Soft and Ion‐Conducting Materials in Bioelectronics: From Conducting Polymers to Hydrogels

Jia, Manping; Rolandi, Marco

doi:10.1002/adhm.201901372

Cited by 73 publications

(57 citation statements)

References 159 publications

(182 reference statements)

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“…Material selection is not only important for device performance, the choice of materials is also crucial for a successful interface between device and tissue, especially when the device is to be implantable. [10,34] For materials and devices to be fully biocompatible, their surface as well as mechanical properties must be accepted by surrounding tissues and their cells. The materials also need to endure the biological environment over the intended timeframe to maintain a stable and reliable device performance.…”

Section: Materials and Microfabrication Methodsmentioning

confidence: 99%

“…Due to their softer mechanical properties organic polymers can provide a more body-friendly interface compared to classic inorganic materials. [6,10] Organic polymers are widely used in medicine, for example in drug delivery applications and as coating on stents. [84] In this chapter, the materials used to fabricate iontronic devices are presented, starting with IEMs and electrode materials, followed by a description of microfabrication techniques.…”

Section: Materials and Microfabrication Methodsmentioning

confidence: 99%

“…[40] Another method of neurotransmitter release can be achieved using materials such as hydrogels and polymers loaded with the neurotransmitter. [6,10] Molecules loaded in a these materials can be released slowly by passive di usion. If the molecule is an ion, active release can be performed from a conducting polymer, known as electrochemical release.…”

Section: Artificial Release Of Neurotransmittersmentioning

confidence: 99%

“…Even though this can be performed very locally and in a controlled manner, an even more seamless interface would be to mimic the signaling as it occurs naturally within the biological system. [9,10] The term "animal electricity" had been around since Galvani's experiments during the 18th century. [11] This concept is still valid in the sense that xi neuronal action potentials are referred to as electrical transmission, even though the charge carriers for these action potentials are ions rather than electrons.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Organic Bioelectronics for Neurotransmitter Release at the Speed of Life

Sjöström

2021

Linköping Studies in Science and Technology. Dissertations

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Section: Materials and Microfabrication Methodsmentioning

confidence: 99%

Section: Materials and Microfabrication Methodsmentioning

confidence: 99%

Section: Artificial Release Of Neurotransmittersmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Organic Bioelectronics for Neurotransmitter Release at the Speed of Life

Sjöström

2021

Linköping Studies in Science and Technology. Dissertations

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“…[ 221,222 ] An in‐depth discussion of developments in both stretchable and degradable conjugated polymers is beyond the scope of this report, but for a full discussion we recommend a number of recent reviews in this area. [ 43,149,215,221,223,224 ]…”

Section: Methodsmentioning

confidence: 99%

Organic Bioelectronics: Using Highly Conjugated Polymers to Interface with Biomolecules, Cells, and Tissues in the Human Body

Higgins

Fiego

Patrick

et al. 2020

Adv Materials Technologies

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Conjugated polymers exhibit interesting material and optoelectronic properties that make them well‐suited to the development of biointerfaces. Their biologically relevant mechanical characteristics, ability to be chemically modified, and mixed electronic and ionic charge transport are captured within the diverse field of organic bioelectronics. Conjugated polymers are used in a wide range of device architectures, and cell and tissue scaffolds. These devices enable biosensing of many biomolecules, such as metabolites, nucleic acids, and more. Devices can be used to both stimulate and sense the behavior of cells and tissues. Similarly, tissue interfaces permit interaction with complex organs, aiding both fundamental biological understanding and providing new opportunities for stimulating regenerative behaviors and bioelectronic based therapeutics. Applications of these materials are broad, and much continues to be uncovered about their fundamental properties. This report covers the current understanding of the fundamentals of conjugated polymer biointerfaces and their interactions with biomolecules, cells, and tissues in the human body. An overview of current materials and devices is presented, along with highlighted major in vivo and in vitro applications. Finally, open research questions and opportunities are discussed.

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Concentration Gradient‐Based Soft Robotics: Hydrogels Out of Water

Lopez-Diaz

Martín-Pacheco

Rodríguez

et al. 2020

Adv Funct Materials

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Hydrogels are biocompatible soft materials that resemble biological tissues more than any other material. However, the use of these systems in soft robotics has been limited to aqueous environments. In the work published to date, hydrogels have relied on external water to swell or shrink in response to stimuli and, therefore, to actuate macroscopically. In the work reported here, this limitation is overcome by synthesizing a novel type of electroactive hydrogels capable of actuating when a low electric field is applied, even outside water. The bending actuation of these materials is caused by the movement of solvated ions within the hydrogel, which generates a concentration gradient, making it possible to use them directly in ambient-air conditions. A mathematical model for this behavior is proposed. Issues like resistive heating and material drying are addressed by preparing graphene hybrid hydrogels and by using hygroscopic salts. Two applications are presented as a demonstration of the capabilities of these hydrogels: a soft gripper with two continuum actuators and a soft fingertip capable of changing its volume and stiffness. In addition, the possibility of fabrication by 3D printing technologies enhances the applicability of these promising materials, thus paving the way for innovative developments.

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Soft and Ion‐Conducting Materials in Bioelectronics: From Conducting Polymers to Hydrogels

Cited by 73 publications

References 159 publications

Organic Bioelectronics for Neurotransmitter Release at the Speed of Life

Organic Bioelectronics for Neurotransmitter Release at the Speed of Life

Organic Bioelectronics: Using Highly Conjugated Polymers to Interface with Biomolecules, Cells, and Tissues in the Human Body

Concentration Gradient‐Based Soft Robotics: Hydrogels Out of Water

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