Eoin Sheridan
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Explore the profile of Eoin Sheridan including associated specialties, affiliations and a list of published articles.
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Articles
12
Citations
70
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Recent Articles
1.
Cunningham J, Briggs A, Cottrell E, Doyle F, Dziedzic K, Finney A, et al.
HRB Open Res
. 2021 Nov;
4:102.
PMID: 34746643
Despite consistent international guidelines for osteoarthritis (OA) management, evidence-based treatments are underutilised. OA management programmes (OAMPs) are being implemented internationally to address this evidence-practice gap. An OAMP is defined as...
2.
Breiner B, Johnson K, Stolarek M, Silva A, Negrea A, Bell N, et al.
Nucleic Acids Res
. 2019 Jul;
47(17):e101.
PMID: 31318971
A new approach to single-molecule DNA sequencing in which dNTPs, released by pyrophosphorolysis from the strand to be sequenced, are captured in microdroplets and read directly could have substantial advantages...
3.
Baker C, Bekker C, McAuslan D, Sheridan E, Bowen W
Opt Express
. 2016 Sep;
24(18):20400-12.
PMID: 27607646
We report on the design, fabrication and characterization of silica microtoroid based cavity opto-electromechanical systems (COEMS). Electrodes patterned onto the microtoroid resonators allow for rapid capacitive tuning of the optical...
4.
Forstner S, Sheridan E, Knittel J, Humphreys C, Brawley G, Rubinsztein-Dunlop H, et al.
Adv Mater
. 2014 Jun;
26(36):6348-53.
PMID: 24889714
A cavity optomechanical magneto-meter operating in the 100 pT range is reported. The device operates at earth field, achieves tens of megahertz bandwidth with 60 μm spatial resolution and microwatt...
5.
Scida K, Sheridan E, Crooks R
Lab Chip
. 2013 May;
13(12):2292-9.
PMID: 23657767
A method for controlling enrichment, separation, and delivery of analytes into different secondary microchannels using simple microfluidic architecture is described. The approach, which is based on bipolar electrochemistry, requires only...
6.
Knust K, Sheridan E, Anand R, Crooks R
Lab Chip
. 2012 Sep;
12(20):4107-14.
PMID: 22952054
In this paper we show that a microelectrochemical cell comprising two parallel microchannels spanned by a single bipolar electrode can be used to simultaneously enrich and separate both anions and...
7.
Sheridan E, Hlushkou D, Knust K, Tallarek U, Crooks R
Anal Chem
. 2012 Aug;
84(17):7393-9.
PMID: 22891868
We have previously demonstrated up to 5 × 10(5)-fold enrichment of anionic analytes in a microchannel using a technique called bipolar electrode focusing (BEF). Here, we demonstrate that BEF can...
8.
Sheridan E, Knust K, Crooks R
Analyst
. 2011 Aug;
136(20):4134-7.
PMID: 21869950
We report a method for removing ions from aqueous solutions without the use of a membrane. The approach, which we call bipolar electrode depletion (BED), is based on the formation...
9.
Sheridan E, Hlushkou D, Anand R, Laws D, Tallarek U, Crooks R
Anal Chem
. 2011 Aug;
83(17):6746-53.
PMID: 21815639
We show that a label-free electrochemical method can be used to monitor the position of an enriched analyte band during bipolar electrode focusing in a microfluidic device. The method relies...
10.
Anand R, Sheridan E, Knust K, Crooks R
Anal Chem
. 2011 Mar;
83(6):2351-8.
PMID: 21351782
Bipolar electrode (BPE) focusing locally enriches charged analytes in a microchannel along an electric field gradient that opposes a counter-flow. This electric field gradient forms at the boundary of an...