Technology in Medicine

Course Description

Introduction to technology in medicine, Electrophysiology (sources of bioelectric signals), Biomedical instrumentation (principles of measurment and processing of bioelectric signals), Organs and systems in the human body 2 (including bioengineering and cellular engineering principles), Organs and systems in the human body 2 (Artificial organs - artificial heart, visual prosthesis (bionic eye), cochlear implant (bionic ear), Implantable devices 1 (Cardiac pacemakers, medical robots), Implantable devices 2 (Intrabody communication), Modelling of biological systems 1 (Modelling of nervous system and brain), Modelling of biological systems 2 (Modelling and visualization of human body), Medical imaging 1 (2D, 3D, 4D), Medical imaging 2 (Functional imaging), Telemetry systems for medical and sports monitoring, m-health, Biomedical engineering ethics.

Learning Outcomes

  1. recognize different technologies in medical application
  2. explain physical principles of operation of medical devices and equipment
  3. analyze interaction of medical instrumentation and tissue
  4. differentiate invasive and non-invasive technologies in medicine
  5. combine knowledge from engineering with living world
  6. identify ethical problems in application of technologies in medicine

Forms of Teaching

Lectures

Lectures

Field work

Field work

Laboratory

Laboratory exercises

Grading Method

Continuous Assessment Exam
Type Threshold Percent of Grade Threshold Percent of Grade
Laboratory Exercises 50 % 20 % 50 % 20 %
Quizzes 50 % 0 % 50 % 0 %
Mid Term Exam: Written 50 % 40 % 0 %
Final Exam: Written 50 % 40 %
Exam: Written 50 % 80 %
Comment:

Short knowledge tests are used to check the readiness of students for a particular laboratory exercise (entrance test) or to check what the student has learned in the exercise (exit test). Short knowledge tests are part of laboratory exercises and are scored as a whole.

Week by Week Schedule

  1. Historical perspective of BME, Ethical issues of BME, Significance of BME for health care & policy
  2. Bioamplifiers in the ECG, EEG, Sensing, conditioning, processing and analysis methods for designing the BMI
  3. Recording systems, Artefacts and electromagnetic interference
  4. Cellular organization, Tissues, Major organ systems
  5. Circulatory assisting devices and artificial heart, Blood gas exchange devices and artificial lungs, Dialisys and artificial kidney, Diabetes and artificiel pancreas, Artificial blood and other applications
  6. Biocompatibility of implantable devices, Implantable biomedical devices - passive, Implantable biomedical devices - active
  7. Soft tissue replacements, Hard tissue replacements, Case studies: joints, valves, neural, vascular, dental, Implantable biomedical devices - active
  8. Midterm exam
  9. Tissues, Major organ systems
  10. Major organ systems, Homeostasis
  11. X-ray principles, Digital radiography, Computed tomography (CT), Interventional radiology - angiography
  12. Ultrasound diagnostics, Medical infrared imaging, Endoscopy, Magnetic resonance imaging (MRI)
  13. Bioamplifiers in the ECG, EEG, Recording systems, Sensing, conditioning, processing and analysis methods for designing the BMI
  14. Ethical issues of BME, Surgical, Therapeutic, Rehabilitative, Life supporting
  15. Final exam

Study Programmes

University undergraduate
Elective Courses (6. semester)
Elective Courses (6. semester)
[FER2-HR] Computer Engineering - module
Elective Courses (6. semester)
[FER2-HR] Control Engineering and Automation - module
Elective Courses (6. semester)
[FER2-HR] Electronic and Computer Engineering - module
Elective Courses (6. semester)
[FER2-HR] Electronics - module
Elective Courses (6. semester)
[FER2-HR] Information Processing - module
Elective Courses (6. semester)
[FER2-HR] Software Engineering and Information Systems - module
Elective Courses (6. semester)
[FER2-HR] Telecommunication and Informatics - module
Elective Courses (6. semester)

Literature

Ante Šantić (1995.), Biomedicinska elektronika,
Rüdiger Kramme, Klaus-Peter Hoffmann, Robert Pozos (2011.), Springer Handbook of Medical Technology, Springer Science & Business Media
(.), R. Magjarević, B. Ferek-Petrić: Implantable Cardiac Pacemakers-50 Years from the First Implantation, http://vestnik.szd.si/index.php/ZdravVest/article/view/224/116,
(.), Pregledni članci iz znanstvenih i stručnih časopisa,
Joseph D. Bronzino, Donald R. Peterson (2006.), Biomedical Engineering Fundamentals, CRC Press

Associate Lecturers

Laboratory exercises

For students

General

ID 229861
  Summer semester
5 ECTS
L1 English Level
L1 e-Learning
30 Lectures
0 Seminar
0 Exercises
15 Laboratory exercises
0 Project laboratory

Grading System

90 Excellent
75 Very Good
65 Good
50 Sufficient