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Development of highly biocompatible neuro-electronic interfaces towards monitoring authentic neuronal signaling in the brain

Agorelius, Johan LU (2020) In Lund University, Faculty of Medicine Doctoral Dissertation Series
Abstract
Background: To understand how the neuronal circuits in the brain process information there is a need for novel
neuro-electronic interfaces that can interact chronically with brain tissue with minimal disturbance of the
physiological conditions in the tissue, in awake and freely moving animals. For this, there is a need for implantable
neuro-electronic interfaces that are mechanically compliant with the tissue and that can remain positionally stable
with respect to the neurons, despite the continuous micromotions in the brain. To reach this goal it is also
important to be able to conduct a detailed analysis of the tissue reactions in the juxtapositional tissue around the
implant as well as to incorporate additional... (More)
Background: To understand how the neuronal circuits in the brain process information there is a need for novel
neuro-electronic interfaces that can interact chronically with brain tissue with minimal disturbance of the
physiological conditions in the tissue, in awake and freely moving animals. For this, there is a need for implantable
neuro-electronic interfaces that are mechanically compliant with the tissue and that can remain positionally stable
with respect to the neurons, despite the continuous micromotions in the brain. To reach this goal it is also
important to be able to conduct a detailed analysis of the tissue reactions in the juxtapositional tissue around the
implant as well as to incorporate additional strategies such as adding tissue modifying drugs to the implant.
Aim: To this end, two different types of implantable neuro-electronic interfaces, addressing the issue of
mechanical compliance with two different approaches, as well as a novel method of sustained drug delivery from
the neural implants were designed, manufactured and evaluated in vivo.
Method: First, arrays of thin gold leads, flexible in 3D, were cut from a 4 μm thin gold sheet, insulated with a thin
layer of Parylene-C (4 μm) and then embedded and structurally locked in a stiff gelatin matrix that dissolves after
implantation. These arrays were implanted in rats and evaluated electrophysiologically for 3 weeks. Second, a
novel tube-like electrode with an opening on the side, comprising a conducting lead embedded in glucose
enveloped by a thin layer of Parylene-C, was developed. After implantation the glucose in this protoelectrode
dissolves transforming the protoelectrode into a highly flexible and low density electrode inside the tissue. Such
tube electrodes were implanted in rats and evaluated by means of immunofluorescence microscopy after 6 weeks.
Further, minocycline loaded nanoparticles were embedded into a gelatin matrix surrounding neural implants and
the tissue reactions were evaluated in genetically modified mice exhibiting fluorescent microglia by means of
immunofluorescence microscopy 3 and 7 days after implantation.
Results: The developed 3D arrays were found to be implantable with preserved conformation and
electrophysiological recordings showed relatively stable recordings, with spike amplitudes over 400 μV. The tube
electrode proved to be sliceable in the brain without dislocating, making it possible to analyze the tissue right
outside the recording site, showing minute glia reactions and no significant loss of neurons as compared to
baseline tissue, even in the inner most zone (0-20 μm). The minocycline loaded nanoparticles where successfully
incorporated in gelatin-coatings of neural implants, and histological analysis showed a significant attenuation of
glia reactions.
Conclusion: Two new types of mechanically compliant neuro-electronic interfaces and implantation methods, as
well as a compatible embedding method of local delivery of drug content, has been successfully developed and
evaluated, showing very promising biocompatibility and stability in the tissue. (Less)
Please use this url to cite or link to this publication:
author
supervisor
opponent
  • professor Ballerini, Laura, University of Trieste, SISSA, Italy
organization
publishing date
type
Thesis
publication status
published
subject
keywords
BMI, brain machine interface, Neuro-electronic interface, neurophysiology, brain computer interface, biocompatibility, biocompatible neural interface, neural interface, histology, electrophysiology
in
Lund University, Faculty of Medicine Doctoral Dissertation Series
issue
2020:128
pages
69 pages
publisher
Lund University, Faculty of Medicine
defense location
Hörsalen Medicon Village, Scheleevägen 2, Byggnad 302, Lund
defense date
2020-12-03 09:00:00
ISSN
1652-8220
ISBN
978-91-7619-991-6
language
Swedish
LU publication?
