Health Engineering Master's program / Biomedical Engineering Track

Course label :	Conference, invited speaker
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	0
Results grid :
Code and label (hp) :	MR_BME_S0_MSO_CIS - BME CIS Conf., invited speak.

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME101 Research Environment and Methodology
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_REM - BME101 Research Enviro & Metho

Education team

Teachers :
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	20
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME102 Biomedical Statistics
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_BST - BME102 Biomedical Statistics

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Fundamentals statistical approaches with biomedical applications. This module aims to provide an introduction to statistical methods commonly used in biomedical research. Topics covered include descriptive statistics, probability distributions, hypothesis testing, correlation and regression and study design. It covers topics in data presentation sampling, significance tests and clinical trials. The module will also cover the use of statistical software packages such as SPSS and R. Chapter 1: Introduction to Biomedical Statistics, Basic statistical concepts and terminology, Types of data and measurement scales, Sampling techniques Chapter 2: Descriptive Statistics, Measures of central tendency and variability, Frequency distributions and graphical displays Chapter 3: Probability, Normal and Binomial Distributions Chapter 4: Hypothesis Testing, Null and alternative hypotheses, errors and T-tests Chapter 5: Model selection and interpretation for BME application

Educational goals

Upon completion of this module, students should be able to: - Understand basic statistical concepts and terminology used in biomedical research. - Apply appropriate statistical techniques for different types of data in BME. - Interpret and communicate the results of statistical analyses. - Critically evaluate the statistical methods used in published biomedical research studies. - Use statistical software packages to analyze biomedical data.

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

Free statistical software for data analysis, Online Database,

Pedagogy

The acquisition of knowledge will follow a red thread that will allow the student to assimilate all the different steps of the methodology. Theoretical methods will be confronted with databased in order to verify their adequacy. Following this knowledge acquisition, students will have to solve a problem in project mode.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	20
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic knowledge in statistic and mathematics

Maximum number of registrants

Remarks

Course label :	BME103 Industry of Biomedical devices
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	1
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_IBD - BME103 Ind.of Biomed.devices

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Medical device in EU: design, develop, and certify. What is this industry, where, who. Discovering the Biomedical industry, their challenge, major companies, market and unployment opportunities. Chapter1: Introduction What is a medical device ? Introduction to the European medical device regulation MDR 2017/745. Qualification and Classification of a MD : Importance of the Intended Use Chapter 2: Design a medical device Introduction to Quality Management System ISO, Design and develop according to ISO Chapter 3: Develop a medical device - Annex I of MDR: General Safety and Performance Requirements, - Main applicable standards (Risk Analysis, Electromedical devices, Software in MD, Biocompatibility,…) - Clinical evaluation - Verification and Validation Chapter 4: Certify a MD Annex II of MDR: Technical Documentation, Notified Body and certification

Educational goals

This course combines lectures, demonstrations, discussions and problem solving exercises exploring design of medical devices. Emphasis on manufacturing skills and design for manufacturing and assembly.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

The acquisition of knowledge will follow a red thread that will allow the student to assimilate all the different steps of the methodology. Theoretical results will be confronted with mechanical tests in order to verify their adequacy. Following this knowledge acquisition, students will have to solve an industrial problem in project mode.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	15
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME114 Mathematics for biomedical engineering
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	1
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_MBE - BME114 Mathematics

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

By achieving this class, you will develop and gain a thorough understanding of scalar, vector, matrix and tensor, solving of linear and nonlinear systems of equation, integral and differential (ODEs, PDEs) calculus, some basic signal and image processing methods, probability calculus and uncertainty quantification. Chapter 1. Scalar, vector, matrix and tensor Chapter 2. Systems of linear and nonlinear equations Chapter 3. Integral and Differential Calculus Chapter 4. Basics for image and signal processing Chapter 5. Probability and statistics

Educational goals

This course aims to review basic mathematic knowledge for a biomedical engineer. Moreover, some Python-based implementations of numerical methods are studied.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Lectures, Practices, Homework Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	15
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME115 Algorthim and Programming
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_APR - BME115 Algorthim & prog.

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides an introduction to programming using the Python programming language. Students will learn the basic programming concepts such as data types, control structures, functions, and file handling, and how to apply them to solve real-world problems. As algorithms and programming are essential steps in data processing, especially in biomedical engineering research, this module allows BME students to update and learn the basics of programming in the Python language with many application linked to biomedical field. Module 1: Introduction to Python Programming. Overview of Python programming, Installing and setting up Python, Running Python code in IDLE, Install new library Module 2: Variables and functions. Variables and data types in Python, Basic operations, String manipulation and formatting, Looping structures (for and while loops), Conditional statements (if-elif-else) Module 3: Input and output files in Biomedical Engineering. Reading and writing to files (Data base, DICOM, Anonymisation), Using context managers, Working with CSV and JSON files... and Panda Module 4: Medical imaging. Reading 3D image, Making threshold, Image analysis, 3D visualisation... Module 5: 3D visualisation in python. Open a 3D model (5a STL, 5b INP, 5c GLB) to represent an anatomical structure in python, make scale factor, virtual twins and holographic representation (Hololens2) Module 6: Final Project. Applying all the concepts learned throughout the course to solve a real-world programming problem (application to Biomechanical engineering and research). Initiation to GITHub and collaborative approach to coding...

Educational goals

BME115 Course Objectives: • Understand the basic syntax and structure of the Python programming language. • Develop an understanding of fundamental programming concepts such as data types, control structures, functions, and file handling. • Learn to write Python code to solve simple to intermediate level programming problems. • Develop problem-solving skills using Python.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

BME laptop and Anaconda distribution

Pedagogy

Quizzes and exams to test knowledge of concepts and syntax. Programming assignments to apply the concepts learned in each module. Final project to demonstrate understanding and problem-solving skills. As you have different ways to succeed in coding, Reverse Classroom will be also investiguate into the correction of different practices to encourage students to become active learners and fosters.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic computer skills, including the ability to use a text editor. Basic math skills, including arithmetic operations and algebraic equations.

Maximum number of registrants

Remarks

Course label :	BME141 Upgrade in physics
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	4
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_UPH - BME141 Upgrade in physics

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides the knowledge of Physics required to follow the key points dealing with medical imaging. It covers the fields of Wave Physics, Electromagnetism, Magnetism and Solid-state Physics.

Educational goals

The purpose of this course is first to develop the generic skills needed to tackle biophysical problems, namely: Theoretical modeling Numerical modeling and solving Experimental skills Bibliography In addition, this course provides some physical concepts needed to encompass a wide range of biomedical topics in diagnosis, therapy, and physiology, as a preparation for following BME modules. The course consists in several case studies, organized around lectures, tutorials, self-learning and practicals: Case study 1: The human auditory system Case study 2: Ultrasound Imaging Case study 3: Hyperthermia

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: Continuous - Evaluation of a written production exercise to be written in a class period, or in homework and self-learning sessions - Evaluation of an oral production exercise (e.g. pitch, presentation alone or in pairs) - Evaluation of the reports and the defense by peers and by a jury.

