Your search keyword '"Kousseff CJ"' showing total 9 results

1. Cation-Dependent Mixed Ionic-Electronic Transport in a Perylenediimide Small-Molecule Semiconductor.

Author

Yu S, Wu HY, Lemaur V, Kousseff CJ, Beljonne D, Fabiano S, and Nielsen CB

Abstract

A rapidly growing interest in organic bioelectronic applications has spurred the development of a wide variety of organic mixed ionic-electronic conductors. While these new mixed conductors have enabled the community to interface organic electronics with biological systems and efficiently transduce biological signals (ions) into electronic signals, the current materials selection does not offer sufficient selectivity towards specific ions of biological relevance without the use of auxiliary components such as ion-selective membranes. Here, we present the molecular design of an n-type (electron-transporting) perylene diimide semiconductor material decorated with pendant oligoether groups to facilitate interactions with cations such as Na + and K + . Using the cyclic 15-crown-5 oligoether motif, we find that the resulting mixed conductor PDI-crown displays a strong dependence on the size of the electrolyte cation when tested in an organic electrochemical transistor configuration. In stark contrast to the low current response on the order of 1 μA observed with aqueous sodium chloride, a nearly 200-fold increase in current is observed with aqueous potassium chloride. We ascribe the high selectivity to extended molecular aggregation and therefore efficient charge transport in the presence of K + due to a favourable sandwich-like structure between two adjacent 15-crown-5 motifs and the potassium ion., (© 2024 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published

2024

2. A Universal Biocompatible and Multifunctional Solid Electrolyte in p-Type and n-Type Organic Electrochemical Transistors for Complementary Circuits and Bioelectronic Interfaces.

Author

Tang CG, Wu R, Chen Y, Zhou Z, He Q, Li T, Wu X, Hou K, Kousseff CJ, McCulloch I, and Leong WL

Abstract

The development of soft and flexible devices for collection of bioelectrical signals is gaining momentum for wearable and implantable applications. Among these devices, organic electrochemical transistors (OECTs) stand out due to their low operating voltage and large signal amplification capable of transducing weak biological signals. While liquid electrolytes have demonstrated efficacy in OECTs, they limit its operating temperature and pose challenges for electronic packaging due to potential leakage. Conversely, solid electrolytes offer advantages such as mechanical flexibility, robustness against environmental factors, and ability to bridge the interface between rigid dry electronics systems and soft wet biological tissues. However, few systems have demonstrated generality and compatibility with a wide range of state-of-the-art organic mixed ionic-electronic conductors (OMIECs). This paper introduces a highly stretchable, flexible, biocompatible, self-healable gelatin-based solid-state electrolyte, compatible with both p- and n-type OMIEC channels while maintaining high performance and excellent stability. Furthermore, this nonvolatile electrolyte is stable up to 120 °C and exhibits high ionic conductivity even in dry environment. Additionally, an OECT-based complementary inverter with a record-high normalized-gain of 228 V -1 and a corresponding ultralow static power consumption of 1 nW is demonstrated. These advancements pave the way for versatile applications ranging from bioelectronics to power-efficient implants., (© 2024 The Author(s). Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

3. Single-Component Electroactive Polymer Architectures for Non-Enzymatic Glucose Sensing.

Author

Kousseff CJ, Wustoni S, Silva RKS, Lifer A, Savva A, Frey GL, Inal S, and Nielsen CB

Subjects

Polymers chemistry, Glucose, Biosensing Techniques methods, Electrochemical Techniques methods

Abstract

Organic mixed ionic-electronic conductors (OMIECs) have emerged as promising materials for biological sensing, owing to their electrochemical activity, stability in an aqueous environment, and biocompatibility. Yet, OMIEC-based sensors rely predominantly on the use of composite matrices to enable stimuli-responsive functionality, which can exhibit issues with intercomponent interfacing. In this study, an approach is presented for non-enzymatic glucose detection by harnessing a newly synthesized functionalized monomer, EDOT-PBA. This monomer integrates electrically conducting and receptor moieties within a single organic component, obviating the need for complex composite preparation. By engineering the conditions for electrodeposition, two distinct polymer film architectures are developed: pristine PEDOT-PBA and molecularly imprinted PEDOT-PBA. Both architectures demonstrated proficient glucose binding and signal transduction capabilities. Notably, the molecularly imprinted polymer (MIP) architecture demonstrated faster stabilization upon glucose uptake while it also enabled a lower limit of detection, lower standard deviation, and a broader linear range in the sensor output signal compared to its non-imprinted counterpart. This material design not only provides a robust and efficient platform for glucose detection but also offers a blueprint for developing selective sensors for a diverse array of target molecules, by tuning the receptor units correspondingly., (© 2024 The Authors. Advanced Science published by Wiley‐VCH GmbH.)

Published

2024

4. Electrochemical modulation of mechanical properties of glycolated polythiophenes.

Author

Abdel Aziz I, Gladisch J, Musumeci C, Moser M, Griggs S, Kousseff CJ, Berggren M, McCulloch I, and Stavrinidou E

Abstract

Electrochemical doping of organic mixed ionic-electronic conductors is key for modulating their conductivity, charge storage and volume enabling high performing bioelectronic devices such as recording and stimulating electrodes, transistors-based sensors and actuators. However, electrochemical doping has not been explored to the same extent for modulating the mechanical properties of OMIECs on demand. Here, we report a qualitative and quantitative study on how the mechanical properties of a glycolated polythiophene, p(g3T2), change in situ during electrochemical doping and de-doping. The Young's modulus of p(g3T2) changes from 69 MPa in the dry state to less than 10 MPa in the hydrated state and then further decreases down to 0.4 MPa when electrochemically doped. With electrochemical doping-dedoping the Young's modulus of p(g3T2) changes by more than one order of magnitude reversibly, representing the largest modulation reported for an OMIEC. Furthermore, we show that the electrolyte concentration affects the magnitude of the change, demonstrating that in less concentrated electrolytes more water is driven into the film due to osmosis and therefore the film becomes softer. Finally, we find that the oligo ethylene glycol side chain functionality, specifically the length and asymmetry, affects the extent of modulation. Our findings show that glycolated polythiophenes are promising materials for mechanical actuators with a tunable modulus similar to the range of biological tissues, thus opening a pathway for new mechanostimulation devices.

