| 1035463 | healthcare waste management | 1st | 1st | 6 | ICAR/03 | ITA |
Educational objectives After passing the exam, the students will acquire the following abilities:
1. identifying and characterizing the potentially non-hazardous and hazardous pollutants in sanitary waste/wastewater produced;
2. identifying suitable treatment processes for the removal of selected contaminants from effluents
3. providing a theoretical description of such processes
Applied knowledge and understanding
After passing the exam, the students will acquire the following abilities:
4. predicting potential adverse effects of contaminants;
5. drawing mass balances for the effluent treatment units,
6. defining the intervention strategy/process layout for sanitary waste/wastewater treatment;
7. deriving, using theoretical models, the removal yield of contaminants for individual treatment units.
After passing the exam, the students will also acquire learning skills, with specific regard to the ability to use suitable methods to make surveys on technical aspects in sanitary engineering at their level of knowledge and understanding. The participation to classroom exercises will contribute to building autonomous learning skills as for the most up-to-date methods, techniques and tools in the field of effluent treatment.
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| 1035476 | FLUID MOTION IN BIOLOGICAL SYSTEMS | 1st | 1st | 6 | ICAR/01 | ITA |
Educational objectives The course aims to provide students with the necessary elements for the study of the Fluids Mechanichs in Biological systems, with particular attention to the circulation of blood in the cardiovascular system, for the purpose of knowledge, analysis and resolution of the main problems arising in the field of biomedical engineering.
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| 10600007 | MATERIALS AND SURFACES FOR BIOMEDICAL USE | 1st | 2nd | 12 | ING-IND/22 | ITA |
Educational objectives Providing critical knowledge of the properties and structure of metallic materials and surfaces used in biomedical applications. Describe the role that such materials have in the design of biomedical and prosthetics devices, including those aspects related to materials transformation and surface treatments. Providing knowledge of the interaction of metallic materials and surfaces with biological systems. Leading the student to develop technical skills needed to understand and work in a highly multidisciplinary and continuously evolving field.
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| NON METALLIC MATERIALS | 1st | 2nd | 6 | ING-IND/22 | ITA |
Educational objectives Providing critical knowledge of the properties and structure of metallic materials and surfaces used in biomedical applications. Describe the role that such materials have in the design of biomedical and prosthetics devices, including those aspects related to materials transformation and surface treatments. Providing knowledge of the interaction of metallic materials and surfaces with biological systems. Leading the student to develop technical skills needed to understand and work in a highly multidisciplinary and continuously evolving field.
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| 1035478 | Artificial Organs Engineering | 1st | 1st | 6 | ING-IND/24 | ITA |
Educational objectives The course aims to provide students with the conceptual tools for the analysis, design and development of biomedical devices and equipment for the support or restoration of vital functions, for the growth of cells or the production of therapeutic substances.
To this end, the course includes a basic part on the physico-chemical and biological processes that take place in these systems and an application part, in which some of the existing equipment or devices are analyzed.
The course is completed with a series of monographic seminars held by professionals working in the medical or biotechnology sector.
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| 1044341 | ELECTRICAL MEASUREMENTS FOR BIOMEDICAL APPLICATION | 1st | 1st | 6 | ING-INF/07 | ITA |
Educational objectives KNOWLEDGE AND UNDERSTANDING. The course aims at providing the basic knowledge needed to perform electrical and electronic measurements, with particular emphasis on measurements relevant to the biomedical field. Specific emphasis is given to measurement for electronic device testing and to electro-physiological measurements. The most recent measurement techniques based on impedance spectroscopy are discussed.
APPLYING KNOWLEDGE AND UNDERSTANDING. The theoretical part of the course is completed and complemented by a series of laboratory experiments which allows the student to put into practice the concepts learnt and to acquire the fundamental skills for developing simple electrical medical instruments and for performing the basic measurements encountered in the field of biomedical engineering. Moreover, the basic concepts concerning the programming and management of virtual instrumentation are applied, developing user interfaces for processing and presentation of physiological signals.