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Lectures, Practices, Homework, Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

-

Maximum number of registrants

Remarks

Course label :	BME142 Upgrade in EEA engg.
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	4
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_UPE - BME142 Upgrade in EEA engg.

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides the knowledge of Electronics, Electricity and Control Systems required to follow the key points dealing with measurements, signals and analysis of signals obtained by sensors: It covers Electricity, Electronics, Automatics, Circuits, Physics Components (transistors, diode), Electronic logic In this project, you will have to produce a synthetic review of biomedical sensors. This sensors can be anything from the simple stethoscope of your private physician, a blood pressure monitor to an MRI or a biomems to detect cancer cells. We don't expect you to look at all biomedical sensors. It's up to you to define the scope of your review. For example, you could focuse on a single sensor and examine its technological variations, or you could focuse on a specific biophysical quantity, e.g. blood pressure, and review all sensors that are able to measure that quantity. What are the motivation for such a review at the start of your Master program ? It's a joint BME 141 & 142 project. We want you to be aware of the context of both courses. Sensors are seen as applications of BME 141 and you'll need to use your knowledge from this course to understand how they work. Besides, BME electronic systems are usually connected to a sensor that provides its input signal. This master is research-oriented. That doesn't mean you are all trained to become academic researchers, but that, wathever your future position will be, you are very likely to be involved in innovative projects aimed at designing novel products and devices. Innovation always starts wit a clear view of the current state of the art. What already exists, and how could I make a difference with the idea that I have? Through the review project, you will learn how to use available bibliographic ressources to build this state of the art, and make it available to other BME students. It's not an individual project, you will have to work as a team and learn how to do that efficiently. The main requirement is that you try and connect your review to the topics of both courses, so you may answer these 3 questions : 1- What are the principles of physics that explain the sensor’s operation ? 2- What is the purpose and importance of the electronic interface ? 3- What knowledge, competence and ressources will you need (or already have) to propose a new type of sensor with better performance. At the end of the project, results will be presented in a group oral defense. Each member of the group should have the same speaking time.

Educational goals

Upon completion of this course, students will be able to : - Understand the basic principles and analyze simple biomedical electronic circuits and interfaces. - Understand operation and use of basic electronic components: diode, transistors and opamps. - Choose appropriate electronic components and circuits to connect to a medical sensor. - Search for references and resources adequate to their specific design project - Interpret datasheets of electronic components. - Make a model biomedical device ￜ an optical pulse oximeter ￜ starting from the physical principles to the printed circuit board

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum. Resources also from laboratory, equipment of the school and laboratories, fablab ...

Pedagogy

Lectures, Practices, Homework, Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME143 Upgrade in Mechanical engg.
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	4
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_UME - BME143 Upgrade in Mechanical

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This module provides the basic and advanced knowledge and skills in mechanical engineering and their application to biomechanics. It covers the latest advancements in the field of mechanical engineering, including modern design techniques, experimentat technologies and advanced manufacturing processes. This module is ideal for BME students from different backgrounds who are looking to upgrade their skills and knowledge and apply it to biomedical applications. The BME143 module will provide all the basics of mechanical engineering taught in the 2 years of the master program. It will be based on concrete examples of how engineering for health can use the resources learned to create the devices of tomorrow. This module will introduce different concepts taught in other parts of the master's program and will allow the research and development of future applications related to the program's project activities. It will also be reinforced by advanced readings of actors of the ecossystem in health engineering with readings of researchers, doctors or companies. Chapter 1 Introduction to Mechanical engineering in biomechanical and biomedical fields Lectures Chapter 2 Rigid body and motion in solids and mechanism (force, torque, speed and spin on the human body) Lectures and practices Chapter 3 Continuum mechanics and Mechanical behavior (Strain and stress on organs and soft tissus) Lecture and practices Chapter 4 Basic to modern design techniques (collaborative CAD design) Lecture and practices Chapter 5 3D reconstruction from medical data and advanced CAD (MRI, CT-Scan, Laser Scan) (Introduction to complexe surfaces in Semester2) Lecture and practices Chapter 6 Advanced manufacturing processes for protypying Biomedical Device Lectures and practices Chapter 7 Mould creation for biomimetic soft materials and biofidelic phantom fabrication (Introduction to experimental biomechanics in Semester2) Practices Chapter 8 Introduction to Finite Element analysis with online simulation platforms and predimensioning Medical Device (Introduction to FEA in Semester2) Lectures and Practices Chapter 9 - Project activity The project proposed at the end of the module is devoted to the development of a hand prosthesis to apply the theoretical and technical concepts discussed in class (mechanical system, computer-aided design (CAD), rapid prototyping ...).

Educational goals

By the end of the course, students will be able to: - Understand and apply advanced mechanical engineering principles and concepts. - Analyze and solve complex mechanical engineering problems using modern design techniques - Evaluate and select the appropriate manufacturing processes for specific biomechanical engineering applications. - Demonstrate effective communication and teamwork skills in a multidisciplinary mechanical engineering environment. - Stay current with the latest advancements in the field of mechanical engineering.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

BME laptops, DICOM/CAD/FEA software provided. Online ressources of the software. Lessons, exercises and self-evaluations on Moodle. BME laboratory, Rapid prototyping laboratory Contacts with teachers, researchers, surgeons and health services

Pedagogy

-

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	12
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

No prerequisite in mechanics (Semester to learn fundamentals of mechanics applied to health) Basic in mathematics from previous modulus (Differential and Integral Calculus, Linear Algebra, Trigonometry, Differential Equation) Some notions of anatomy, medical imaging, pathologies and treatments could be added value in the module for the project activity.

Maximum number of registrants

Remarks

None

Course label :	BME144 Multi-bodies dynamics of complex biomechanical systems
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_MBD - BME144 Multi-bodies dynamics .

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

By achieving this class, you will develop and gain a thorough understanding of the basics of human dynamic movement and rigid musculoskeletal modeling. Difference lectures on the motion capture techniques, medical imaging and multi-body dynamics will be provided. Lab works using OpenSIM software will be conducted.

