Host response to microgel coatings on neural electrodes implanted in the brain

Gutowski, S.; Templeman, Kellie L.; South, Antoinette B.; Gaulding, Jeffrey C.; Shoemaker, James T.; LaPlaca, Michelle C.; Bellamkonda, Ravi V.; Lyon, L. Andrew; Garcı́a, Andrés J.

doi:10.1002/jbm.a.34799

Cited by 49 publications

(50 citation statements)

References 47 publications

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“…Here, reduced protein adsorption and inflammation are desired and current studies explore the applicability of microgel coated maBrought to you by | Carleton University OCUL Authenticated Download Date | 6/21/15 5:39 PM terials for this purpose [30]. Moreover, polyelectrolyte-mediated cross-linking of PNIPAM-co-AAc microgel films at Au coated substrates can resist large forces compared to their own mass and actuate in response to humidity [47].…”

Section: Biotechnical and Medical Applicationsmentioning

confidence: 97%

Responsive Microgels at Surfaces and Interfaces

Wellert

Richter

Hellweg

et al. 2014

Zeitschrift Für Physikalische Chemie

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Stimuli responsive surface structures attract increasing attention due to a large variety of envisioned applications. The controlled organization of poly(N-isopropyl acrylamid), PNIPAM microgel particles at solid surfaces inspired numerous research activities. In this review article, we briefly discuss the swelling/deswelling properties of adsorbed microgel particles in comparison to the behavior in the bulk phase. The presence of the solid interface highly influences and changes their behavior with respect to the properties in solution. Furthermore, the confinement on a solid substrate allows the direct and in-situ investigation of the mechanical properties of the microgel particles. Additionally, we briefly review the research on microgel particles at liquid interfaces. At these interfaces new interesting effects occur. Moreover, we discuss some interesting work on potential applications. In this context, microgel particles are often used as an active component for responsive coatings of various functionality envisioning applications, e.g. in medicine, biotechnology, and nanooptics.Zusammenfassung: Responsive Oberflächenmaterialien finden aufgrund der damit verbundenen potentiellen technischen Anwendungsmöglichkeiten große Beachtung in der aktuellen Forschung. Die Möglichkeit, kolloidale Gelpartikel aus poly(N-Isopropylacrylamid), PNIPAM an festen Oberflächen kontrolliert anzuordnen, inspirierte vielfältige Forschungsakivitäten. In diesem Übersichtsartikel diskutieren wir das Quellverhalten adsorbierter Mikrogelpartikel im Vergleich zu

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Section: Biotechnical and Medical Applicationsmentioning

confidence: 97%

Responsive Microgels at Surfaces and Interfaces

Wellert

Richter

Hellweg

et al. 2014

Zeitschrift Für Physikalische Chemie

View full text Add to dashboard Cite

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“…However, a number of in vivo studies looking at either stiff materials or those coated with compliant polymers have indicated that haptic-mediated mechanotransduction may not play as significant a role as initially thought (see Sections 4.1.3, 4.2.1, 4.3 and 4.6.1) . (117, 195) The second, and perhaps more predominant hypothesis, is that mechanical differences between the brain and microelectrodes induce adverse strains in the surrounding tissue during regular brain micromotion. (95, 138, 196) Therefore, compliant materials that have mechanical properties closer to that of brain tissue have received extensive attention towards improving microelectrode integration within the surrounding tissue.…”

Section: Materials Strategies For Improving Microelectrode Biocompamentioning

confidence: 99%

“…using conformal microgel coatings of poly(N-isopropylacrylamide) (pNIPAm) cross-linked with poly(ethylene glycol diacrylate) (PEG-DA) on silicon microelectrodes. (195) Long polyethylene glycol (PEG) chains take advantage of entropic and osmotic repulsion to prevent cell adhesion through the inhibition of protein adsorption. In vitro analyses demonstrated significantly reduced astrocyte and microglia adhesion to microgel-coated microelectrodes, compared to uncoated controls.…”

Section: Materials Strategies For Improving Microelectrode Biocompamentioning

confidence: 99%

Progress towards biocompatible intracortical microelectrodes for neural interfacing applications

et al. 2014

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To ensure long-term consistent neural recordings, next-generation intracortical microelectrodes are being developed with an increased emphasis on reducing the neuro-inflammatory response. The increased emphasis stems from the improved understanding of the multifaceted role that inflammation may play in disrupting both biologic and abiologic components of the overall neural interface circuit. To combat neuro-inflammation and improve recording quality, the field is actively progressing from traditional inorganic materials towards approaches that either minimizes the microelectrode footprint or that incorporate compliant materials, bioactive molecules, conducting polymers or nanomaterials. However, the immune-privileged cortical tissue introduces an added complexity compared to other biomedical applications that remains to be fully understood. This review provides a comprehensive reflection on the current understanding of the key failure modes that may impact intracortical microelectrode performance. In addition, a detailed overview of the current status of various materials-based approaches that have gained interest for neural interfacing applications is presented, and key challenges that remain to be overcome are discussed. Finally, we present our vision on the future directions of materials-based treatments to improve intracortical microelectrodes for neural interfacing.

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“…No differences in glial and neuronal responses have been found between Parylene C and silicon dioxide surfaces, two commonly used insulation materials [33], and polyethylene glycol based hydrogel coatings did not shown benefit [36]. These results suggest that physical chemistry alone may not be sufficient to alter the host tissue response.…”

Section: Current Understanding Of Failure Mechanismsmentioning

confidence: 98%

Recent advances in neural electrode–tissue interfaces

Woeppel

Yang

Cui

2017

Current Opinion in Biomedical Engineering

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Neurotechnology is facing an exponential growth in the recent decades. Neural electrode-tissue interface research has been well recognized as an instrumental component of neurotechnology development. While satisfactory long-term performance was demonstrated in some applications, such as cochlear implants and deep brain stimulators, more advanced neural electrode devices requiring higher resolution for single unit recording or microstimulation still face significant challenges in reliability and longevity. In this article, we review the most recent findings that contribute to our current understanding of the sources of poor reliability and longevity in neural recording or stimulation, including the material failure, biological tissue response and the interplay between the two. The newly developed characterization tools are introduced from electrophysiology models, molecular and biochemical analysis, material characterization to live imaging. The effective strategies that have been applied to improve the interface are also highlighted. Finally, we discuss the challenges and opportunities in improving the interface and achieving seamless integration between the implanted electrodes and neural tissue both anatomically and functionally.

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Host response to microgel coatings on neural electrodes implanted in the brain

Cited by 49 publications

References 47 publications

Responsive Microgels at Surfaces and Interfaces

Responsive Microgels at Surfaces and Interfaces

Progress towards biocompatible intracortical microelectrodes for neural interfacing applications

Recent advances in neural electrode–tissue interfaces

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