Porous PEDOT:PSS Particles and their Application as Tunable Cell Culture Substrate

Rauer, Sebastian; Bell, Daniel Josef; Jain, Puja; Rahimi, Khosrow; Felder, Daniel; Linkhorst, John; Weßling, Matthias

doi:10.1002/admt.202100836

Cited by 15 publications

(16 citation statements)

References 72 publications

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“…Airborne H 2 O molecules have been shown to passivate the surface-exposed SO 3 H groups and hinder their ionization . The PEDOT:PSS surface is mainly covered with the hydrophilic PSS chains, ,− and H 2 O molecules can form hydrogen bonds with the surface-exposed SO 3 H groups (Figure B). Accordingly, deionized water vapor is introduced to the argon chamber to bring the RH level to 10%.…”

Section: Resultsmentioning

confidence: 99%

Highly Rectifying Water-Mediated Hydrogen Bond-Coupled Organic–Inorganic Interfaces

Hossein‐Babaei

Karimpour

2023

ACS Appl. Mater. Interfaces

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Asymmetrically conducting interfaces are the building blocks of electronic devices. While p–n junction diodes made of seminal inorganic semiconductors with rectification ratios close to the theoretical limits are routinely fabricated, the analogous organic–inorganic and organic–organic interfaces are still too leaky to afford functional use. We report fabricating highly rectifying organic–inorganic interfaces by forming water-mediated hydrogen bonds between the hydrophilic surfaces of a hole-conducting polymer anode and a polycrystalline n-type metal oxide cathode. These hydrogen bonds simultaneously strengthen the anode–cathode electronic coupling, facilitate the matching between their incompatible surface structures, and passivate the detrimental surface imperfections. Compared to an analogous directly joined interface, our hydrogen-bonded Au-PEDOT:PSS–H2O–TiO2-Ti diodes demonstrate 105 times higher rectification ratios. These results illustrate the strong electronic coupling power of the hydrogen bonds on a macroscopic scale and underscore the hydrogen-bonded interfaces as the building blocks of fabricating organic electronic and optoelectronic devices. The presented interface model is anticipated to advance designing electronic devices based on the organic–organic and organic–inorganic hetero-interfaces. Described electronic implications of hydrogen bonding on the conductive polymer interfaces are anticipated to be impactful in the organic electronics and neuromorphic engineering.

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Section: Resultsmentioning

confidence: 99%

Highly Rectifying Water-Mediated Hydrogen Bond-Coupled Organic–Inorganic Interfaces

Hossein‐Babaei

Karimpour

2023

ACS Appl. Mater. Interfaces

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“…From the material side, it is becoming evident that striving toward softer materials (in the 10-100 kPa range), such as hydrogels or viscoelastic materials, achieve tighter interaction with biological tissue. [42,[78][79][80][81] These materials bear the potential for lifelong implantation and continuous monitoring and interaction with the surrounding tissue by further displaying biomimetic (and conductive) tissue-like architectures, which can be achieved through innovative techniques such as additive manufacturing and bioprinting. However, it is still challenging to create devices with such materials with a high electrode count, as they are not compatible with standard microfabrication techniques and chemicals, thereby introducing many extra steps that make the processing highly manual and labor-intensive.…”

Section: Biological Compliancementioning

confidence: 99%

Toward the Next Generation of Neural Iontronic Interfaces

Forró

Musall

Montes³

et al. 2023

Adv Healthcare Materials

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Neural interfaces are evolving at a rapid pace owing to advances in material science and fabrication, reduced cost of scalable complementary metal oxide semiconductor (CMOS) technologies, and highly interdisciplinary teams of researchers and engineers that span a large range from basic to applied and clinical sciences. This study outlines currently established technologies, defined as instruments and biological study systems that are routinely used in neuroscientific research. After identifying the shortcomings of current technologies, such as a lack of biocompatibility, topological optimization, low bandwidth, and lack of transparency, it maps out promising directions along which progress should be made to achieve the next generation of symbiotic and intelligent neural interfaces. Lastly, it proposes novel applications that can be achieved by these developments, ranging from the understanding and reproduction of synaptic learning to live‐long multimodal measurements to monitor and treat various neuronal disorders.

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“…compliant surfaces. [26][27][28] However, despite modifications of PE-DOT:PSS and PPy systems, including incorporation into a hydrogel matrix to provide better cell interfaces, these composites have limitations. The porous nature of these conductive hydrogels is minimal which results in limited ability for cells to integrate and migrate through the matrix.…”

Section: Introductionmentioning

confidence: 99%

“…[ 24,25 ] Now, poly(3,4‐ethylenedioxythiopene) is doped with PSS, or commonly known as PEDOT:PSS, and can be electrodeposited into small, confined microchannels for equally “fuzzy” but also more mechanically compliant surfaces. [ 26–28 ] However, despite modifications of PEDOT:PSS and PPy systems, including incorporation into a hydrogel matrix to provide better cell interfaces, these composites have limitations. The porous nature of these conductive hydrogels is minimal which results in limited ability for cells to integrate and migrate through the matrix.…”

Section: Introductionmentioning

confidence: 99%

Tunable Conductive Hydrogel Scaffolds for Neural Cell Differentiation

Tringides

Boulingre

Khalil

et al. 2022

Adv Healthcare Materials

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Multielectrode arrays would benefit from intimate engagement with neural cells, but typical arrays do not present a physical environment that mimics that of neural tissues. It is hypothesized that a porous, conductive hydrogel scaffold with appropriate mechanical and conductive properties could support neural cells in 3D, while tunable electrical and mechanical properties could modulate the growth and differentiation of the cellular networks. By incorporating carbon nanomaterials into an alginate hydrogel matrix, and then freeze‐drying the formulations, scaffolds which mimic neural tissue properties are formed. Neural progenitor cells (NPCs) incorporated in the scaffolds form neurite networks which span the material in 3D and differentiate into astrocytes and myelinating oligodendrocytes. Viscoelastic and more conductive scaffolds produce more dense neurite networks, with an increased percentage of astrocytes and higher myelination. Application of exogenous electrical stimulation to the scaffolds increases the percentage of astrocytes and the supporting cells localize differently with the surrounding neurons. The tunable biomaterial scaffolds can support neural cocultures for over 12 weeks, and enable a physiologically mimicking in vitro platform to study the formation of neuronal networks. As these materials have sufficient electrical properties to be used as electrodes in implantable arrays, they may allow for the creation of biohybrid neural interfaces and living electrodes.

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Porous PEDOT:PSS Particles and their Application as Tunable Cell Culture Substrate

Cited by 15 publications

References 72 publications

Highly Rectifying Water-Mediated Hydrogen Bond-Coupled Organic–Inorganic Interfaces

Highly Rectifying Water-Mediated Hydrogen Bond-Coupled Organic–Inorganic Interfaces

Toward the Next Generation of Neural Iontronic Interfaces

Tunable Conductive Hydrogel Scaffolds for Neural Cell Differentiation

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