MAKING JUDGEMENTS. Laboratory activities aim at allowing the student to make autonomous judgements; the actual autonomy reached by the student is assessed by means of a specific practical session during the final examination. The student gets acquainted with solving new problems in realistic experimental scenarios.
COMMUNICATION SKILLS. The experimental activities include group work, which enhances the student communication skills and interaction capabilities. The oral examination enhances the student capabilities to communicate his/her knowledge. Moreover, student must redact a written technical report concerning the development of a biomedical instrument.
LEARNING SKILLS. The didactic paradigm of the course urges the student to autonomously acquire new technical knowledge, related to the course syllabus, mainly as a result of the problem solving approach of experimental activities. The teaching material, reach of literature references, develops autonomous study capabilities.
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| 1044424 | HEALTH CARE MANAGEMENT AND ECONOMICS | 1st | 2nd | 6 | ING-IND/35 | ITA |
Educational objectives Knowledge and understanding
The course deals with the decision making processes of firms, focusing in particular on the healthcare industry. Students are expected to learn the basic principles of:
• microeconomic analysis of the firm,
• the structure of firms and their internal organization in the healthcare industry,
• economic evaluation of investment projects,
• cost-effectiveness analysis and cost-utility analisys
• the organization of national health system
Applying knowledge and understanding
Students will be able to apply basic methods and models of microeconomics, corporate finance, evaluation of health care programmes, in order to:
• identify the determinants of firms’ strategic choices, focusing in particular on the firms operating in the healthcare industry,
• evaluate the profitability of investment projects,
• compare different healthcare projects.
Making judgements
Lectures, practical exercises and problem-solving sessions will provide students with the ability to assess the main strengths and weaknesses of theoretical models when used to identify firms’strategies and evaluate healthcare projects.
Communication
By the end of the course, students are able to discuss ideas, problems and solutions provided by microeconomics, corporate finance and evaluation techniques of healthcare programmes both with a specialized and a non-specialized audience. These capabilities are tested and evaluated in the final written exam and possibly in the oral exam.
Lifelong learning skills
Students are expected to develop those learning skills necessary to undertake additional studies on relevant topics in microeconomics, corporate finance and evaluation of health care programmes with a high degree of autonomy. During the course, students are encouraged to investigate further any topics of major interest, by consulting supplementary academic publications, specialized books, and internet sites. These capabilities are tested and evaluated in the final written exam and possibly in the oral exam, where students may have to discuss and solve some new problems based on the topics and material covered in class.
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| 1035472 | Electromagnetic compatibility of medical devices | 1st | 2nd | 3 | ING-INF/02 | ITA |
Educational objectives Knowledge and understanding:
• understanding of the basic concepts of electromagnetic compatibility, both in the ITC and in the specific context of medical equipment;
• knowledge of the main regulations on electromagnetic compatibility.
Applying knowledge and understanding:
• acquisition of methodological tools and essential skills to recognize and detect electromagnetic interference;
• acquisition of the basic tools for the design of compatible devices.
Communication:
• interacting with non-engineering personnel using biomedical devices.
Lifelong learning skill:
• following developments on electromagnetic compatibility regulations;
• addressing problems of electromagnetic compatibility deriving from the development of new telecommunication technologies and new biomedical instruments.
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| 1036360 | BIOMATERIAL RESISTANCE | 1st | 2nd | 6 | ICAR/08 | ITA |
Educational objectives The teaching “Strength of Biomaterials”, given at the 5th year of the Master Degree in Biomedical Engineering, is in direct succession to that of "Mechanics applied to Solids and Structures” of the Bachelor Degree in Clinical Engineering at the 2nd year of the Bachelor Degree in Clinical Engineering, and constitutes a natural progression. In fact, the knowledge gained in “Mechanics applied to Solids and Structures”, as the theory of beams, mechanics of three-dimensional solids, of the prism of SAINT-VENANT, find immediate application in the study of the mechanical behaviour of long bones, of biological tissues and biomaterials, of the major bone joints of the human body and of prostheses that replace these joints.
Expected results of learning.
We expect that the candidate master engineer acquires the skills to study the the mechanical behaviour of long bones, of biological tissues and biomaterials, of the major bone joints of the human body and of prostheses that replace these joints.
