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Nanoparticle-based drug delivery systems for neural interfaces - a novel approach for improved biocompatibility.

Dontsios Holmkvist, Alexander LU (2020) In Lund University, Faculty of Medicine Doctoral Dissertation Series
Abstract
The overall purpose of this thesis was to reduce brain tissue responses around implanted microelectrodes using a pharmacological strategy. One of the main aims was to develop and evaluate drug delivery systems that allow local administration of anti-inflammatory pharmaceutics. The drug Minocycline was therefore encapsulated into biodegradable poly (D,L-lactic-co-glycolic acid) nanoparticles and thereby also protecting the drug from degradation. The nanoparticle construct resulted in a sustained release of Minocycline over 30 days. This constitutes a substantial increase in release time compared to what has until now been achieved for the drug. The drug-loaded nanoparticles were then embedded in a fast-dissolving gelatin coating surrounding... (More)
The overall purpose of this thesis was to reduce brain tissue responses around implanted microelectrodes using a pharmacological strategy. One of the main aims was to develop and evaluate drug delivery systems that allow local administration of anti-inflammatory pharmaceutics. The drug Minocycline was therefore encapsulated into biodegradable poly (D,L-lactic-co-glycolic acid) nanoparticles and thereby also protecting the drug from degradation. The nanoparticle construct resulted in a sustained release of Minocycline over 30 days. This constitutes a substantial increase in release time compared to what has until now been achieved for the drug. The drug-loaded nanoparticles were then embedded in a fast-dissolving gelatin coating surrounding the implant which enabled local and sustained drug release at the target site. This technique supersedes any of the conventional administration routes and minimizes the risk for systemic side effects. The developed drug delivery system was found to significantly attenuate the acute brain tissue responses around implanted microelectrodes in mice. Coatings with Minocycline-loaded nanoparticles significantly reduced the activation of microglia cells compared to control coatings with gelatin alone both 3 and 7 days post implantation. This without affecting the overall microglia population. A significant reduction of the astrocytic response was also found 7 days post implantation in comparison to control implants. No effect on neurons or total cell count was found which may suggest that the Minocycline-loaded nanoparticles are non-toxic to the central nervous system. The thesis also presents a novel nanoparticle-eluting compartmentalized microelectrode that transforms into a flexible tube once implanted. (Less)
Please use this url to cite or link to this publication:
author
supervisor
opponent
  • professor Hilborn, Jöns, Uppsala universitet
organization
publishing date
type
Thesis
publication status
published
subject
keywords
Neural interfaces, brain damage/injury, Minocycline, Gelatin, Nanoparticles, Drug-delivery systems, Biocompatibility, Tissue responses, immunohistochemistry (IHC), Poly(D,L-lactic-co-glycolic acid) (PLGA), Hydrophobic ion paring, Emulsification-solvent-diffusion method, Drug release, Microglia activation
in
Lund University, Faculty of Medicine Doctoral Dissertation Series
issue
2020:120
pages
55 pages
publisher
Lund University, Faculty of Medicine
defense location
Hörsalen Medicon Village, Scheleevägen 2, Byggnad 302, Lund
defense date
2020-11-19 09:00:00
ISSN
1652-8220
ISBN
978-91-7619-983-1
language
English
LU publication?
yes
id
282ffcc2-fcd5-4d0f-adfb-cfa844a47c9b
date added to LUP
2020-10-26 11:01:45
date last changed
2024-03-15 13:01:36
@phdthesis{282ffcc2-fcd5-4d0f-adfb-cfa844a47c9b,
  abstract     = {{The overall purpose of this thesis was to reduce brain tissue responses around implanted microelectrodes using a pharmacological strategy. One of the main aims was to develop and evaluate drug delivery systems that allow local administration of anti-inflammatory pharmaceutics. The drug Minocycline was therefore encapsulated into biodegradable poly (D,L-lactic-co-glycolic acid) nanoparticles and thereby also protecting the drug from degradation. The nanoparticle construct resulted in a sustained release of Minocycline over 30 days. This constitutes a substantial increase in release time compared to what has until now been achieved for the drug. The drug-loaded nanoparticles were then embedded in a fast-dissolving gelatin coating surrounding the implant which enabled local and sustained drug release at the target site. This technique supersedes any of the conventional administration routes and minimizes the risk for systemic side effects. The developed drug delivery system was found to significantly attenuate the acute brain tissue responses around implanted microelectrodes in mice. Coatings with Minocycline-loaded nanoparticles significantly reduced the activation of microglia cells compared to control coatings with gelatin alone both 3 and 7 days post implantation. This without affecting the overall microglia population. A significant reduction of the astrocytic response was also found 7 days post implantation in comparison to control implants. No effect on neurons or total cell count was found which may suggest that the Minocycline-loaded nanoparticles are non-toxic to the central nervous system. The thesis also presents a novel nanoparticle-eluting compartmentalized microelectrode that transforms into a flexible tube once implanted.}},
  author       = {{Dontsios Holmkvist, Alexander}},
  isbn         = {{978-91-7619-983-1}},
  issn         = {{1652-8220}},
  keywords     = {{Neural interfaces; brain damage/injury; Minocycline; Gelatin; Nanoparticles; Drug-delivery systems; Biocompatibility; Tissue responses; immunohistochemistry (IHC); Poly(D,L-lactic-co-glycolic acid)  (PLGA); Hydrophobic ion paring; Emulsification-solvent-diffusion method; Drug release; Microglia activation}},
  language     = {{eng}},
  number       = {{2020:120}},
  publisher    = {{Lund University, Faculty of Medicine}},
  school       = {{Lund University}},
  series       = {{Lund University, Faculty of Medicine Doctoral Dissertation Series}},
  title        = {{Nanoparticle-based drug delivery systems for neural interfaces - a novel approach for improved biocompatibility.}},
  url          = {{https://lup.lub.lu.se/search/files/85792885/e_spik_ex_Alexander_H.pdf}},
  year         = {{2020}},
}