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1. Textile Actuators Comprising Reduced Graphene Oxide as the Current Collector.

Author

Dutta, Sujan, Mehraeen, Shayan, Martinez, Jose G., Bashir, Tariq, Persson, Nils‐Krister, and Jager, Edwin W. H.

Subjects
GRAPHENE oxide, CARBON-based materials, ACTUATORS, WEARABLE technology, YARN, ELECTROTEXTILES, DISPLACEMENT (Mechanics)
Abstract

Electronic textiles (E‐textiles) are made using various materials including carbon nanotubes, graphene, and graphene oxide. Among the materials here, e‐textiles are fabricated with reduced graphene oxide (rGO) coating on commercial textiles. rGO‐based yarns are prepared for e‐textiles by a simple dip coating method with subsequent non‐toxic reduction. To enhance the conductivity, the rGO yarns are coated with poly(3,4‐ethylene dioxythiophene): poly(styrenesulfonic acid) (PEDOT) followed by electrochemical polymerization of polypyrrole (PPy) as the electromechanically active layer, resulting in textile actuators. The rGO‐based yarn actuators are characterized in terms of both isotonic displacement and isometric developed forces, as well as electron microscopy and resistance measurements. Furthermore, it is demonstrated that both viscose rotor spun (VR) and viscose multifilament (VM) yarns can be used for yarn actuators. The resulting VM‐based yarn actuators exhibit high strain (0.58%) in NaDBS electrolytes. These conducting yarns can also be integrated into textiles and fabrics of various forms to create smart e‐textiles and wearable devices. [ABSTRACT FROM AUTHOR]

Published
2024
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4. Electrochemical control of bone microstructure on electroactive surfaces for modulation of stem cells and bone tissue engineering.

Author

Cao, Danfeng, Martinez, Jose G., Anada, Risa, Hara, Emilio Satoshi, Kamioka, Hiroshi, and Jager, Edwin W. H.

Subjects
STEM cells, STEM cell niches, BONE cells, TISSUE engineering, CYTOLOGY
Abstract

Controlling stem cell behavior at the material interface is crucial for the development of novel technologies in stem cell biology and regenerative medicine. The composition and presentation of bio-factors on a surface strongly influence the activity of stem cells. Herein, we designed an electroactive surface that mimics the initial process of trabecular bone formation, by immobilizing chondrocyte-derived plasma membrane nanofragments (PMNFs) on its surface for rapid mineralization within 2 days. Moreover, the electroactive surface was based on the conducting polymer polypyrrole (PPy), which enabled dynamic control of the presentation of PMNFs on the surface via electrochemical redox switching, further resulting in the formation of bone minerals with different morphologies. Furthermore, bone minerals with contrasting surface morphologies had differential effects on the differentiation of human bone marrow-derived stem cells (hBMSCs) cultured on the surface. Together, this electroactive surface showed multifunctional characteristics, not only allowing dynamic control of PMNF presentation but also promoting the formation of bone minerals with different morphologies within 2 days. This electroactive substrate could be valuable for more precise control of stem cell growth and differentiation, and further development of more suitable microenvironments containing bone apatite for housing a bone marrow stem cell niche, such as biochips/bone-on-chips. [ABSTRACT FROM AUTHOR]

Published
2023
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5. Textile Actuators Comprising Reduced Graphene Oxide as the Current Collector

Author

Dutta, Sujan, Mehraeen, Shayan, Martinez, Jose G., Bashir, Tariq, Persson, Nils-Krister, Jager, Edwin W. H., Dutta, Sujan, Mehraeen, Shayan, Martinez, Jose G., Bashir, Tariq, Persson, Nils-Krister, and Jager, Edwin W. H.

Abstract

Electronic textiles (E-textiles) are made using various materials including carbon nanotubes, graphene, and graphene oxide. Among the materials here, e-textiles are fabricated with reduced graphene oxide (rGO) coating on commercial textiles. rGO-based yarns are prepared for e-textiles by a simple dip coating method with subsequent non-toxic reduction. To enhance the conductivity, the rGO yarns are coated with poly(3,4-ethylene dioxythiophene): poly(styrenesulfonic acid) (PEDOT) followed by electrochemical polymerization of polypyrrole (PPy) as the electromechanically active layer, resulting in textile actuators. The rGO-based yarn actuators are characterized in terms of both isotonic displacement and isometric developed forces, as well as electron microscopy and resistance measurements. Furthermore, it is demonstrated that both viscose rotor spun (VR) and viscose multifilament (VM) yarns can be used for yarn actuators. The resulting VM-based yarn actuators exhibit high strain (0.58%) in NaDBS electrolytes. These conducting yarns can also be integrated into textiles and fabrics of various forms to create smart e-textiles and wearable devices.

Published
2023
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6. Effect of Core Yarn on Linear Actuation of Electroactive Polymer Coated Yarn Actuators

Author

Mehraeen, Shayan, Asadi, Milad, Martinez, Jose. G., Persson, Nils-Krister, Stålhand, Jonas, Jager, Edwin W. H., Mehraeen, Shayan, Asadi, Milad, Martinez, Jose. G., Persson, Nils-Krister, Stålhand, Jonas, and Jager, Edwin W. H.

