Opening the black box of traumatic brain injury: a holistic approach combining human 3D neural tissue and an in vitro traumatic brain injury induction device

Loussert-Fonta, Céline; Stoppini, Luc; Neuenschwander, Yoan; Righini, Ophélie; Prim, Denis; Schmidt, Cédric; Heuschkel, Marc O.; Gomez Baisac, Loris; Jovic´, Milica; Pfeifer, Marc E.; Extermann, Jérôme; Roux, Adrien

doi:10.3389/fnins.2023.1189615

Front. Neurosci.

2023

DOI: 10.3389/fnins.2023.1189615

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Opening the black box of traumatic brain injury: a holistic approach combining human 3D neural tissue and an in vitro traumatic brain injury induction device

Céline Loussert-Fonta,

Luc Stoppini,

Yoan Neuenschwander

et al.

Abstract: Traumatic brain injury (TBI) is caused by a wide range of physical events and can induce an even larger spectrum of short- to long-term pathophysiologies. Neuroscientists have relied on animal models to understand the relationship between mechanical damages and functional alterations of neural cells. These in vivo and animal-based in vitro models represent important approaches to mimic traumas on whole brains or organized brain structures but are not fully representative of pathologies occurring after traumas … Show more

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2024

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Cited by 2 publications

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The e-Flower: A hydrogel-actuated 3D MEA for brain spheroid electrophysiology

Martinelli,

Akouissi,

Liebi

et al. 2024

Sci. Adv.

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Traditional microelectrode arrays (MEAs) are limited to measuring electrophysiological activity in two dimensions, failing to capture the complexity of three-dimensional (3D) tissues such as neural organoids and spheroids. Here, we introduce a flower-shaped MEA (e-Flower) that can envelop submillimeter brain spheroids following actuation by the sole addition of the cell culture medium. Inspired by soft microgrippers, its actuation mechanism leverages the swelling properties of a polyacrylic acid hydrogel grafted to a polyimide substrate hosting the electrical interconnects. Compatible with standard electrophysiology recording systems, the e-Flower does not require additional equipment or solvents and is ready to use with preformed 3D tissues. We designed an e-Flower achieving a curvature as low as 300 micrometers within minutes, a value tunable by the choice of reswelling media and hydrogel cross-linker concentration. Furthermore, we demonstrate the ability of the e-Flower to detect spontaneous neural activity across the spheroid surface, demonstrating its potential for comprehensive neural signal recording.

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The e-Flower: A hydrogel-actuated 3D MEA for brain spheroid electrophysiology

Martinelli,

Akouissi,

Liebi

et al. 2024

Sci. Adv.

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Epileptiform activity in brain organoids derived from patient with Glucose Transporter 1 Deficiency Syndrome

Müller,

Lengacher,

Friscourt

et al. 2024

Front. Neurosci.

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IntroductionGlucose Transporter 1-Deficiency Syndrome (GLUT1-DS) is a rare genetic disorder caused by mutations in the gene encoding for GLUT1 and characterized by impaired glucose uptake in the brain. This leads to brain hypometabolism and the development of symptoms that include epilepsy, motor dysfunctions and cognitive impairment. The development of patient-specific in vitro models is a valuable tool for understanding the pathophysiology of rare genetic disorders and testing new therapeutic interventions.MethodsIn this study, we generated brain organoids from induced pluripotent stem cells (iPSCs) derived either from a GLUT1-DS patient or a healthy individual. The functional organoids were analyzed for cellular composition, maturity, and electrophysiological activity using a custom-made microelectrode array (MEA) platform, which allowed for the detection of spikes, burst patterns, and epileptiform discharges.ResultsImmunostaining revealed a similar distribution of neurons and astrocytes in both healthy and GLUT1-DS brain organoids, though GLUT1-DS brain organoids exhibited reduced cellular density and smaller overall size. Electrophysiological recordings demonstrated functional spike profiles in both organoid types. Notably, our study demonstrates that brain organoids derived from a GLUT1-DS patient exhibit distinct epileptiform activity and heightened sensitivity to glucose deprivation, reflecting key features of the disorder.DiscussionThese findings validate the use of brain organoids as a model for studying GLUT1-DS and highlight their potential for testing novel therapeutic strategies aimed at improving glucose metabolism and managing epilepsy in patients.

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Opening the black box of traumatic brain injury: a holistic approach combining human 3D neural tissue and an in vitro traumatic brain injury induction device

Cited by 2 publications

References 47 publications

The e-Flower: A hydrogel-actuated 3D MEA for brain spheroid electrophysiology

The e-Flower: A hydrogel-actuated 3D MEA for brain spheroid electrophysiology

Epileptiform activity in brain organoids derived from patient with Glucose Transporter 1 Deficiency Syndrome

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