Educational goals

Using lectures and hands-on project, the course explores principles of multi-body dynamics of complex biomechanical systems. Moreover, the simulation of medical devices (orthosis, prosthesis, exoskeleton) in interaction with human body will be studied.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum. Software: OpenSIM

Pedagogy

Lectures, Practices, Homework, Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	40
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME104 Biomaterial
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_BIM - BME104 Biomaterial

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Introduction to biomedical materials for biomedical devices, biomaterials & bio-compatibility. This course introduces students to the fundamental principles and concepts of biomedical materials, including biomaterials and bio-compatibility. The course covers topics such as the properties of materials, selection criteria for biomedical devices, and the design and testing of biomedical materials. Chapter 1 : Introduction to Biomaterials and Biomedical Devices, application, challenges into biomedical engineering research Chapter 2 : Mechanical engineering to biomaterial, Properties of Biomaterials, Biocompatibility, biodegradability, Surface properties, Modification techniques Chapter 3 : Selection Criteria for Biomedical Devices (GrantaANSYS), Design considerations for biomedical devices, Regulatory and safety considerations Chapter 4 : Types of Biomaterials, Metals and alloys, Ceramics and glasses, Polymers and composites, Natural biomaterials (new lecture in 2023) Chapter 5 : Research in biomaterial

Educational goals

Course Goals and Learning Objectives: - To understand the basic principles of biomaterials and their applications in biomedical devices - To learn the selection criteria for choosing appropriate materials for biomedical devices (GrantaANSYS) - To understand the principles of bio-compatibility and the role of materials in bio-compatibility - To gain knowledge on the different types of biomaterials and their properties - To be able to evaluate the suitability of different materials for specific biomedical applications

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Online resources with Moodle, Books, Papers BME laboratory, Practice tools and platforms Software GrantaANSYS

Pedagogy

This course is delivered through a combination of lectures, group discussions with surgeons, and hands-on activities with faculty of medicine, labs and hospitals. Students will be expected to read actively reference in discussions and activities. Case studies into GrantaANSYS. Apply the concepts learned in class to a specific biomedical device or application in the transdisciplinary projects proposed in Semesters2 and 3.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	15
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic understanding of the following subjects: Material sciences, Biomechanics, Anatomy and Physiology, chemistry, Medical technology for surgery Varying prerequisites according to the lectures/chapters (Some supports will be provides to the student before the class)

Maximum number of registrants

Remarks

Course label :	BME130 Biology
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_BIO - BME130 Biology

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Fundamentals of biology and physiology from an engineering perspective. Genetics, molecular biology and basic cellular physiology Chapter1: Introduction of biology for BME Chapter2: Chapter3: Chapter4 Chapter5: Chapter6: Chapter7:

Educational goals

The learning objective of the BME130 Biology is to: - Understanding the basics of biology, chemistry, physics, and mathematics that are relevant to biomedical engineering. - Understanding the principles of tissue engineering, including the design and construction of scaffolds, cell culture, and tissue regeneration. - Developing communication skills necessary to work effectively in interdisciplinary teams, including technical writing, oral presentation, and collaboration.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Moodle Platform, Online documents, Papers, MOOC

Pedagogy

MOOC, lectures, online discussion with Biologists from USA

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	25
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Basic understanding of specific subjects learned into the BME program such as: Mathematics, Physics, Anatomy and Physiology, Cell

Maximum number of registrants

Remarks

Course label :	BME150 Biomedical Engineering project (option 2)
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	12
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_BEP - BME150 Biomedical Engineering

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Project proposed by medical worker and compagnies including every fileds of biomedical engineering. The transdisciplinary projects of the BME concern an important part of the program for the application of the knowledge and skills taught in the training, deep application or discovery of new fields, in relation with Biomedical Engineering. They allow the consolidation of methodological knowledge and skills, thus reinforcing the personalization and the overall coherence of the BME training. This project is transdisciplinary in terms of the scientific and technical skills required to complete the project. The interdisciplinarity between the medical world, research or business is also strongly represented in this type of project in engineering for health with application in laboratory and / or business and / or hospital. Sequence: Phase1: On the beginning of the semester, a list of projects is proposed by professors, researchers, doctors or company partner of the program including different fields of biomedical engineering. Phase2 : Students position themselves according to their wishes. It is also possible for students to propose their own topic, validated by the teaching team. Each student is assigned a mentor who can be a doctor, researcher or teacher in the training. Each mentor defines with the student the objectives to be reached by the end of the project (achievable and more advanced objectives) Phase 3: the student has hours allocated to this activity (in the form of half days in the semester). He/she has access to the facilities and equipped rooms of Centrale Lille to carry out his/her project. They can also contact teachers, researchers, industrial experts or health personnel to help them. Phase 4: Evaluation in the form of a report and defense Phase 5: Possible prolongation at the end of the semester in the form of a "summer internship" or "Internship” for master thesis

Educational goals

The pedagogical objectives may vary according to the project selected by the student. However, the student will eventually be able to - Be more autonomous in the management of a project (development of objectives, tasks, planning, budget, etc.) - Manage a project in relation with doctors, engineers and researchers. - Conduct a targeted literature review and position your project in relation to the state of the art in a medical, societal and economic context. - Apply the fundamental and theoretical principles learned in class to a specific subject - Develop tools thanks to technical and scientific skills. For example: development of an image analysis interface, integration of a sensor in a medical device, digital modeling for diagnosis, realization of a prototype, etc. - Apply, integrate and appropriate knowledge and skills - Develop the autonomy expected in internships and in professional life

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: Evaluation of the reports and the defense by peers and by a jury composed by experts.

Online resources

LMS learning management system (Moodle) with documents, previous year projects, publications, forum. Resource also from laboratory, equipment of the school and laboratories, fablab ...

Pedagogy

This project, personal or in group, allows students to increase their skills on topics that interest them, in connection with their professional future. The team is composed of students and teachers and researchers of the BME master. The student has a personalized coaching to allow him to follow the project throughout the semester. The teaching members of the team are responsible for consulting with each other, launching the project, helping the students and the team as a whole, ensuring regular exchanges, formalizing the need, etc. They also have the possibility of calling on consultants from the school or from BME partners to help them progress. Depending on the needs, courses, lectures or guest speakers can be used to share with other projects in the class or other classes.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

BME101 Research Environment and Methodology BME141 Upgrade in physics BME142 Upgrade in EEA engg BME143 Upgrade in Mechanical engg.