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| 1044320 | CONTROL IN BIOLOGICAL SYSTEMS | 1st | 2nd | 3 | ING-INF/04 | ITA |
Educational objectives General goals
The course provides the knowledge and skills to describe biological systems and feedback phenomena by mathematical modeling.
Specific outcomes
Knowledge and understanding
The Students must be able to analyze, with the instruments of automatic control theory, a biological system and interpret physiological phenomena
Capability to apply knowledge and understanding
The Students will be able to understand and to analyze a biological system and its relevant properties
Critical and judgment skill
The Students will be able to analyze a biological system, identifying the main variables of interest, proposing the most suitable control strategy
Communication skills
The course activities will allow the Students to increase their communication capabilities in scientific fields.
Learning ability
One of the aim of the course is to increase the critical skills of the Students; he will be able to tackle a biological/physiological control problem, starting to the literature analysis, to the modeling aspects, to the control face, up to the implementation.
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| 1052300 | MEDICAL ROBOTICS | 1st | 2nd | 6 | ING-INF/04, ING-INF/04 | ITA |
Educational objectives General objectives
Introduction to the basic robotic technologies in the medical context, with particular emphasis on surgical robotics.
Expected learning results: Knowledge of the main robotic surgical systems, of the challenges and methodologies of medical robot design and control.
Specific objectives
Knowledge and understanding
The student will learn: to critically read articles that describe the main technologies involved in medical robotics; to discuss in detail the state of the art of robotic applications in medicine; how to approach the design of robot-assisted medical systems; robot modeling and control methodologies needed in the development of medical robotic systems.
Apply knowledge and understanding
The student will be able to approach the design of new robotic technologies for medical applications.
In particular, he/she will be able to develop kinematic model of medical robots, to design functional and control architecture for medical procedures supported by robots.
Critical and judgment skills
The student will be able to estimate the potential benefits deriving from the introduction of robotic support in a medical procedure and to evaluate the clinical, legal, social and economic constraints in the implementation of robotic technology in a medical sector.
Communication skills:
The student will learn to communicate and collaborate with people of different backgrounds for the definition of objectives and constraints in the project of medical robots based on clinical needs.
Learning ability
The student will be able to independently learn new concepts useful for the design and development of new technologies for medical applications.
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| MODULO I | 1st | 2nd | 3 | ING-INF/04, ING-INF/04 | ITA |
Educational objectives General objectives
Introduction to the basic robotic technologies in the medical context, with particular emphasis on surgical robotics.
Expected learning results: Knowledge of the main robotic surgical systems, of the challenges and methodologies of medical robot design and control.
Specific objectives
Knowledge and understanding
The student will learn: to critically read articles that describe the main technologies involved in medical robotics; to discuss in detail the state of the art of robotic applications in medicine; how to approach the design of robot-assisted medical systems; robot modeling and control methodologies needed in the development of medical robotic systems.
Apply knowledge and understanding
The student will be able to approach the design of new robotic technologies for medical applications.
In particular, he/she will be able to develop kinematic model of medical robots, to design functional and control architecture for medical procedures supported by robots.
Critical and judgment skills
The student will be able to estimate the potential benefits deriving from the introduction of robotic support in a medical procedure and to evaluate the clinical, legal, social and economic constraints in the implementation of robotic technology in a medical sector.
Communication skills:
The student will learn to communicate and collaborate with people of different backgrounds for the definition of objectives and constraints in the project of medical robots based on clinical needs.
Learning ability
The student will be able to independently learn new concepts useful for the design and development of new technologies for medical applications.
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| MODULO II | 1st | 2nd | 3 | ING-INF/04, ING-INF/04 | ITA |
Educational objectives General objectives
Provide basic tools for modeling and control of robotic systems for service and medical applications.
Specific objectives
Knowledge and understanding:
The student will learn actuators and sensors used in robotic systems and their working principles and the basic methods for modeling, analysis and kinematic control of robotic manipulators, motion control algorithms.
Apply knowledge and understanding:
The student will be able to analyze the kinematic structures of serial manipulators and design algorithms for motion control and the execution of assigned tasks.
