51³Ô¹Ïapp

To enrol in a course/subject in GSBmE you will need to know the course code and course name. This applies to enrolment in both Postgraduate and Postgraduate Research courses. Below you will find brief descriptions of all courses currently offered by GSBmE. Note that courses offered may change from time to time, so you should always check this page when considering changes to your program.

All courses are 10 weeks in duration, will be offered in Term 1 (T1), Term 2 (T2) or Term 3 (T3) and have been assigned varying Units of Credit (UoC).

GSBmE courses

    • Course Code:Ìýµþ±õ°¿²Ñ1010
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýEngineering in Medicine and Biology
      UoC:Ìý6
      Term:Ìý°Õ2
      Class Details:ÌýTimetable and contact information

      This course introduces the field of biomedical engineering. Topics include:

      • a basic introduction to biological systems
      • the engineering approach to biological systems
      • the application of basic engineering concepts to solving biomedical problems, with examples from cutting-edge technologies such as the artificial heart, bionic eye, magnetic resonance imaging and tissue engineering.
    • Course Code:ÌýBIOM2451
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýBiomechanics for Sports Scientists
      UoC:Ìý6
      Term:ÌýT1
      Class Details:ÌýTimetable and contact information

      Note:ÌýThis course is NOT available to students enrolled in an Engineering program.

      This course focuses on the basic principles of biomechanics and applies them to the analysis of human movement and the musculoskeletal system. Basic mechanics (statics, kinematics and dynamics) will be studied in two dimensions. Topics include:

      • the biomechanics of the human gaitÌý– walking and running
      • the mechanics of tissues in the musculoskeletal system
      • methods of assessing movementÌý– quantitative and qualitative
    • Course Code:ÌýBIOM9020
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMasters Project A
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      ÌýThis course includes:

      • developing a design or a process or investigating a hypothesis following industry and professional engineering standards
      • critically reflecting on a specialist body of knowledge related to their thesis topic
      • applying scientific and engineering methods to solve an engineering problem.
      • analysing data objectively using quantitative and mathematical method
    • Course Code:ÌýBIOM9914
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMasters Project B
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      ÌýThis course includes:

      • evaluating and critically reviewing the scientific literature
      • Writing a scientific report and communicating scientific findings to an educated audience
      • Designing, carrying out, analysing and reporting on research tasks
    • Course Code:ÌýBIOM9027
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMedical Imaging
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      ÌýThis course includes:

      • the fundamentals of producing a medical image
      • image collection techniques
      • image reconstruction algorithms
      • image analysis methods
      • demonstrate oral and written communication in professional and lay domains.
      • to solve biomedical problems by applying all of the above
    • Course Code:ÌýBIOM9311
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMass Transfer in Medicine
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      The focus of this course is mass transfer in the living organism and in extracorporeal medical devices. It includes:

      • principles of diffusion and convection
      • models of gas transfer in the lung
      • transfer of solutes at the capillary level
      • haemodialysis, haemofiltration, plasma filtration and blood oxygenators
      • transfer across the peritoneal membrane-dialysis or drug delivery
      • drug delivery across the skin
    • Course Code:ÌýBIOM9332
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýBiocompatibility
      UoC:Ìý6
      Term:Ìý°Õ2
      Class Details:ÌýTimetable and contact information
      Assumed knowledge:ÌýNot recommended for Stage 2 and 3 students

      This course includes:

      • the interaction of biological fluids and cells with foreign surfaces
      • in vitro tests to assess biocompatibility and thrombogenicity
      • the current status of biocompatible materials as applied to extracorporeal systems
      • surgical implants and prosthetic devices
    • Course Code:ÌýBIOM9333
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýCellular and Tissue Engineering
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      This course outlines the concepts of cell-based products for the pharmaceutical and medical industries from both a theoretical and practical perspective.

      It will cover the basis of how proteins are produced by cells; recombinant technologies to produce proteins and biologics from bacterial, mammalian and viral systems; process design and optimisation needed for commercial production of biologicals; case studies of currently manufactured biological products; cell isolation including blood and progenitor cells; and translation of these technologies for tissue engineering and regenerative medicine. A combination of lectures, tutorials, laboratory classes and a site visit are included in this course.

