News Reader

A team of scientists from Germany (Matthew Larkum, Humboldt University of Berlin) and Greece (Panayiota Poirazi, Institute of Molecular Biology and Biotechnology, Foundation for Research and Technology - Hellas (IMBB-FORTH)) have discovered a unique form of cell messaging occurring in the human brain that's not been seen before.

Single human neurons may be much more powerful computational devices than once thought, according to a new study that identifies previously unknown electrical activity in neural dendrites.

At the end of a neuron, tree-like appendages called dendrites send and receive electrochemical signals, which play a critical role in how the brain compiles information to determine its next actions. The results published in the Jan. 3 issue of Science unveil unexpectedly complex electrical activity in the dendrites of human pyramidal neurons, which may help uniquely boost the processing power of the human brain, allowing us to understand and solve complicated problems.

Neurologically speaking, the physiology that makes the human brain so particularly special and capable remains poorly understood. One possibility may lie in the thickness of the human brain's cortical layers, particularly layers 2 and 3, which contain a disproportionate amount of brain matter compared to other species as well as numerous neurons with large and elaborate dendritic trees.

"The dendrites are central to understanding the brain because they are at the core of what determines the computational power of single neurons," said study co-author Matthew Larkum, a neuroscientist at Humboldt University of Berlin. According to Larkum, recording the activity of dendrites in living rodents is rather challenging – and nearly impossible in humans. As a result, almost all that is known about active dendrites has been gleaned from the brains of rodents.

To address this, the researchers directly probed the active properties of layer 2 and 3 dendrites in slices of human brain tissue and revealed several new classes of electrical activity unique to pyramidal neurons in these layers, unknown and far more complex than in all other neurons studied to date.

By modeling these unique electrical properties, Larkum and his colleagues demonstrated that the properties allowed single neurons to solve computational problems, which were considered to require multi-layer neural networks.

These are layer 2/3 neurons of the human neocortex.

"There was a 'eureka' moment when we saw the dendritic action potentials for the first time," said Larkum. "The experiments were very challenging, so to push the questions past just repeating what has been done in rodents already was very satisfying."

Larkum notes, however, that almost nothing is known about these dendrites in other species and it remains to be seen if this particular dendritic activity is uniquely complex in humans or uniquely simple in rodents, or something in the middle.

"We are missing the information about how they operate when the whole brain is active, which can help in answering this question," said Larkum.

Original publication:
Gidon et al. (2020) Dendritic action potentials and computation in human layer 2/3 cortical neurons. Science. DOI: https://doi.org/10.1126/science.aax6239

Source:
AAAS
Technologynetworks

Contact:
Prof. Dr. Matthew Larkum
HU Berlin
ECN Member
Charité Universitätsmedizin Berlin
Charité Cross Over - Campus Mitte
Charitéplatz 1
10117 Berlin
Email: matthew.larkum(at)hu-berlin.de

LARKUM LAB

Go back

Learning is experience. Everything else is just information.

Postal Address

Charité – Universitätsmedizin Berlin
Einstein Center for Neurosciences Berlin
Charitéplatz 1
D-10117 Berlin

Campus Address

Charité Campus Mitte
Neuroscience Research Center
Hufelandweg 14
Level 01, room 020

Get in touch

You can find contact persons and telephone numbers on our contact page

Copyright 2024. All Rights Reserved.
Settings saved
Datenschutzeinstellungen

Lorem ipsum dolor sit amet, consectetuer adipiscing elit. Aenean commodo ligula eget dolor. Aenean massa. Cum sociis natoque penatibus et magnis dis parturient montes.

Dies sind Blindinhalte in jeglicher Hinsicht. Bitte ersetzen Sie diese Inhalte durch Ihre eigenen Inhalte. Lorem ipsum dolor sit amet, consectetuer adipiscing elit. Aenean commodo.

user_privacy_settings

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert die Privacy Level Einstellungen aus dem Cookie Consent Tool "Privacy Manager".

user_privacy_settings_expires

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert die Speicherdauer der Privacy Level Einstellungen aus dem Cookie Consent Tool "Privacy Manager".

ce_popup_isClosed

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert, dass das Popup (Inhaltselement - Popup) durch einen Klick des Benutzers geschlossen wurde.

onepage_animate

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert, dass der Scrollscript für die Onepage Navigation gestartet wurde.

onepage_position

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert die Offset-Position für die Onepage Navigation.

onepage_active

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert, dass die aktuelle Seite eine "Onepage" Seite ist.

view_isGrid

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert die gewählte Listen/Grid Ansicht in der Demo CarDealer / CustomCatalog List.

portfolio_MODULE_ID

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert den gewählten Filter des Portfoliofilters.

Eclipse.outdated-browser: "confirmed"

Domainname: Domain hier eintragen
Ablauf: 30 Tage
Speicherort: Localstorage
Beschreibung: Speichert den Zustand der Hinweisleiste "Outdated Browser".
You are using an outdated browser. The website may not be displayed correctly. Close