Maximum number of registrants

Remarks

Course label :	BME121 French as foreign language
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Madam VERONIQUE DZIWNIEL / Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_FFL - BME121 French as foreign lang

Education team

Teachers : Madam VERONIQUE DZIWNIEL / Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

As soon as they arrive at the BME master’s program, international students take a test that allows them to be divided into groups of different levels. As international students, who automatically take French as a foreign language courses, they benefit, from their first session, from an FLE training program adapted to their language level and based on interaction and communication in French cultural and professional contexts established by the teacher. Thereafter, the teaching offers face-to-face classes as well as autonomous access to the digital platform offered by the company goFLUENT. This face-to-face/non-face pedagogy aims to help students become more comfortable in communicating in the 5 skills outlined by the Common European Framework of Reference for Languages: - Oral and written comprehension - Oral and written expression - Oral interaction (taking part in a conversation) The pedagogical material proposed by goFLUENT being more oriented towards oral and written comprehension, as well as grammatical and lexical revision or deepening, the face-to-face courses will be careful to encourage above all oral and written production and to clarify the notions not acquired in Unsupervised session. Complementarity between the two sources can be established. Deepening of linguistic skills and performances, often (but not always) acquired through "immersions", of varying length, in the target language context. Cultural" broadening towards: - Training and personal development - The notion and the world of work and its transformations - The business world and its marketing strategies

Educational goals

Better assimilate thematic vocabulary, both general and professional. Improve their language skills. At the end of the semester, students will be able to: - Understand and produce written or oral documents dealing with aspects of the academic and business environment - Talk about themselves, their personal and student background, and their work experience - Project themselves in a job market and understand the cultural codes and issues of the respective countries - Describe, analyze and comment on a social fact, i.e. to carry out various exchanges Specific contribution of the course to the competency framework: at the end of the course, the student will have progressed in taking into account the international dimension through his/her ability to communicate in a foreign language, and in international and responsible management, through his/her ability to convince and to be accountable, to take into account the cultural specificities of the partners

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

LMS - learning management system (Moodle) with all course documents, corrected exercises, forum.

Pedagogy

Tutorials in groups of accompanied levels, independent work on the digital platform

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME122 German as foreign language
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S1_MSO_GFL - BME122 German as foreign lang

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

As soon as they arrive at the BME master’s program, international students take a test that allows them to be divided into groups of different levels. Thereafter, the teaching offers face-to-face lessons that aims to help students become more comfortable in communicating in the 5 skills outlined by the Common European Framework of Reference for Languages: - Oral and written comprehension - Oral and written expression - Oral interaction (taking part in a conversation) The pedagogical material proposed by books being more oriented towards oral and written comprehension, as well as grammatical and lexical revision or deepening, the face-to-face courses will be careful to encourage above all oral and written production and to clarify the notions not acquired in Unsupervised session. Complementarity between the two sources can be established.

Educational goals

Better assimilate thematic vocabulary, both general and professional. Improve their language skills. At the end of the semester, students will be able to: - Understand and produce written or oral documents dealing with aspects of the academic and business environment - Talk about themselves, their personal and student background, and their work experience - Project themselves in a job market and understand the cultural codes and issues of the respective countries - Describe, analyze and comment on a social fact, i.e. to carry out various exchanges Specific contribution of the course to the competency framework: at the end of the course, the student will have progressed in taking into account the international dimension through his/her ability to communicate in a foreign language, and in international and responsible management, through his/her ability to convince and to be accountable, to take into account the cultural specificities of the partners

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, forum.

Pedagogy

Tutorials in groups of accompanied levels, independent work, books

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME211 Electronics
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_ELE - BME211 Electronics

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides the knowledge of Physics required to follow the key points dealing with sensors. It covers knowledge in the field of Sensors (basic operating principle including industrial sensors), electric actuators (in medical equipment & safety procedures), CEM

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	24
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME212 Sensors, part 1
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_SEN - BME212 Sensors, part 1

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides the knowledge of Physics required to follow the key points dealing with sensor-obtained Signal Processing It covers knowledge in the field of Sampling & Approximation theory, principal fundamental methods, statistical learning for signal processing

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	24
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME213 Mechanical engg.
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	4
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_MEN - BME214 Mechanical engg.

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Courses Description: This module covers advanced topics in the field of Biomechanical engineering, including advanced mechanics of materials, finite element analysis, and computational modeling techniques. Students will develop an understanding of the principles of biomechanics and how they apply to the design and analysis of biomechanical systems. Chapter 1: Introduction to biomechanical engineering Basic principles of biomechanics, Review of mechanics of materials, Applications of biomechanical engineering. Lectures and practices Chapter 2: Advanced mechanics of materials Stress and strain analysis, Failure criteria, Introduction to fatigue analysis Lectures and practices Chapter 3: Experimenta biomechanics Mechanical behavior of soft tissues, experimental test, post-treatment, representative synthetic materials Lectures and practices in BME laboratory Chapter 4: Finite Element Analysis Introduction to finite element analysis, Pre-processing, solving, and post-processing, Applications of FEA in biomechanical engineering Lectures and practices Chapter 5: Computational modeling and Virtual twins Image reconstruction, Numerical models of the human body, Multiscale modeling and Patient-specific models Lectures and practices Chapter 6: Implant and MD designs Design considerations for medical devices, geometrical optimization Lectures and practices Chapter 7: Clinical applications of biomechanical engineering Project with clinical applications with medical partners Lectures, mentoring and project

Educational goals

Learning Objectives: - Analyze the mechanics of complex biological systems using advanced analytical and numerical methods. - Develop computational models to simulate the behavior of biological tissues and structures. - Design and evaluate medical devices and implants using principles of biomechanical engineering. - Understand the principles of Physiology/Pathology/Treatment and their applications in clinical practice.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum. Resources also from BME laboratory, equipment of the school and laboratories

Pedagogy

Lectures, Practices, Homework, project, Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	60
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Continuity of first semester BME101 Research Environment and Methodology BME103 Industry and development of Biomedical devices BME114 Mathematics for biomedical engineering BME115 Algorthims and Programming BME104 Biomaterial BME143 Upgrade in Mechanical engg. (Option1) BME144 Multi-bodies dynamics of complex biomechanical systems

Maximum number of registrants

Remarks

Course label :	BME215 Signal processing, Part 1
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_SP1 - BME215 Signal processing,part1

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides the knowledge of Physics required to follow the key points dealing with sensor-obtained Signal Processing It covers knowledge in the field of Sampling & Approximation theory, principal fundamental methods, statistical learning for signal processing

Educational goals

Course objectives - Learn some basic signal types and properties - Learn how to digitize a signal - First set of signal processing tools (frequency analysis, filtering, etc.) - Offline signal processing (Python + Jupyter Lab + scipy.signal) - Live signal processing/visualization (Python + pyqtgraph + scipy.signal)

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Lectures, Practices, Homework, Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	24
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME203 Project management, part 1
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	1
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_PMA - BME203 Project management, 1

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Principles of the design process, problem-solving, and decision-making using studies cases. Marketing strategies for different marketplaces.

Educational goals

The aim of this course is to develop capabilities to define, frame and communicate to ensure short term performance of a project. Based on international project management methodologies, students apply tools and techniques to specify the final product of a project, to plan tasks of a project, to estimate budget and time for the development, to anticipate risks in the project, to organize stakeholders of the project and to establish communication documents for workgroups and decision-makers of the project. Course Plan: Course 1: Defining the final product of a project Course 2: Structuring tasks, time and costs of the project development Course 3: Anticipating risks in the project Course 4: Organizing project stakeholders Course 5: Communicating project information to workgroup and steering commitee

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Each student develops skills on a personal project about a biomedical subject. The student's work is evaluated through a project presentation on the ability to be clear coherent and precised.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	15
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME201 Materials and Bio-compatiblity
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	1
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_MBC - BME201 Mat. & Bio-comp.

