Checking date: 09/06/2021

Course: 2021/2022

Introduction to Bioengineering
Study: Bachelor in Biomedical Engineering (257)

Coordinating teacher: ABELLA GARCIA, MONICA

Department assigned to the subject: Department of Bioengineering and Aerospace Engineering

Type: Compulsory
ECTS Credits: 6.0 ECTS


Requirements (Subjects that are assumed to be known)
It is convenient, although not a requirement, to have a good previous background on: - Physics - Chemistry - Biology
The course provides an updated perspective of the major developments in biomedical engineering, and introduces the way biology, mathematics and engineering can be applied to biomedical problems. The fundamental principles that underlie biomedical engineering design, analysis, and modeling procedures will be developed in addition to practical examples of the techniques commonly used to solve them. Students will thus acquire an overview of most of the major fields of activity in which biomedical engineers are engaged and they will also have the opportunity to see these technologies in practice by visiting the real environment of a modern hospital (Gregorio Marañón) and an important research center (CIEMAT).
Skills and learning outcomes
Description of contents: programme
The discipline of biomedical engineering has evolved over the past fifty years, making it clear that it includes a diverse, seemingly all-encompassing range of fields of specialization such as bioinstrumentation, bioimaging, biomechanics, biomaterials, and biomolecular engineering. The program below constitutes a selection of the most important basic tools that will be necessary for a biomedical engineer, suited to a 6 credit course. PROGRAM: - Introduction to Biomedical Engineering: The Role of a Biomedical Engineer - Basics on Medical Instrumentation and Devices: Electricity and Electronics - Medical Imaging: Digital image processing, X-Ray, Nuclear Medicine, Magnetic Resonance, Ultrasound and Medical Optics - The foundations of modern Biomedicine: Cell and Molecular Biology, Genomics and Bioinformatics - Regenerative Medicine and Tissue Engineering
Learning activities and methodology
Teaching methodology will be mainly based on the following modules: * Introduction: Presentation of the course, the degree and the tracks and discussion of the role of the Biomedical Engineer and possible professional outcomes. Almost half of the session will be interactive, conducted by the doubts and questions from the students. * Basic concepts: Theoretical sessions covering basic concepts that will be vital to the professional development in the different areas: Tissue Engineering, Medical Imaging and Biomedical Instrumentation. * Practical cases: Example of current tecnology, examining the involved disciplines and identification of the application of the basic concets seen in the theoretical sessions. * Laboratory sessions: Practical sessions where the students see the comented technologies and use different tolos that they will encounter in theri professionl life. A report guideline will be handed to be filled up during the session. * Visits: Visits to two centers, Gregorio Marañón Hospital and CIEMAT research Center, that will allow the students to see firsthand how daily work is in these environments and what type of technologies are used. A list of questions will be handed to be filled up during the session. Grading will be based: 60% of continuous evaluation based mainly on short exams and laboratory/visits reports and 40% of a final exam covering the whole subject. Help sessions and tutorial classes will be held prior to the final exam. Attendance to lectures and short-exams is not compulsory. However, failure to attend any exam will result in a mark of 0 in the corresponding continuous evaluation block. The practical sessions may consist on laboratory work or visits to research or clinical centers. A laboratory report may be required for each of them. The attendance to practical sessions is mandatory. Failure to hand in the laboratory reports or unjustified lack of attendance will result in 0 marking for that continuous evaluation block.
Assessment System
  • % end-of-term-examination 40
  • % of continuous assessment (assigments, laboratory, practicals...) 60
Calendar of Continuous assessment
Basic Bibliography
  • J.D. Bronzino. The Biomedical Engineering Handbook. CRC Press, 1995.
  • J.D. Enderle, S.M. Blanchard, and J.D. Bronzino. Introduction to Biomedical Engineering. Boston: Elsevier Academic Press, 2005.
  • J.G. Webster. Medical Instrumentation Application and Design. Ed., John Wiley Sons, Inc., 2010.
  • Jerry L. Prince, Jonathan Links. Medical Imaging Signals and Systems. Prentice Hall. 2014
  • M. Saltzman. Biomedical Engineering: Bridging Medicine and Technology. Cambridge University Press, 2009.
Detailed subject contents or complementary information about assessment system of B.T.

The course syllabus may change due academic events or other reasons.

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