Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Neuroplasticity01:01

Neuroplasticity

344
Neuroplasticity reflects the brain's remarkable capacity to adapt and evolve, responding dynamically to learning, experiences, or injury by reorganizing its neural circuitry. This reorganization involves creating new neural connections and refining old ones through a series of biological processes that contribute to the brain's lifelong development and adaptability.
344
Long-term Potentiation01:25

Long-term Potentiation

2.8K
Long-term potentiation, or LTP, is one of the ways by which synaptic plasticity—changes in the strength of chemical synapses—can occur in the brain. LTP is the process of synaptic strengthening that occurs over time between pre and postsynaptic neuronal connections. The synaptic strengthening of LTP works in opposition to the synaptic weakening of long-term depression (LTD) and together are the main mechanisms that underlie learning and memory.
Hebbian LTP
LTP can occur when...
2.8K
Neural Circuits01:25

Neural Circuits

1.2K
Neural circuits and neuronal pools are two of the main structures found in the nervous system. Neural circuits are networks of neurons that work together to carry out a specific task or process. They consist of interconnected neurons and glial cells, which provide structural and metabolic support.
Neuronal pools are collections of nerve cells with similar functions and interact through chemical and electrical signals. These pools include both interneurons (the central neural circuit nodes that...
1.2K
Integration of Synaptic Events01:28

Integration of Synaptic Events

1.5K
Synaptic integration mainly includes the summation of graded potentials. Graded potentials, regardless of their type, cause subtle alterations in membrane voltage, resulting in either depolarization or hyperpolarization. These incremental changes, when combined or summed, can propel the neuron toward its threshold. Consider, for example, a membrane experiencing a +15 mV shift, causing it to depolarize from -70 mV to -55 mV. In this scenario, graded potentials govern the membrane's ability to...
1.5K

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Motor and cognitive effects of video game training in people with multiple sclerosis: a randomized controlled trial.

European journal of physical and rehabilitation medicine·2026
Same author

Direct Synthesis of Ultrathin Hexagonal Boron Nitride Films on Si(001).

Nano letters·2026
Same author

Urinary Exosomal microRNAs as a Novel Approach to Study People with Multiple Sclerosis and Severe Gait Disability: A Preliminary Observation.

Non-coding RNA·2026
Same author

Prediction performance of random reservoirs with different topology for nonlinear dynamical systems with different number of degrees of freedom.

Chaos (Woodbury, N.Y.)·2026
Same author

Design of a card-based operational framework for the implementation of inclusive representation in clinical trials.

Trials·2026
Same author

Large-Scale Cooperative Sulfur Vacancy Dynamics in Two-Dimensional MoS<sub>2</sub> From Machine Learning Interatomic Potentials.

Small (Weinheim an der Bergstrasse, Germany)·2026

Related Experiment Video

Updated: Jun 29, 2025

Assembly and Characterization of Biomolecular Memristors Consisting of Ion Channel-doped Lipid Membranes
08:07

Assembly and Characterization of Biomolecular Memristors Consisting of Ion Channel-doped Lipid Membranes

Published on: March 9, 2019

7.8K

Blooming and pruning: learning from mistakes with memristive synapses.

Kristina Nikiruy1, Eduardo Perez2,3, Andrea Baroni2

  • 1Micro- and Nanoelectronic Systems, Department of Electrical Engineering and Information Technology, TU Ilmenau, Ilmenau, Germany. kristina.nikiruy@tu-ilmenau.de.

Scientific Reports
|April 2, 2024
PubMed
Summary
This summary is machine-generated.

This study introduces a neuromorphic circuit that learns from mistakes, mimicking brain development. It uses memristive devices for efficient, self-organized learning in neural networks for association tasks.

Keywords:
Learning from mistakesMemristive devicesNeuromorphic computing

More Related Videos

A Method for Growing Bio-memristors from Slime Mold
07:46

A Method for Growing Bio-memristors from Slime Mold

Published on: November 2, 2017

8.9K
Presynaptically Silent Synapses Studied with Light Microscopy
11:02

Presynaptically Silent Synapses Studied with Light Microscopy

Published on: January 4, 2010

11.5K

Related Experiment Videos

Last Updated: Jun 29, 2025

Assembly and Characterization of Biomolecular Memristors Consisting of Ion Channel-doped Lipid Membranes
08:07

Assembly and Characterization of Biomolecular Memristors Consisting of Ion Channel-doped Lipid Membranes

Published on: March 9, 2019

7.8K
A Method for Growing Bio-memristors from Slime Mold
07:46

A Method for Growing Bio-memristors from Slime Mold

Published on: November 2, 2017

8.9K
Presynaptically Silent Synapses Studied with Light Microscopy
11:02

Presynaptically Silent Synapses Studied with Light Microscopy

Published on: January 4, 2010

11.5K

Area of Science:

  • Neuroscience
  • Materials Science
  • Computer Engineering

Background:

  • Brain development involves synaptic pruning for environmental adaptation and cognitive skill formation.
  • A 1999 learning scheme proposed error-based synaptic connection elimination.
  • CMOS integrated HfO2-based memristive devices offer potential for neuromorphic computing.

Purpose of the Study:

  • To implement a learning scheme inspired by brain's blooming and pruning in a neuromorphic circuit.
  • To utilize HfO2-based memristive devices for hardware-based, local, and energy-efficient learning.
  • To identify system and device parameters for a robust memristive neuromorphic circuit capable of association tasks.

Main Methods:

  • Implementation of a two-layer neural network using CMOS integrated HfO2-based memristive devices.
  • Development of a self-organized learning scheme without positive reinforcement, leveraging device variability.
  • Combined experimental and simulation-based parameter study.

Main Results:

  • Demonstration of a compact and robust memristive neuromorphic circuit.
  • Successful implementation of hardware, local, and energy-efficient learning.
  • Identification of key parameters for effective association task handling.

Conclusions:

  • The HfO2-based memristive neuromorphic circuit effectively implements error-based learning.
  • This approach offers a promising pathway for energy-efficient, self-organized learning hardware.
  • The study provides a framework for designing robust memristive circuits for cognitive tasks.