Your search keyword '"Domart F"' showing total 10 results

1. An efficient methodology for Electrical Monitoring in manufacturing environment

Author

Domart, F., primary, Saout, D., additional, Degand, F., additional, Tran, A., additional, Chauvet, A., additional, Grolier, JL., additional, and Richard, O., additional

Published

2008

2. Dual Gate oxide reliability improved by Spacer and Salicide process optimisation

Author

Richou, G., primary, Ottenwaelder, D., additional, Baltzinger, J.L., additional, Delahaye, B., additional, Domart, F., additional, Soudry, A., additional, Coudray, A., additional, Langlois, J.F., additional, Liebault, J., additional, Donnard, D., additional, Garroux, D., additional, Fraquet, P., additional, Nogueira, F., additional, Laporte, N., additional, Lefevre, H., additional, and Brun, J.P., additional

Published

2008

3. Correlation of metallic contamination with gate disturb failure mechanism on EEPROM cell: data analysis and process robustness improvement for contamination free manufacturing.

Author

Baltzinger, J.-L., Delahaye, B., Sanogo, M., Richou, G., Boissy, P., Domart, F., Delabriere, S., Zinger, A., and Grolier, J.-L.

Published

2007

4. The synaptic vesicle protein Mover/TPRG1L is associated with lipid droplets in astrocytes.

Author

Krohn J, Domart F, Do TT, and Dresbach T

Abstract

Crucial brain functions such as neurotransmission, myelination, and signaling pose a high demand for lipids. Lipid dysregulation is associated with neuroinflammation and neurodegeneration. Astrocytes protect neurons from lipid induced damage by accumulating and metabolizing toxic lipids in organelles called lipid droplets (LDs). LDs have long been considered as lipid storage compartments in adipocytes, but less is known about their biogenesis and composition in the brain. In particular, proteins covering the LD surface are not yet fully identified. Here, we report that the presynaptic protein Mover/TPRG1L, which regulates the probability of neurotransmitter release in neurons, is a component of the LD coat in astrocytes. Using conventional and super-resolution microscopy, we demonstrate that Mover surrounds naive and oleic acid induced astrocytic LDs. We confirm the identity of astrocytic LDs using the neutral lipid stains Bodipy and LipidTox, as well as immunofluorescence for perilipin-2, a known component of the LD coat. In astrocytes, recombinant Mover was sufficient to induce an accumulation of LDs. Furthermore, we identified point mutations that abolish targeting to LDs and show similarities in the required binding sequences for association to the presynapse and LDs. Our results show that Mover is not only a presynaptic protein but also a candidate for LD regulation. This highlights the dual role of Mover in synaptic transmission and regulation of astrocytic LDs, which may be particularly important in the context of lipid-related neurological disorders., (© 2023 The Authors. GLIA published by Wiley Periodicals LLC.)

Published

2023

5. Imaging the structural organization of chemical elements in growth cones of developing hippocampal neurons.

Author

Carmona A, Chen S, Domart F, Choquet D, and Ortega R

Subjects

Actins analysis, Actins metabolism, Animals, Cells, Cultured, Hippocampus metabolism, Neurites metabolism, Rats, Growth Cones metabolism, Neurons metabolism

Abstract

During neurodevelopment, neurons form growth cones, F-actin rich extensions located at the distal end of the neurites. Growth cones allow dendrites and axons to build synaptic connections through a process of neurite guidance whose mechanisms have not been fully elucidated. Calcium is an important element in this process by inducing F-actin reorganization. We hypothesized that other biologically active elements might be involved in the growth cone-mediated neurite guidance mechanisms. We performed super resolution and confocal microscopy of F-actin, followed by synchrotron X-ray fluorescence microscopy of phosphorous, sulfur, chlorine, potassium, calcium, iron and zinc on growth cones from primary rat hippocampal neurons. We identified two main patterns of element organization. First, active growth cones presenting an asymmetric distribution of Ca co-localized with the cytoskeleton protein F-actin. In active growth cones, we found that the distributions of P, S, Cl, K, and Zn are correlated with Ca. This correlation is lost in the second pattern, quiescent growth cones, exhibiting a spread elemental distribution. These results suggest that Ca is not the only element required in the F-actin rich active regions of growth cones. In addition, highly concentrated Fe spots of submicrometer size were observed in calcium-rich areas of active growth cones. These results reveal the need for biological active elements in growth cones during neural development and may help explain why early life deficiencies of elements, such as Fe or Zn, induce learning and memory deficits in children., (© The Author(s) 2021. Published by Oxford University Press.)

