High-resolution Spatiotemporal Analysis of Single Serotonergic Axons in an System

Overview

Journal Front Neurosci

Date 2022 Nov 10

PMID 36353595

Authors

Melissa Hingorani

Adele M L Viviani

Jenna E Sanfilippo

Skirmantas Janusonis

Affiliations

Soon will be listed here.

Abstract

Vertebrate brains have a dual structure, composed of () axons that can be well-captured with graph-theoretical methods and () axons that form a dense matrix in which neurons with precise connections operate. A core part of this matrix is formed by axons (fibers) that store and release 5-hydroxytryptamine (5-HT, serotonin), an ancient neurotransmitter that supports neuroplasticity and has profound implications for mental health. The self-organization of the serotonergic matrix is not well understood, despite recent advances in experimental and theoretical approaches. In particular, individual serotonergic axons produce highly stochastic trajectories, fundamental to the construction of regional fiber densities, but further advances in predictive computer simulations require more accurate experimental information. This study examined single serotonergic axons in culture systems (co-cultures and monolayers), by using a set of complementary high-resolution methods: confocal microscopy, holotomography (refractive index-based live imaging), and super-resolution (STED) microscopy. It shows that serotonergic axon walks in neural tissue may strongly reflect the stochastic geometry of this tissue and it also provides new insights into the morphology and branching properties of serotonergic axons. The proposed experimental platform can support next-generation analyses of the serotonergic matrix, including seamless integration with supercomputing approaches.

Citing Articles

An experimental platform for stochastic analyses of single serotonergic fibers in the mouse brain.

Mays K, Haiman J, Janusonis S Front Neurosci. 2023; 17:1241919.

PMID: 37869509 PMC: 10587471. DOI: 10.3389/fnins.2023.1241919.

Predicting the distribution of serotonergic axons: a supercomputing simulation of reflected fractional Brownian motion in a 3D-mouse brain model.

Janusonis S, Haiman J, Metzler R, Vojta T Front Comput Neurosci. 2023; 17:1189853.

PMID: 37265780 PMC: 10231035. DOI: 10.3389/fncom.2023.1189853.

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