bioconjugate chemistry.

[10]  T. W. Sanders,et al.  Effects of polyaspartic acid on pharmacokinetics of tobramycin in two strains of rat , 1994, Antimicrobial Agents and Chemotherapy.

[11]  F. Ricci,et al.  Dual-Reporter Drift Correction To Enhance the Performance of Electrochemical Aptamer-Based Sensors in Whole Blood. , 2016, Journal of the American Chemical Society.

[12]  Kevin W Plaxco,et al.  Exploiting binding-induced changes in probe flexibility for the optimization of electrochemical biosensors. , 2010, Analytical chemistry.

[13]  Kevin W Plaxco,et al.  Structure-switching biosensors: inspired by Nature. , 2010, Current opinion in structural biology.

[14]  Jonathan S. Lindsey,et al.  Characterization of charge storage in redox-active self-assembled monolayers , 2002 .

[15]  A. Heeger,et al.  An electronic, aptamer-based small-molecule sensor for the rapid, label-free detection of cocaine in adulterated samples and biological fluids. , 2006, Journal of the American Chemical Society.

[16]  Kevin W Plaxco,et al.  A Biomimetic Phosphatidylcholine-Terminated Monolayer Greatly Improves the In Vivo Performance of Electrochemical Aptamer-Based Sensors. , 2017, Angewandte Chemie.

[17]  A. Heeger,et al.  Label-free electronic detection of thrombin in blood serum by using an aptamer-based sensor. , 2005, Angewandte Chemie.

[18]  Mario Leclerc,et al.  Label-free electrochemical detection of protein based on a ferrocene-bearing cationic polythiophene and aptamer. , 2006, Analytical chemistry.

[19]  Hua-Zhong Yu,et al.  A robust electronic switch made of immobilized duplex/quadruplex DNA. , 2010, Angewandte Chemie.

[20]  T. Meade,et al.  Electrochemistry of redox-active self-assembled monolayers. , 2010, Coordination chemistry reviews.

[21]  Kevin W Plaxco,et al.  Reagentless measurement of aminoglycoside antibiotics in blood serum via an electrochemical, ribonucleic acid aptamer-based biosensor. , 2010, Analytical chemistry.

[22]  A. Alvarez Carrera,et al.  [Basic concepts of pharmacokinetics]. , 1991, Revista espanola de anestesiologia y reanimacion.

[23]  João P. Hespanha,et al.  High-Precision Control of Plasma Drug Levels Using Feedback-Controlled Dosing. , 2018, ACS pharmacology & translational science.

[24]  Kevin W. Plaxco,et al.  High Surface Area Electrodes Generated via Electrochemical Roughening Improve the Signaling of Electrochemical Aptamer-Based Biosensors. , 2017, Analytical chemistry.

[25]  Kevin W Plaxco,et al.  Calibration-Free Electrochemical Biosensors Supporting Accurate Molecular Measurements Directly in Undiluted Whole Blood. , 2017, Journal of the American Chemical Society.

[26]  Kevin W Plaxco,et al.  An electrochemical sensor for the detection of protein-small molecule interactions directly in serum and other complex matrices. , 2009, Journal of the American Chemical Society.

[27]  Arica A Lubin,et al.  Continuous, real-time monitoring of cocaine in undiluted blood serum via a microfluidic, electrochemical aptamer-based sensor. , 2009, Journal of the American Chemical Society.

[28]  Chunhai Fan,et al.  Electrochemical interrogation of conformational changes as a reagentless method for the sequence-specific detection of DNA , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[29]  M. Bergeron,et al.  Temporal changes of pharmacokinetics, nephrotoxicity, and subcellular distribution of tobramycin in rats , 1994, Antimicrobial Agents and Chemotherapy.

[30]  Kevin W Plaxco,et al.  Maximizing the Signal Gain of Electrochemical-DNA Sensors. , 2016, Analytical chemistry.

[31]  Arica A Lubin,et al.  Optimization of electrochemical aptamer-based sensors via optimization of probe packing density and surface chemistry. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[32]  E. Prasad,et al.  The role of ligand displacement in SmII-HMPA-based reductions. , 2004, Journal of the American Chemical Society.