    • Course Code:ÌýBIOM9410
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýRegulatory Requirements for Biomedical Technology
      UoC:Ìý6
      Term:ÌýT1
      Class Details:ÌýTimetable and contact information

      The regulatory requirements of medical devices in Australia, Japan, North America and Europe will be reviewed in this course. The aims of this course are to:

      • give a broad overview the regulation of medical devices around the world and
      • relate these regulations to the development and marketing of a variety of medical devices
    • Course Code:ÌýBIOM9420
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýClinical Laboratory Science
      UoC:Ìý6
      Term:Ìý°Õ2
      Class Details:ÌýTimetable and contact information

      This course has been designed to provide students with a taste of some of the many different aspects of clinical medicine where biomedical engineers are of fundamental importance for the development of instrumentation to diagnose and monitor diseases.Ìý

      It is focused on the fundamental science that underlies some of the diagnostic tests and the students are encouraged to explore how biomedical engineers have taken these fundamentals and made them work within a diagnostic laboratory environment.

      The course will cover the technologies, tests and operation of a variety of clinical laboratory testing systems (biochemistry, haematology and immunology) and how they apply to a particular organ or system. The students will also be exposed to the underlying principles involved in the measurement of certain physiological parameters from some of the complex organ systems including the urinary, cardiac and gastro-intestinal systems. An important component of the course is two practical sessions. The first focuses on the fundamentals of enzyme biochemistry and how this might be useful in generating a test for a particular disease and the second will build upon this knowledge to design, fabricate and test a diagnostic test strip for glucose.

    • Course Code:ÌýBIOM9450
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýClinical Information Systems
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      This course introduces medical informatics with a focus on healthcare information and communications technology, including:

      • evidence-based medicine and clinical decision support systems
      • physiological measurements and telehealth systems
      • medical coding and classification
      • standards for medical data interchange
      • aspects of database design, dynamic HTML and web services

      Students will learn HTML, Structured Query Language (SQL) and PHP scripting and use these tools by way of tutorials and a major project.

    • Course Code:ÌýBIOM9541
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMechanics of the Human Body
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      This course covers in-depth methods used in the analysis of the biomechanics of the musculoskeletal system. It includes:

      • methods to analyse body segment and joint kinematics
      • joint kinetics
      • work and power
      • muscle forces and associated energy cost
      • applications of biomechanics in clinical, occupational and recreational areas
    • Course Code:ÌýBIOM9561
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMechanical Properties of Biomaterials
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      This course covers the physical properties of materials having significance to biomedical engineering, including human tissues; skin; soft tissues; bone; metals; polymers and ceramics; as well as the effects of degradation and corrosion.

    • Course Code:ÌýBIOM9621
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýBiological Signal Analysis
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      Note:ÌýBasic electronics and mathematics background required

      ÌýThis course focuses on the use of digital computers to extract information from biological signals. It covers:

      • signal processing using filtering, averaging, curve-fitting and related techniques
      • analysis using model simulations, correlation, spectral analysis etc.
    • Course Code:ÌýBIOM9640
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýBiomedical Instrumentation
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      This course is an introduction to physiological measurement of bioelectric phenomena and neurostimulation. Its aim is to give you an understanding of the physical principles that govern the measurement of a biological variable or system by a transducer, which converts the variable into an electrical signal.

      By the end of the course you should understand various measurement devices and approaches including the underlying biological process that generates the quantity to be measured or controlled. The basic medical instrumentation used clinically to perform these functions is also examined.

      The course has a focus on bioelectric phenomena, bioelectrodes, medical electronics and neurostimulation. It includes a revision of DC and AC circuit theory, hands-on practice in the use and testing of medical transducers and electromedical equipment commonly used in hospitals and research laboratories to make measurements of biomedical variables of clinical significance.Ìý

    • Course Code:ÌýBIOM9650
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýBiosensors and Transducers
      UoC:Ìý6
      Term:ÌýT1
      Class Details:ÌýTimetable and contact information

      This course is an introduction to physiological measurement using biosensors and transducers. Its aim is to give you an understanding of the physical principles that govern the measurement of a biological variable or system by a transducer, which converts the variable into an electrical signal.

