Lectures related to Brain–computer interface

Motor Neuroprosthetics: Brain-Machine Interfaces

Explores Brain-Machine Interfaces for motor control and communication using neural signals.

Explores neural signal processing for brain-computer interfaces, including decoding techniques like Kalman filters and spike sorting.

Neural Interfaces: Fundamentals of Neuroengineering

Explores the fundamentals of neural interfaces, covering design principles, evolution of cortical interfaces, and innovations in electrode technology.

Motor Neuroprosthetics: Brain-Machine Interfaces

Explores brain-machine interfaces for motor neuroprosthetics, covering recording techniques, EEG signals, and motor decoding.

Peripheral sensory feedback

Explores the importance and organization of sensory feedback in the peripheral nervous system, including artificial implementations.

Miniaturized CMOS Interfaces

Explores miniaturized CMOS interfaces for neural signals processing and neurostimulation.

Brain-Computer Interfaces: Gait Restoration

Explores Brain-Computer Interfaces for restoring gait function after spinal cord injury and stroke, showcasing promising results and future possibilities.

Sensory Feedback in Neuroprosthetics

Explores the importance of real-time sensory feedback in enhancing the control and functional impact of prosthetic hands through various neuroengineering methods.

Cortex-Wide Opto-Electrophysiological Recordings: eSee-Shells

Focuses on the development of 'eSee-Shells', chronic multimodal neural interface devices using transparent, inkjet-printed electrocorticography (ECoG) arrays.

Neural Signals and Signal Processing

Explores neural signals, EMG control, muscle synergies, and HD-EMG for prosthetic devices.

Neural Interfaces: Decoding Signals for Neuroprostheses

Explores decoding neural signals for neuroprostheses, including muscle force production and spike detection.

Ethics at the human-machine interface: Brain-Computer Interfaces and Neuroethics

Explores the ethical implications of brain-computer interfaces and the societal challenges at the human-machine interface, emphasizing the importance of cognitive liberty and mental privacy.

Bioelectronic Medicine Fundamentals

Covers the basics of bioelectronic medicine, including ANS control, neural interfaces, and clinical applications.

How to Read Research Articles

Explores how to read academic research articles, emphasizing the importance of titles, abstracts, figures, and discussions in understanding scientific literature.

Software-Hardware Systems: IoT mmWave Technology and RFID Sensing

Explores IoT mmWave technology and RFID sensing for software-hardware systems.

Neural Interfaces: Course Overview

Covers neural interfaces, course structure, projects, and interdisciplinary design principles.

Neuralink & Visual Prostheses

Explores the advancements in brain-machine interfaces and visual prostheses, addressing challenges and future prospects.

Neural Engineering: Fundamentals and Applications

Covers neural engineering fundamentals, brain-computer interfaces, neuroprosthetics, and deep brain stimulation for enhancing human function.

Motor Neuroprosthetics: peripheral nervous system

Explores motor neuroprosthetics, covering topics like amputation causes, EMG decoding, robotic hands, sensory feedback, and advanced control techniques.

Master in Neuro-X: Interdisciplinary Approaches to Neurotechnology

Presents the Master in Neuro-X program, emphasizing its interdisciplinary approach and career opportunities in neurotechnology.