The Culture of Primary Motor and Sensory Neurons in Defined Media on Electrospun Poly-L-lactide Nanofiber Scaffolds

Leach, Michelle K.; Feng, Zhongyuan; Gertz, Caitlyn C.; Tuck, Samuel J.; Regan, Tara M.; Naim, Youssef; Vincent, Andrea M.; Corey, Joseph M.

doi:10.3791/2389

Cited by 31 publications

(25 citation statements)

References 9 publications

(2 reference statements)

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“…In correspondence with our results, others have shown that primary neurons polarize in parallel with fiber orientation [19]. In the CNS, neuronal networks are highly complex and ordered structures with neurons extending often long axons/dendrites in a directed fashion.…”

Section: Topography Influence Hnpc Nuclei Alignment and Migration Ratsupporting

confidence: 78%

Tailor-Made Electrospun Culture Scaffolds Control Human Neural Progenitor Cell Behavior—Studies on Cellular Migration and Phenotypic Differentiation

Englund-Johansson¹,

Netanyah²,

Johansson³

2017

JBNB

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In neuroscience research, cell culture systems are essential experimental platforms. It is of great interest to explore in vivo-like culture substrates. We explored how basic properties of neural cells, nuclei polarization, phenotypic differentiation and distribution/migration, were affected by the culture at poly-L-lactic acid (PLLA) fibrous scaffolds, using a multipotent mitogen-expanded human neural progenitor cell (HNPC) line. HNPCs were seeded, at four different surfaces: two different electrospun PLLA (d = 1.2 -1.3 µm) substrates (parallel or random aligned fibers), and planar PLL-and PLLA surfaces. Nuclei analysis demonstrated a non-directed cellular migration at planar surfaces and random fibers, different from cultures at aligned fibers where HNPCs were oriented parallel with the fibers. At aligned fibers, HNPCs displayed the same capacity for phenotypic differentiation as after culture on the planar surfaces. However, at random fibers, HNPCs showed a significant lower level of phenotypic differentiation compared with cultures at the planar surfaces. A clear trend towards greater neuronal formation at aligned fibers, compared to cultures at random fibers, was noted. We demonstrated that the topography of in vivo-resembling PLLA scaffolds significantly influences HNPC behavior, proven by different migration behavior, phenotypic differentiation potential and nuclei polarization.This knowledge is useful in future exploration of in vivo-resembling neural cell system using electrospun scaffolds.

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Section: Topography Influence Hnpc Nuclei Alignment and Migration Ratsupporting

confidence: 78%

Tailor-Made Electrospun Culture Scaffolds Control Human Neural Progenitor Cell Behavior—Studies on Cellular Migration and Phenotypic Differentiation

Englund-Johansson¹,

Netanyah²,

Johansson³

2017

JBNB

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“…Briefly, rats were decapitated and DRG were collected by microdissection into sterile calcium-and magnesium-free modified Hank's balanced salt solution (HBSS) (Sigma Aldrich; Lonza, Belgium) (7,20,22). The dorsal root ganglia from each rat were digested with trypsin (0.25% trypsin-0.02% EDTA) (Gibco; OK, US) at 37°C for 10 min.…”

Section: +mentioning

confidence: 99%

Evaluation of Cisplatin Neurotoxicity in Cultured Rat Dorsal Root Ganglia via Cytosolic Calcium Accumulation

Erol¹,

Yiğitaslan²,

Ünel³

et al. 2016

Balkan Med J

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“…Typically, in primary cultures of mammalian brain neurons, the cells are plated with a relatively high density, on coated coverslips without a glial feeder layer (e.g., [31][32][33][34][35][36][37][38][39] ). When the plating density of neurons is reduced using this method, the initial lack of glial sheet leads to poor neuronal growth and dendritic extension (panels B, C in Figures 8-10), as reported previously [40][41][42] , probably due to poor glial growth 43,44 .…”

Section: Neuronal Culturesmentioning

confidence: 99%

Rapid Genotyping of Animals Followed by Establishing Primary Cultures of Brain Neurons

Koh

Iwabuchi

Huang

et al. 2015

JoVE

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High-resolution analysis of the morphology and function of mammalian neurons often requires the genotyping of individual animals followed by the analysis of primary cultures of neurons. We describe a set of procedures for: labeling newborn mice to be genotyped, rapid genotyping, and establishing low-density cultures of brain neurons from these mice. Individual mice are labeled by tattooing, which allows for long-term identification lasting into adulthood. Genotyping by the described protocol is fast and efficient, and allows for automated extraction of nucleic acid with good reliability. This is useful under circumstances where sufficient time for conventional genotyping is not available, e.g., in mice that suffer from neonatal lethality. Primary neuronal cultures are generated at low density, which enables imaging experiments at high spatial resolution. This culture method requires the preparation of glial feeder layers prior to neuronal plating. The protocol is applied in its entirety to a mouse model of the movement disorder DYT1 dystonia (ΔE-torsinA knock-in mice), and neuronal cultures are prepared from the hippocampus, cerebral cortex and striatum of these mice. This protocol can be applied to mice with other genetic mutations, as well as to animals of other species. Furthermore, individual components of the protocol can be used for isolated sub-projects. Thus this protocol will have wide applications, not only in neuroscience but also in other fields of biological and medical sciences. Video LinkThe video component of this article can be found at

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The Culture of Primary Motor and Sensory Neurons in Defined Media on Electrospun Poly-L-lactide Nanofiber Scaffolds

Cited by 31 publications

References 9 publications

Tailor-Made Electrospun Culture Scaffolds Control Human Neural Progenitor Cell Behavior—Studies on Cellular Migration and Phenotypic Differentiation

Tailor-Made Electrospun Culture Scaffolds Control Human Neural Progenitor Cell Behavior—Studies on Cellular Migration and Phenotypic Differentiation

Evaluation of Cisplatin Neurotoxicity in Cultured Rat Dorsal Root Ganglia via Cytosolic Calcium Accumulation

Rapid Genotyping of Animals Followed by Establishing Primary Cultures of Brain Neurons

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