33 research outputs found
A review of electrochemical impedance spectroscopy for bioanalytical sensors
Electrochemical impedance spectroscopy (EIS) is a powerful technique for both quantitative and qualitative analysis. This review uses a systematic approach to examine how electrodes are tailored for use in EIS-based applications, describing the chemistries involved in sensor design, and discusses trends in the use of bio-based and non-bio-based electrodes. The review finds that immunosensors are the most prevalent sensor strategy that employs EIS as a quantification technique for target species. The review also finds that bio-based electrodes, though capable of detecting small molecules, are most applicable for the detection of complex molecules. Non-bio-based sensors are more often employed for simpler molecules and less often have applications for complex systems. We surmise that EIS has advanced in terms of electrode designs since our last review on the subject, although there are still inconsistencies in terms of equivalent circuit modelling for some sensor types. Removal of ambiguity from equivalent circuit models may help advance EIS as a choice detection method, allowing for lower limits of detection than traditional electrochemical methods such as voltammetry or amperometry
Twittering about research : a case study of the world's first Twitter poster competition
The Royal Society of Chemistry held, to our knowledge, the worldâs first Twitter conference at 9am on February 5th, 2015. This paper reports the details of the event and discusses the outcomes, such as the potential for the use of social media to enhance scientific communication at conferences. In particular, the present work argues that social media outlets such as Twitter broaden audiences, speed up communication, and force clearer and more concise descriptions of a researcherâs work. The benefits of poster presentations are also discussed in terms of potential knowledge exchange and networking. This paper serves as a proof-of-concept approach for improving both the public opinion of the poster, and the enhancement of the poster through an innovative online format that some may feel more comfortable with, compared to face-to-face communication
Detection of theophylline utilising portable electrochemical sensors
The electrochemical oxidation of theophylline (TP) is investigated utilising screen-printed electrodes.
Through thorough investigation of pH, we propose a reaction mechanism, finding that the oxidation of
TP is stable over a wide pH range, in particular under acidic conditions. Conversely under alkaline
conditions, theophylline fouls the electrode surface. The screen-printed carbon sensors are applied
towards the electroanalytical sensing of TP with a remarkable amount of success in aqueous solution at
physiological pH. The screen-printed sensors have been shown to be applicable to the detection of TP
at unharmful, medicinally relevant (55â110 mM), and toxic concentrations in aqueous media at
physiological pH. Thus this work presents a proof-of-concept approach towards TP detection utilising
sensors commonly implemented in point-of-care applications
Twittering about research: A case study of the worldâs first twitter poster competition [Version 3]
The Royal Society of Chemistry held, to our knowledge, the worldâs first Twitter conference at 9am on February 5 th, 2015. The conference was a Twitter-only conference, allowing researchers to upload academic posters as tweets, replacing a physical meeting. This paper reports the details of the event and discusses the outcomes, such as the potential for the use of social media to enhance scientific communication at conferences. In particular, the present work argues that social media outlets such as Twitter broaden audiences, speed up communication, and force clearer and more concise descriptions of a researcherâs work. The benefits of poster presentations are also discussed in terms of potential knowledge exchange and networking. This paper serves as a proof-of-concept approach for improving both the public opinion of the poster, and the enhancement of the poster through an innovative online format that some may feel more comfortable with, compared to face-to-face communication
Screen-printed back-to-back electroanalytical sensors
We introduce the concept of screen-printed back-to-back electroanalytical
sensors where in this facile and generic approach, screenprinted
electrodes are printed back-to-back with a common electrical
connection to the two working electrodes with the counter and
reference electrodes for each connected in the same manner as a
normal âtraditionalâ screen-printed sensor would be. This approach
utilises the usually redundant back of the screen-printed sensor,
