A microfluidic culture platform for CNS axonal injury, regeneration and transport

Taylor, Anne Marion; Blurton‐Jones, Mathew; Rhee, Seog Woo; Cribbs, David H.; Cotman, Carl W.; Jeon, Neon Li

doi:10.1038/nmeth777

Cited by 1,002 publications

(1,192 citation statements)

References 36 publications

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“…A great strength of compartmentalized neuronal co-culture systems is the ability to selectively treat cell or outgrowth compartments, 11,39 making fluidic isolation in the CNA systems a pre-requisite for general applicability. Although apparently trivial, this requires pressures and flow rates to be precisely balanced throughout the period of treatment.…”

Section: Compartment-specific Microfluidic Treatmentsmentioning

confidence: 99%

“…Arrayed and disentangled neurite outgrowths provide a useful analytical display, [6][7][8] and the compartmentalized arrangement also brings the opportunity for selectively treating or isolating the soma or outgrowths for off-chip analysis. 11,12 These systems have been used to great effect to study axon degeneration and regeneration following chemical 12,13 or laser [13][14][15] axotomy, tauopathy 16 and viral 17,18 dissemination, and mRNA localization in axons. 11 The systems have also been adapted for engineering the polarity of the synaptic junction using geometric diodes 19 or for synaptogenesis screening using HEK293 cells disguised as post-synaptic structures by recombinant decoration with neurolignin-1.…”

Section: Introductionmentioning

confidence: 99%

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Microfluidic construction of minimalistic neuronal co-cultures

et al. 2013

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In this paper we present compartmentalized neuron arraying (CNA) microfluidic circuits for the preparation of neuronal networks using minimal cellular inputs (10-100-fold less than existing systems).The approach combines the benefits of microfluidics for precision single cell handling with biomaterial patterning for the long term maintenance of neuronal arrangements. A differential flow principle was used for cell metering and loading along linear arrays. An innovative water masking technique was developed for the inclusion of aligned biomaterial patterns within the microfluidic environment. For patterning primary neurons the technique involved the use of meniscus-pinning micropillars to align a water mask for plasma stencilling a poly-amine coating. The approach was extended for patterning the human SH-SY5Y neuroblastoma cell line using a poly(ethylene glycol) (PEG) back-fill and for dopaminergic LUHMES neuronal precursors by the further addition of a fibronectin coating. The patterning efficiency E patt was .75% during lengthy in chip culture, with y85% of the outgrowth channels occupied by neurites. Neurons were also cultured in next generation circuits which enable neurite guidance into all outgrowth channels for the formation of extensive inter-compartment networks. Fluidic isolation protocols were developed for the rapid and sustained treatment of the different cellular and sub-cellular compartments. In summary, this research demonstrates widely applicable microfluidic methods for the construction of compartmentalized brain models with single cell precision. These minimalistic ex vivo tissue constructs pave the way for high throughput experimentation to gain deeper insights into pathological processes such as Alzheimer and Parkinson Diseases, as well as neuronal development and function in health.

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Section: Compartment-specific Microfluidic Treatmentsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Microfluidic construction of minimalistic neuronal co-cultures

et al. 2013

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“…The development of polarized morphology follows cell adhesion, and continues for days and weeks before maturation, introducing additional challenges for engineering the neurites after the establishment of the patterns of adhesion. Microfluidics [33][34][35][36] has been used for positioning neuronal somata. However, culturing neurons within microfluidic chips over long terms is a challenge, possibly due to limited nutrient exchange.…”

Section: Introductionmentioning

confidence: 99%

Surface Coating as a Key Parameter in Engineering Neuronal Network Structures In Vitro

et al. 2012

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By quantitatively comparing a variety of macromolecular surface coating agents, we discovered that surface coating strongly modulates the adhesion and morphogenesis of primary hippocampal neurons and serves as a switch of somata clustering and neurite fasciculation in vitro. The kinetics of neuronal adhesion on poly-lysine-coated surfaces is much faster than that on laminin and Matrigel-coated surfaces, and the distribution of adhesion is more homogenous on poly-lysine. Matrigel and laminin, on the other hand, facilitate neuritogenesis more than poly-lysine does. Eventually, on Matrigel-coated surfaces of self-assembled monolayers, neurons tend to undergo somata clustering and neurite fasciculation. By replacing coating proteins with cerebral astrocytes, and patterning neurons on astrocytes through self-assembled monolayers, microfluidics and micro-contact printing, we found that astrocyte promotes soma adhesion and astrocyte processes guide neurites. There, astrocytes could be a versatile substrate in engineering neuronal networks in vitro. Besides, quantitative measurements of cellular responses on various coatings would be valuable information for the neurobiology community in the choice of the most appropriate coating strategy.

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“…Microfluidic devices were prepared as described in [10]. Axonal length and branching were determined in 50-100 neurons per condition from triplicate wells per experiment and from at least three independent experiments.…”

Section: Methodsmentioning

confidence: 99%

Somatic and axonal LIGHT signaling elicit degenerative and regenerative responses in motoneurons, respectively

et al. 2014

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A receptor-ligand interaction can evoke a broad range of biological activities in different cell types depending on receptor identity and cell type-specific post-receptor signaling intermediates. Here, we show that the TNF family member LIGHT, known to act as a deathtriggering factor in motoneurons through LT-bR, can also promote axon outgrowth and branching in motoneurons through the same receptor. LIGHT-induced axonal elongation and branching require ERK and caspase-9 pathways. This distinct response involves a compartment-specific activation of LIGHT signals, with somatic activation-inducing death, while axonal stimulation promotes axon elongation and branching in motoneurons. Following peripheral nerve damage, LIGHT increases at the lesion site through expression by invading B lymphocytes, and genetic deletion of Light significantly delays functional recovery. We propose that a central and peripheral activation of the LIGHT pathway elicits different functional responses in motoneurons.

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A microfluidic culture platform for CNS axonal injury, regeneration and transport

Cited by 1,002 publications

References 36 publications

Microfluidic construction of minimalistic neuronal co-cultures

Microfluidic construction of minimalistic neuronal co-cultures

Surface Coating as a Key Parameter in Engineering Neuronal Network Structures In Vitro

Somatic and axonal LIGHT signaling elicit degenerative and regenerative responses in motoneurons, respectively

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