      By the end of the course you should understand various measurement devices and approaches including the underlying biological process that generates the quantity to be measured or controlled. The basic biosensors and transducers used to measure pressure, flow, volume and biochemical sensing are examined along with aspects of imaging instrumentation.Ìý

    • Course Code:ÌýBIOM9660
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýBionics and Neuromodulation
      UoC:Ìý6
      Term:Ìý°Õ2
      Class Details:ÌýTimetable and contact information

      This course is an introduction to the engineering issues related to implantable bionics for therapeutic electrical stimulation of neural and muscle tissue. Its aim is to give you an understanding of the requirements (electrical, mechanical, chemical, etc.) of implantable neurostimulators.

      During the course, in small groups students will conduct extensive practical tasks to reinforce the material presented in the lectures and tutorials.

    • Course Code:ÌýBIOM9701
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýDynamics of the Cardiovascular System
      UoC:Ìý6
      Term:ÌýT1
      Class Details:ÌýTimetable and contact information

      Assumed knowledge:ÌýBasic physics and calculus. Familiarity with MATLAB desirable.

      This course covers the structure of the heart, organisation of the mammalian vasculature, the mechanical, electrical and metabolic aspects of cardiac pumping, solid and fluid mechanics of blood vessels, the rheology of blood, as well as biomedical engineering applications in the cardiovascular system.Ìý

    • Course Code:ÌýBIOM9711
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýModelling Organs, Tissues and Devices
      UoC:Ìý6
      Term:ÌýT1
      Class Details:ÌýTimetable and contact information

      Assumed knowledge:ÌýCalculus and differential equations. Familiarity with MATLAB desirable.

      Computer modelling of complex physiological systems and their interaction with medical devices is becoming increasingly important in modern medical device design. This course provides a practical overview of computational modelling in bioengineering, focusing on a range of applications including:

      • electrical stimulation of neural and cardiac tissues
      • implantable drug delivery
      • cancer therapy
      • biomechanics
      • blood flow
      • 3D surface techniques for realistic modelling and visualisation of organs, tissues and devices.
    • Course Code:ÌýBIOM9811
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýApplications of Light in Engineering, Technology and the Life Sciences
      UoC:Ìý6
      Term:ÌýT1
      Class Details:ÌýTimetable and contact information

      This course will culminate in a design project where students will learn how to design, build and test diverse light based detection, sensing and imaging systems. On the completion of the course students will be able use light to measure, probe and interrogate diverse effects in various industrial and clinical scenarios and in the environment.

    • Course Code:ÌýBIOM9914
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMasters Project
      UoC:Ìý6
      Term:ÌýT3
      Class Details:ÌýTimetable and contact information

      ÌýThis course includes:

      • Evaluate and critically review the scientific literature
      • Write a scientific report and communicate scientific findings to an educated audience
      • Design, carry out, analyse and report on research tasks
    • Course Code:Ìý (UG) (PG)Ìý
      °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýRehabilitation and Assistive Technology
      UoC:Ìý6
      Term:Ìý°Õ2 (3UOC) + T3 (3UOC) = 6UOC
      Class Details:ÌýTimetable and contact information

      Check out this video giving you an exciting overview of the course:

      ENGG3060 – Biomechanics of Physical Rehabilitation is an exciting and real-world, hands-on course where you will co-design with a real client to design and prototype a device that assists in the life of a person with a disability.

      The course is spread across Term 2 and Term 3 (3UoC + 3UoC = 6UoC), enabling students time to build a robust relationship with their client and to design and build a working prototype of their rehabilitation device.

      At the end of the year there will be a showcase event where students can present their work to their clients and industry.Ìý

      Ìý
      All engineering students are welcome to apply, not just Biomedical Engineering students.  

