Dear researchers, neuroscientists, electrophysiologists and enthusiasts,

ScienceBeam Academy has the pleasure to invite you to register for upcoming neuroscience online courses as described below:

“Deep Dive into Event Related Potentials (ERPs) Technique” Online Course

Prospective overview of the sessions:

Basics of EEG signal and EEG recordings

Overview of the theory behind neural signals (History)
Generation and Propagation of ERP and EEG
Different EEG Recording Systems with its specifics (Amplifier, Electrodes etc.)
10/20 Electrode System, Reference, Montages, Impedance, etc.
Brain Rhythms and Cognition (Based on Clinical and Research Studies)

Basics of ERP Components

ERP Components (MMN, P300, N400, N170, VPP, CNV, Sensory ERP Components, etc.)
Difference Wave, Forward-Inverse Problem
Challenges in ERP Source Localization
Peaks and Components

EEG-ERP Prepossessing with Various Preprocessing Pipelines

Basic Principles and Challenges
Filtering, Baseline Correction, Interpolation, Artifact Rejection and Correction, Re-referencing, ICA etc.
Pipelines: MAKATO, HAPPE, BEAP and etc.

Experimental Design

Principles of Experimental design for ERP in Clinical and Research Settings
Significance of Measurement Window
Common Design Problems and Solutions
Case Studies on research articles with good and bad design

Basic Analysis

Quantifying ERP Amplitudes and Latencies
Introduction to the Analysis tool boxes (EEGLAB, ERPLAB)
FFT, Time Frequency Analysis

Common Mistakes (in lack of parameters)

Overlapping
Filtering
Epoching
Baseline Correction
Measurement Window

Instructor: Mrs. Pragati Gupta, M.Sc. in Neuro-psychology from Gujarat Forensic Sciences University, India and a Student Member at Indian Academy of Neuroscience
Course Length: 7-sessions online course
Introductory webinar: https://sciencebeam.com/erplab-webinar/
Registration: https://sciencebeam.com/pragati-gupta-course/

Deadline: March 25, 2021

“Modeling Electrophysiological Activities: From Single Neuron to Nervous Tissue” Online Course. Theoretical and experimental hands-on course including lab sessions, in which you will learn about extracellular recording from rat models and also working with single-unit and Local Field Potential (LFP) data.

Prospective overview of the sessions:

Session 1:

Systems and complex system in neurosciences
Origins of electrophysiological signals and measurements
Electrophysiology and relevant features for computational modeling:

Membrane potential
Raster plot
Local field potential

Session 2:

Understanding the time evolution of the electrophysiological signals from a dynamical systems point of view.
Introduction to dynamical systems for neurosciences:

Differential equations
Phase space representation
Stability and domain of attraction

Unidimensional and bidimensional models

Dynamics of integrate-and-fire models
Repertoire of 2 D models
Reduction of Hodgkin-Huxley model

Session 3:

2D and Higher dimensions models:

Particular role of the reset
Possibility of chaos

Models of synapses
Limits of models:

Biophysical and mechanistic description
Phenomenology

Introduction to the first lab session (with Brian2 simulator)

Session 4:

First Lab Session:

Repertoire of electrophysiological patterns
Models of networks
Global measure on simulations

Session 5:

Second lab session:

analysis of the results
relations to the data

Conclusive discussion

Instructor: Dr. Damien Depannmaecker, Post-Doc researcher at Department of Integrative and Computational Neuroscience, Paris Saclay Institute of Neuroscience, France
Course Length: 5-sessions hands-on online course
Introductory webinar: https://sciencebeam.com/modeling-electrophysiological-activities/
Registration: https://sciencebeam.com/online-course-modeling-electrophysiological-activities-from-single-neuron-to-nervous-tissue/

Deadline: April 1^st, 2021

If you require any further information, feel free to contact me: workshop@sciencebeam.com

Mary Reae

Human Neuroscience Department Manager

www.sciencebeam.com

WhatsApp Num.: 008613380781282