Whole Human-brain Mapping of Single Cortical Neurons for Profiling Morphological Diversity and Stereotypy

Overview

Journal Sci Adv

Specialties Biology
Science

Date 2023 Oct 12

PMID 37824619

Authors

Xiaofeng Han

Shuxia Guo

Nan Ji

Tian Li

Jian Liu

Xiangqiao Ye

Yi Wang

Zhixi Yun

Feng Xiong

Jing Rong

Di Liu

Hui Ma

Yujin Wang

Yue Huang

Peng Zhang

Wenhao Wu

Liya Ding

Michael Hawrylycz

Ed Lein

Giorgio A Ascoli

Wei Xie

Lijuan Liu

Liwei Zhang

Hanchuan Peng

Affiliations

Soon will be listed here.

Abstract

Quantifying neuron morphology and distribution at the whole-brain scale is essential to understand the structure and diversity of cell types. It is exceedingly challenging to reuse recent technologies of single-cell labeling and whole-brain imaging to study human brains. We propose adaptive cell tomography (ACTomography), a low-cost, high-throughput, and high-efficacy tomography approach, based on adaptive targeting of individual cells. We established a platform to inject dyes into cortical neurons in surgical tissues of 18 patients with brain tumors or other conditions and one donated fresh postmortem brain. We collected three-dimensional images of 1746 cortical neurons, of which 852 neurons were reconstructed to quantify local dendritic morphology, and mapped to standard atlases. In our data, human neurons are more diverse across brain regions than by subject age or gender. The strong stereotypy within cohorts of brain regions allows generating a statistical tensor field of neuron morphology to characterize anatomical modularity of a human brain.

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