      For students enrolled in the BE/MBiomedE and MBiomedE programs, ENGG3060 will count towards your program as an equivalent of BIOM9551. For students in other programs, ENGG3060 may count towards your program as a discipline elective.

      The 2022 course outline will be updated soon. 

      Any questions email challeng@unsw.edu.au or talk to Student Support Services.Ìý

Research Project courses

Research thesis topics are available through Moodle, please complete thisÌýÌýfor details on how to access. Please contact the school' Thesis Coordinator,ÌýDr Michael StevensÌýfor information.Ìý Enrolment in Thesis B and Thesis C of your thesis project is dependent on a satisfactory performance in part A.ÌýÌý

Please refer to the course outlines below for further information including assessment criteria and what you are required to complete.

  • These codes are for students enrolled in the dual degree program with biomedical engineering. All Biomedical Engineering undergraduate students, regardless of their specialisation,Ìýenrol in the same thesis codes as set out below.

    Note:ÌýFor students who have already commenced Thesis A in S2-2018 you will need to enrol in the OLD Thesis B codes for T1-2019. Thesis B runs from Week 1, Term 1 until Week 3, term 2, 2019 allowing 13 teaching weeks to complete your thesis. Please take care to enrol in the correct thesis code and DO NOT enrol in the new 4 UOC thesis codes above. Please refer to the Thesis B codes below:

    • BIOM5003 Thesis B (6 UOC) for students in MECH / MTRN
    • BIOM5911 Thesis B (6UOC) for students in ELEC / TELE / MATS SCI
    • BIOM5932 Thesis B (6 UOC) for students in CHEM ENG
    • BIOM5951 Thesis B (6 UOC) for students in CSE / BINF / SFTWARE

    VisitÌýUndergraduate Engineering Thesis FAQsÌýfor more information.

  • BIOM9914 Masters Research Project

    Course Code:ÌýBIOM9914
    °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMasters Research Project
    UoC:Ìý12
    Term:ÌýT1, T2, T3
    Class Details:Ìý
    BIOM9914 Course Outline

    Assumed knowledge:ÌýCandidates must contact the School's Thesis Coordinator,ÌýDr Michael StevensÌýfor consent to enrol. BIOM9914 is only available to high achieving students with prior written school approval.

    This is the course for the postgraduate masters research projects to be undertaken in one semester. It consists of 12 UOC. It allows coursework students to experience research training either within the School or with collaborating institutions.Ìý Application is subject to academic performance and school approval.

    This research work can also be conducted over 2 terms by enrolling in two 6UOC courses - see information for coursesÌý BIOM9020 and 9021. Performance is assessed on the basis of a report in the format of either a thesis or a publication-ready research paper. Other assessment tasks may apply, so please discuss requirements with the school's Thesis Coordinator.

    BIOM9020 and BIOM9021 Masters Research Project

    Course Codes:ÌýBIOM9020 and BIOM9021
    °ä´Ç³Ü°ù²õ±ðÌý±·²¹³¾±ð:ÌýMasters Research Project
    UoC:Ìý6 per semester
    Term:ÌýHpW 0, T1, T2, T3
    Class Details:Ìý
    BIOM9020 Course Outline
    BIO9021 Course Outline

    Assumed knowledge:ÌýCandidates must contact the School's Thesis Coordinator,ÌýÌýDr Michael StevensÌýÌýfor consent to enrol.ÌýBIOM9020 / BIOM9021Ìýis only available to high achieving students with prior written school approval.

    These courses form the postgraduate masters research project to be undertaken over two semesters. It allows coursework students to experience research training either within the School or with collaborating institutions. Candidates should complete the application form (as above) in consultation with a GSBME supervisor who will act as their supervisor. A second co-supervisor/assessor must also be nominated on this application. Application is subject to academic performance and school approval.

    Performance is assessed on the basis of a report in the format of either a thesis or a publication-ready research paper. Other assessment tasks may apply, so please discuss current requirements with the GSBME Thesis Coordinator.