Critical and judgment skills:
The student will be able to identify the functional characteristics of a robotic system with reference to the type of task, mainly of interest for medical applications, to analyze the complexity of implementation, the performances and any critical issues.
Communication skills:
The course will allow students to be able to present the main problems and the technical solutions related to the use and application of robotic systems.
Learning ability:
The course aims at developing autonomous learning abilities in the students, oriented to the analysis and solution of problems in the use of robots.
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| 1044517 | BIOMEDICAL TECHNIQUES AND EQUIPMENTS | 1st | 2nd | 12 | ING-INF/02, ING-INF/01 | ITA |
Educational objectives The course aims to provide a basic formation on the operation principle of the standard and state-of-the-art biomedical instrumentation.
The course also intends to introduce the students to the use of software for biomedical data elaboration and of the characterization methods for the devices used in medical imaging systems
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| MODULO 1 | 1st | 2nd | 6 | ING-INF/02 | ITA |
Educational objectives The course aims to provide a basic formation on the operation principle of the standard and state-of-the-art biomedical instrumentation.
The course also intends to introduce the students to the use of software for biomedical data elaboration and of the characterization methods for the devices used in medical imaging systems.
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| MODULO 2 | 1st | 2nd | 6 | ING-INF/01 | ITA |
Educational objectives The course aims to provide a basic formation on the operation principle of the standard and state-of-the-art biomedical instrumentation.
The course also intends to introduce the students to the use of software for biomedical data elaboration and of the characterization methods for the devices used in medical imaging systems.
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| 10606370 | Digital Signal Processing | 1st | 2nd | 6 | ING-INF/03 | ITA |
Educational objectives The course presents theoretical and practical topics concerning digital signal processing. About 40% of the course consists of practical experiences carried out on the Colab platform using the Python language. After attending the course the student will be able to analyze and implement FIR filters, IIR filters, smoothing filters, upsampling, downsampling and resampling operations, transform operations. It will have some experience with the ECG and audio signals and with the time series processing.
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| 1044322 | BIOMECHANIS | 2nd | 1st | 9 | ING-IND/12, ING-IND/12 | ITA |
Educational objectives The aim of this course is providing students with basics of instrumentation management and the comprehension of biomechanical models used in motion analysis. The course describes the operation principle of sensors typically used in a movement analysis laboratory, such as force, position, velocity and displacement transducers. Subsequently, it explains the principal techniques for the experimental data analysis of biomechanical variables, which exhaustively represent human movement kinematics and kinetics.
Class attendance is expected and strongly encouraged.
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| 1021814 | Bioelectromagnetic Interaction I | 2nd | 1st | 3 | ING-INF/02 | ITA |
Educational objectives KNOWLEDGE AND UNDERSTANDING In-depth knowledge of methodological tools and topics of Bioelectromagnetism (interaction of fields with molecular structures, techniques for calculating the EM field within cellular compartments, quantitative modeling of the electromagnetic field action at the membrane and cellular channel levels, EM field measurement techniques and permittivity, stimulator design), aspects that form the basis for the analysis and verification of new therapeutic and diagnostic techniques, and the evaluation of new telecommunications technologies.
APPLICATIVE CAPABILITIES Skills in designing and setting up experimental evaluation benches and measurement campaigns. Ability to develop bioelectromagnetic modeling in a design key, in order to verify and predict the behavior of some applications that use electromagnetic fields on humans.
JUDGMENT AUTONOMY Potential for critical analysis of the fundamental applicative aspects related to the use of electromagnetic fields in biomedical contexts and in the
evaluation of the impact of new telecommunications technologies.
COMMUNICATION SKILLS Acquisition of in-depth knowledge for the dissemination of scientific knowledge in the field of bioelectromagnetism.
ABILITY TO LEARN Gradual achievement and extension of an in-depth knowledge level suitable for the formation of an expert professional figure in the evaluation of human
exposure to EM fields.