Abstract

Smart textiles combine the features of conventional textiles with promising properties of smart materials such as electromechanically active polymers, resulting in textile actuators. Textile actuators comprise of individual yarn actuators, so understanding their electro-chemo-mechanical behavior is of great importance. Herein, this study investigates the effect of inherent structural and mechanical properties of commercial yarns, that form the core of the yarn actuators, on the linear actuation of the conducting-polymer-based yarn actuators. Commercial yarns were coated with poly(3,4-ethylenedioxythiophene)-poly(styrenesulfonate) (PEDOT:PSS) to make them conductive. Then polypyrrole (PPy) that provides the electromechanical actuation is electropolymerized on the yarn surface under controlled conditions. The linear actuation of the yarn actuators is investigated in aqueous electrolyte under isotonic and isometric conditions. The yarn actuators generated an isotonic strain up to 0.99% and isometric force of 95 mN. The isometric strain achieved in this work is more than tenfold and threefold greater than the previously reported yarn actuators. The isometric actuation force shows an increase of nearly 11-fold over our previous results. Finally, a qualitative mechanical model is introduced to describe the actuation behavior of yarn actuators. The strain and force created by the yarn actuators make them promising candidates for wearable actuator technologies. © 2023 The Authors. Advanced Materials Technologies published by Wiley-VCH GmbH.

Published
2023
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8. Soft actuators that self-create bone for biohybrid (micro)robotics

Author

Cao, Danfeng, Martinez, Jose Gabriel, Hara, Emilio Satoshi, Jager, Edwin W. H., Cao, Danfeng, Martinez, Jose Gabriel, Hara, Emilio Satoshi, and Jager, Edwin W. H.

Abstract

Here we present a new class of variable stiffness actuators for soft robotics based on biohybrid materials that change their state from soft-to-hard by creating their own bones. The biohybrid variable stiffness soft actuators were fabricated by combining the electromechanically active polymer polypyrrole (PPy) with a soft substrate of polydimethylsiloxane or alginate gel. These actuators were functionalized with cell-derived plasma membrane nanofragments (PMNFs), which promote rapid mineralization within 2 days. These actuators were used in robotic devices, and PMNF mineralization resulted in the robotic devices to achieve a soft to stiff state change and thereby a decreased or stopped actuation. Moreover, perpendicularly and diagonally patterned actuators were prepared. The patterned actuators showed programmed directional actuation motion and could be fixated in this programmed state. Finally, patterned actuators that combined soft and rigid parts in one actuator showed more complex actuation motion. Together, these variable stiffness actuators could expand the range of applications of morphing robotics with more complex structures and functions., Funding: Japanese Society of the Promotion of Science (JSPS) Bridge Fellowship program [BR170502]; KAKENHI [JP20H04534]; JSPS [JPJSBP 120 209 923]; STINT; Swedish Research Council [VR2014-3079]; China Scholarship Council [201808330454]

Published
2022
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9. Ionofibers: Ionically Conductive Textile Fibers for Conformal i-Textiles

Author

Huniade, Claude, Melling, Daniel, Vancaeyzeele, Cédric, Nguyen, Tran-Minh Giao, Vidal, Frédéric, Plesse, Cédric, Jager, Edwin W. H., Bashir, Tariq, Persson, Nils-Krister, Huniade, Claude, Melling, Daniel, Vancaeyzeele, Cédric, Nguyen, Tran-Minh Giao, Vidal, Frédéric, Plesse, Cédric, Jager, Edwin W. H., Bashir, Tariq, and Persson, Nils-Krister

Abstract

With the rise of ion-based devices using soft ionic conductors, ionotronics show the importance of matching electronic and biological interfaces. Since textiles are conformal, an essential property for matching interfaces, light-weight and comfortable, they present as an ideal candidate for a new generation of ionotronics, i-textiles. As fibers are the building blocks of textiles, ionically conductive fibers, named ionofibers, are needed. However, ionofibers are not yet demonstrated to fulfill the fabric manufacturing requirements such as mechanical robustness and upscaled production. Considering that ionogels are known to be conformal films with high ionic conductivity, ionofibers are produced from commercial core yarns with specifically designed ionogel precursor solution via a continuous dip-coating process. These ionofibers are to be regarded as composites, which keep the morphology and improve the mechanical properties from the core yarns while adding the (ionic) conductive function. They keep their conductivity also after their integration into conformal fabrics; thus, an upscaled production is a likely outlook. The findings offer promising perspectives for i-textiles with enhanced textile properties and in-air electrochemical applications., WEAFING

Published
2022
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10. Fast and High-Strain Electrochemically Driven Yarn Actuators in Twisted and Coiled Configurations

Author

Aziz, Shazed, Martinez, Jose G., Salahuddin, Bidita, Persson, Nils-Krister, Jager, Edwin W. H., Aziz, Shazed, Martinez, Jose G., Salahuddin, Bidita, Persson, Nils-Krister, and Jager, Edwin W. H.