Published

2022

6. New Strategies for Engineering Tensile Strained Si Layers for Novel n-Type MOSFET.

Author

David T, Berbezier I, Aqua JN, Abbarchi M, Ronda A, Pons N, Domart F, Costaganna P, Uren G, and Favre L

Abstract

We report a novel approach for engineering tensely strained Si layers on a relaxed silicon germanium on insulator (SGOI) film using a combination of condensation, annealing, and epitaxy in conditions specifically chosen from elastic simulations. The study shows the remarkable role of the SiO 2 buried oxide layer (BOX) on the elastic behavior of the system. We show that tensely strained Si can be engineered by using alternatively rigidity (at low temperature) and viscoelasticity (at high temperature) of the SiO 2 substrate. In these conditions, we get a Si strained layer perfectly flat and free of defects on top of relaxed Si 1- x Ge x . We found very specific annealing conditions to relax SGOI while keeping a homogeneous Ge concentration and an excellent thickness uniformity resulting from the viscoelasticity of SiO 2 at this temperature, which would allow layer-by-layer matter redistribution. Remarkably, the Si layer epitaxially grown on relaxed SGOI remains fully strained with -0.85% tensile strain. The absence of strain sharing (between Si 1- x Ge x and Si) is explained by the rigidity of the Si 1- x Ge x /BOX interface at low temperature. Elastic simulations of the real system show that, because of the very specific elastic characteristics of SiO 2 , there are unique experimental conditions that both relax Si 1- x Ge x and keep Si strained. Various epitaxial processes could be revisited in light of these new results. The generic and simple process implemented here meets all the requirements of the microelectronics industry and should be rapidly integrated in the fabrication lines of large multifinger 2.5 V n-type MOSFET on SOI used for RF-switch applications and for many other applications.

Published

2021

7. Cytoplasmic aggregation of uranium in human dopaminergic cells after continuous exposure to soluble uranyl at non-cytotoxic concentrations.

Author

Carmona A, Porcaro F, Somogyi A, Roudeau S, Domart F, Medjoubi K, Aubert M, Isnard H, Nonell A, Rincel A, Paredes E, Vidaud C, Malard V, Bresson C, and Ortega R

Subjects

Cell Line, Dopaminergic Neurons chemistry, Humans, Organometallic Compounds metabolism, Spectrometry, X-Ray Emission, Synchrotrons, Uranium analysis, Dopaminergic Neurons metabolism, Uranium metabolism

Abstract

Uranium exposure can lead to neurobehavioral alterations in particular of the monoaminergic system, even at non-cytotoxic concentrations. However, the mechanisms of uranium neurotoxicity after non-cytotoxic exposure are still poorly understood. In particular, imaging uranium in neurons at low intracellular concentration is still very challenging. We investigated uranium intracellular localization by means of synchrotron X-ray fluorescence imaging with high spatial resolution (< 300 nm) and high analytical sensitivity (< 1 μg.g -1 per 300 nm pixel). Neuron-like SH-SY5Y human cells differentiated into a dopaminergic phenotype were continuously exposed, for seven days, to a non-cytotoxic concentration (10 μM) of soluble natural uranyl. Cytoplasmic submicron uranium aggregates were observed accounting on average for 62 % of the intracellular uranium content. In some aggregates, uranium and iron were co-localized suggesting common metabolic pathways between uranium and iron storage. Uranium aggregates contained no calcium or phosphorous indicating that detoxification mechanisms in neuron-like cells are different from those described in bone or kidney cells. Uranium intracellular distribution was compared to fluorescently labeled organelles (lysosomes, early and late endosomes) and to fetuin-A, a high affinity uranium-binding protein. A strict correlation could not be evidenced between uranium and the labeled organelles, or with vesicles containing fetuin-A. Our results indicate a new mechanism of uranium cytoplasmic aggregation after non-cytotoxic uranyl exposure that could be involved in neuronal defense through uranium sequestration into less reactive species. The remaining soluble fraction of uranium would be responsible for protein binding and for the resulting neurotoxic effects., (Copyright © 2020 Elsevier B.V. All rights reserved.)

Published

2021

8. Correlating STED and synchrotron XRF nano-imaging unveils cosegregation of metals and cytoskeleton proteins in dendrites.

Author

Domart F, Cloetens P, Roudeau S, Carmona A, Verdier E, Choquet D, and Ortega R

Subjects

Animals, Copper metabolism, Cytoskeletal Proteins metabolism, Dendritic Spines metabolism, Microscopy, Confocal methods, Microscopy, Fluorescence methods, Microtubules metabolism, Microtubules ultrastructure, Nanostructures, Rats, Rats, Sprague-Dawley, Spectrometry, X-Ray Emission methods, Synchrotrons, Zinc metabolism, Cytoskeletal Proteins ultrastructure, Dendritic Spines ultrastructure, Metals metabolism

Abstract

Zinc and copper are involved in neuronal differentiation and synaptic plasticity but the molecular mechanisms behind these processes are still elusive due in part to the difficulty of imaging trace metals together with proteins at the synaptic level. We correlate stimulated-emission-depletion microscopy of proteins and synchrotron X-ray fluorescence imaging of trace metals, both performed with 40 nm spatial resolution, on primary rat hippocampal neurons. We reveal the co-localization at the nanoscale of zinc and tubulin in dendrites with a molecular ratio of about one zinc atom per tubulin-αβ dimer. We observe the co-segregation of copper and F-actin within the nano-architecture of dendritic protrusions. In addition, zinc chelation causes a decrease in the expression of cytoskeleton proteins in dendrites and spines. Overall, these results indicate new functions for zinc and copper in the modulation of the cytoskeleton morphology in dendrites, a mechanism associated to neuronal plasticity and memory formation., Competing Interests: FD, PC, SR, AC, EV, DC, RO No competing interests declared, (© 2020, Domart et al.)

