Compartmentalized primary cultures of dorsal root ganglion neurons to model peripheral pathophysiological conditions

Giorgi, Simona; Lamberti, Angela C.; Butrón, Laura; Gross-Amat, Olivia; Alarcón-Alarcón, David; Rodrı́guez-Cañas, E.; Fernández-Carvajal, Asia; Ferrer-Montiel, Antonio

doi:10.1177/17448069231197102

Cited by 2 publications

(1 citation statement)

References 41 publications

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“…Despite these advances, there are currently no available data concerning trigeminal nerve regeneration after axotomy using microfluidic compartmentalized chips. Indeed, only one recent study presented compartmentalized models of primary sensory neurons from dorsal root ganglia (DRG) exposed either to inflammatory mediators (mimicking inflammatory peripheral sensitization) or paclitaxel (chemotherapy sensitization) ( Giorgi et al, 2023 ). We recently developed and validated a microfluidic co-culture between mouse trigeminal sensory neurons (responsible for corneal innervation) and primary mouse corneal epithelial cells to evaluate direct toxicity on nerve endings entangled in epithelial cells and indirect toxicity on somas after acute and repeated exposure to benzalkonium chloride, a commonly used preservative in eyedrops ( Bonneau et al, 2023 ).…”

Section: Introductionmentioning

confidence: 99%

Assessment of corneal nerve regeneration after axotomy in a compartmentalized microfluidic chip model with automated 3D high resolution live-imaging

Bonneau,

Potey,

Blond

et al. 2024

Front. Cell. Neurosci.

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IntroductionDamage to the corneal nerves can result in discomfort and chronic pain, profoundly impacting the quality of life of patients. Development of novel in vitro method is crucial to better understand corneal nerve regeneration and to find new treatments for the patients. Existing in vitro models often overlook the physiology of primary sensory neurons, for which the soma is separated from the nerve endings.MethodsTo overcome this limitation, our novel model combines a compartmentalized microfluidic culture of trigeminal ganglion neurons from adult mice with live–imaging and automated 3D image analysis offering robust way to assess axonal regrowth after axotomy.ResultsPhysical axotomy performed by a two-second aspiration led to a reproducible 70% axonal loss and altered the phenotype of the neurons, increasing the number of substance P-positive neurons 72 h post-axotomy. To validate our new model, we investigated axonal regeneration after exposure to pharmacological compounds. We selected various targets known to enhance or inhibit axonal regrowth and analyzed their basal expression in trigeminal ganglion cells by scRNAseq. NGF/GDNF, insulin, and Dooku-1 (Piezo1 antagonist) enhanced regrowth by 81, 74 and 157%, respectively, while Yoda-1 (Piezo1 agonist) had no effect. Furthermore, SARM1-IN-2 (Sarm1 inhibitor) inhibited axonal regrowth, leading to only 6% regrowth after 72 h of exposure (versus 34% regrowth without any compound).DiscussionCombining compartmentalized trigeminal neuronal culture with advanced imaging and analysis allowed a thorough evaluation of the extent of the axotomy and subsequent axonal regrowth. This innovative approach holds great promise for advancing our understanding of corneal nerve injuries and regeneration and ultimately improving the quality of life for patients suffering from sensory abnormalities, and related conditions.

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Section: Introductionmentioning

confidence: 99%