Abstract

Commercially available yarns are promising precursor for artificial muscles for smart fabric-based textile wearables. Electrochemically driven conductive polymer (CP) coated yarns have already shown their potential to be used in smart fabrics. Unfortunately, the practical application of these yarns is still hindered due to their slow ion exchange properties and low strain. Here, a method is demonstrated to morph poly-3,4-ethylenedioxythiophene:poly-styrenesulfonate (PEDOT:PSS) coated multifilament textile yarns in highly twisted and coiled structures, providing >1% linear actuation in <1 s at a potential of +0.6 V. A potential window of +0.6 V and -1.2 V triggers the fully reversible actuation of a coiled yarn providing >1.62% strain. Compared to the untwisted, regular yarns, the twisted and coiled yarns produce >9x and >20x higher strain, respectively. The strain and speed are significantly higher than the maximum reported results from other electrochemically operated CP yarns. The yarn’s actuation is explained by reversible oxidation/reduction reactions occurring at CPs. However, the helical opening/closing of the twisted or coiled yarns due to the torsional yarn untwisting/retwisting assists the rapid and large linear actuation. These PEDOT:PSS coated yarn actuators are of great interest to drive smart textile exoskeletons.

Published
2021
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11. EMIm-OTf Ionogel Coated Fibres - Characterisation and Development, Aiming at Ionic Smart Textiles

Author

Huniade, Claude, Mehraeen, Shayan, Jager, Edwin W. H., Bashir, Tariq, Persson, Nils-Krister, Huniade, Claude, Mehraeen, Shayan, Jager, Edwin W. H., Bashir, Tariq, and Persson, Nils-Krister

Abstract

Ions are prevalent within bioelectronics, as they are the main charge carriers in living systems. In contrast to electronic systems, ionic ones are closer to what can be found in our body; in muscles, neurons and nerves. Textiles are a much-used biomedical material, both in vivo and in vitro due to its membrane character, highly efficient area, softness, biocompatibility and biodegradability. Modifying the physicochemical properties of the core or the surface of textile has been reported a countless number of times, but still, its use in a bioelectrical context is limited. Fibres are the building blocks of textiles and what make textiles an architected class of material. Then ionically conductive fibres are of great interest. Here, we show the preparation of iono-conductive textile fibres through the (semi-)continuous dip-coating of ionogel on the cellulose-based viscose. Ionogels are composed of salts in liquid state and a 3-dimensional solid network, in our case an ionic liquid (IL), 1-Ethyl-3-methylimidazolium trifluoromethanesulfonate, commonly named EMIm OTf or EMIm Triflate, and a thiol acrylate network, allowing the mobility of the ions within or in/out of the gel. This specific combination is a first effort towards the development of ionic textile fibres and ionic smart textiles, as a variety of ILs with different cations and anions exists, potentially allowing a large number of different combinations. We investigate how the coating of this ionogel affects the mechanical properties as well as the conductivity in AC or DC arrangement and their relation to temperature and humidity. Also, the thermal stability and sensitivity of degradation of the fibre system is studied. Moreover, we introduce different textile structures, and potential applications directed to bioelectronics.

Published
2021

16. Switchable presentation of cytokines on electroactive polypyrrole surfaces for hematopoietic stem and progenitor cells

Author

Baumgartner, Johanna, Jönsson, Jan-Ingvar, Jager, Edwin W. H., Baumgartner, Johanna, Jönsson, Jan-Ingvar, and Jager, Edwin W. H.

Abstract

Hematopoietic stem cells are used in transplantations for patients with hematologic malignancies. Scarce sources require efficient strategies of expansion, including polymeric biomaterials mimicking architectures of bone marrow tissue. Tissue microenvironment and mode of cytokine presentation strongly influence cell fate. Although several cytokines with different functions as soluble or membrane-bound mediators have already been identified, their precise roles have not yet been clarified. A need exists for in vitro systems that mimic the in vivo situation to enable such studies. One way is to establish surfaces mimicking physiological presentation using protein-immobilization onto polymer films. However these films merely provide a static presentation of the immobilized proteins. It would be advantageous to also dynamically change protein presentation and functionality to better reflect the in vivo conditions. The electroactive polymer polypyrrole shows excellent biocompatibility and electrochemically alters its surface properties, becoming an interesting choice for such setups. Here, we present an in vitro system for switchable presentation of membrane-bound cytokines. We use interleukin IL-3, known to affect hematopoiesis, and show that when immobilized on polypyrrole films, IL-3 is bioavailable for the bone marrow-derived FDC-P1 progenitor cell line. Moreover, IL-3 presentation can be successfully altered by changing the redox state of the film, in turn influencing FDC-P1 cell viability. This novel in vitro system provides a valuable tool for stimuli-responsive switchable protein presentation allowing the dissection of relevant mediators in stem and progenitor cell behavior.

Published
2018
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17. Patterning highly conducting conjugated polymer electrodes for soft and flexible microelectrochemical devices

Author

Khaldi, Alexandre, Falk, Daniel, Bengtsson, Katarina, Maziz, Ali, Filippini, Daniel, Robinson, Nathaniel D, Jager, Edwin W. H., Khaldi, Alexandre, Falk, Daniel, Bengtsson, Katarina, Maziz, Ali, Filippini, Daniel, Robinson, Nathaniel D, and Jager, Edwin W. H.

