Integrated Hollow Microneedle-optofluidic Biosensor for Therapeutic Drug Monitoring in Sub-nanoliter Volumes

Overview

Journal Sci Rep

Specialty Science

Date 2016 Jul 7

PMID 27380889

Citations 24

Authors

Sahan A Ranamukhaarachchi

Celestino Padeste

Matthias Dubner

Urs O Hafeli

Boris Stoeber

Victor J Cadarso

Affiliations

Soon will be listed here.

Abstract

Therapeutic drug monitoring (TDM) typically requires painful blood drawn from patients. We propose a painless and minimally-invasive alternative for TDM using hollow microneedles suitable to extract extremely small volumes (<1 nL) of interstitial fluid to measure drug concentrations. The inner lumen of a microneedle is functionalized to be used as a micro-reactor during sample collection to trap and bind target drug candidates during extraction, without requirements of sample transfer. An optofluidic device is integrated with this microneedle to rapidly quantify drug analytes with high sensitivity using a straightforward absorbance scheme. Vancomycin is currently detected by using volumes ranging between 50-100 μL with a limit of detection (LoD) of 1.35 μM. The proposed microneedle-optofluidic biosensor can detect vancomycin with a sample volume of 0.6 nL and a LoD of <100 nM, validating this painless point of care system with significant potential to reduce healthcare costs and patients suffering.

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