Published

2020

9. Manganese levels in infant formula and young child nutritional beverages in the United States and France: Comparison to breast milk and regulations.

Author

Frisbie SH, Mitchell EJ, Roudeau S, Domart F, Carmona A, and Ortega R

Subjects

Animals, Beverages adverse effects, Beverages standards, Child, Preschool, France, Goats, Humans, Infant, Infant Formula adverse effects, Infant Formula standards, Infant, Newborn, Manganese adverse effects, Milk chemistry, Milk Substitutes standards, Oryza, Soy Milk chemistry, Spectrometry, X-Ray Emission, United States, Beverages analysis, Infant Formula chemistry, Manganese analysis, Milk Substitutes chemistry, Milk, Human chemistry

Abstract

Exposure to high levels of manganese (Mn) in children has recently been associated with adverse neurodevelopmental effects. Current infant formula regulations for Mn content were set between 1981 (United States), 2006 (European Union, France), and 2007 (Codex Alimentarius) prior to the publication of much of the growing body of research on the developmental neurotoxicity of Mn. In this study, we sought to measure the concentrations of Mn in some infant formulas and young child nutritional beverages available on the United States (US) and French markets using ion beam analysis by particle induced X-ray emission (PIXE) spectrometry and then compare the analytical results to concentrations reported in the literature for breast milk and applicable infant formula regulations and guidelines. We were particularly interested in measuring Mn concentrations in product types for which there is very little data from previous surveys, especially soy-based, rice-based, goat-milk based, chocolate-flavored, and nutritional beverages for young children that are not regulated as infant or follow-on formulas (e.g. "toddler formulas" and "toddler powders"). We purchased 44 infant formulas and young child nutritional beverage products in the US and France with varying protein sources (cow-milk, goat-milk, soy, rice) labelled for birth to 3 years. We selected these samples using maximum variation sampling to explore market extremes to facilitate comparisons to regulatory limits. Since this sampling method is non-probabilistic, other inferences cannot be made beyond this set of samples to the overall markets. We used ion beam analysis to measure the concentrations of Mn in each product. The range of measured Mn concentrations in the products is 160-2,800 μg/L, substantially higher than the 3-6 μg/L mean Mn concentration reported in human breast milk. All products satisfied national and Codex Alimentarius Commission (CAC) international standards for minimum Mn content in infant formulas; however, 7/25 of the products purchased in the US exceeded the CAC Guidance Upper Level of 100 μg Mn/kcal for infant formula., Competing Interests: EJM’s affiliation is with Better Life Laboratories, a nonprofit organization that conducts scientific research and provides technical expertise, equipment, and training to help needy people around the world. Better Life Laboratories received no specific funding for this project from any donors. Donors to Better Life Laboratories provided no input in choosing the subject matter of this project, the hypotheses that were tested, the individual samples that were analyzed, the method of analysis, the research findings, or the manner of disseminating the results. This does not alter our adherence to PLOS ONE policies on sharing data and materials.

Published

2019

10. Zinc and Copper Effects on Stability of Tubulin and Actin Networks in Dendrites and Spines of Hippocampal Neurons.

Author

Perrin L, Roudeau S, Carmona A, Domart F, Petersen JD, Bohic S, Yang Y, Cloetens P, and Ortega R

Subjects

Animals, Astrocytes, Cations metabolism, Cells, Cultured, Chelating Agents pharmacology, Coculture Techniques, Copper administration & dosage, Dendrites drug effects, Dermoscopy, Fluorescent Antibody Technique, Hippocampus cytology, Hippocampus drug effects, Rats, Sprague-Dawley, Spectrometry, X-Ray Emission, Zinc administration & dosage, Actins metabolism, Copper metabolism, Dendrites metabolism, Hippocampus metabolism, Tubulin metabolism, Zinc metabolism

Abstract

Zinc and copper ions can modulate the activity of glutamate receptors. However, labile zinc and copper ions likely represent only the tip of the iceberg and other neuronal functions are suspected for these metals in their bound state. We performed synchrotron X-ray fluorescence imaging with 30 nm resolution to image total biometals in dendrites and spines from hippocampal neurons. We found that zinc is distributed all along the dendrites while copper is mainly pinpointed within the spines. In spines, zinc content is higher within the spine head while copper is higher within the spine neck. Such specific distributions suggested metal interactions with cytoskeleton proteins. Zinc supplementation induced the increase of β-tubulin content in dendrites. Copper supplementation impaired the β-tubulin and F-actin networks. Copper chelation resulted in the decrease of F-actin content in dendrites, drastically reducing the number of F-actin protrusions. These results indicate that zinc is involved in microtubule stability whereas copper is essential for actin-dependent stability of dendritic spines, although copper excess can impair the dendritic cytoskeleton.

Published

2017