Abstract

There is a need for soft actuators in various biomedical applications in order to manipulate delicate objects such as cells and tissues. Soft actuators are able to adapt to any shape and limit the stress applied to delicate objects. Conjugated polymer actuators, especially in the so-called trilayer configuration, are interesting candidates for driving such micromanipulators. However, challenges involved in patterning the electrodes in a trilayer with individual contact have prevented further development of soft micromanipulators based on conjugated polymer actuators. To allow such patterning, two printing-based patterning techniques have been developed. First an oxidant layer is printed using either syringe-based printing or micro-contact printing, followed by vapor phase polymerization of the conjugated polymer. Sub-millimeter patterns with electronic conductivities of 800 Scm-1 are obtained. Next, laser ablation is used to cleanly cut the final device structures including the printed patterns, resulting in fingers with individually controllable digits and miniaturized hands. The methods presented in this paper will enable integration of patterned electrically active conjugated polymer layers in many types of complex 3-D structures., Funding agencies:This study was financially supported by Linköping University, COST Action MP1003 ESNAM (European Scientific Network for Artificial Muscles), the Swedish Research Council (VR – 2010-6672, 2014-3079, 2015-03298), the Knut & Alice Wallenberg Stiftelse (LiU-2010-00318 & LiU-2012- 01361), and the EU FP7 Marie Curie action IEF (625923 POLYACT)

Published
2018
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18. The role of ATP signalling in response to mechanical stimulation studied in T24 cells using new microphysiological tools

Author

Guan, Na N., Sharma, Nimish, Hallén‐Grufman, Katarina, Jager, Edwin W. H., Svennersten, Karl, Guan, Na N., Sharma, Nimish, Hallén‐Grufman, Katarina, Jager, Edwin W. H., and Svennersten, Karl

Abstract

The capacity to store urine and initiate voiding is a valued characteristic of the human urinary bladder. To maintain this feature, it is necessary that the bladder can sense when it is full and when it is time to void. The bladder has a specialized epithelium called urothelium that is believed to be important for its sensory function. It has been suggested that autocrine ATP signalling contributes to this sensory function of the urothelium. There is well‐established evidence that ATP is released via vesicular exocytosis as well as by pannexin hemichannels upon mechanical stimulation. However, there are still many details that need elucidation and therefore there is a need for the development of new tools to further explore this fascinating field. In this work, we use new microphysiological systems to study mechanostimulation at a cellular level: a mechanostimulation microchip and a silicone‐based cell stretcher. Using these tools, we show that ATP is released upon cell stretching and that extracellular ATP contributes to a major part of Ca2+ signalling induced by stretching in T24 cells. These results contribute to the increasing body of evidence for ATP signalling as an important component for the sensory function of urothelial cells. This encourages the development of drugs targeting P2 receptors to relieve suffering from overactive bladder disorder and incontinence.

Published
2018
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19. Knitting and weaving artificial muscles

Author

Maziz, Ali, Concas, Alessandro, Khaldi, Alexandre, Stålhand, Jonas, Persson, Nils-Krister, Jager, Edwin W. H., Laboratoire de Physico-chimie des Polymères et des Interfaces (LPPI), Fédération INSTITUT DES MATÉRIAUX DE CERGY-PONTOISE (I-MAT), Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine-Université de Cergy Pontoise (UCP), Université Paris-Seine-Université Paris-Seine, Department of Physics, Chemistry and Biology [Linköping] (IFM), and Linköping University (LIU)

Subjects
soft robotics, Artificial muscles, SciAdv r-articles, Robotics, [CHIM.MATE]Chemical Sciences/Material chemistry, Electrical Engineering, Electronic Engineering, Information Engineering, actuators, Conducting Polymers, Applied Sciences and Engineering, advanced textile technology, Humans, [CHIM]Chemical Sciences, Artificial Organs, Muscle, Skeletal, Elektroteknik och elektronik, Research Articles, Research Article
Abstract

Textile artificial muscles were developed using weaving to increase the force and knitting to amplify the strain., A need exists for artificial muscles that are silent, soft, and compliant, with performance characteristics similar to those of skeletal muscle, enabling natural interaction of assistive devices with humans. By combining one of humankind’s oldest technologies, textile processing, with electroactive polymers, we demonstrate here the feasibility of wearable, soft artificial muscles made by weaving and knitting, with tunable force and strain. These textile actuators were produced from cellulose yarns assembled into fabrics and coated with conducting polymers using a metal-free deposition. To increase the output force, we assembled yarns in parallel by weaving. The force scaled linearly with the number of yarns in the woven fabric. To amplify the strain, we knitted a stretchable fabric, exhibiting a 53-fold increase in strain. In addition, the textile construction added mechanical stability to the actuators. Textile processing permits scalable and rational production of wearable artificial muscles, and enables novel ways to design assistive devices.

