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1. Organic Electrochemical Transistors Based on the Conjugated Polyelectrolyte PCPDTBT‐SO ₃ K (CPE‐K)

   https://doi.org/10.1002/adma.201908120  

   Lill, Alexander_T; Cao, David_X; Schrock, Max; Vollbrecht, Joachim; Huang, Jianfei; Nguyen‐Dang, Tung; Brus, Viktor_V; Yurash, Brett; Leifert, Dirk; Bazan, Guillermo_C; et al (July 2020, Advanced Materials)

   Abstract PCPDTBT‐SO₃K (CPE‐K), a conjugated polyelectrolyte, is presented as a mixed conductor material that can be used to fabricate high transconductance accumulation mode organic electrochemical transistors (OECTs). OECTs are utilized in a wide range of applications such as analyte detection, neural interfacing, impedance sensing, and neuromorphic computing. The use of interdigitated contacts to enable high transconductance in a relatively small device area in comparison to standard contacts is demonstrated. Such characteristics are highly desired in applications such as neural‐activity sensing, where the device area must be minimized to reduce invasiveness. The physical and electrical properties of CPE‐K are fully characterized to allow a direct comparison to other top performing OECT materials. CPE‐K demonstrates an electrical performance that is among the best reported in the literature for OECT materials. In addition, CPE‐K OECTs operate in the accumulation mode, which allows for much lower energy consumption in comparison to commonly used depletion mode devices. 

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2. Development, Modeling, and Testing of a Passive Compliant Bistable Undulatory Robot

   Kwan, Anson; Aukes, Daniel M. (August 2023, Biomimetic and Biohybrid Systems. Living Machines 2023. Lecture Notes in Computer Science)

   Meder, F. (Ed.)

   This proposed device uses a single actuator to transition a bistable constrained compliant beam to generate undulatory motion. Undulatory locomotion is a unique form of swimming that generates thrust through the propagation of a wave through a fish’s body. This paper draws inspiration from Anguilliformes and discusses the kinematics and dynamics of wave propagation of a bistable underwater robot. Thrust generation is explored through modeling and experimentation of the length constraint to better understand the device. This paper validates the theoretical spine behavior through experimentation and provides a path forward for future development in device optimization for various applications. Previous work developed devices that utilized either paired soft actuators or multiple redundant classical actuators that resulted in a complex prototype with intricate controls. Our work contrasts with prior work in that it aims to achieve undulatory motion through passive actuation from a single actively driven point which simplifies the control. Through this work, the goal is to further explore low-cost soft robotics via bistable mechanisms, continuum material properties, and simplified modeling practices. 

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3. Realizing nanostructure-enabled applications through dealloyed materials

   https://doi.org/10.1557/s43577-025-00907-w  

   Şeker, Erkin; Shi, Shan; McCue, Ian (May 2025, MRS Bulletin)

   Nanoporous metals produced via dealloying have attracted significant interest due to the interesting physics surrounding their morphological evolution and how their topologically complex structure influences mechanical, optical, and electrochemical properties. Their impressive nanostructure-enabled properties – such as increased catalytic activity, surface-enhanced Raman signals, high strength and large surface-to-volume ratio – have led to catalysts, sensors, actuators, energy storage, and biomedical device coatings with superior properties and performance. However, translation of nanoporous metals into practical applications has revealed needs for new material systems and manufacturing approaches, and consequently better predictive models for application-specific operating conditions. The goal of this MRS Bulletin issue is to elaborate on the latest advances in emerging methods and technologies of dealloyed materials that enable new structures and form factors, machine learning-guided design and synthesis, material recovery and sustainability for scaled-up production, and stable performance in intended operational environments. 

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4. Fabrication, modeling, and characterization of soft twisting electrothermal actuators with directly printed oblique heater

   https://doi.org/10.1088/1361-6439/ac4956  

   Cao, Yang; Dong, Jingyan (January 2022, Journal of Micromechanics and Microengineering)

   Abstract Soft electrothermal actuators have drawn extensive attention in recent years for their promising applications in biomimetic and biomedical areas. Most soft electrothermal actuators reported so far demonstrated uniform bending deformation, due to the deposition based fabrication of the conductive heater layer from nanomaterial-based solutions, which generally provides uniform heating capacity and uniform bending deformation. In this paper, a soft electrothermal actuator that can provide twisting deformation was designed and fabricated. A metallic microfilament heater of the soft twisting actuator was directly printed using electrohydrodynamic (EHD) printing, and embedded between two structural layers, a polyimide film and a polydimethylsiloxane layer, with distinct thermal expansion properties. Assisted by the direct patterning capabilities of EHD printing, a skewed heater pattern was designed and printed. This skewed heater pattern not only produces a skewed parallelogram-shaped temperature field, but also changes the stiffness anisotropy of the actuator, leading to twisting deformation with coupled bending. A theoretical kinematic model was built for the twisting actuator to describe its twisting deformation under different actuation effects. Based on that model, influence of design parameters on the twisting angle and motion trajectory of the twisting actuator were studied and validated by experiments. Finite element analysis was utilized for the thermal and deformation analysis of the actuator. The fabricated twisting actuator was characterized on its heating and twisting performance at different supply voltages. Using three twisting actuators, a soft gripper was designed and fabricated to implement pick-and-place operations of delicate objects. 

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5. Bioionic Liquids: Enabling a Paradigm Shift Toward Advanced and Smart Biomedical Applications

   https://doi.org/10.1002/aisy.202200306  

   Kanjilal, Baishali; Zhu, Yangzhi; Krishnadoss, Vaishali; Unagolla, Janitha_M; Saemian, Parnian; Caci, Alessia; Cheraghali, Danial; Dehzangi, Iman; Khademhosseini, Ali; Noshadi, Iman (February 2023, Advanced Intelligent Systems)

   Ionic liquids (ILs) exhibit unique properties of good ionic conductivity, electrochemical and thermal stability, and nonflammability, which make them promising candidates for biomedical applications. The limitations of their cytocompatibility are enhanced by using bioionic liquids (BILs) derived from biological molecules such as amines, sugars, and organic acids. BILs can be synthesized using tailorable chemistries that enable their immobilization onto biopolymers. For example, the cholinium ion and its derivatives have found significant interest in tissue engineering and drug delivery systems. Ion‐doped BIL‐functionalized polymers and their composites can also be used to design pH and electrical responsive actuators and sensors. The cytocompatibility and low immunogenicity of BIL‐functionalized polymers enable the possibilities of their use for power storage devices as well as implantable devices. These devices are gaining recognition and importance in nucleic acid delivery and molecular medicine. This review focuses on the recent advances of BILs in biomedical applications. Specifically, the review explores BILs as agents for biopolymer functionalization and highlights BILs as solvents for supermolecular ionic networks. 

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