Organic Bioelectronics for <i>In Vitro</i> Systems

Pitsalidis, Charalampos; Pappa, Anna‐Maria; Boys, Alexander J.; Fu, Ying; Moysidou, Chrysanthi‐Maria; Niekerk, Douglas van; Sáez, Janire; Savva, Achilleas; Iandolo, Donata; Owens, Róisı́n M.

doi:10.1021/acs.chemrev.1c00539

Cited by 59 publications

(59 citation statements)

References 796 publications

(1,720 reference statements)

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“…1,2 The interest is motivated by the possibility to combine electrochemical transduction mechanisms known from metallic electrodes with the intrinsic ampli cation properties of a transistor structure. 3 The ampli cation is highly wanted to improve signal to noise ratio in challenging sensor applications aiming for instance at biochemical detection in complex mixtures 4 or single cell bioelectronic monitoring. 5 Signi cant progress on this concept has been made by the introduction of organic or carbon-based semiconducting materials with high stability in water such as carbon nanotubes, 6,7 graphene, 8,9 or organic semiconductors.…”

Section: Introductionmentioning

confidence: 99%

“…24,3 A second, emerging class of biosensors that takes advantage of OECT ampli cation regards impedance based sensors for monitoring cellular adhesion and cell layer barrier properties as quanti ed by the transepithelial electrical resistance (TEER). 25,4 Monitoring such cellular properties is of importance in studies of wound healing, cancer development, toxicity assays or recognition processes in the immune system. 25 Impedance based biosensors quantify the ionic current that passes through a cellular layer when an AC voltage is applied.…”

Section: Introductionmentioning

confidence: 99%

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AC amplification gain in organic electrochemical transistors for impedance-based single cell sensors

Bonafè

Decataldo

Zironi

et al. 2022

Preprint

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Research on water-gated and organic electrochemical transistor (OECT) architectures is motivated by the prospect of a highly biocompatible interface capable of amplifying bioelectronic signals at the site of detection. Despite many demonstrations in these directions, a quantitative model for OECTs as impedance biosensors is still lacking. We overcome this issue by introducing a model experiment where we simulate the detection of a single cell by the impedance sensing of a dielectric microparticle. The highly reproducible experiment allows us to study the impact of transistor geometry and operation conditions on device sentivity. With the data we rationalize a mathematical model that provides clear guidelines for the optimization of OECTs as single cell sensors, and we verify the quantitative predictions in an in-vitro experiment. In the optimized geometry, the OECT-based impedance sensor allows to record single cell adhesion and detachment transients, showing a maximum gain of (20.2±0.9) dB with respect to a single electrode based impedance sensor.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

AC amplification gain in organic electrochemical transistors for impedance-based single cell sensors

Bonafè

Decataldo

Zironi

et al. 2022

Preprint

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“…Considering these properties, PEDOT:PSS-based scaffolds have come to the fore as multifunctional biomaterials with tailor-made properties allowing the development of smart bioelectronic interfaces for in vitro models. 23 Organic bioelectronic interfaces for in vitro 3D stem cell cultures e can be customized to mimic accurately the micro-environment required for stem cell growth. For example, Iandolo et al developed composite PEDOT:PSS/collagen scaffolds with highly elastic mechanical properties that supported "soft" neural crest-derived stem cell culture.…”

Section: Introductionmentioning

confidence: 99%

“…22 Both GOPS and PEGDE render PEDOT:PSS water-stable via similar mechanisms — a reaction of the epoxy rings moiety present in their structures with the weakly nucleophilic PSS - . 23 Importantly, the choice of cross-linker impacts the electrochemical, 24 surface topography, 21 and mechanical properties 25 of PEDOT:PSS structures. Considering these properties, PEDOT:PSS-based scaffolds have come to the fore as multifunctional biomaterials with tailor-made properties allowing the development of smart bioelectronic interfaces for in vitro models.…”