Published
2017

21. Doping Polypyrrole Films with 4-N-Pentylphenylboronic Acid to Enhance Affinity towards Bacteria and Dopamine

Author

Golabi, Mohsen, Padiolleau, Laurence, Chen, Xi, Jafari, Mohammad Javad, Sheikhzadeh, Elham, Turner, Anthony P. F., Jager, Edwin W. H., and Beni, Valerio

Subjects
inorganic chemicals, Annan kemi, Biogenic Amines, Polymers, Materials by Structure, Dopamine, Materials Science, lcsh:Medicine, Electrode Recording, Research and Analysis Methods, Polypropylenes, Biochemistry, Physical Chemistry, Bacterial Adhesion, Catecholamines, Nitriles, Electrochemistry, Electron Microscopy, Vitamin C, Amines, Acetonitrile, lcsh:Science, Membrane Electrophysiology, Microscopy, Bacteria, Organic Compounds, Organic Chemistry, Electrophysiological Techniques, lcsh:R, Chemical Compounds, Biology and Life Sciences, Neurochemistry, Membranes, Artificial, Neurotransmitters, Vitamins, Polymer Chemistry, Boronic Acids, Hormones, Chemistry, Bioassays and Physiological Analysis, Macromolecules, Chemical Properties, Physical Sciences, lcsh:Q, Scanning Electron Microscopy, Other Chemistry Topics, Research Article, Neuroscience
Abstract

Here we demonstrate the use of a functional dopant as a fast and simple way to tune the chemical affinity and selectivity of polypyrrole films. More specifically, a boronic-functionalised dopant, 4-N-Pentylphenylboronic Acid (PBA), was used to provide to polypyrrole films with enhanced affinity towards diols. In order to prove the proposed concept, two model systems were explored: (i) the capture and the electrochemical detection of dopamine and (ii) the adhesion of bacteria onto surfaces. The chemisensor, based on overoxidised polypyrrole boronic doped film, was shown to have the ability to capture and retain dopamine, thus improving its detection; furthermore the chemisensor showed better sensitivity in comparison with overoxidised perchlorate doped films. The adhesion of bacteria, Deinococcus proteolyticus, Escherichia coli, Streptococcus pneumoniae and Klebsiella pneumoniae, onto the boric doped polypyrrole film was also tested. The presence of the boronic group in the polypyrrole film was shown to favour the adhesion of sugar-rich bacterial cells when compared with a control film (Dodecyl benzenesulfonate (DBS) doped film) with similar morphological and physical properties. The presented single step synthesis approach is simple and fast, does not require the development and synthesis of functional monomers, and can be easily expanded to the electrochemical, and possibly chemical, fabrication of novel functional surfaces and interfaces with inherent pre-defined sensing and chemical properties. Funding Agencies|Ministry of Science Research and Technology of Iran; Linkoping University; Swedish Research Council [VR-2014-3079]; Erasmus exchange program of the European Commission

Published
2016

23. Conjugated Polymers as Actuators for Medical Devices and Microsystems

Author

Jager, Edwin W. H.

Subjects
NATURAL SCIENCES, NATURVETENSKAP, sense organs
Abstract

In conducting polymers ion transport occurs during the (electro-)chemical oxidation and reduction of the polymer. This redox change results in a change of material properties such as conductivity, electrochromism, and wettability. The ion transport during this redox switching has also been used in drug release applications. This reversible intercalation motion of the ions also results in a volume change of conducting polymers. These materials were proposed as actuator materials by Baughman et al. for their large strains and low operating potentials. The first such conducting polymer-based actuator was demonstrated in the early 90’s by Pei and Inganäs. The phenomenon was thereafter demonstrated by other laboratories and the new field of conjugated polymer actuators emerged. Initial research was focused on understanding the physical principles behind the electrochemically induced actuation and exploring the limitations.

Published
2010

24. Electrochemical Control of Growth Factor Presentation To Steer Neural Stem Cell Differentiation

Author

Herland, Anna, Persson, Kristin M, Lundin, Vanessa, Fahlman, Mats, Berggren, Magnus, Jager, Edwin W H, Teixeira, Ana I, Herland, Anna, Persson, Kristin M, Lundin, Vanessa, Fahlman, Mats, Berggren, Magnus, Jager, Edwin W H, and Teixeira, Ana I

Abstract

Graphical Abstract Let it grow: The conjugated polymer poly(3,4-ethylenedioxythiophene) (PEDOT) was synthesized with heparin as the counterion to form a cell culture substrate. The surface of PEDOT:heparin in the neutral state associated biologically active growth factors (see picture). Electrochemical in situ oxidation of PEDOT during live cell culture decreased the bioavailability of the growth factor and created an exact onset of neural stem cell differentiation., funding agencies|Swedish Research Council (VR)||Swedish Foundation for Strategic Research (SSF; the OBOE center)||Karolinska Institute||VR||Onnesjo foundation||Linkoping University

Published
2011
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25. Electronic control of cell detachment using a self-doped conducting polymer

Author

Persson, Kristin M, Karlsson, Roger, Svennersten, Karl, Löffler, Susanne, Jager, Edwin W H, Richter-Dahlfors, Agneta, Konradsson, Peter, Berggren, Magnus, Persson, Kristin M, Karlsson, Roger, Svennersten, Karl, Löffler, Susanne, Jager, Edwin W H, Richter-Dahlfors, Agneta, Konradsson, Peter, and Berggren, Magnus

Abstract

An electronic detachment technology based on thin films of a poly(3,4-ethylene-dioxythiophene) derivative is evaluated for controlled release of human epithelial cells. When applying a potential of 1 V, the redox-responsive polymer films detach and disintegrate and at the same time release cells cultured on top in the absence of any enzymatic treatment with excellent preservation of membrane proteins and cell viability.

