Wirelessly triggered bioactive molecule delivery from degradable electroactive polymer films

Ashton, Mark; Appen, Isabel C.; Fırlak, Melike; Stanhope, Naomi E.; Schmidt, Christine E.; Eisenstadt, W.R.; Hur, Byul; Hardy, John G.

doi:10.1002/pi.6089

Cited by 20 publications

(19 citation statements)

References 122 publications

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“…The safety data sheets for the starting materials and products (FeCl 3 , Py, PPy, and PSS) show FeCl 3 to be a corrosive irritant that is toxic to aquatic life, and Py is corrosive and could be toxic if swallowed, however, PPy and PSS are nontoxic. In silico toxicity screening studies of the starting materials and products (FeCl 3 , Py, PPy, and PSS, Table S1, Supporting Information) using Derek Nexus (Derek Nexus: 6.0.1, Nexus: 2.2.2) [ 61,62 ] demonstrated they were nonsensitizers of skin, and in silico mutagenicity screening studies using Sarah Nexus (Sarah Nexus: 3.0.0, Sarah Model: 2.0) demonstrated they were non‐mutagenic. Complementary in vitro studies were undertaken using ATDC‐5 cells seeded on ADA‐GEL and 3D‐printed 0.1 m PPy‐ADA‐GEL (3D AG‐PPy:PSS) scaffolds to determine the cytocompatibility of and cell‐seeding efficiency on the modified ADA‐GEL ( Figure ).…”

Section: Resultsmentioning

confidence: 99%

Electrically Conductive and 3D‐Printable Oxidized Alginate‐Gelatin Polypyrrole:PSS Hydrogels for Tissue Engineering

Distler

Polley

Shi

et al. 2021

Adv Healthcare Materials

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Electroactive hydrogels can be used to influence cell response and maturation by electrical stimulation. However, hydrogel formulations which are 3D printable, electroactive, cytocompatible, and allow cell adhesion, remain a challenge in the design of such stimuli‐responsive biomaterials for tissue engineering. Here, a combination of pyrrole with a high gelatin‐content oxidized alginate‐gelatin (ADA‐GEL) hydrogel is reported, offering 3D‐printability of hydrogel precursors to prepare cytocompatible and electrically conductive hydrogel scaffolds. By oxidation of pyrrole, electroactive polypyrrole:polystyrenesulfonate (PPy:PSS) is synthesized inside the ADA‐GEL matrix. The hydrogels are assessed regarding their electrical/mechanical properties, 3D‐printability, and cytocompatibility. It is possible to prepare open‐porous scaffolds via bioplotting which are electrically conductive and have a higher cell seeding efficiency in scaffold depth in comparison to flat 2D hydrogels, which is confirmed via multiphoton fluorescence microscopy. The formation of an interpenetrating polypyrrole matrix in the hydrogel matrix increases the conductivity and stiffness of the hydrogels, maintaining the capacity of the gels to promote cell adhesion and proliferation. The results demonstrate that a 3D‐printable ADA‐GEL can be rendered conductive (ADA‐GEL‐PPy:PSS), and that such hydrogel formulations have promise for cell therapies, in vitro cell culture, and electrical‐stimulation assisted tissue engineering.

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Section: Resultsmentioning

confidence: 99%

Electrically Conductive and 3D‐Printable Oxidized Alginate‐Gelatin Polypyrrole:PSS Hydrogels for Tissue Engineering

Distler

Polley

Shi

et al. 2021

Adv Healthcare Materials

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“…Polymer-based drugs can deliver necessary doses to patients with a controlled release. This is possible by electrical stimulation of the polymer coating, which in turn will allow for a proper amount of the drug to be released at specific times [130]. This process requires a very low amount of power and operates at a low voltage to make it safer for humans.…”

Section: (D) Wearable Electronicsmentioning

confidence: 99%

“…These electroactive polymers are biodegradable and maintain safe conditions for humans. This process is beneficial since it can release the drug at more advantageous times to avoid potentially harmful side effects [130]. Current progress shows tremendous potential and more research is ongoing to ensure reliability of such applications [132].…”

Section: (D) Wearable Electronicsmentioning

confidence: 99%

Recent Progress on Electroactive Polymers: Synthesis, Properties and Applications

et al. 2021

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Electroactive polymers (EAPs) are an advanced family of polymers that change their shape through electric stimulation and have been a point of interest since their inception. This unique functionality has helped EAPs to contribute to versatile fields, such as electrical, biomedical, and robotics, to name a few. Ionic EAPs have a significant advantage over electronic EAPs. For example, Ionic EAPs require a lower voltage to activate than electronic EAPs. On the other hand, electronic EAPs could generate a relatively larger actuation force. Therefore, efforts have been focused on improving both kinds to achieve superior properties. In this review, the synthesis routes of different EAP-based actuators and their properties are discussed. Moreover, their mechanical interactions have been investigated from a tribological perspective as all these EAPs undergo surface interactions. Such interactions could reduce their useful life and need significant research attention for enhancing their life. Recent advancements and numerous applications of EAPs in various sectors are also discussed in this review.

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“…Electrical stimulation in particular can offer control over drug delivery according to the strength, duration and frequency of the applied field. Consequently, electroconductive/active biomaterials have received great attention in recent years for wound healing and tissue engineering applications due to their potential to allow direct delivery of electrical signals, which are stimulatory to cells/tissues and further trigger a controlled/responsive release of therapeutics to the site of interest [4], potentially wirelessly [5]. Responsiveness to an electric field is an inherent feature of electroconductive/active materials, and their properties can be tailored to suit the delivery of various pharmacological agents and biomolecules.…”

Section: Introductionmentioning

confidence: 99%

Electroresponsive Silk-Based Biohybrid Composites for Electrochemically Controlled Growth Factor Delivery

et al. 2020

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Stimuli-responsive materials are very attractive candidates for on-demand drug delivery applications. Precise control over therapeutic agents in a local area is particularly enticing to regulate the biological repair process and promote tissue regeneration. Macromolecular therapeutics are difficult to embed for delivery, and achieving controlled release over long-term periods, which is required for tissue repair and regeneration, is challenging. Biohybrid composites incorporating natural biopolymers and electroconductive/active moieties are emerging as functional materials to be used as coatings, implants or scaffolds in regenerative medicine. Here, we report the development of electroresponsive biohybrid composites based on Bombyx mori silkworm fibroin and reduced graphene oxide that are electrostatically loaded with a high-molecular-weight therapeutic (i.e., 26 kDa nerve growth factor-β (NGF-β)). NGF-β-loaded composite films were shown to control the release of the drug over a 10-day period in a pulsatile fashion upon the on/off application of an electrical stimulus. The results shown here pave the way for personalized and biologically responsive scaffolds, coatings and implantable devices to be used in neural tissue engineering applications, and could be translated to other electrically sensitive tissues as well.

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Wirelessly triggered bioactive molecule delivery from degradable electroactive polymer films

Cited by 20 publications

References 122 publications

Electrically Conductive and 3D‐Printable Oxidized Alginate‐Gelatin Polypyrrole:PSS Hydrogels for Tissue Engineering

Electrically Conductive and 3D‐Printable Oxidized Alginate‐Gelatin Polypyrrole:PSS Hydrogels for Tissue Engineering

Recent Progress on Electroactive Polymers: Synthesis, Properties and Applications

Electroresponsive Silk-Based Biohybrid Composites for Electrochemically Controlled Growth Factor Delivery

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