Design of composite microneedle sensor systems for the measurement of transdermal pH

Carbon loaded polystyrene microneedle patches have been prepared using silicone micro-moulding techniques and the ability of the needles to serve as viable transdermal sensors has been evaluated. The population of quinone groups at the interface of the embedded carbon nanoparticles was increased thr...

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Published in	Materials chemistry and physics Vol. 227; pp. 340 - 346
Main Authors	Hegarty, Catherine, McConville, Aaron, McGlynn, Ruairi J., Mariotti, Davide, Davis, James
Format	Journal Article
Language	English
Published	Lausanne Elsevier B.V 01.04.2019 Elsevier BV
Subjects	Composite Microneedle Molding (process) Nanoparticles Needles Oxidation Penetration depth Polystyrene resins Position sensing Quinones Sensor Sensors Transdermal pH Quinones Transdermal Composite Microneedle Sensor
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Abstract	Carbon loaded polystyrene microneedle patches have been prepared using silicone micro-moulding techniques and the ability of the needles to serve as viable transdermal sensors has been evaluated. The population of quinone groups at the interface of the embedded carbon nanoparticles was increased through anodisation and their pH dependent redox transitions exploited as the basis of a reagentless pH sensor. The peak position of the quinone oxidation process was found to shift in accordance with Nernstian behaviour and the influence of penetration depth on response has been investigated. The analytical applicability of the microneedle electrode patch was critically evaluated through using tomato skin as model transdermal skin mimic. Despite the increased complexity of the matrix, the microneedle sensor response was found to compare favourably with conventional/commercial pH probes. •Demonstration of silicone micro-mould templates for microneedle sensor construction.•Design and development of low cost carbon composite microneedle sensors.•Evaluation of carbon nanoparticle - interfacial electroanalytical properties.•Demonstration of voltammetric sensing capability in authentic samples.•Characterisation of microneedle piercing capability and pH sensing performance.
AbstractList	Carbon loaded polystyrene microneedle patches have been prepared using silicone micro-moulding techniques and the ability of the needles to serve as viable transdermal sensors has been evaluated. The population of quinone groups at the interface of the embedded carbon nanoparticles was increased through anodisation and their pH dependent redox transitions exploited as the basis of a reagentless pH sensor. The peak position of the quinone oxidation process was found to shift in accordance with Nernstian behaviour and the influence of penetration depth on response has been investigated. The analytical applicability of the microneedle electrode patch was critically evaluated through using tomato skin as model transdermal skin mimic. Despite the increased complexity of the matrix, the microneedle sensor response was found to compare favourably with conventional/commercial pH probes. Carbon loaded polystyrene microneedle patches have been prepared using silicone micro-moulding techniques and the ability of the needles to serve as viable transdermal sensors has been evaluated. The population of quinone groups at the interface of the embedded carbon nanoparticles was increased through anodisation and their pH dependent redox transitions exploited as the basis of a reagentless pH sensor. The peak position of the quinone oxidation process was found to shift in accordance with Nernstian behaviour and the influence of penetration depth on response has been investigated. The analytical applicability of the microneedle electrode patch was critically evaluated through using tomato skin as model transdermal skin mimic. Despite the increased complexity of the matrix, the microneedle sensor response was found to compare favourably with conventional/commercial pH probes. •Demonstration of silicone micro-mould templates for microneedle sensor construction.•Design and development of low cost carbon composite microneedle sensors.•Evaluation of carbon nanoparticle - interfacial electroanalytical properties.•Demonstration of voltammetric sensing capability in authentic samples.•Characterisation of microneedle piercing capability and pH sensing performance.
Author	McConville, Aaron Hegarty, Catherine Davis, James Mariotti, Davide McGlynn, Ruairi J.
Author_xml	– sequence: 1 givenname: Catherine surname: Hegarty fullname: Hegarty, Catherine – sequence: 2 givenname: Aaron orcidid: 0000-0001-9644-9029 surname: McConville fullname: McConville, Aaron – sequence: 3 givenname: Ruairi J. surname: McGlynn fullname: McGlynn, Ruairi J. – sequence: 4 givenname: Davide surname: Mariotti fullname: Mariotti, Davide – sequence: 5 givenname: James surname: Davis fullname: Davis, James email: james.davis@ulster.ac.uk
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Snippet	Carbon loaded polystyrene microneedle patches have been prepared using silicone micro-moulding techniques and the ability of the needles to serve as viable...
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SubjectTerms	Composite Microneedle Molding (process) Nanoparticles Needles Oxidation Penetration depth Polystyrene resins Position sensing Quinones Sensor Sensors Transdermal
Title	Design of composite microneedle sensor systems for the measurement of transdermal pH
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