Published
2011
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26. Mechanical stimulation of epithelial cells using polypyrrole microactuators.

Author

Svennersten, Karl, Berggren, Magnus, Richter-Dahlfors, Agneta, Jager, Edwin W H, Svennersten, Karl, Berggren, Magnus, Richter-Dahlfors, Agneta, and Jager, Edwin W H

Abstract

The importance of mechanotransduction for physiological systems is becoming increasingly recognized. The effect of mechanical stimulation is well studied in organs and tissues, for instance by using flexible tissue culture substrates that can be stretched by external means. However, on the cellular and subcellular level, dedicated technology to apply appropriate mechanical stimuli is limited. Here we report an organic electronic microactuator chip for mechanical stimulation of single cells. These chips are manufactured on silicon wafers using traditional microfabrication and photolithography techniques. The active unit of the chip consists of the electroactive polymer polypyrrole that expands upon the application of a low potential. The fact that polypyrrole can be activated in physiological electrolytes makes it well suited as the active material in a microactuator chip for biomedical applications. Renal epithelial cells, which are responsive to mechanical stimuli and relevant from a physiological perspective, are cultured on top of the microactuator chip. The cells exhibit good adhesion and spread along the surface of the chip. After culturing, individual cells are mechanically stimulated by electrical addressing of the microactuator chip and the response to this stimulation is monitored as an increase in intracellular Ca(2+). This Ca(2+) response is caused by an autocrine ATP signalling pathway associated with mechanical stimulation of the cells. In conclusion, the present work demonstrates a microactuator chip based on an organic conjugated polymer, for mechanical stimulation of biological systems at the cellular and sub-cellular level., Funding Agencies|Swedish Foundation for Strategic Research (OBOE Strategic Research Center for Organic Bioelectronics)||VINNOVA||Knut and Alice Wallenberg Foundation||Royal Swedish Academy of Science||Onnesjo Foundation

Published
2011
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27. Organic electronics for precise delivery of neurotransmitters to modulate mammalian sensory function.

Author

Simon, Daniel T, Kurup, Sindhulakshmi, Larsson, Karin C, Hori, Ryusuke, Tybrandt, Klas, Goiny, Michel, Jager, Edwin W H, Berggren, Magnus, Canlon, Barbara, Richter-Dahlfors, Agneta, Simon, Daniel T, Kurup, Sindhulakshmi, Larsson, Karin C, Hori, Ryusuke, Tybrandt, Klas, Goiny, Michel, Jager, Edwin W H, Berggren, Magnus, Canlon, Barbara, and Richter-Dahlfors, Agneta

Abstract

Significant advances have been made in the understanding of the pathophysiology, molecular targets and therapies for the treatment of a variety of nervous-system disorders. Particular therapies involve electrical sensing and stimulation of neural activity, and significant effort has therefore been devoted to the refinement of neural electrodes. However, direct electrical interfacing suffers from some inherent problems, such as the inability to discriminate amongst cell types. Thus, there is a need for novel devices to specifically interface nerve cells. Here, we demonstrate an organic electronic device capable of precisely delivering neurotransmitters in vitro and in vivo. In converting electronic addressing into delivery of neurotransmitters, the device mimics the nerve synapse. Using the peripheral auditory system, we show that out of a diverse population of cells, the device can selectively stimulate nerve cells responding to a specific neurotransmitter. This is achieved by precise electronic control of electrophoretic migration through a polymer film. This mechanism provides several sought-after features for regulation of cell signalling: exact dosage determination through electrochemical relationships, minimally disruptive delivery due to lack of fluid flow, and on-off switching. This technology has great potential as a therapeutic platform and could help accelerate the development of therapeutic strategies for nervous-system disorders.

Published
2009
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28. New materials for micro-scale sensors and actuators An engineering review

Author

Wilson, Stephen A., Jourdain, Renaud P. J., Zhang, Qi, Dorey, Robert A., Bowen, Chris R., Willander, Magnus, Wahab, Qamar Ul, Safaa, M. Al-hilli, Nur, Omer, Quandt, Eckhard, Johansson, Christer, Pagounis, Emmanouel, Kohl, Manfred, Matovic, Jovan, Samel, Björn, van der Wijngaart, Wouter, Jager, Edwin W. H., Carlsson, Daniel, Djinovic, Zoran, Wegener, Michael, Moldovan, Carmen, Iosub, Rodica, Abad, Estefania, Wendlandt, Michael, Rusu, Cristina, Persson, Katrin, Wilson, Stephen A., Jourdain, Renaud P. J., Zhang, Qi, Dorey, Robert A., Bowen, Chris R., Willander, Magnus, Wahab, Qamar Ul, Safaa, M. Al-hilli, Nur, Omer, Quandt, Eckhard, Johansson, Christer, Pagounis, Emmanouel, Kohl, Manfred, Matovic, Jovan, Samel, Björn, van der Wijngaart, Wouter, Jager, Edwin W. H., Carlsson, Daniel, Djinovic, Zoran, Wegener, Michael, Moldovan, Carmen, Iosub, Rodica, Abad, Estefania, Wendlandt, Michael, Rusu, Cristina, and Persson, Katrin