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Materials used in the body as well as functionalization of materials. Topics include classification of materials (ceramic, metals, polymers), mechanical properties, modes of failure, immune response to biomaterials, etc.

Educational goals

Introduction to bio-compatibility. This course introduces students to the fundamental principles and concepts of biomedical materials, including biomaterials and bio-compatibility. The course covers topics such as the properties of materials, selection criteria for biomedical devices, and the design and testing of biomedical materials. In addition to traditional classroom instruction, the course includes a hands-on learning experience through a visit to the hospital's surgical block, allowing students to observe and assist in real surgical procedures.

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Moodle, online documents, Software

Pedagogy

Lectures and Demonstrations: Traditional classroom lectures and live demonstrations will be conducted to cover theoretical aspects of surgical techniques, instruments, and procedures. Laboratory Sessions: Practical hands-on sessions in a simulated environment to study biocompatibility Hospital Visit - Surgical Block: To provide students with a firsthand experience of the surgical environment, observe live surgeries, and understand the dynamics of a functioning operating room. A scheduled visit to CHULille where students will have the opportunity to observe and assist in selected surgeries under the guidance of experienced surgical staff. Students are expected to adhere to hospital protocols, maintain a professional demeanor, and actively participate in the learning experience. Case Studies: Analysis of real-life surgical cases of Hip prosthesis Invited professionals from the field of surgery will share their insights and experiences with the students

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

BME104

Maximum number of registrants

Remarks

Course label :	BME230 Biotechnology
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_BIO - BME230 Biotechnology

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course combines lectures, demonstrations, discussions and problem solving exercises exploring biotechnology.

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	25
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME250 Biomedical Engineering Project
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	12
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_BEP - BME250 Biomedical Engineering

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Project proposed by medical worker and compagnies including every fileds of biomedical engineering. The transdisciplinary projects of the BME concern an important part of the program for the application of the knowledge and skills taught in the training, deep application or discovery of new fields, in relation with Biomedical Engineering. They allow the consolidation of methodological knowledge and skills, thus reinforcing the personalization and the overall coherence of the BME training. This project is transdisciplinary in terms of the scientific and technical skills required to complete the project. The interdisciplinarity between the medical world, research or business is also strongly represented in this type of project in engineering for health with application in laboratory and / or business and / or hospital. Sequence: Phase1: On the beginning of the semester, a list of projects is proposed by professors, researchers, doctors or company partner of the program including different fields of biomedical engineering. Phase2 : Students position themselves according to their wishes. It is also possible for students to propose their own topic, validated by the teaching team. Each student is assigned a mentor who can be a doctor, researcher or teacher in the training. Each mentor defines with the student the objectives to be reached by the end of the project (achievable and more advanced objectives) Phase 3: the student has hours allocated to this activity (in the form of half days in the semester). He/she has access to the facilities and equipped rooms of Centrale Lille to carry out his/her project. They can also contact teachers, researchers, industrial experts or health personnel to help them. Phase 4: Evaluation in the form of a report and defense Phase 5: Possible prolongation at the end of the semester in the form of a "summer internship" or "Internship” for master thesis

Educational goals

The pedagogical objectives may vary according to the project selected by the student. However, the student will eventually be able to - Be more autonomous in the management of a project (development of objectives, tasks, planning, budget, etc.) - Manage a project in relation with doctors, engineers and researchers. - Conduct a targeted literature review and position your project in relation to the state of the art in a medical, societal and economic context. - Apply the fundamental and theoretical principles learned in class to a specific subject - Develop tools thanks to technical and scientific skills. For example: development of an image analysis interface, integration of a sensor in a medical device, digital modeling for diagnosis, realization of a prototype, etc. - Apply, integrate and appropriate knowledge and skills - Develop the autonomy expected in internships and in professional life

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: Evaluation of the reports and the defense by peers and by a jury composed by experts.

Online resources

LMS learning management system (Moodle) with documents, previous year projects, publications, forum. Resources also from laboratory, equipment of the school and laboratories, fablab ...

Pedagogy

This project, personal or in group, allows students to increase their skills on topics that interest them, in connection with their professional future. The team is composed of students and teachers and researchers of the BME program. The student has a personalized coaching to allow him to follow the project throughout the semester. The teaching members of the team are responsible for consulting with each other, launching the project, helping the students and the team as a whole, ensuring regular exchanges, formalizing the need, etc. They also have the possibility of calling on consultants from the school or from BME partners to help them progress. Depending on the needs, courses, lectures or guest speakers can be used to share with other projects in the class or other classes.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

1st semester courses and BME150 Trans-disciplinary project + BME203 Project management, Part 1 BME211 Electronics BME212 Sensors, Part 1 BME213 Mechanical engg., Part 1

Maximum number of registrants

Remarks

Some examples of projects from previous years:

Course label :	BME221 French as foreign language
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Madam VERONIQUE DZIWNIEL / Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_FFL - BME221 French as foreign lang

Education team

Teachers : Madam VERONIQUE DZIWNIEL / Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

As soon as they arrive at the BME master’s program, international students take a test that allows them to be divided into groups of different levels. As international students, who automatically take French as a foreign language courses, they benefit, from their first session, from an FLE training program adapted to their language level and based on interaction and communication in French cultural and professional contexts established by the teacher. Thereafter, the teaching offers face-to-face classes as well as autonomous access to the digital platform offered by the company goFLUENT. This face-to-face/non-face pedagogy aims to help students become more comfortable in communicating in the 5 skills outlined by the Common European Framework of Reference for Languages: - Oral and written comprehension - Oral and written expression - Oral interaction (taking part in a conversation) The pedagogical material proposed by goFLUENT being more oriented towards oral and written comprehension, as well as grammatical and lexical revision or deepening, the face-to-face courses will be careful to encourage above all oral and written production and to clarify the notions not acquired in Unsupervised session. Complementarity between the two sources can be established. Deepening of linguistic skills and performances, often (but not always) acquired through "immersions", of varying length, in the target language context. Cultural" broadening towards: - Training and personal development - The notion and the world of work and its transformations - The business world and its marketing strategies

Educational goals

Better assimilate thematic vocabulary, both general and professional. Improve their language skills. At the end of the semester, students will be able to: - Understand and produce written or oral documents dealing with aspects of the academic and business environment - Talk about themselves, their personal and student background, and their work experience - Project themselves in a job market and understand the cultural codes and issues of the respective countries - Describe, analyze and comment on a social fact, i.e. to carry out various exchanges Specific contribution of the course to the competency framework: at the end of the course, the student will have progressed in taking into account the international dimension through his/her ability to communicate in a foreign language, and in international and responsible management, through his/her ability to convince and to be accountable, to take into account the cultural specificities of the partners

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, forum.

