Morphometric assessment of toxicant induced neuronal degeneration in full and restricted contact co-cultures of embryonic cortical rat neurons and astrocytes: Using m-Dinitrobezene as a model neurotoxicant

Dixon, Angela R.; Philbert, Martin A.

doi:10.1016/j.tiv.2014.12.015

Cited by 6 publications

(6 citation statements)

References 60 publications

(78 reference statements)

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“…The findings of the present study provide further support for other published literature 6,7,[23][24][25][26][27] demonstrating the protective/ameliorative effects to toxins/toxicants of coculturing neuronal-astrocyte cells, and specifically does so in a transwell/restricted contact model (as applied in this study), for which there are limited other publications, 6,25,28 as well doing so using human-derived cells 8,9,29 instead of rodent-derived cells.…”

Section: Introductionsupporting

confidence: 89%

“…These findings are in agreement with literature data, although still limited in this area, on neuroprotection effects by astrocytes on neurons, that evaluated different end points and compounds (eg, 6-hydroxydopamine, tributyltin, trimethyltin, 2,5-hexanedione, MeHg, MGO, m-dinitrobenzene, and small iron oxide particles) using different co-culture models. 6,7,[23][24][25][26][27] In particular, these CNS co-culture models apply primary rodent astrocytes and neurons or mixture of primary/ immortalized rodent astrocytes and human neurons mainly by using 2 methods of co-culture:…”

Section: Discussionmentioning

confidence: 99%

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Human Co-culture Model of Neurons and Astrocytes to Test Acute Cytotoxicity of Neurotoxic Compounds

et al. 2017

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Alternative methods and their use in planning and conducting toxicology experiments have become essential for modern toxicologists, thus reducing or replacing living animals. Although in vitro human co-culture models allow the establishment of biologically relevant cell-cell interactions that recapitulate the tissue microenvironment and better mimic its physiology, the number of publications is limited specifically addressing this scientific area and utilizing this test method which could provide an additional valuable model in toxicological studies. In the present study, an in vitro model based on central nervous system (CNS) cell co-cultures was implemented using a transwell system combining human neuronal cells (SH-SY5Y cell line) and glial cells, namely astrocytes (D384 cell line), to investigate neuroprotection of D384 on SH-SY5Y and vice versa. The model was applied to test acute (24-48 hours) cytotoxicity of 3 different neurotoxicants: (1) methyl mercury (1-2.5 μM), (2) FeO nanoparticles (1-100 μg/mL), and (3) methylglyoxal (0.5-1 mM). Data were compared to mono-cultures evaluating the mitochondrial function and cell morphology. The results clearly showed that all compounds tested affected the mitochondrial activity and cell morphology in both mono-culture and co-culture conditions. However, astrocytes, when cultured together with neurons, diminish the neurotoxicant-induced cytotoxic effects that occurred in neurons cultured alone, and astrocytes become more resistant in the presence of neurons. This human CNS co-culture system seems a suitable cell model to feed high-throughput acute screening platforms and to evaluate both human neuronal and astrocytic toxicity and neuroprotective effects of new and emerging materials (eg, nanomaterials) and new products with improved sensitivity due to the functional neuron-astrocyte metabolic interactions.

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Section: Introductionsupporting

confidence: 89%

Section: Discussionmentioning

confidence: 99%

Human Co-culture Model of Neurons and Astrocytes to Test Acute Cytotoxicity of Neurotoxic Compounds

et al. 2017

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“…At power densities of 68 and 101 W/mm 2 , however, morphological neurite alterations occurred in and around the NIR-focused region. The observed morphological changes were neurite transection, beading, and fragmentation, which were used as indicators of neurite injury and degeneration in cultured nerve cells [25][26][27] . At the highest power level of 101 W/mm 2 , it was found that the surrounding agarose hydrogel also melted due to the thermoplasmonic heat.…”

Section: Resultsmentioning

confidence: 99%

Thermoplasmonic neural chip platform for in situ manipulation of neuronal connections in vitro

Hong

Nam

2020

Nat Commun

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Cultured neuronal networks with a controlled structure have been widely studied as an in vitro model system to investigate the relationship between network structure and function. However, most cell culture techniques lack the ability to control network structures during cell cultivation, making it difficult to assess functional changes induced by specific structural changes. In this study, we present an in situ manipulation platform based on gold-nanorod-mediated thermoplasmonics to interrogate an in vitro network model. We find that it is possible to induce new neurite outgrowths, eliminate interconnecting neurites, and estimate functional relationships in matured neuronal networks. This method is expected to be useful for studying functional dynamics of neural networks under controlled structural changes.

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“…Microfluidic devices with semblance to Teflon Campenot chambers, parse soma and neurites into separate compartments linked by a series of grooves that serve as a passageway for neurites. These unique segregated culture schemes have been broadly adapted as in vitro models for axonal injury [1], axonal transport [2], and neurite-glia interactions [3–5]. However, slight deviations in device geometry among these Campenot-like microfluidic devices induce vastly different nutrient transport profiles that influence cell viability and neurite extension, and there is limited work offering a detailed rationale for these observations.…”

Section: Introductionmentioning

confidence: 99%

Morphometric and computational assessments to evaluate neuron survival and maturation within compartmentalized microfluidic devices: The influence of design variation on diffusion-driven nutrient transport

Dixon

Horst

Garcia

et al. 2019

Neuroscience Letters

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Burgeoning use of segregated microfluidic platforms that parse somas and neurites into discrete compartments is fueling unique examinations of neuronal structure and physiology in a manner impossible to achieve with non-compartmentalized systems. However, even though this line of axon-soma polarizing microfluidic devices stems from the same general design of a Campenot chamber set-up, slight deviations in device geometry appear to induce vastly different nutrient transport profiles that influence neuron survival and maturation. Here we examine the uptake of nerve growth factor (NGF) by a pheochromocytoma PC12 cell line cultured using two Campenot-like device designs, a “Standard” layout, representative of a commercial device, and a custom “Notch” layout, predicted to encourage more efficient nutrient transfer that gives rise to sustained neuron viability and extensive neurite elaboration. Exploiting in vitro culture schemes coupled with computational analyses, we identify the influence of device design geometry on the interplay between neuronal survival and maturation, gauged from morphometric assessments and the spatiotemporal distribution of NGF. Computer simulations of NGF transport within the devices revealed that the microfluidic neuron culture system is highly sensitive to change, where nutrient transport is intricately linked to device geometry and cell plating density, and premature depletion of nutrients is observed if specific design criteria are not met. This study underscores the importance of validating specific device geometries for a particular neuro-based assessment, while showcasing computational modeling as a powerful tool to achieve this goal.

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Morphometric assessment of toxicant induced neuronal degeneration in full and restricted contact co-cultures of embryonic cortical rat neurons and astrocytes: Using m-Dinitrobezene as a model neurotoxicant

Cited by 6 publications

References 60 publications

Human Co-culture Model of Neurons and Astrocytes to Test Acute Cytotoxicity of Neurotoxic Compounds

Human Co-culture Model of Neurons and Astrocytes to Test Acute Cytotoxicity of Neurotoxic Compounds

Thermoplasmonic neural chip platform for in situ manipulation of neuronal connections in vitro

Morphometric and computational assessments to evaluate neuron survival and maturation within compartmentalized microfluidic devices: The influence of design variation on diffusion-driven nutrient transport

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