Abstract

This paper provides a detailed overview of developments in transducer materials technology relating to their current and future applications in micro-scale devices. Recent advances in piezoelectric, magnetostrictive and shape-memory alloy systems are discussed and emerging transducer materials such as magnetic nanoparticles, expandable micro-spheres and conductive polymers are introduced. Materials properties, transducer mechanisms and end applications are described and the potential for integration of the materials with ancillary systems components is viewed as an essential consideration. The review concludes with a short discussion of structural polymers that are extending the range of micro-fabrication techniques available to designers and production engineers beyond the limitations of silicon fabrication technology., QC 20100525

Published
2007
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30. Microsystems based on polypyrrole microactuators : microrobots and cell clinics

Author

Jager, Edwin W. H. and Jager, Edwin W. H.

Abstract

Conducting polymers like polypyrrole (PPy) are suitable materials for actuators. PPy undergoes a volume change, driven by redox processes accompanied by ion movement. This volume change is reversible. By combining PPy with a support and/or electrode layer into a bilayer, actuators can be made. These actuators are operated in a liquid electrolyte. The microactuators presented in this thesis are based on an Au/PPy bilayer in which the Au acts both as a structural layer and electrode. PPy doped with DBS- ( dodecylbenzenesulfonate) anions (PPy(DBS)) is used and the microactuators are operated in an aqueous salt solution, usually NaDBS. However, the microactuators function also in other biological more relevant media, like blood plasma, urine, and cell culture media, making them excellent tools for cell biology and biomedicine. The thesis is focussed on methods to microfabricate devices, and their operation and use. PPy/Au microactuators, which have all the electrodes necessary for the actuation --the working, counter, and reference electrodes -- on-chip, were developed. The microactuators' performance was as good as when standard, off-chip counter and reference electrodes were used. Specifically, the speed of actuation was the same. A novel microfabrication method based on a Ti sacrificial layer was developed in order to create individually addressable and controllable polypyrrole-gold microactuators. Using these individually controlled microactuators, a micrometer-sized manipulator or microrobotic arm was fabricated. This microrobotic arm can pick up, lift, move, and place micrometer-sized objects within an area of about 250 x 100 μm2, making the microrobot an excellent tool for single cell manipulation. Also, these individually controlled microactuators were used to obtain movements both out of and in the plane of the substrate surface. A scheme to make true three-dimensional movements is demonstrated. Finally, the development of a cell clinic is presented. This is a

Published
2001

31. Electrochemomechanical devices from polymer conductors and semiconductors

Author

Inganäs, Olle, Jager, Edwin W. H., Inganäs, Olle, and Jager, Edwin W. H.

Abstract

Conjugated polymer (CP) actuators are devices where the volume of a CP material is changed during a change of the state of oxidation or reduction of the polymer. The volume change is extracted as a geo-metrical change in uni- or bimorphs, where the active material may be combined with the passive supporting material. In bimorphs, which have an active layer supported on a passive Ælm, bending of the assembly occurs as the dimensional change is driven by electrochemistry., Updated by: E.W.H. Jager, O. Inganäs Electrochemomechanical Devices from Conjugated PolymersReference Module in Materials Science and Materials Engineering, 2016, DOI: 10.1016/B0-08-043152-6/00458-7

Published
2001
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32. Textile Muscle Fibers Made by and for Continuous Production Using Doped Conducting Polymers.

Author

Huniade, Claude, Martinez, Jose G., Mehraeen, Shayan, Jager, Edwin W. H., Bashir, Tariq, and Persson, Nils‐Krister

Subjects
*TEXTILE fibers, *ELECTROLYTE solutions, *ELECTRIC stimulation, *SKELETAL muscle, *KNITTING machines
Abstract

Like skeletal muscles having a fibrous structure, conducting polymers can actuate upon electrical stimulation and can be shaped into fibers. Through textile assembly strategies of such fibers, complex actuating architectures are possible. However, state‐of‐the‐art strategies using short pieces of yarn, which compel manual integration, are not fully taking advantage of textiles. To manufacture actuating textiles that best exploit textile properties like softness and pliability, and to enable production upscaling, a production of continuous, actuating fibers is presented here. These fibers are produced from commercial polyamide 6/6 filaments by first continuously dip‐coating in a modified commercial poly(3,4−ethylenedioxythiophene):poly(styrene sulfonate) (PEDOT:PSS) dispersion before the electropolymerization of polypyrrole (PPy), where the fibers are withdrawn continuously through an electrolyte solution containing the pyrrole monomer. By employing a cyclic dip‐coating with individual viscosity, drying temperature, and withdrawal speed for each layer, and by adjusting the tension, speed, and applied potential of the electropolymerization, their isotonic strain is enhanced threefold. Their specific tension, at 400 µN tex−1, reaches slightly higher than human skeletal muscle fibers. Furthermore, these continuous actuating fibers produced on the meter are processable in an industrial knitting machine. This study anchors the development of textile muscle fibers for future textile muscles. [ABSTRACT FROM AUTHOR]

Published
2024
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33. Electrochemical bacterial detection using poly(3-aminophenylboronic acid)-based imprinted polymer.