Pedagogy

Tutorials in groups of accompanied levels, independent work on the digital platform.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME222 German as a foreign language
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S2_MSO_GFL - BME222 German as foreign lang

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

As soon as they arrive at the BME master’s program, international students take a test that allows them to be divided into groups of different levels. Thereafter, the teaching offers face-to-face lessons that aims to help students become more comfortable in communicating in the 5 skills outlined by the Common European Framework of Reference for Languages: - Oral and written comprehension - Oral and written expression - Oral interaction (taking part in a conversation) The pedagogical material proposed by books being more oriented towards oral and written comprehension, as well as grammatical and lexical revision or deepening, the face-to-face courses will be careful to encourage above all oral and written production and to clarify the notions not acquired in Unsupervised session. Complementarity between the two sources can be established.

Educational goals

Better assimilate thematic vocabulary, both general and professional. Improve their language skills. At the end of the semester, students will be able to: - Understand and produce written or oral documents dealing with aspects of the academic and business environment - Talk about themselves, their personal and student background, and their work experience - Project themselves in a job market and understand the cultural codes and issues of the respective countries - Describe, analyze and comment on a social fact, i.e. to carry out various exchanges Specific contribution of the course to the competency framework: at the end of the course, the student will have progressed in taking into account the international dimension through his/her ability to communicate in a foreign language, and in international and responsible management, through his/her ability to convince and to be accountable, to take into account the cultural specificities of the partners

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, forum.

Pedagogy

Tutorials in groups of accompanied levels, independent work, books

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	Summer Internship (Optional )
Teaching departement :	CMA /
Teaching manager :
Education language :	French
Potential ects :	0
Results grid :
Code and label (hp) :	-

Education team

Teachers :
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME321 French as foreign language
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Madam VERONIQUE DZIWNIEL / Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_FFL - BME321 French as foreign lang

Education team

Teachers : Madam VERONIQUE DZIWNIEL / Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

As soon as they arrive at the BME master’s program, international students take a test that allows them to be divided into groups of different levels. As international students, who automatically take French as a foreign language courses, they benefit, from their first session, from an FLE training program adapted to their language level and based on interaction and communication in French cultural and professional contexts established by the teacher. Thereafter, the teaching offers face-to-face classes as well as autonomous access to the digital platform offered by the company goFLUENT. This face-to-face/non-face pedagogy aims to help students become more comfortable in communicating in the 5 skills outlined by the Common European Framework of Reference for Languages: - Oral and written comprehension - Oral and written expression - Oral interaction (taking part in a conversation) The pedagogical material proposed by goFLUENT being more oriented towards oral and written comprehension, as well as grammatical and lexical revision or deepening, the face-to-face courses will be careful to encourage above all oral and written production and to clarify the notions not acquired in Unsupervised session. Complementarity between the two sources can be established. Deepening of linguistic skills and performances, often (but not always) acquired through "immersions", of varying length, in the target language context. Cultural" broadening towards: - Training and personal development - The notion and the world of work and its transformations - The business world and its marketing strategies

Educational goals

Better assimilate thematic vocabulary, both general and professional. Improve their language skills. At the end of the semester, students will be able to: - Understand and produce written or oral documents dealing with aspects of the academic and business environment - Talk about themselves, their personal and student background, and their work experience - Project themselves in a job market and understand the cultural codes and issues of the respective countries - Describe, analyze and comment on a social fact, i.e. to carry out various exchanges Specific contribution of the course to the competency framework: at the end of the course, the student will have progressed in taking into account the international dimension through his/her ability to communicate in a foreign language, and in international and responsible management, through his/her ability to convince and to be accountable, to take into account the cultural specificities of the partners

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Tutorials in groups of accompanied levels, independent work on the digital platform

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME322 German as foreign language
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_GFL - BME322 German as foreign lang

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

As soon as they arrive at the BME master’s program, international students take a test that allows them to be divided into groups of different levels. As international students, who automatically take French as a foreign language courses, they benefit, from their first session, from an FLE training program adapted to their language level and based on interaction and communication in French cultural and professional contexts established by the teacher. Thereafter, the teaching offers face-to-face classes as well as autonomous access to the digital platform offered by the company goFLUENT. This face-to-face/non-face pedagogy aims to help students become more comfortable in communicating in the 5 skills outlined by the Common European Framework of Reference for Languages: - Oral and written comprehension - Oral and written expression - Oral interaction (taking part in a conversation) The pedagogical material proposed by goFLUENT being more oriented towards oral and written comprehension, as well as grammatical and lexical revision or deepening, the face-to-face courses will be careful to encourage above all oral and written production and to clarify the notions not acquired in Unsupervised session. Complementarity between the two sources can be established. Deepening of linguistic skills and performances, often (but not always) acquired through "immersions", of varying length, in the target language context. Cultural" broadening towards: - Training and personal development - The notion and the world of work and its transformations - The business world and its marketing strategies

Educational goals

Better assimilate thematic vocabulary, both general and professional. Improve their language skills. At the end of the semester, students will be able to: - Understand and produce written or oral documents dealing with aspects of the academic and business environment - Talk about themselves, their personal and student background, and their work experience - Project themselves in a job market and understand the cultural codes and issues of the respective countries - Describe, analyze and comment on a social fact, i.e. to carry out various exchanges Specific contribution of the course to the competency framework: at the end of the course, the student will have progressed in taking into account the international dimension through his/her ability to communicate in a foreign language, and in international and responsible management, through his/her ability to convince and to be accountable, to take into account the cultural specificities of the partners

Sustainable development goals

Knowledge control procedures

Continuous Assessment
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Tutorials in groups of accompanied levels, independent work, books

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME311 Machine Learning and Deep Learning in Biomedical Eng
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_MLD - BME311 Machine Learning & Deep

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks

Course label :	BME312 Sensors, part 2
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :
Education language :
Potential ects :	1
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_SEN - BME312 Sensors, part 2

Education team

Teachers :
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	24
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Sensor Part 1

Maximum number of registrants

Remarks

Course label :	BME313 Mechanical engg.
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_MEN - BME313 Mechanical engg.

