Hollow Microneedle‐based Plasmonic Sensor for on Patch Detection of Molecules in Dermal Interstitial Fluid

Author:

Miranda Bruno12,Battisti Mario3,De Martino Selene3ORCID,Nocerino Valeria14,Dardano Principia1,De Stefano Luca1,Cangiano Giancarlo5

Affiliation:

1. Institute of Applied Sciences and Intelligent Systems (ISASI) National Research Council Via P. Castellino 111 Naples 80131 Italy

2. DIETI University of Naples “Federico II” Via Claudio 21 Napoli 80125 Italy

3. Materias S.r.l. Corso Nicolangelo Protopisani 50 Naples 80146 Italy

4. Department of Engineering Università degli Studi di Napoli Parthenope Centro Direzionale di Napoli Isola C4 Naples 80143 Italy

5. Co.Di.Me. S.r.l. Corso Novara n° 10 Naples 80142 Italy

Abstract

AbstractInterstitial fluid (ISF) extraction and analysis are challenges that can be tackled by Hollow MicroNeedles (HMNs) technology, overcoming most of the difficulties associated with in situ detection. Herein, a plasmonic transducer, composed of gold nanoparticles embedded in poly(ethylene glycol) diacrylate (PEGDA) hydrogels, is integrated in the inner cavity of HMNs to detect biomarkers from the ISF‐based point‐of‐care. The wearable HMN‐based patch is used for minimally invasive pierce of the skin. The large swelling capability of the plasmonic transducer allows the uptake of ISF by capillarity. Biotin, as a small model molecule, is efficiently collected in the inner cavity of HMN and its high specificity with the streptavidin is exploited as a validation of the plasmonic nanocomposite functionality embedded within. The recognition of biotin is achieved in dual‐optical mode: the localized surface plasmon resonance (label‐free) and the metal‐enhanced fluorescence (label‐based). Overall, the proposed HMN‐based patch for target sensing in ISF can represent a novel point‐of‐use device for the detection of biomarkers as an alternative to conventional hospital or lab settings to help faster medical decision‐making.

Publisher

Wiley

Subject

Industrial and Manufacturing Engineering,Mechanics of Materials,General Materials Science

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