Topography, Cell Response, and Nerve Regeneration

Hoffman–Kim, Diane; Mitchel, Joseph F.; Bellamkonda, Ravi V.

doi:10.1146/annurev-bioeng-070909-105351

Cited by 466 publications

(449 citation statements)

References 181 publications

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“…1 Microenvironmental cues, such as cellular, biochemical, mechanical, and topographical cues, can influence cell behaviors, including viability, proliferation, differentiation, migration, and protein and gene expressions. [2][3][4][5][6] Notably, many native microenvironmental cues are lost in traditional twodimensional (2D) cultures, in which cells spread on substrates that are often several orders of magnitudes stiffer than brain tissue and lack the brain's extracellular matrix (ECM) organization. 7 Cells in 2D are forced to adapt a planar morphology and can form intercellular connections only in the lateral direction.…”

mentioning

confidence: 99%

Three-Dimensional Neural Spheroid Culture: AnIn VitroModel for Cortical Studies

Dingle

Boutin

Chirila

et al. 2015

Tissue Engineering Part C: Methods

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There is a high demand for in vitro models of the central nervous system (CNS) to study neurological disorders, injuries, toxicity, and drug efficacy. Three-dimensional (3D) in vitro models can bridge the gap between traditional two-dimensional culture and animal models because they present an in vivo-like microenvironment in a tailorable experimental platform. Within the expanding variety of sophisticated 3D cultures, scaffold-free, self-assembled spheroid culture avoids the introduction of foreign materials and preserves the native cell populations and extracellular matrix types. In this study, we generated 3D spheroids with primary postnatal rat cortical cells using an accessible, size-controlled, reproducible, and cost-effective method. Neurons and glia formed laminin-containing 3D networks within the spheroids. The neurons were electrically active and formed circuitry through both excitatory and inhibitory synapses. The mechanical properties of the spheroids were in the range of brain tissue. These in vivo-like features of 3D cortical spheroids provide the potential for relevant and translatable investigations of the CNS in vitro.

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mentioning

confidence: 99%

Three-Dimensional Neural Spheroid Culture: AnIn VitroModel for Cortical Studies

Dingle

Boutin

Chirila

et al. 2015

Tissue Engineering Part C: Methods

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107

106

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“…This study showed that the introduction of an aligned matrix significantly increased Schwann cell migration and the rate of axonal growth after five days in culture [4]. Studies by Kim et al and later by Clements et al similarly allude to more efficient migration of Schwann cells and axonal regeneration through the addition of topographical guidance cues [18,21,41]. Similarly the introduction of structured fibres may have increased rates of migration and growth during the initial stages of repair.…”

Section: Discussionmentioning

confidence: 57%

“…Localised effects occur on the growth cone of the regenerating axons in response to contact mediated intraluminal guidance cues. The effects of this localised signalling on nerve repair are still being realised [21]. These localised changes in signalling result in overall changes in the axonal regenerative response.…”

Section: Discussionmentioning

confidence: 99%

“…The use of topographical guidance cues has shown to have beneficial effects for nerve repair. Topographical cues have been shown to introduce complex signalling responses within the growth cone of a regenerating and have resulted in profound changes in the neuronal response to injury [21]. Structural cues have been incorporated on a number of substrates in vitro resulting in a significant increase in aligned neurite outgrowth [21e23].…”

Section: Introductionmentioning

confidence: 99%

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The effect of intraluminal contact mediated guidance signals on axonal mismatch during peripheral nerve repair

et al. 2012

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Publication InformationDaly, WT,Yao, L,Abu-rub, MT,O'Connell, C,Zeugolis, DI,Windebank, AJ,Pandit, AS (2012) b s t r a c tThe current microsurgical gold standard for repairing long gap nerve injuries is the autograft. Autograft provides a protective environment for repair and a natural internal architecture, which is essential for regeneration. Current clinically approved hollow nerve guidance conduits allow provision of this protective environment; however they fail to provide an essential internal architecture to the regenerating nerve. In the present study both structured and unstructured intraluminal collagen fibres are investigated to assess their ability to enhance conduit mediated nerve repair. This study presents a direct comparison of both structured and unstructured fibres in vivo. The addition of intraluminal guidance structures was shown to significantly decrease axonal dispersion within the conduit and reduced axonal mismatch of distal nerve targets (p < 0.05). The intraluminal fibres were shown to be successfully incorporated into the host regenerative process, acting as a platform for Schwann cell migration and axonal regeneration. Ultimately the fibres were able to provide a platform for nerve regeneration in a long term regeneration study (16 weeks) and facilitated increased guidance of regenerating axons towards their distal nerve targets.

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“…1,2 Among several different topographies, micrometer sized pillars have been used for different purposes such as to promote neuronal axonal growth and orientation [3][4][5] and cellular differentiation. [5][6][7][8] Smaller diameter pillars, nanopillars, are applied for different purposes, for example, examination of neuronal development 9 and pinning neurons.…”

Section: Introductionmentioning

confidence: 99%

Neuronal Growth on a-Si and Au Nanopillars

Kasai

Filip

et al. 2016

Electrochemistry

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Neuronal patterning is useful for understanding signal propagation between neurons as well as for biosensors and cell-based assays. The patterning of living cells has been made possible by employing surface physicochemical and topographic features. This study investigated neuronal growth on patterned nanopillars. Rat cortical neurons were cultivated on quartz substrates with amorphous silicon (a-Si) and Au pillars 100 and 500 nm in diameter. The neurites grew better with the larger diameter pillars, and the partly-selective neurite growth was observed for a-Si pillars but not for Au pillars. These results reveal the possibility of controlling neuronal growth by using a-Si nanopillars.

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Topography, Cell Response, and Nerve Regeneration

Cited by 466 publications

References 181 publications

Three-Dimensional Neural Spheroid Culture: AnIn VitroModel for Cortical Studies

Three-Dimensional Neural Spheroid Culture: AnIn VitroModel for Cortical Studies

The effect of intraluminal contact mediated guidance signals on axonal mismatch during peripheral nerve repair

Neuronal Growth on a-Si and Au Nanopillars

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