Electrochemically Controlled Drug Release from a Conducting Polymer Hydrogel (PDMAAp/PEDOT) for Local Therapy and Bioelectronics

Kleber, Carolin; Lienkamp, Karen; Rühe, Jürgen; Asplund, Maria

doi:10.1002/adhm.201801488

Cited by 75 publications

(72 citation statements)

References 40 publications

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“…Since the stimulation ended after the total release had plateaued, the total release was considered similar to the total releasable drug load. The increase in dye loading, specifically fluorescein, was comparable to PEDOT hydrogels designed specifically for drug delivery; however, the passive diffusion release from these hydrogels is substantially higher than the PEDOT/SNP composite in this work . This result indicates that SNP doping not only improves drug loading and release capacity, but also broadens the drug choice as a majority of the previous conducting polymer drug release work focused on negatively charged drugs.…”

Section: Resultsmentioning

confidence: 65%

“…Examples including nanotubes and nanopores, graphene oxide, graphene/silica composites, and functionalized carbon nanotubes (CNT) have been successful in increasing the quantity of the drug payload. Conducting polymer hydrogels are capable of storing greater quantities of drug by increasing their volume . The ion pump approach can further circumvent this issue by incorporating a fluid channel and an external reservoir (which can be refilled), but this requires extensive microfabrication and is not immediately compatible with many current electrically interfacing devices.…”

Section: Introductionmentioning

confidence: 99%

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Nanoparticle Doped PEDOT for Enhanced Electrode Coatings and Drug Delivery

Woeppel

Zheng

Schulte

et al. 2019

Adv Healthcare Materials

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In order to address material limitations of biologically interfacing electrodes, modified silica nanoparticles are utilized as dopants for conducting polymers. Silica precursors are selected to form a thiol modified particle (TNP), following which the particles are oxidized to sulfonate modified nanoparticles (SNPs). The selective inclusion of hexadecyl trimethylammonium bromide allows for synthesis of both porous and nonporous SNPs. Nonporous nanoparticle doped polyethylenedioxythiophene (PEDOT) films possess low interfacial impedance, high charge injection (4.8 mC cm−2), and improved stability under stimulation compared to PEDOT/poly(styrenesulfonate). Porous SNP dopants can serve as drug reservoirs and greatly enhance the capability of conducting polymer‐based, electrically controlled drug release technology. Using the SNP dopants, drug loading and release is increased up to 16.8 times, in addition to greatly expanding the range of drug candidates to include both cationic and electroactive compounds, all while maintaining their bioactivity. Finally, the PEDOT/SNP composite is capable of precisely modulating neural activity in vivo by timed release of a glutamate receptor antagonist from coated microelectrode sites. Together, this work demonstrates the feasibility and potential of doping conducting polymers with engineered nanoparticles, creating countless options to produce composite materials for enhanced electrical stimulation, neural recording, chemical sensing, and on demand drug delivery.

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Section: Resultsmentioning

confidence: 65%

Section: Introductionmentioning

confidence: 99%

Nanoparticle Doped PEDOT for Enhanced Electrode Coatings and Drug Delivery

Woeppel

Zheng

Schulte

et al. 2019

Adv Healthcare Materials

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“…In this fashion, charged small molecule drugs are delivered with precise spatiotemporal control . For example the anti‐inflammatory drug, dexamethasone, can be delivered using PDMAAp/PEDOT . Other polymer backbones include electroactive hybrid hydrogel composed of PEG diacrylate–polyacrylamide, PPy, and SWCNTs and reduced graphene oxide (rGO) nanosheets with PVA hybrid hydrogels.…”

Section: Hydrogels and Hydrophilic Polymersmentioning

confidence: 99%

“…[21,22,84] For example the anti-inflammatory drug, dexamethasone, can be delivered using PDMAAp/PEDOT. [85] Other polymer backbones include electroactive hybrid hydrogel composed of PEG diacrylate-polyacrylamide, PPy, and SWCNTs [86] and reduced graphene oxide (rGO) nanosheets with PVA hybrid hydrogels. In the PVA hybrid hydrogel, when the device is on, rGO works as a percolating pathway for transferring electrons and enhancing drug release.…”

Section: Hydrogels For Biomolecule Deliverymentioning

confidence: 99%

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

Jia

Rolandi

2020

Adv Healthcare Materials

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Bioelectronics devices that directly interface with cells and tissue have applications in neural and cardiac stimulation and recording, electroceuticals, and brain machine interfaces for prostheses. The interface between bioelectronic devices and biological tissue is inherently challenging due to the mismatch in both mechanical properties (hard vs soft) and charge carriers (electrons vs ions). In addition to conventional metals and silicon, new materials have bridged this interface, including conducting polymers, carbon‐based nanomaterials, as well as ion‐conducting polymers and hydrogels. This review provides an update on advances in soft bioelectronic materials for current and future therapeutic applications. Specifically, this review focuses on soft materials that can conduct both electrons and ions, and also deliver drugs and small molecules. The future opportunities and emerging challenges in the field are also highlighted.

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“…CPHs furthermore enable the immobilization of biomolecules and thus have the potential to improve the device tissue integration by supporting neural cell adhesion and proliferation . In addition, CPHs have been proposed as advanced drug‐release systems which, as a result of their 3D hydrogel matrix and the swellability of the layers, facilitate the controlled release of higher drug quantities when compared to conventional CPs . A quality of great importance for making such coatings truly useful for multimodal applications is the possibility to selectively pattern the material on the device at a precision of a few micrometers.…”

Section: Introductionmentioning

confidence: 99%

Wafer‐Scale Fabrication of Conducting Polymer Hydrogels for Microelectrodes and Flexible Bioelectronics

et al. 2019

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Future‐oriented directions in neural interface technologies point towards the development of multimodal devices that combine different functionalities such as neural stimulation, neurotransmitter sensing, and drug release within one platform. Conducting polymer hydrogels (CPHs) are suggested as materials for the coating of standard metal electrodes to add functionalities such as local delivery of therapeutic drugs. However, to make such coatings truly useful for multimodal devices, it is necessary to develop process technologies that allow the micropatterning of CPHs onto selected electrode sites. In this study, a wafer‐scale fabrication procedure is presented, which is used to coat the CPH, based on the hydrogel P(DMAA‐co‐5%MABP‐co‐2,5%SSNa) and the conducting polymer poly(3,4‐ethylenedioxythiophene) (PEDOT), onto flexible neural probes. The resulting material has favorable properties for the generation of recording electrodes and in addition offers a convenient platform for biofunctionalization. By controlling the PEDOT content within the hydrogel matrix, charge injection limits of up to 3.7 mC cm−2 are obtained. Long‐term stability is tested by immersing coated samples in phosphate‐buffered saline solution at 37 °C for 1 year. Non‐cytotoxicity of the coatings is confirmed with a direct cell culture test using a fluorescent neuroblastoma cell line.

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Electrochemically Controlled Drug Release from a Conducting Polymer Hydrogel (PDMAAp/PEDOT) for Local Therapy and Bioelectronics

Cited by 75 publications

References 40 publications

Nanoparticle Doped PEDOT for Enhanced Electrode Coatings and Drug Delivery

Nanoparticle Doped PEDOT for Enhanced Electrode Coatings and Drug Delivery

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

Wafer‐Scale Fabrication of Conducting Polymer Hydrogels for Microelectrodes and Flexible Bioelectronics

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