Module Details
Module Code: |
BIOE7002 |
Title: |
Biomechanics & Biofluids
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Long Title:
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Biomechanics & Biofluids
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NFQ Level: |
Intermediate |
Valid From: |
Semester 1 - 2016/17 ( September 2016 ) |
Field of Study: |
5212 - Biomedical Engineering
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Module Description: |
The biomechanics section of this module includes, 2D principal stresses, biomechanics of human tissue, analysis of angular motion and impact in the field of Biomechanics. The biofluids section of the course introduces the student to the mechanics of blood flow, analysis of pipe flow of Newtonain and non-Newtonian fluids together with lubrication and wear of human joints.
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Learning Outcomes |
On successful completion of this module the learner will be able to: |
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Learning Outcome Description |
LO1 |
Select and apply theories of motion to analyse and solve quantative problems involving angular motion in the field of biomechanics |
LO2 |
Discuss and use engineering calculations to illustrate the mechanical properties of human tissue in the context of its function. |
LO3 |
Describe the mechanics of cardiovascular blood flow and apply fluid mechanic flow models to flow in tubes. |
LO4 |
Classify wear and lubrication mechanisms, in particular, as related to human joints. |
Dependencies |
Module Recommendations
This is prior learning (or a practical skill) that is strongly recommended before enrolment in this module. You may enrol in this module if you have not acquired the recommended learning but you will have considerable difficulty in passing (i.e. achieving the learning outcomes of) the module. While the prior learning is expressed as named MTU module(s) it also allows for learning (in another module or modules) which is equivalent to the learning specified in the named module(s).
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Biomechanics 1 |
Incompatible Modules
These are modules which have learning outcomes that are too similar to the learning outcomes of this module. You may not earn additional credit for the same learning and therefore you may not enrol in this module if you have successfully completed any modules in the incompatible list.
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No incompatible modules listed |
Co-requisite Modules
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No Co-requisite modules listed |
Requirements
This is prior learning (or a practical skill) that is mandatory before enrolment in this module is allowed. You may not enrol on this module if you have not acquired the learning specified in this section.
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No requirements listed |
Indicative Content |
Complex 2D stresses
Introduction to plane stress, stresses on oblique planes, 2D direct stress system, 2D shear stress system, general 2D stress system, equations of transformation of plane stress, stress to strain transformation, Poisson’s ratio
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Tissue Biomechanics
Direct, shear bending and torque actions, and the corresponding stresses and strains in biological tissues. Stress relaxation and creep, stability and instability. Biomechanical characterisation of bone and the soft connective tissue (Skin, muscle, tendon, ligaments, etc.) covering structure, function and physiological factors. Clinical applications in the design of incisions, scar therapy and wound healing
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Angular Kinematics of human movement
Polar Coordinates, Angular Position and Displacement, Angular Velocity, Angular Acceleration, Dimensions and Units, Rotational Motion about a Fixed Axis, Relationships between Linear and Angular Quantities, Uniform Circular Motion, Rotational Motion with Constant Acceleration, Relative Motion, Linkage Systems.
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Angular Kinetics of human movement
Kinetics of Angular Motion, Torque and Angular Acceleration, Mass Moment of Inertia, Parallel-Axis Theorem, Radius of Gyration, Segmental Motion Analysis, Rotational Kinetic Energy, Angular Work and Power.
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Impluse and Momentum
Linear momentum and Impulse, Applications of the Impulse-Momentum Method, Conservation of linear Momentum, Impact and collisions, One-Dimensional Collisions, Two Dimensional Collisions, Angular Impulse and Momentum.
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Introduction to Cardiovascular Mechanics
Basic principles of Biofluid Mechanics, Generation of flow in the Cardiovascular System, Hemodynamics in Vascular Channels, General Aspects of Control of Cardiovascular Function.
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Circulatory Biofluid Mechanics
Blood flow in the Circulatory System, Systemic and Pulmonary Circulations, The Circulation in the Heart.
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Blood Rheology: Properties of Flowing Blood
Viscosity of Blood, Yield Stress of Blood, Blood Vessel Structure. Diseases Related to Obstruction of Blood Flow.
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Lubrication of joints
Mechanical properties of human cartilage. Introduction to the theories of Synovial Joint lubrication. Lubrication and wear of prosthetic joints.
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Module Content & Assessment
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Assessment Breakdown | % |
Coursework | 20.00% |
End of Module Formal Examination | 80.00% |
Assessments
End of Module Formal Examination |
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Reassessment Requirement |
Repeat examination
Reassessment of this module will consist of a repeat examination. It is possible that there will also be a requirement to be reassessed in a coursework element.
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The University reserves the right to alter the nature and timings of assessment
Module Workload
Workload: Full Time |
Workload Type |
Contact Type |
Workload Description |
Frequency |
Average Weekly Learner Workload |
Hours |
Lecture |
Contact |
Class based tuition |
Every Week |
4.00 |
4 |
Independent & Directed Learning (Non-contact) |
Non Contact |
Self-directed learning |
Every Week |
3.00 |
3 |
Total Hours |
7.00 |
Total Weekly Learner Workload |
7.00 |
Total Weekly Contact Hours |
4.00 |
Workload: Part Time |
Workload Type |
Contact Type |
Workload Description |
Frequency |
Average Weekly Learner Workload |
Hours |
Lecture |
Contact |
Classed based tuition |
Every Week |
3.00 |
3 |
Independent & Directed Learning (Non-contact) |
Non Contact |
Self-directed learning |
Every Week |
4.00 |
4 |
Total Hours |
7.00 |
Total Weekly Learner Workload |
7.00 |
Total Weekly Contact Hours |
3.00 |
Module Resources
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Recommended Book Resources |
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J.L. Meriam, L.G. Kraige. (2015), Engineering Mechanics-Dynamics, 8th. Wiley, p.736, [ISBN: 1119022533].
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Özkaya, N., Nordin, M., Goldsheyder, D., Leger, D. (2012), Fundamentals of Biomechanics, 3rd. Springer-Verlag, New York, p.275, [ISBN: 978-1-4899-93].
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Kleinstreuer, C.. (2006), Biofluid Dynamics, 1st Ed.. CRC Press, USA, [ISBN: 978-0849322211].
| Supplementary Book Resources |
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Norden, Frankel. (2012), Biomechanics in the Musculoskeletal System, 4th. Kluwer, p.475, [ISBN: 1609133358].
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Vikki Hazelwood (Editor), Antonio Valdevit (Editor), Alfred Ascione (Editor). (2011), Biomedical Engineering Principles, 2nd. CRC Press, p.540, [ISBN: 1439812322].
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S. A. Berger, W. Goldsmith, E. R. Lewis. (2000), Introduction to bioengineering, 1st. Oxford University Press, p.544, [ISBN: 0198565151].
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A. Tozeren. (2000), Human body dynamics, Springer, New York, [ISBN: 9780387988016].
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A.E. Profio. (1993), Biomedical Engineering, John Wiley & Sons.
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J. L. Meriam, L. G. Kraige,. (2011), Engineering Mechanics: Statics, 7th. Wiley, p.544, [ISBN: 0470917873].
| This module does not have any article/paper resources |
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This module does not have any other resources |
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