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Micropatterning neuronal networks

Micropatterning neuronal networks
Micropatterning neuronal networks
Spatially organised neuronal networks have wide reaching applications, including fundamental research, toxicology testing, pharmaceutical screening and the realisation of neuronal implant interfaces. Despite the large number of methods catalogued in the literature there remains the need to identify a method that delivers high pattern compliance, long-term stability and is widely accessible to neuroscientists. In this comparative study, aminated (polylysine/polyornithine and aminosilanes) and cytophobic (poly(ethylene glycol) (PEG) and methylated) material contrasts were evaluated. Backfilling plasma stencilled PEGylated substrates with polylysine does not produce good material contrasts, whereas polylysine patterned on methylated substrates becomes mobilised by agents in the cell culture media which results in rapid pattern decay. Aminosilanes, polylysine substitutes, are prone to hydrolysis and the chemistries prove challenging to master. Instead, the stable coupling between polylysine and PLL-g-PEG can be exploited: Microcontact printing polylysine onto a PLL-g-PEG coated glass substrate provides a simple means to produce microstructured networks of primary neurons that have superior pattern compliance during long term (>1 month) culture
0003-2654
3256-3264
Hardelauf, Heike
ff18e0f8-62ed-4edf-9746-f72701657440
Waide, Sarah
ccca6a91-1339-435e-ac06-5ef9127cb288
Sisnaiske, Julia
01f67fb6-134e-4f7a-bfe4-3fd6d3b6606e
Jacob, Peter
233e0040-1f79-4f57-a1c3-eafdd049ba2a
Hausherr, Vanessa
393f6ca2-d3cb-4726-a90e-7234733ac920
Schöbel, Nicole
b4c14448-cd05-4fad-b5bc-49086bdf9487
Janasek, Dirk
39a248d4-ac4a-4f07-9919-7bc1098cd715
van Thriel, Christoph
ae7b78df-634f-4c82-8554-2fea1c18b4e5
West, Jonathan
f1c2e060-16c3-44c0-af70-242a1c58b968
Hardelauf, Heike
ff18e0f8-62ed-4edf-9746-f72701657440
Waide, Sarah
ccca6a91-1339-435e-ac06-5ef9127cb288
Sisnaiske, Julia
01f67fb6-134e-4f7a-bfe4-3fd6d3b6606e
Jacob, Peter
233e0040-1f79-4f57-a1c3-eafdd049ba2a
Hausherr, Vanessa
393f6ca2-d3cb-4726-a90e-7234733ac920
Schöbel, Nicole
b4c14448-cd05-4fad-b5bc-49086bdf9487
Janasek, Dirk
39a248d4-ac4a-4f07-9919-7bc1098cd715
van Thriel, Christoph
ae7b78df-634f-4c82-8554-2fea1c18b4e5
West, Jonathan
f1c2e060-16c3-44c0-af70-242a1c58b968

Hardelauf, Heike, Waide, Sarah, Sisnaiske, Julia, Jacob, Peter, Hausherr, Vanessa, Schöbel, Nicole, Janasek, Dirk, van Thriel, Christoph and West, Jonathan (2014) Micropatterning neuronal networks. Analyst, 139 (13), 3256-3264. (doi:10.1039/c4an00608a).

Record type: Article

Abstract

Spatially organised neuronal networks have wide reaching applications, including fundamental research, toxicology testing, pharmaceutical screening and the realisation of neuronal implant interfaces. Despite the large number of methods catalogued in the literature there remains the need to identify a method that delivers high pattern compliance, long-term stability and is widely accessible to neuroscientists. In this comparative study, aminated (polylysine/polyornithine and aminosilanes) and cytophobic (poly(ethylene glycol) (PEG) and methylated) material contrasts were evaluated. Backfilling plasma stencilled PEGylated substrates with polylysine does not produce good material contrasts, whereas polylysine patterned on methylated substrates becomes mobilised by agents in the cell culture media which results in rapid pattern decay. Aminosilanes, polylysine substitutes, are prone to hydrolysis and the chemistries prove challenging to master. Instead, the stable coupling between polylysine and PLL-g-PEG can be exploited: Microcontact printing polylysine onto a PLL-g-PEG coated glass substrate provides a simple means to produce microstructured networks of primary neurons that have superior pattern compliance during long term (>1 month) culture

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More information

Accepted/In Press date: 19 May 2014
e-pub ahead of print date: 19 May 2014
Published date: 7 July 2014
Organisations: Cancer Sciences

Identifiers

Local EPrints ID: 375891
URI: http://eprints.soton.ac.uk/id/eprint/375891
DOI: doi:10.1039/c4an00608a
ISSN: 0003-2654
PURE UUID: 52ae17b9-184a-4a05-9bb1-cc03ad299c07
ORCID for Jonathan West: ORCID iD orcid.org/0000-0002-5709-6790

Catalogue record

Date deposited: 17 Apr 2015 13:23
Last modified: 15 Mar 2024 03:44

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Contributors

Author: Heike Hardelauf
Author: Sarah Waide
Author: Julia Sisnaiske
Author: Peter Jacob
Author: Vanessa Hausherr
Author: Nicole Schöbel
Author: Dirk Janasek
Author: Christoph van Thriel
Author: Jonathan West ORCID iD

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