Microneedles for Continuous, Minimally Invasive Monitoring: A Technology Overview

Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known as stratum corneum, providing minimally invasive access to interstitial fluid (ISF), which enables the monitoring of biochemical parameters in real‐t...

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Published inAdvanced Sensor Research Vol. 4; no. 7
Main Authors Conejo‐Cuevas, Guillermo, Aller Pellitero, Miguel, Ruiz‐Rubio, Leire, del Campo, Francisco Javier
Format Journal Article
LanguageEnglish
Published Wiley-VCH 01.07.2025
Subjects
aptamers
electrochemical sensors
interstitial fluid
microneedles
wearable biosensors
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ISSN2751-1219
2751-1219
DOI10.1002/adsr.202500057

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Abstract Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known as stratum corneum, providing minimally invasive access to interstitial fluid (ISF), which enables the monitoring of biochemical parameters in real‐time. This review covers recent progress to date in the area of electrochemical sensing using microneedles, and provides an overview of fabrication materials and processes, as well as applications. The main body of the review focuses on the fabrication of microneedle structures and their transformation into electrochemical biosensors for continuous monitoring. To this end, the main recognition elements and electrode functionalization ways are described, paying closer attention to aptamers and continuous aptamer‐based sensing, whose importance, merits, and limitations are highlighted. In addition to covering the main current applications, the review discusses the future threats and opportunities of microneedle‐based in vivo monitoring. This review explores recent advances in electrochemical sensing using microneedles—small, minimally invasive devices that access interstitial fluid for real‐time molecular monitoring. It highlights fabrication methods, materials, and biosensor development, with a focus on aptamer‐based sensing. The review also discusses current applications, challenges, and future prospects of microneedle‐based in vivo monitoring systems.
AbstractList Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known as stratum corneum, providing minimally invasive access to interstitial fluid (ISF), which enables the monitoring of biochemical parameters in real‐time. This review covers recent progress to date in the area of electrochemical sensing using microneedles, and provides an overview of fabrication materials and processes, as well as applications. The main body of the review focuses on the fabrication of microneedle structures and their transformation into electrochemical biosensors for continuous monitoring. To this end, the main recognition elements and electrode functionalization ways are described, paying closer attention to aptamers and continuous aptamer‐based sensing, whose importance, merits, and limitations are highlighted. In addition to covering the main current applications, the review discusses the future threats and opportunities of microneedle‐based in vivo monitoring.
Abstract Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known as stratum corneum, providing minimally invasive access to interstitial fluid (ISF), which enables the monitoring of biochemical parameters in real‐time. This review covers recent progress to date in the area of electrochemical sensing using microneedles, and provides an overview of fabrication materials and processes, as well as applications. The main body of the review focuses on the fabrication of microneedle structures and their transformation into electrochemical biosensors for continuous monitoring. To this end, the main recognition elements and electrode functionalization ways are described, paying closer attention to aptamers and continuous aptamer‐based sensing, whose importance, merits, and limitations are highlighted. In addition to covering the main current applications, the review discusses the future threats and opportunities of microneedle‐based in vivo monitoring.
Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known as stratum corneum, providing minimally invasive access to interstitial fluid (ISF), which enables the monitoring of biochemical parameters in real‐time. This review covers recent progress to date in the area of electrochemical sensing using microneedles, and provides an overview of fabrication materials and processes, as well as applications. The main body of the review focuses on the fabrication of microneedle structures and their transformation into electrochemical biosensors for continuous monitoring. To this end, the main recognition elements and electrode functionalization ways are described, paying closer attention to aptamers and continuous aptamer‐based sensing, whose importance, merits, and limitations are highlighted. In addition to covering the main current applications, the review discusses the future threats and opportunities of microneedle‐based in vivo monitoring. This review explores recent advances in electrochemical sensing using microneedles—small, minimally invasive devices that access interstitial fluid for real‐time molecular monitoring. It highlights fabrication methods, materials, and biosensor development, with a focus on aptamer‐based sensing. The review also discusses current applications, challenges, and future prospects of microneedle‐based in vivo monitoring systems.
Author Ruiz‐Rubio, Leire
Conejo‐Cuevas, Guillermo
del Campo, Francisco Javier
Aller Pellitero, Miguel
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  givenname: Francisco Javier
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  surname: del Campo
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Snippet Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known as...
Abstract Microneedles are small piercing structures, with sizes in the micron‐to‐millimeter range, designed to penetrate painlessly the outer skin layer, known...
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SubjectTerms aptamers
electrochemical sensors
interstitial fluid
microneedles
wearable biosensors
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Title Microneedles for Continuous, Minimally Invasive Monitoring: A Technology Overview
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