yes
id
00f84390-9797-4504-8c1b-b4c0bbda54d6
date added to LUP
2020-11-12 08:49:13
date last changed
2021-03-22 16:23:29
@phdthesis{00f84390-9797-4504-8c1b-b4c0bbda54d6,
  abstract     = {{Background: To understand how the neuronal circuits in the brain process information there is a need for novel<br/>neuro-electronic interfaces that can interact chronically with brain tissue with minimal disturbance of the<br/>physiological conditions in the tissue, in awake and freely moving animals. For this, there is a need for implantable<br/>neuro-electronic interfaces that are mechanically compliant with the tissue and that can remain positionally stable<br/>with respect to the neurons, despite the continuous micromotions in the brain. To reach this goal it is also<br/>important to be able to conduct a detailed analysis of the tissue reactions in the juxtapositional tissue around the<br/>implant as well as to incorporate additional strategies such as adding tissue modifying drugs to the implant.<br/>Aim: To this end, two different types of implantable neuro-electronic interfaces, addressing the issue of<br/>mechanical compliance with two different approaches, as well as a novel method of sustained drug delivery from<br/>the neural implants were designed, manufactured and evaluated in vivo.<br/>Method: First, arrays of thin gold leads, flexible in 3D, were cut from a 4 μm thin gold sheet, insulated with a thin<br/>layer of Parylene-C (4 μm) and then embedded and structurally locked in a stiff gelatin matrix that dissolves after<br/>implantation. These arrays were implanted in rats and evaluated electrophysiologically for 3 weeks. Second, a<br/>novel tube-like electrode with an opening on the side, comprising a conducting lead embedded in glucose<br/>enveloped by a thin layer of Parylene-C, was developed. After implantation the glucose in this protoelectrode<br/>dissolves transforming the protoelectrode into a highly flexible and low density electrode inside the tissue. Such<br/>tube electrodes were implanted in rats and evaluated by means of immunofluorescence microscopy after 6 weeks.<br/>Further, minocycline loaded nanoparticles were embedded into a gelatin matrix surrounding neural implants and<br/>the tissue reactions were evaluated in genetically modified mice exhibiting fluorescent microglia by means of<br/>immunofluorescence microscopy 3 and 7 days after implantation.<br/>Results: The developed 3D arrays were found to be implantable with preserved conformation and<br/>electrophysiological recordings showed relatively stable recordings, with spike amplitudes over 400 μV. The tube<br/>electrode proved to be sliceable in the brain without dislocating, making it possible to analyze the tissue right<br/>outside the recording site, showing minute glia reactions and no significant loss of neurons as compared to<br/>baseline tissue, even in the inner most zone (0-20 μm). The minocycline loaded nanoparticles where successfully<br/>incorporated in gelatin-coatings of neural implants, and histological analysis showed a significant attenuation of<br/>glia reactions.<br/>Conclusion: Two new types of mechanically compliant neuro-electronic interfaces and implantation methods, as<br/>well as a compatible embedding method of local delivery of drug content, has been successfully developed and<br/>evaluated, showing very promising biocompatibility and stability in the tissue.}},
  author       = {{Agorelius, Johan}},
  isbn         = {{978-91-7619-991-6}},
  issn         = {{1652-8220}},
  keywords     = {{BMI; brain machine interface; Neuro-electronic interface; neurophysiology; brain computer interface; biocompatibility; biocompatible neural interface; neural interface; histology; electrophysiology}},
  language     = {{swe}},
  month        = {{11}},
  number       = {{2020:128}},
  publisher    = {{Lund University, Faculty of Medicine}},
  school       = {{Lund University}},
  series       = {{Lund University, Faculty of Medicine Doctoral Dissertation Series}},
  title        = {{Development of highly biocompatible neuro-electronic interfaces  towards monitoring authentic neuronal signaling in the brain}},
  url          = {{https://lup.lub.lu.se/search/files/86692220/e_spik_phd_thesis_Johan_Agorelius.pdf}},
  year         = {{2020}},
}