converting this âdead-spaceâ into a further electrochemical sensor
which results in improvements in the analytical performance. In the
use of the back-to-back design, the electrode area is consequently
doubled with improvements in the analytical performance observed
with the analytical sensitivity (gradient of a plot of peak height/
analytical signal against concentration) doubling and the corresponding
limit-of-detection being reduced.We also demonstrate that
through intelligent electrode design, a quadruple in the observed
analytical sensitivity can also be realised when double microband
electrodes are used in the back-to-back configuration as long as they
are placed sufficiently apart such that no diffusional interaction
occurs. Such work is generic in nature and can be facilely applied to a
plethora of screen-printed (and related) sensors utilising the
commonly overlooked redundant back of the electrode providing
facile improvements in the electroanalytical performance
Biosemiotics, politics and Th.A. Sebeokâs move from linguistics to semiotics
This paper will focus on the political implications for the language sciences of Sebeokâs move from linguistics to a global semiotic perspective, a move that ultimately resulted in biosemiotics. The paper will seek to make more explicit the political bearing of a biosemiotic perspective in the language sciences and the human sciences in general. In particular, it will discuss the definition of language inherent in Sebeokâs project and the fundamental re-drawing of the grounds of linguistic debate heralded by Sebeokâs embrace of the concept of modelling. Thus far, the political co-ordinates of the biosemiotic project have not really been made explicit. This paper will therefore seek to outline
1. how biosemiotics enables us to reconfigure our understanding of the role of language in culture;
2. how exaptation is central to the evolution of language and communication, rather than adaptation;
3. how communication is the key issue in biosphere, rather than language, not just because communication includes language but because the language sciences often refer to language as if it were mere âchatterâ, âtropesâ and âfigures of speechâ;
4. how biosemiotics, despite its seeming âneutralityâ arising from its transdisciplinarity, is thoroughly political;
5. how the failure to see the implications of the move from linguistics to semiotics arises from the fact that biosemiotics is devoid of old style politics, which is based on representation (devoid of experience) and âconstruction of [everything] in discourseâ (which is grounded in linguistics, not communication study).
In contrast to the post-âlinguistic turnâ idea that the world is âconstructed in discourseâ, we will argue that biosemiotics entails a reconfiguration of the polis and, in particular, offers the chance to completely reconceptualise ideology
Forensic electrochemistry: indirect electrochemical sensing of the components of the new psychoactive substance "Synthacaine"
âSynthacaineâ is a New Psychoactive Substance which is, due to its inherent psychoactive properties,
reported to imitate the effects of cocaine and is therefore consequently branded as âlegal cocaineâ. The
only analytical approach reported to date for the sensing of âSynthacaineâ is mass spectrometry. In this
paper, we explore and evaluate a range of potential analytical techniques for its quantification and potential
use in the field screening âSynthacaineâ using Raman spectroscopy, presumptive (colour) testing, High
Performance Liquid Chromatography (HPLC) and electrochemistry. HPLC analysis of street samples
reveals that âSynthacaineâ comprises a mixture of methiopropamine (MPA) and 2-aminoindane (2-AI).
Raman spectroscopy and presumptive (colour) tests, the Marquis, Mandelin, Simonâs and Robadope test,
are evaluated towards a potential in-the-field screening approach but are found to not be able to discriminate
between the two when they are both present in the same sample, as is the case in the real
street samples. We report for the first time a novel indirect electrochemical protocol for the sensing of
MPA and 2-AI which is independently validated in street samples with HPLC. This novel electrochemical
approach based upon one-shot disposable cost effective screen-printed graphite macroelectrodes holds
potential for in-the-field screening for âSynthacaineâ.
Introduction
In the last few years there has been a striking increase in the
sale of âNew Psychoactive Substancesâ (NPSs) formerly known as
âlegal highsâ.1 These chemicals may be bought through the
internet at low cost and are sometimes pure compounds
which display highly similar chemical structures to existing
controlled substances within the phenethylamine class.