Author

Golabi M, Kuralay F, Jager EWH, Beni V, and Turner APF

Subjects
Dielectric Spectroscopy, Electrodes, Molecular Imprinting, Poly A chemistry, Biosensing Techniques, Boronic Acids chemistry, Polymers chemistry, Staphylococcus epidermidis isolation & purification
Abstract

Biosensors can deliver the rapid bacterial detection that is needed in many fields including food safety, clinical diagnostics, biosafety and biosecurity. Whole-cell imprinted polymers have the potential to be applied as recognition elements in biosensors for selective bacterial detection. In this paper, we report on the use of 3-aminophenylboronic acid (3-APBA) for the electrochemical fabrication of a cell-imprinted polymer (CIP). The use of a monomer bearing a boronic acid group, with its ability to specifically interact with cis-diol, allowed the formation of a polymeric network presenting both morphological and chemical recognition abilities. A particularly beneficial feature of the proposed approach is the reversibility of the cis-diol-boronic group complex, which facilitates easy release of the captured bacterial cells and subsequent regeneration of the CIP. Staphylococcus epidermidis was used as the model target bacteria for the CIP and electrochemical impedance spectroscopy (EIS) was explored for the label-free detection of the target bacteria. The modified electrodes showed a linear response over the range of 10 3 -10 7 cfu/mL. A selectivity study also showed that the CIP could discriminate its target from non-target bacteria having similar shape. The CIPs had high affinity and specificity for bacterial detection and provided a switchable interface for easy removal of bacterial cell., (Copyright © 2016 Elsevier B.V. All rights reserved.)

Published
2017
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34. Knitting and weaving artificial muscles.

Author

Maziz A, Concas A, Khaldi A, Stålhand J, Persson NK, and Jager EW

Subjects
Humans, Artificial Organs, Muscle, Skeletal, Robotics
Abstract

A need exists for artificial muscles that are silent, soft, and compliant, with performance characteristics similar to those of skeletal muscle, enabling natural interaction of assistive devices with humans. By combining one of humankind's oldest technologies, textile processing, with electroactive polymers, we demonstrate here the feasibility of wearable, soft artificial muscles made by weaving and knitting, with tunable force and strain. These textile actuators were produced from cellulose yarns assembled into fabrics and coated with conducting polymers using a metal-free deposition. To increase the output force, we assembled yarns in parallel by weaving. The force scaled linearly with the number of yarns in the woven fabric. To amplify the strain, we knitted a stretchable fabric, exhibiting a 53-fold increase in strain. In addition, the textile construction added mechanical stability to the actuators. Textile processing permits scalable and rational production of wearable artificial muscles, and enables novel ways to design assistive devices.

Published
2017
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35. Electrochemical modulation of epithelia formation using conducting polymers.

Author

Svennersten K, Bolin MH, Jager EW, Berggren M, and Richter-Dahlfors A

Subjects
Animals, Cell Adhesion physiology, Cell Line, Cell Survival physiology, Dogs, Electrodes, Fibronectins metabolism, Microscopy, Fluorescence, Electrochemistry methods, Epithelial Cells cytology, Epithelial Cells metabolism, Polymers chemistry
Abstract

Conducting polymers are soft, flexible materials, exhibiting material properties that can be reversibly changed by electrochemically altering the redox state. Surface chemistry is an important determinant for the molecular events of cell adhesion. Therefore, we analyzed whether the redox state of the conducting polymer PEDOT:Tosylate can be used to control epithelial cell adhesion and proliferation. A functionalized cell culture dish comprising two adjacent electrode surfaces was developed. Upon electronic addressing, reduced and oxidized surfaces are created within the same device. Simultaneous analysis of how a homogenous epithelial MDCK cell population responded to the electrodes revealed distinct surface-specific differences. Presentation of functional fibronectin on the reduced electrode promoted focal adhesion formation, involving alpha(v)beta(3) integrin, cell proliferation, and ensuing formation of polarized monolayers. In contrast, the oxidized surface harbored only few cells with deranged morphology showing no indication of proliferation. This stems from the altered fibronectin conformation, induced by the different surface chemistry of the PEDOT:Tosylate electrode in the oxidized state. Our results demonstrate a novel use of PEDOT:Tosylate as a cell-hosting material in multiple-electrode systems, where cell adhesion and proliferation can be controlled by electrochemical modulation of surface properties.

Published
2009
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