Published

2024

5. The Role of Side Chains and Hydration on Mixed Charge Transport in n-Type Polymer Films.

Author

Surgailis J, Flagg LQ, Richter LJ, Druet V, Griggs S, Wu X, Moro S, Ohayon D, Kousseff CJ, Marks A, Maria IP, Chen H, Moser M, Costantini G, McCulloch I, and Inal S

Abstract

Introducing ethylene glycol (EG) side chains to a conjugated polymer backbone is a well-established synthetic strategy for designing organic mixed ion-electron conductors (OMIECs). However, the impact that film swelling has on mixed conduction properties has yet to be scoped, particularly for electron-transporting (n-type) OMIECs. Here, the authors investigate the effect of the length of branched EG chains on mixed charge transport of n-type OMIECs based on a naphthalene-1,4,5,8-tetracarboxylic-diimide-bithiophene backbone. Atomic force microscopy (AFM), grazing-incidence wide-angle X-ray scattering (GIWAXS), and scanning tunneling microscopy (STM) are used to establish the similarities between the common-backbone films in dry conditions. Electrochemical quartz crystal microbalance with dissipation monitoring (EQCM-D) and in situ GIWAXS measurements reveal stark changes in film swelling properties and microstructure during electrochemical doping, depending on the side chain length. It is found that even in the loss of the crystallite content upon contact with the aqueous electrolyte, the films can effectively transport charges and that it is rather the high water content that harms the electronic interconnectivity within the OMIEC films. These results highlight the importance of controlling water uptake in the films to impede charge transport in n-type electrochemical devices., (© 2024 The Authors. Advanced Materials published by Wiley‐VCH GmbH.)

Published

2024

6. The organic electrochemical transistor conundrum when reporting a mixed ionic-electronic transport figure of merit.

Author

Shahi M, Le VN, Alarcon Espejo P, Alsufyani M, Kousseff CJ, McCulloch I, and Paterson AF

Published

2024

7. Mixed Ionic and Electronic Conduction in Small-Molecule Semiconductors.

Author

Kousseff CJ, Halaksa R, Parr ZS, and Nielsen CB

Subjects

Electronics, Semiconductors

Abstract

Small-molecule organic semiconductors have displayed remarkable electronic properties with a multitude of π-conjugated structures developed and fine-tuned over recent years to afford highly efficient hole- and electron-transporting materials. Already making a significant impact on organic electronic applications including organic field-effect transistors and solar cells, this class of materials is also now naturally being considered for the emerging field of organic bioelectronics. In efforts aimed at identifying and developing (semi)conducting materials for bioelectronic applications, particular attention has been placed on materials displaying mixed ionic and electronic conduction to interface efficiently with the inherently ionic biological world. Such mixed conductors are conveniently evaluated using an organic electrochemical transistor, which further presents itself as an ideal bioelectronic device for transducing biological signals into electrical signals. Here, we review recent literature relevant for the design of small-molecule mixed ionic and electronic conductors. We assess important classes of p- and n-type small-molecule semiconductors, consider structural modifications relevant for mixed conduction and for specific interactions with ionic species, and discuss the outlook of small-molecule semiconductors in the context of organic bioelectronics.

Published

2022

8. Biotin-tagged fluorescent sensor to visualize 'mobile' Zn 2+ in cancer cells.

Author

Fang L, Trigiante G, Kousseff CJ, Crespo-Otero R, Philpott MP, and Watkinson M

Subjects

Biotin chemical synthesis, Biotin toxicity, Fluorescence, Fluorescent Dyes chemical synthesis, Fluorescent Dyes toxicity, Humans, Keratinocytes drug effects, Lactams, Macrocyclic chemical synthesis, Lactams, Macrocyclic toxicity, Ligands, MCF-7 Cells, Microscopy, Fluorescence, Zinc metabolism, Biotin analogs & derivatives, Biotin pharmacology, Fluorescent Dyes pharmacology, Lactams, Macrocyclic pharmacology, Zinc analysis

Abstract

A cancer cell-targeting fluorescent sensor has been developed to image mobile Zn2+ by introducing a biotin group. It shows a highly selective response to Zn2+in vitro, no toxicity in cellulo and images 'mobile' Zn2+ specifically in cancer cells. We believe this probe has the potential to help improve our understanding of the role of Zn2+ in the processes of cancer initiation and development.

Published

2018

9. Synthesis and metal binding properties of N -alkylcarboxyspiropyrans.

Author

Perry A and Kousseff CJ

Abstract

Spiropyrans bearing an N -alkylcarboxylate tether are a common structure in dynamic, photoactive materials and serve as colourimetric/fluorimetric cation receptors. In this study, we describe an efficient synthesis of spiropyrans with 2-12 carbon atom alkylcarboxylate substituents, and a systematic analysis of their interactions with metal cations using 1 H NMR and UV-visible spectroscopy. All N -alkylcarboxyspiropyrans in this study displayed a strong preference for binding divalent metal cations and a modest increase in M 2+ binding affinity correlated with increased alkycarboxylate tether length.

Published

2017