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course will provide students with advanced knowledge and skills in Computer-Aided Design (CAD) and Finite Element Analysis (FEA) for biomedical applications. The course will cover the design of medical devices and implants using 4D Magnetic Resonance Imaging (4DMRI) and flow data. Students will learn how to use advanced CAD software to create, analyze and optimize biomedical designs that take into account the complex anatomical features and flow patterns of the human body. The course will also cover topics related to material selection, biocompatibility, and regulatory requirements for MD. The BME313 module is based on Patient-Specific simulation of different anatomical parts to better characterize, understand and adapt the surgical treatment in relation to the patient. Examples of case studies are based on bone tissue (treatment with prosthetic elements for maxilofascial, hip prosthesis development) but also soft biological tissue with organ models (applications on the brain, heart or pelvic system) Chapter 1: Advanced Anatomical moddels using CAD Design Complex surface with CAD design for biomedical applications, Keywords: NURBS, Patient-specific models, Parametric models, automatisation using medical imaging. Chapter 2: Advanced Numerical simulation using FEA Topologial optimization of the implant into the Patient-Specific environnement Keywords: Topology optimization, Optimization algorithms, Material distribution, Design freedom, Stress minimization, Weight reduction, Stiffness maximization Chapter 3: Experimental test on biocompatible materials Anysotropy, Cyclic tests, Degradation, Resorbability and Mechanical behavior Chapter 4: Virtual twins and Surgery 4.0 Integration of the virtual twins into the real life, Training mannequins for surgeons Keywords: Additive manufacturing, process, evaluation and decision support, augmented reality with holograms, integration for future surgery Chapter 5: Application of CAD design principles to real-world biomedical problems Group projects and case studies (Project to create a heart phantom compatible with an MRI environment.)

Educational goals

Learning Objectives: - Analyze the mechanics of complex biological systems using advanced numerical methods. - Develop computational models to simulate the behavior of biological tissues and structures. - Design and evaluate medical devices and implants using principles of biomechanical engineering. - Understand the principles of Physiology/Pathology/Treatment and their applications in clinical practice.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum. Resources also from laboratory, equipment of the school and laboratories, Business and opensource software suite for the digital chain Anonymized health data corresponding to patient MRI, 4D-MRI, CT-Scan

Pedagogy

Lectures, Practices, Homework, Project Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	48
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

First year of the BME program BME101 Research Environment and Methodology BME103 Industry and development of Biomedical devices BME114 Mathematics for biomedical engineering BME115 Algorthims and Programming BME143 Upgrade in Mechanical engg. (Option1) BME144 Multi-bodies dynamics of complex biomechanical systems BME213 Mechanical engg., Part 1 BME201 Materials and Bio-compatiblity

Maximum number of registrants

Remarks

Course label :	BME314 Surgical robotics
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_SRO - BME314 Surgical robotics

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course introduces students to the principles and applications of surgical robotics with a specific emphasis on soft robotics. Topics include the fundamentals of surgical procedures, robotic systems in surgery, and the integration of soft robotics for enhanced flexibility and adaptability. The course involves a combination of theoretical lectures, hands-on laboratory sessions, and real-world case studies. Robotics and the bio-inspiration

Educational goals

Lesson 1 - Kinematics Modeling > Overview > Geometric based modeling > Elastic based modeling Lesson 2 - Dynamics modeling > Hamilton based modeling > Lagrangian based approach Lesson 3 - Motion control > PID based Control > Motion planning based control Lesson 4 - Soft Robotics Fundamentals and integrations in surgery > Introduction to soft robotics > Soft actuators and sensors > Advantages and challenges of soft robotics in surgery > Case studies on soft robotic surgical tools Lesson 5 - Project Work and Presentations > Design and development of a soft robotic surgical tool > Final project presentations and evaluations

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: None

Online resources

Moodle, ANSYS, Onshape, Electrronical components Online documents

Pedagogy

Lesson, Practices, projects

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	24
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

CAD design and Python, Mathematics, Mechanical Engineering, FEA

Maximum number of registrants

Remarks

None

Course label :	BME315 Signal processing, Part 2
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_SP2 - BME315 Signal processing, 2

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This signal processing course series focuses on the application of image processing techniques to biomedical applications. The progression of courses covers key aspects of image processing, mathematical morphology, segmentation, and the integration of eye tracking technology.

Educational goals

Course 1 : Image processing intro Introduction to image processing, covering acquisition, representation, and enhancement. Students engage in hands-on exercises using python. Course 2 : Mathematical morphology Exploration of mathematical morphology as a tool for shape and structure analysis in ultrasound images. Topics include fundamental principles, morphological operations, and applications in medical imaging. Course 3 : Basic mathematical morphology exercises (Lab1) A hands-on laboratory session reinforcing the principles covered in mathematical morphology. Students engage in practical exercises implementing dilation, erosion, and other morphological operations. The lab enhances proficiency in applying these operations and troubleshooting challenges commonly encountered in signal processing. Course 4 : Segmentation, lesson and practices Building on the foundational knowledge, this course focuses on segmentation techniques in signal processing. Students learn about various segmentation algorithms, challenges in segmentation, and practical applications. The course includes hands-on group exercises, allowing students to analyze and implement segmentation methods for real-world scenarios. Course 5 : Eye tracker The final course introduces the integration of eye tracking technology into signal processing. Students gain insights into the principles of eye tracking, eye movement patterns in signal analysis, and practical applications. The course includes hands-on experience with eye tracking devices, emphasizing their role in optimizing signal processing interpretation, especially in dynamic scenarios.

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: None

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Lectures, Practices, Homework, Report Examples and application based on illustrations and concrete situations from biomedical engineering and research.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	24
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Signal Processing part1, python

Maximum number of registrants

Remarks

None

Course label :	BME303 Project Management, part 2
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	1
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_PMA - BME303 Project Management, 2

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

The aim of this course is to develop capabilities to define, monitor and control long term performance on a complex project. Based on complexity and uncertainty management litterature, students apply tools and techniques to specify benefits and outcomes of a project and to make the link between short term performance and long term performance in a project. Course 1: Defining benefits and outcomes of a project Course 2: Plan a complex project development Course 3: Identifying uncertainties in a project Course 4: Developing organization based on influence networks Course 5: Communicating complex project information to decision-makers

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments:

Online resources

LMS learning management system (Moodle) with all course documents, corrected exercises, publication, forum.

Pedagogy

Lectures, Practices, Homework, Examples and application based on Biomedical Engineering Project

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	20
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Students should have knowledge about basis of project management (BME 203)

Maximum number of registrants

Remarks

Course label :	BME301 Ethic
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_ETH - BME301 Ethic

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This unit deals with ethical problems. It covers the field of animal and human ethics and ethical committee procedures.

Educational goals

Lecture 1 : Introduction to Ethics, Scientific misconducts Lecture 2 : Handling data, scientific record, intellectual property Lecture 3 : Authorship, competing interests and collaborative research Lecture 4 : Using humans and animals in biomedical experimentations Lecture 5 : Presentation

Sustainable development goals

Knowledge control procedures

Final Exam
Comments: none

Online resources

Moodle, Online documentations

Pedagogy

Lectures, use-case, presentation of a project

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

None

Maximum number of registrants

Remarks

none

Course label :	BME331 Anatomy for engineers
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_ANA - BME331 Anatomy for engineers

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides a foundational understanding of human anatomy with a focus on its relevance to biomedical engineering. Students will explore anatomical terms, the skeletal system, joints, the nervous system, and the digestive system. The course integrates anatomical knowledge with principles of biomedical engineering, fostering a holistic approach to the human body.

