Structured courses from Year 1 foundations to Year 4 advanced specialisations — built for biomedical engineering students across Africa.
Master the human body systems — cardiovascular, nervous, musculoskeletal and more, with clinical applications in mind.
Introduction to medical devices, sensors, signal conditioning and measurement systems used in clinical environments.
Physics principles applied to biology and medicine — optics, acoustics, radiation and thermodynamics in clinical context.
Python and MATLAB fundamentals for biomedical data analysis, signal processing and device programming.
Electronic circuits, amplifiers, filters and signal conditioning for biological measurement systems.
Acquisition, filtering and analysis of ECG, EEG and EMG signals using digital signal processing techniques.
Microcontrollers, Arduino and Raspberry Pi for medical device prototyping and real-time data acquisition.
Statistical analysis and visualisation of clinical data using Python, Pandas and Matplotlib.
Mechanical principles of the human body — gait analysis, joint forces, prosthetics and orthotics design.
X-ray, MRI, CT, ultrasound and PET imaging — physics, acquisition, reconstruction and clinical interpretation.
Design, calibration and maintenance of clinical instruments — ventilators, infusion pumps and patient monitors.
Materials used in medical implants — metals, polymers, ceramics and biocompatibility testing.
Surgical robots, rehabilitation robotics, exoskeletons and autonomous medical systems design and control.
Machine learning and deep learning applied to medical diagnosis, imaging analysis and clinical decision support.
ISO standards, FDA and CE marking processes, risk management and regulatory submission for medical devices.
Design and build a fully functional medical device — from concept and prototyping to clinical evaluation.
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