Enabling actuation and sensing in organs-on-chip using electroactive polymers

Motreuil-Ragot, Paul; Hunt, Andrés; Kasi, Dhanesh G.; Brajon, Bruno; Maagdenberg, Arn van den; Orlova, Valeria V.; Mastrangeli, Massimo; Sarro, P.M.

doi:10.1109/robosoft48309.2020.9115977

Cited by 6 publications

(9 citation statements)

References 17 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…[21]. Top right: an 8-mm long IPMC cantilever fitting in a single well of a 12-well plate by means of a custom electrode holder [30]. Bottom left: a silicon frame embedding 8 floating-gate field-effect transistors and supporting an optically transparent PDMS membrane.…”

Section: Topography: Engineered Heart Tissue Structuresmentioning

confidence: 99%

“…Hz) [30]. C) Analyte detection from the output characteristics of a dual-gate nMOS-based electrochemical charge sensor [35].…”

Section: ) A) Contraction Force Exerted By a 3 µL-derived Engineered ...mentioning

confidence: 99%

“…The latter are typically bulky, expensive and nonuser-friendly, and may thus limit the adoption of OoC devices by researchers and industry. To this limitation, we proposed the first actuating and sensing smart material-based OoC device (Fig 2, top right), and demonstrated its functionality by culturing human vascular smooth muscle cells (vSMC) [30].…”

Section: Actuation: Electro-active Polymer-based Substratementioning

confidence: 99%

“…A) Contraction force exerted by a 3 µL-derived engineered heart tissue, estimated by software-based optical tracking of micropillar displacement [21]. B) Displacement of an 8 mm-long IPMC cantilever driven by low input voltage (5 Vpp, 1Hz)[30]. C) Analyte detection from the output characteristics of a dual-gate nMOS-based electrochemical charge sensor[35].…”

mentioning

confidence: 99%

See 3 more Smart Citations

Microelectromechanical Organs-on-Chip

Mastrangeli

Aydogmus

Dostanic

et al. 2021

2021 21st International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers)

Self Cite

View full text Add to dashboard Cite

Stemming from the convergence of tissue engineering and microfluidics, organ-on-chip (OoC) technology can reproduce in vivo-like dynamic microphysiological environments for tissues in vitro. The possibility afforded by OoC devices of realistic recapitulation of tissue and organ (patho)physiology may hold the key to bridge the current translational gap in drug development, and possibly foster personalized medicine. Here we underline the biotechnological convergence at the root of OoC technology, and outline research tracks under development in our group at TU Delft along two main directions: fabrication of innovative microelectromechanical OoC devices, integrating stimulation and sensing of tissue activity, and their embedding within advanced platforms for pre-clinical research. We conclude with remarks on the role of open technology platforms for the broader establishment of OoC technology in pre-clinical research and drug development.

show abstract

Section: Topography: Engineered Heart Tissue Structuresmentioning

confidence: 99%

“…Hz) [30]. C) Analyte detection from the output characteristics of a dual-gate nMOS-based electrochemical charge sensor [35].…”

Section: ) A) Contraction Force Exerted By a 3 µL-derived Engineered ...mentioning

confidence: 99%

Section: Actuation: Electro-active Polymer-based Substratementioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Microelectromechanical Organs-on-Chip

Mastrangeli

Aydogmus

Dostanic

et al. 2021

2021 21st International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers)

Self Cite

View full text Add to dashboard Cite

show abstract

“…Hence lab-on-chip and organ-on-chip devices can benefit from the integration of IPMCs because of their actuation and sensing capabilities. Utilisation of a 180 µm-thick IPMC has been studied for actuating and sensing in bio-MEMS transducers applications [10], with a focus on sensing intrinsic tissue contraction [11,12]. However, these studies could not realize measurement of tissue contractions, indicating that the stiffness of the 180 µm-thick IPMC is too high to allow the cultured tissue to induce a displacement on the ionic electroactive polymer.…”

Section: Introductionmentioning

confidence: 99%

Manufacturing thin ionic polymer metal composite for sensing at the microscale

Ragot

Hunt

Sacco

et al. 2023

Smart Mater. Struct.

View full text Add to dashboard Cite

Ionic polymer metal composites (IPMCs) are a class of materials with a rising appeal in biological micro-electromechanical systems (bio-MEMS) due to their unique properties (low voltage output, bio-compatibility, affinity with ionic medium). While tailoring and improving actuation capabilities of IPMCs is a key motivator in almost all IPMC manufacturing reports, very little efforts have been dedicated to sensing using IPMC thinner than 100 μm. Most reports on IPMC manufacturing and utilization rely on 180μm-thick Nafion with platinum electrodes, too stiff for bio-MEMS applications. The same fabrication process on thinner membranes does yield in very poor electrodes and performance, and needs to be studied to increase flexibility and sensitivity in the microscale range. This study demonstrates an electroless Pt deposition method for fabricating bio-MEMS-suitable 50 μm-thick IPMC samples. First, we perform a comparative study on the platinum distribution within the Nafion backbone as well as on the surface for the standard electroless deposition recipe for thin (50 μm) and thick (180 μm) Nafion. We report strong differences in platinum distribution for thick and thin IPMC that experienced the same manufacturing process. By varying chemical concentrations from the standard recipe we obtain convenient platinum distribution on thin Nafion, with platinum mainly localized in proximity of surface, as well as electrodes with lower sheet resistance. We could measure the flexural rigidity as 3.43 10−8 N.m2, 46 times lower than standard 180 μm thick IPMC. The calculated sensitivity is 0.476 ± 0.02 mV/mm and the limit of detection for our sensor is 500 ± 20 μm. This procedure sets a milestone for manufacturing 50 μm-thick IPMC for transducers and sensors in bio-MEMS applications.

show abstract