âSynthacaineâ is a slang term derived from âsyntheticâ and
âcocaine
Forensic electrochemistry: simultaneous voltammetric detection of MDMA and its fatal counterpart "Dr Death" (PMA)
The simultaneous detection of substances present in drugs of abuse is increasingly important since some materials are known for their high mortality rate. One drug that received considerable attention is para-methoxyamphetamine (PMA), commonly known as âDr Deathâ â this substance is linked with several deaths internationally and can often be found together with 3,4-methylenedioxymethamphetamine (MDMA) in drugs sold under the alias âecstasyâ, a very popular drug of abuse. This work reports for the first time the detection and quantification of MDMA and PMA simultaneously through an electrochemical technique using screen-printed graphite electrodes (SPEs). The electroanalytical sensing of MDMA/PMA, MDMA and PMA are explored directly at bare unmodified SPEs yielding a detection limit (3Ï) corresponding to 0.25 ÎŒg mLâ1/0.14 ÎŒg mLâ1 for MDMA/PMA, 0.04 ÎŒg mLâ1 MDMA and 0.03 ÎŒg mLâ1 PMA. Raman spectroscopy and presumptive colour tests were also performed on MDMA/PMA, MDMA and PMA using the Marquis, Mandelin, Simon's and Robadope tests but were found to not be able discriminate when PMA and MDMA are both present in the same samples. We report a novel electrochemical protocol for the sensing of PMA and MDMA which is independently validated in a synthetic (MDMA/PMA) sample with HPLC
The fabrication, characterisation and electrochemical investigation of screen-printed graphene electrodes
We report the fabrication, characterisation (SEM, Raman spectroscopy, XPS and ATR) and electrochemical
implementation of novel screen-printed graphene electrodes. Electrochemical characterisation of the fabricated
graphene electrodes is undertaken using an array of electroactive redox probes and biologically relevant
analytes, namely: potassium ferrocyanide(II), hexaammine-ruthenium(III) chloride, N,N,N0 ,N0-tetramethyl-pphenylenediamine
(TMPD), b-nicotinamide adenine dinucleotide (NADH), L-ascorbic acid (AA), uric acid (UA)
and dopamine hydrochloride (DA). The electroanalytical capabilities of the fabricated electrodes are also
considered towards the sensing of AA and DA. The electrochemical and (electro)analytical performances of
the fabricated screen-printed graphene electrodes are considered with respect to the relative surface
morphologies and material compositions (elucidated via SEM, Raman, XPS and ATR spectroscopy), the density
of electronic states (% global coverage of edge-plane like sites/defects) and the specific fabrication conditions
utilised. Comparisons are made between two screen-printed graphene electrodes and alternative graphite
based screen-printed electrodes. The graphene electrodes are fabricated utilising two different commercially
prepared âgrapheneâ inks, which have long screen ink lifetimes (43 hours), thus this is the first report of a true
mass-reproducible screen-printable graphene ink. Through employment of appropriate controls/comparisons
we are able to report a critical assessment of these screen-printed graphene electrodes. This work is of high
importance and demonstrates a proof-of-concept approach to screen-printed graphene electrodes that are
highly reproducible, paving the way for mass-producible graphene sensing platforms in the future
The fabrication, characterisation and electrochemical investigation of screen-printed graphene electrodes
We report the fabrication, characterisation (SEM, Raman spectroscopy, XPS and ATR) and electrochemical
implementation of novel screen-printed graphene electrodes. Electrochemical characterisation of the fabricated
graphene electrodes is undertaken using an array of electroactive redox probes and biologically relevant
analytes, namely: potassium ferrocyanide(II), hexaammine-ruthenium(III) chloride, N,N,N0 ,N0-tetramethyl-pphenylenediamine
(TMPD), b-nicotinamide adenine dinucleotide (NADH), L-ascorbic acid (AA), uric acid (UA)
and dopamine hydrochloride (DA). The electroanalytical capabilities of the fabricated electrodes are also
considered towards the sensing of AA and DA. The electrochemical and (electro)analytical performances of
the fabricated screen-printed graphene electrodes are considered with respect to the relative surface
morphologies and material compositions (elucidated via SEM, Raman, XPS and ATR spectroscopy), the density
of electronic states (% global coverage of edge-plane like sites/defects) and the specific fabrication conditions
utilised. Comparisons are made between two screen-printed graphene electrodes and alternative graphite
based screen-printed electrodes. The graphene electrodes are fabricated utilising two different commercially
prepared âgrapheneâ inks, which have long screen ink lifetimes (43 hours), thus this is the first report of a true
mass-reproducible screen-printable graphene ink. Through employment of appropriate controls/comparisons
we are able to report a critical assessment of these screen-printed graphene electrodes. This work is of high
importance and demonstrates a proof-of-concept approach to screen-printed graphene electrodes that are
highly reproducible, paving the way for mass-producible graphene sensing platforms in the future