Themed collection Microfluidics for Wearable and Implantable Technologies

This review outlines a system-level framework for active implantable drug delivery systems (AIDDSs), analyzing how design choices in actuation, powering, and communication affect clinical translation and the development of scalable devices.

Recent advances in wearable and implantable microfluidics enable real-time sensing, drug delivery, and closed-loop therapy, with emerging trends in stretchability, multimodal integration, and AI-driven data processing.

This review highlights how microfluidic technologies advance wearable and implantable biomedical devices for real-time health monitoring and targeted therapy, while addressing materials, fabrication, applications, and clinical translation challenges.

Liquid transport is an essential functionality in microfluidic operation. This review summarizes emerging strategies for liquid management in bioelectronics, with a focus on system-level integration and applications.

This review highlights advances in capillary microfluidic wearables enabling power-free, continuous biofluid monitoring and biosensing, with emphasis on fluidic architectures, analyte detection, and pathways for clinical translation.

Microneedle-based platform enables passive, zero-power extraction of interstitial fluid from skin models, demonstrating rapid sampling kinetics, efficient uptake, and accurate quantitative recovery of cortisol for wearable diagnostic applications.

A multifunctional microfluidic bioelectronic suture enables real-time wound monitoring and electrical stimulation to accelerate healing.

Schematic of the drug release (a) from MN patches by a general surface coating method and (b) from the MN patch with a hole combined with a microfluidic chip.

Herein, we report the first electrochemical microfluidic thread/paper-based analytical device (μTPAD) by harnessing the synergistic combination of embroidery as a manufacturing technique and paper-based technology.

Hydrophilic PDMS–PEG soft wearable microfluidics are developed via one-pot soft lithography, which doubles the sweat collection volume and advances noninvasive, reliable sampling for clinical analysis.

A wearable microfluidic device captures sweat on the dorsal distal phalanges of the fingers during everyday activity.

A stretchable liquid diode enables tuneable, passive, and unidirectional flow by coupling surface wettability modulation with mechanical stretching. This approach enables programmable liquid routing, for wearable microfluidic applications.

A wearable microfluidic device with magneto-active bistable valves enables energy-efficient, on-demand, and contamination-free sweat collection with high spatial and temporal resolution.

A flexible microchannel-confined droplet-based electricity generator (MC-DEG) is proposed, enabling biomechanical energy conversion and physiological signal monitoring.

Out-of-surface microchannels (OSMiCs) are arched, monolithic PDMS structures that shrink under tensile strain, directly converting skin stretching into fluid pressure and addressing a critical challenge in wearable microfluidics.

A multi-channel wearable sensing patch based on gate-all-around field-effect transistors that enables comprehensive health monitoring.

A novel wearable microfluidic device designed for dual-mode sweat sampling, addressing the limitations in real-time and on-demand modes operation, with applications in chronic disease management, athletic performance optimization, and early-stage condition detection.

Wearable microneedle-paper device enables simultaneous, minimally invasive detection of cortisol and dopamine in interstitial fluid via colorimetric distance-based sensing for simple, low-cost, equipment-free stress monitoring.

Ketone bodies are key products of fat metabolism, primarily consisting of acetoacetate (AcAc), β-hydroxybutyrate (BHB), and acetone (acetone).

Quantitative analysis of amino acid loss in sweat during exercise using a smartphone-enabled, microfluidic platform.