Alkanethiol
Monolayer End Groups Affect the Long-Term Operational Stability and
Signaling of Electrochemical, Aptamer-Based Sensors in Biological
Fluids
posted on 2020-02-20, 17:06authored byAlexander Shaver, Samuel D. Curtis, Netzahualcóyotl Arroyo-Currás
Electrochemical aptamer-based
(E-AB) sensors achieve highly precise measurements of specific molecular
targets in untreated biological fluids. This unique ability, together
with their measurement frequency of seconds or faster, has enabled
the real-time monitoring of drug pharmacokinetics in live animals
with unprecedented temporal resolution. However, one important weakness
of E-AB sensors is that their bioelectronic interface degrades upon
continuous electrochemical interrogationa process typically
seen as a drop in faradaic and an increase in charging currents over
time. This progressive degradation limits their in vivo operational
life to 12 h at best, a period that is much shorter than the elimination
half-life of the vast majority of drugs in humans. Thus, there is
a critical need to develop novel E-AB interfaces that resist continuous
electrochemical interrogation in biological fluids for prolonged periods.
In response, our group is pursuing the development of better packed,
more stable self-assembled monolayers (SAMs) to improve the signaling
and extend the operational life of in vivo E-AB sensors from hours
to days. By invoking hydrophobicity arguments, we have created SAMs
that do not desorb from the electrode surface in aqueous physiological
solutions and biological fluids. These SAMs, formed from 1-hexanethiol
solutions, decrease the voltammetric charging currents of E-AB sensors
by 3-fold relative to standard monolayers of 6-mercapto-1-hexanol,
increase the total faradaic current, and alter the electron transfer
kinetics of the platform. Moreover, the stability of our new SAMs
enables uninterrupted, continuous E-AB interrogation for several days
in biological fluids, like undiluted serum, at a physiological temperature
of 37 °C.