PEER-REVIEWED PUBLICATION

2021

A flexible strain-responsive sensor fabricated from a biocompatible electronic ink via an additive-manufacturing process

Britton J, Krukiewicz K, et al.

Materials & Design

National University of Ireland Galway, Silesian University of Technology, Polimerbio S.L., University of the Basque Country (UPV/EHU)

RESEARCH SUMMARY
This study developed a biocompatible, strain-responsive biosensor fabricated from an environmentally sustainable elastomeric copolymer (x-pentadecalactone-co-e-decalactone; PDL) reinforced with silver nanowires (AgNW) to create a conductive electronic ink suitable for direct-write additive manufacturing. Electrochemical characterization showed a low percolation threshold (conductive behavior emerging around ~0.4% w/w AgNW and stabilizing by ~1% w/w), with the optimized 2% w/w AgNW formulation achieving low sheet resistance (~320 Ω/sq) and high capacitance (~2.06 mF/cm^2). Cytocompatibility was demonstrated using primary mixed neural cell cultures, where PDL/AgNW substrates supported neuronal adhesion and were associated with reduced astrocyte activation relative to controls. The optimized ink was then used to print high-resolution (sub-100 µm) interdigitated electrode strain sensors via pneumatic extrusion. Under simulated physiological conditions, the printed sensors showed measurable, repeatable impedance changes under cyclic strain, remained functional for ~21 days in PBS at 37°C (≈0.9 million cycles), and produced strain gauge factors on the order of ~2–3, supporting potential use in chronic monitoring applications such as intracranial pressure/brain swelling.

CELLSCALE INSTRUMENT USED

MechanoCulture T6

Biosensor strain-response testing was performed using a CellScale MCT6 bioreactor (MechanoCulture T6) configured to mechanically actuate clamped printed strain-sensor specimens while submerged in PBS at 37°C. A 60-interdigitated electrode sensor design was mounted using metallic grips and subjected to cyclic uniaxial actuation at 0.5 Hz with a 5% strain input (reported as a linear actuation/strain regimen), while impedance was recorded using a potentiostat with a 1 V AC sinusoidal input at 1 kHz. Measurements were collected daily over 21 days to quantify sensitivity (ΔZ/Z0), gauge factor stability, and durability under long-term cyclic strain exposure, reaching approximately 907,000 strain cycles under hydrated, temperature-controlled conditions.
AUTHORS

James Britton, Katarzyna Krukiewicz, Malu Chandran, Jorge Fernandez, Anup Poudel, Jose-Ramon Sarasua, Una FitzGerald, Manus J.P. Biggs.

PUBLICATION DETAILS
JOURNAL

Materials & Design

YEAR

2021

INSTITUTIONS

National University of Ireland Galway, Silesian University of Technology, Polimerbio S.L., University of the Basque Country (UPV/EHU)

COUNTRIES

Ireland, Poland, Spain

INSTRUMENT USED

MechanoCulture T6

TESTING METHODS

Fatigue TestingHydrated and Temperature Controlled TestingTensile Testing

RESEARCH APPLICATIONS

Material Fatigue and DurabilityPolymers and Elastomers TestingWearable Bioelectronics

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