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| 1047748 | CHEMICAL ENGINEERING FOR BIOMEDICAL SYSTEMS | 2nd | 1st | 6 | ING-IND/24 | ITA |
Educational objectives The course aims to provide students with the cultural and methodological bases for the study of the physico-chemical and biological phenomena involved in biomedical systems using an approach typical of chemical engineering. In particular, the primary objectives of the course are to develop the students' ability to quantitatively analyze biotechnological processes in which enzymes or cells are present and to apply the acquired knowledge to the design and modeling of biomedical equipment and devices.
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| 1022858 | MACHINE LEARNING | 2nd | 1st | 6 | ING-INF/05 | ITA |
Educational objectives General Objectives:
The objectives of this course are to present a wide spectrum of Machine Learning methods and algorithms, discuss their properties, convergence criteria and applicability. The course will also present examples of successful application of Machine Learning algorithms in different application scenarios.
The main outcome of the course is the capability of the students of solving learning problems, by a proper formulation of the problem, a proper choice of the algorithm suitable to solve the problem and the execution of experimental analysis to evaluate the results obtained.
Specific Objectives:
Knowledge and understanding:
Providing a wide overview of the main machine learning methods and algorithms for the classification, regression, unsupervised learning and reinforcement learning problems. All the problems are formally defined and theoretical basis as well as technical and implementation details are provided in order to understand the proposed solutions.
Applying knowledge and understanding:
Solving specific machine learning problems starting from training data, through a proper application of the studied methods and algorithms. The development of two homeworks (small projects to be developed at home) allows the students to apply the acquired knowledge.
Making judgements:
Ability of evaluating performance of a machine learning system using proper metrics and evaluation methodologies.
Communication skills:
Ability of writing a technical report describing the results of the homeworks, thus showing abilities in communicating results obtained from the application of the acquired knowledge in solving a specific problem.
Being exposed to examples of communication of results obtained in practical cases given by experts within seminars offered during the course.
Learning skills:
Self-study of specific application domains, problems and solutions during the homeworks, with possible application of teamwork for the solution of specific problems.
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| 1044557 | Hospital plants and technological systems | 2nd | 2nd | 9 | ING-IND/10 | ITA |
Educational objectives The course deepens the problems concerning plan, execution, maintenance and management of the Hospital plants and technological systems.
At the end of the course, students know different plants and technological systems and the ways to design, inspect and manage them, focusing on the problem of safety.
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| 1044766 | BIOMECHANICS AND TISSUE ENGINEERING LABORATORY | 2nd | 2nd | 3 | ING-IND/12 | ITA |
Educational objectives The goal of the course is to show how the knowledges in biomedical engineering and in experimental biology can work together to get a comprehensive evaluation of the properties of living tissues, thorough specific laboratory experiences. At the end of the Lab classes the students are expected to be able to design an experimental testing protocol aimed at the measurement of the biomechanical properties of living tissues-
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| 10589485 | THERAPEUTIC APPLICATIONS OF LOW FREQUENCY ELECTROMAGNETIC FIELDS | 2nd | 2nd | 3 | ING-INF/02 | ENG |
Educational objectives The main objective of this interdisciplinary course is to provide students with the theoretical and practical tools necessary for understanding important biomedical applications widely used in clinical practice based on the biological effects of electromagnetic fields.
Upon successful completion of the exam, students will have an overview of clinical applications based on electromagnetic fields, starting from basic biophysical principles to
the functioning of the entire device. They will be able to support medical personnel adequately, know how to use the necessary measurement software and techniques for
validation and use. They will be ready to apply the topics covered during the course in the workplace as design and optimization guidelines and deepen them towards technologically more innovative applications.
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| 1023029 | Image processing | 2nd | 2nd | 6 | ING-INF/03 | ITA |
Educational objectives The course aims at providing the student with an overall vision of the image processing issues , such as the use of transformed domain, filtering, encoding, and of its main applications tc.) (such as restoration, denoising, enhancement, tomography, etc. At the end of the Course the student is aware of the main representation domains of signals and images both in continuous and discrete domain, and can manage software for image processing purposes.
Through developing in depth theoretical and practical projects the students gains ability of
i) autonomously comprehending cutting edge image processing papers,
ii) presenting their contents,
iii) realizing and critically analysing image processing experiments.
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