posted on 2021-12-15, 19:08authored byRobert
D. Crapnell, Elena Bernalte, Alejandro Garcia-Miranda Ferrari, Matthew J. Whittingham, Rhys J. Williams, Nicholas J. Hurst, Craig E Banks
This manuscript provides
the first report of a fully additively
manufactured (AM) electrochemical cell printed all-in-one, where all the electrodes and cell are printed as one, requiring
no post-assembly or external electrodes. The three-electrode cell
is printed using a standard non-conductive poly(lactic acid) (PLA)-based
filament for the body and commercially available conductive carbon
black/PLA (CB/PLA, ProtoPasta) for the three electrodes (working,
counter, and reference; WE, CE, and RE, respectively). The electrochemical
performance of the cell is evaluated first against the well-known
near-ideal outer-sphere redox probe hexaamineruthenium(III) chloride
(RuHex), showing that the cell performs well using an AM electrode
as the pseudo-RE. Electrochemical activation of the
WE via chronoamperometry and NaOH provides enhanced electrochemical
performances toward outer-sphere probes and for electroanalytical
performance. It is shown that this activation can be completed using
either an external commercial Ag|AgCl RE or through simply using the
internal AM CB/PLA pseudo-RE and CE. This all-in-one electrochemical cell (AIOEC) was applied toward
the well-known detection of ascorbic acid (AA) and acetaminophen (ACOP),
achieving linear trends with limits of detection (LODs) of 13.6 ±
1.9 and 4.5 ± 0.9 μM, respectively. The determination of
AA and ACOP in real samples from over-the-counter effervescent tablets
was explored, and when analyzed individually, recoveries of 102.9
and 100.6% were achieved against UV–vis standards, respectively.
Simultaneous detection of both targets was also achieved through detection
in the same sample exhibiting 149.75 and 81.35% recoveries for AA
and ACOP, respectively. These values differing from the originals
are likely due to electrode fouling due to the AA oxidation being
a surface-controlled process. The cell design produced herein is easily
tunable toward different sample volumes or container shapes for various
applications among aqueous electroanalytical sensing; however, it
is a simple example of the capabilities of this manufacturing method.
This work illustrates the next step in research synergising AM and
electrochemistry, producing operational electrochemical sensing platforms
in a single print, with no assembly and no requirements for exterior
or commercial electrodes. Due to the flexibility, low-waste, and rapid
prototyping of AM, there is scope for this work to be able to span
and impact a plethora of research areas.