Section: Introductionmentioning

confidence: 99%

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3D Organic Bioelectronics for Monitoring In Vitro Stem Cell Cultures

Savva

Sáez

Barberio

et al. 2022

Preprint

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Three-dimensional in vitro stem cell models has enabled a fundamental understanding of cues that direct stem cell fate and be used to develop novel stem cell treatments. While sophisticated 3D tissues can be generated, technology that can accurately monitor these complex models in a high-throughput and non-invasive manner is not well adapted. Here we show the development of 3D bioelectronic devices based on the electroactive polymer poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) - PEDOT:PSS and their use for non-invasive, electrical monitoring of stem cell growth. We show that the electrical, mechanical and wetting properties as well as the pore size/architecture of 3D PEDOT:PSS scaffolds can be fine-tuned simply by changing the processing crosslinker additive. We present a comprehensive characterization of both 2D PEDOT:PSS thin films of controlled thicknesses, and 3D porous PEDOT:PSS structures made by the freeze-drying technique. By slicing the bulky scaffolds we show that homogeneous, porous 250 um thick PEDOT:PSS slices are produced, generating biocompatible 3D constructs able to support stem cell cultures. These multifunctional membranes are attached on Indium-Tin oxide substrates (ITO) with the help of an adhesion layer that is used to minimize the interface charge resistance. The optimum electrical contact result in 3D devices with a characteristic and reproducible, frequency dependent impedance response. This response changes drastically when human adipose derived stem cells grow within the porous PEDOT:PSS network as revealed by fluorescence microscopy. The increase of these stem cell population within the PEDOT:PSS porous network impedes the charge flow at the interface between PEDOT:PSS and ITO, enabling the interface resistance to be extracted by equivalent circuit modelling, used here as a figure of merit to monitor the proliferation of stem cells. The strategy of controlling important properties of 3D PEDOT:PSS structures simply by altering processing parameters can be applied for development of a number of stem cell in vitro models. We believe the results presented here will advance 3D bioelectronic technology for both fundamental understanding of in vitro stem cell cultures as well as the development of personalized therapies.

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Brain‐Inspired Organic Electronics: Merging Neuromorphic Computing and Bioelectronics Using Conductive Polymers

Krauhausen,

Coen,

Spolaor

et al. 2023

Adv Funct Materials

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Neuromorphic computing offers the opportunity to curtail the huge energy demands of modern artificial intelligence (AI) applications by implementing computations into new, brain‐inspired computing architectures. However, the lack of fabrication processes able to integrate several computing units into monolithic systems and the need for new, hardware‐tailored training algorithms still limit the scope of application and performance of neuromorphic hardware. Recent advancements in the field of organic transistors present new opportunities for neuromorphic systems and smart sensing applications, thanks to their unique properties such as neuromorphic behavior, low‐voltage operation, and mixed ionic‐electronic conductivity. Organic neuromorphic transistors push the boundaries of energy efficient brain‐inspired hardware AI, facilitating decentralized on‐chip learning and serving as a foundation for the advancement of closed‐loop intelligent systems in the next generation. The biocompatibility and dual ionic‐electronic conductivity of organic materials introduce new prospects for biointegration and bioelectronics. Their ability to sense and regulate biosystems, as well as their neuro‐inspired functions can be combined with neuromorphic computing to create the next‐generation of bioelectronics. These systems will be able to seamlessly interact with biological systems and locally compute biosignals in a relevant matter.

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Organic Bioelectronics for In Vitro Systems

Cited by 59 publications

References 796 publications

AC amplification gain in organic electrochemical transistors for impedance-based single cell sensors

AC amplification gain in organic electrochemical transistors for impedance-based single cell sensors

3D Organic Bioelectronics for Monitoring In Vitro Stem Cell Cultures

Brain‐Inspired Organic Electronics: Merging Neuromorphic Computing and Bioelectronics Using Conductive Polymers

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