Educational goals

Class 1 anatomical Terms Class 2 Introduction to human anatomy Class 3 Skeletal System Class 4 General Anatomy Joints Class 5 General Anatomy - Nervous system Class 6 General Anatomy - Digestive system Class 7 Intersectinf Anatomy and biomedical Eng. Class 8 Ankle Joint Anatomy Class 9 Hip anatomy tutorial Class 10 Integration and applications

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Anatomical models and physical mannequins with: - Human Skeleton Models: Life-sized or miniature models of the human skeleton for studying bone structure and joint articulation. - Joint Models: Detailed models illustrating different types of joints, such as the ankle and hip joints, for hands-on exploration. 3D Anatomy Software and platforms: interactive 3D anatomy software that allows students to explore the human body in a virtual environment. Experts in Biomedical Engineering: Invite professionals from the biomedical engineering field to share their experiences and demonstrate how anatomical knowledge is applied in real-world projects. Anatomy books and Online Resources. Partnerships with CHU-Lille

Pedagogy

Regular quizzes and exams to assess theoretical understanding. Laboratory sessions for hands-on experience in anatomical studies. Group projects and presentations evaluating the application of anatomy in biomedical engineering.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	30
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

None

Maximum number of registrants

Remarks

None

Course label :	BME332 Medical imaging
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	2
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_MIM - BME332 Medical imaging

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

This course provides the knowledge of Physics required to follow the key points dealing with medical imaging: It covers knowledge of MRI Technology, US transducers, introduction to multi-physics simulation (COMSOL)

Educational goals

Lesson 1 - Magnetic Resonance Imaging >>> Introduce students to the principles, technology, and applications of Magnetic Resonance Imaging (MRI) in medical diagnostics. >>> Physical and mathematical aspects >>> Practice with matlab and labMRI Lesson 2 - Computed Tomography >>> Provide an overview of the principles, technology, and applications of Computed Tomography (CT) in medical imaging. >>> Physical and mathematical aspects of X-Ray >>> Practice with matlab Lesson 3 Ultrasound Imaging >>> Introduce students to the principles, technology, and clinical applications of Ultrasound Imaging in medical diagnostics >>> Practice with matlab and hands-on

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: None

Online resources

Moodle, Matlab

Pedagogy

Lectures, practices

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	36
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Electronics lessons from M1, Matlab, Python

Maximum number of registrants

Remarks

None

Course label :	BME350 Biomedical Engineering project
Teaching departement :	MSO / Structures, Mechanisms and Construction
Teaching manager :	Mister OLIVIER MAYEUR
Education language :
Potential ects :	10
Results grid :
Code and label (hp) :	MR_BME_S3_MSO_BEP - BME350 Biomedical Engineering

Education team

Teachers : Mister OLIVIER MAYEUR
External contributors (business, research, secondary education): various temporary teachers

Summary

Project proposed by medical worker and compagnies including every fileds of biomedical engineering. The transdisciplinary projects of the BME concern an important part of the program for the application of the knowledge and skills taught in the training, deep application or discovery of new fields, in relation with Biomedical Engineering. They allow the consolidation of methodological knowledge and skills, thus reinforcing the personalization and the overall coherence of the BME training. This project is transdisciplinary in terms of the scientific and technical skills required to complete the project. The interdisciplinarity between the medical world, research or business is also strongly represented in this type of project in engineering for health with application in laboratory and / or business and / or hospital. Sequence: Phase1: On the beginning of the semester, a list of projects is proposed by professors, researchers, doctors or company partner of the program including different fields of biomedical engineering. Phase2 : Students position themselves according to their wishes. It is also possible for students to propose their own topic, validated by the teaching team. Each student is assigned a mentor who can be a doctor, researcher or teacher in the training. Each mentor defines with the student the objectives to be reached by the end of the project (achievable and more advanced objectives) Phase 3: the student has hours allocated to this activity (in the form of half days in the semester). He/she has access to the facilities and equipped rooms of Centrale Lille to carry out his/her project. They can also contact teachers, researchers, industrial experts or health personnel to help them. Phase 4: Evaluation in the form of a report and defense Phase 5: Possible prolongation at the end of the semester in the form of a "summer internship" or "Internship” for master thesis

Educational goals

The pedagogical objectives may vary according to the project selected by the student. However, the student will eventually be able to - Be more autonomous in the management of a project (development of objectives, tasks, planning, budget, etc.) - Manage a project in relation with doctors, engineers and researchers. - Conduct a targeted literature review and position your project in relation to the state of the art in a medical, societal and economic context. - Apply the fundamental and theoretical principles learned in class to a specific subject - Develop tools thanks to technical and scientific skills. For example: development of an image analysis interface, integration of a sensor in a medical device, digital modeling for diagnosis, realization of a prototype, etc. - Apply, integrate and appropriate knowledge and skills - Develop the autonomy expected in internships and in professional life

Sustainable development goals

Knowledge control procedures

Continuous Assessment / Final Exam
Comments: Evaluation of the reports and the defense by peers and by a jury composed by experts.

Online resources

LMS learning management system (Moodle) with documents, previous year projects, publications, forum. Resources also from laboratory, equipment of the school and laboratories, fablab ...

Pedagogy

This project, personal or in group, allows students to increase their skills on topics that interest them, in connection with their professional future. The team is composed of students and teachers and researchers of the BME master. The student has a personalized coaching to allow him to follow the project throughout the semester. The teaching members of the team are responsible for consulting with each other, launching the project, helping the students and the team as a whole, ensuring regular exchanges, formalizing the need, etc. They also have the possibility of calling on consultants from the school or from BME partners to help them progress. Depending on the needs, courses, lectures or guest speakers can be used to share with other projects in the class or other classes.

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

First year courses and Trans-disciplinary projects + BME303 Project management, Part 2 BME312 Sensors, Part 2 BME313 Mechanical engg., Part 2

Maximum number of registrants

Remarks

Some examples of projects from previous years:

Course label :	Internship
Teaching departement :	CMA /
Teaching manager :
Education language :	French
Potential ects :	30
Results grid :
Code and label (hp) :	-

Education team

Teachers :
External contributors (business, research, secondary education): various temporary teachers

Summary

Educational goals

Sustainable development goals

Knowledge control procedures

Final Exam
Comments:

Online resources

Pedagogy

Sequencing / learning methods

Number of hours - Lectures :	0
Number of hours - Tutorial :	0
Number of hours - Practical work :	0
Number of hours - Seminar :	0
Number of hours - Half-group seminar :	0
Number of student hours in TEA (Autonomous learning) :	0
Number of student hours in TNE (Non-supervised activities) :	0
Number of hours in CB (Fixed exams) :	0
Number of student hours in PER (Personal work) :	0
Number of hours - Projects :	0

Prerequisites

Maximum number of registrants

Remarks