Code: 17ABBPPSA Patient and Device Simulators and Testers
Lecturer: doc. Ing. Jiĝí Hozman Ph.D. Weekly load: 2P+2L Completion: A, EX
Department: 17110 Credits: 4 Semester: W
Description:
During the course attention will be given to the two large groups, i.e. patient simulators and instrumentation testers. The use of these two groups in clinical practice will also be part of the course. As an essential part of the teaching will be included laboratory exercises in the workplace simulated workplace intensive care unit, where all the samples are carried out with two groups of devices. The course has a direct relationship to future career opportunities. Great emphasis is placed on managing interdisciplinary teaching (especially linking physiology and engineering principles). Given the organization of teaching as a 2-hour blocks 1 for 14 days is shown below, only 7 lectures (there will be performed standard exercises or intensive/block instruction will be implemented due to the time of experiments and the limited possibilities in terms of number of students).
Contents:
1. Course introduction, educational video, course requirements, overview of the wholebody patients simulators, medical devices testers and analyzers, fundamental principles of the selected medical devices
2. Fundamental principles of patients simulators, analogies among physical domains doc
3. Control and scenario development environment for patient simulator, methodology and posibility of the scenario usage and development
4. Conceptual model development methodology
5. Illustration of the selected example of the human haemodynamics model
6. Applied pharmacology fundamentals for the wholebody patient simulators
7. Applied anaesthesiology fundamentals for the wholebody patient simulators
8. Scenario development based on the applied anaesthesiology and usage of the relevant medical devices
9. Other simulators, testers and analyzers and possible application within the domain of medical devices
10. Other simulators, testers and analyzers and possible application within the domain of respiratory care
11. Other simulators, testers and analyzers and possible application within the domain of medical imaging including phantoms
12. Design and development of the patient and device simulators internal electronic blocks (circuits)
13. Selected examples of the electronic circuits for the wholebody patient simulators and medical device testers (ECG, EEG, SpO2, NIBP, ...)

Seminar contents:
1. Introduction to the practice (introduction to the Müse control and scenario creation environment for CAE Healthcare ECS and HPS full body patient simulators), completion requirements, subject organization, OSH, concept and overview of laboratories
2. Müse Control and Scenario Environment for CAE Healthcare Full Body Patient Simulators ECS and HPS Models - Part 2
3. Müse Control and Scenario Environment for CAE Healthcare Full Body Patient Simulators ECS and HPS Models - Part 2
4. Full Body Patient Simulator ECS and HPS - General description, arrangement, components, HW accessories
5. Müse Control and Scenario Creation Environment for CAE Healthcare Full Body Patient Simulators ECS and HPS Models - Scenario Creation with Full Body Simulator - Part 3
6. Müse environment for control and scenario creation for CAE Healthcare full body patient simulators ECS and HPS models - scenario creation in connection with whole body simulator - part 2 (assignment of task for processing LOG file)
7. Overview, principle and ways of using medical devices, especially medical electrical devices. Use of HPS whole body simulator with vital signs monitor
8. Test No. 1
9. Use of HPS full body simulator with lung ventilator
10. Overview, principles and application of instrument simulators, analyzers and testers - part 1
11. Use of HPS whole body simulator with anesthesia device including built-in vital signs monitor
12. Overview, principles and usage of instrument simulators, analyzers and testers - part 2
13. Test No. 2, complex task with HPS and all available instruments + MÜSE SW environment, METI vision

Recommended literature:
[1] Willem van Meurs: Modeling and Simulation in Biomedical Engineering. Applications in Cardiorespiratory Physiology. McGraw-Hill: New York, 2011. 193 p. ISBN: 978-0-07-171446-4
[2] Richard H Riley (ed.): A Manual of Simulation in Healthcare. 1st ed. Oxford University Press: Oxford, 2008. 352 p. ISBN: 978-0199205851
[3] Kyle, R., Bosseau Murray, W.: Clinical Simulation. Operations, Engineering and Management. 1st ed. Academic Press: Burlington, 2007. 848 p. ISBN: 978-0123725318
[4] Sokolowski, J. A.(ed.), Banks, C. M.(ed.): Modeling and Simulation in the Medical and Health Sciences. Hoboken: Wiley, 2011. 301 p. ISBN: 978-0-470-76947-8
[5] Kol. User´s guide - ECS, HPS. [online]. Sarasota (FL): CAE Healthcare, 2014. [cit. 14-02-2014].
http://www.caehealthcare.com/eng/support/user-guides


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