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Biomedical Engineering and Design - Level 5

4.5( 4 REVIEWS )
623 STUDENTS
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Overview

Biomedical Engineering and Design – Level 5 is designed to teach you the engineering design principles and fundamentals of Biomedical Engineering and their correlation with mechanics, electronics and mathematics.

The course will make you learn about anatomy as well as physiology and give you the ability to interpret, analyze and evaluate experimental results in order to improve the technology available. Biomedical Engineering and Design – Level 5 will also teach you about the instruments that are used to diagnose and treat diseases and disabilities.

Biomedical Engineering and Design – Level 5 will unlock your potential to make life-changing advancements by working in a versatile range of projects such as artificial organs, automated patient monitoring, blood chemistry sensors, advanced therapeutic and surgical devices. The course will also cover the application of clinical decision making, design of optimal clinical devices, medical imaging systems, and computer modelling of physiological systems, biomaterials design, and biomechanics for injury.

Why Study at 1Training

1Training is a leading online provider for several accrediting bodies and provides learners with the opportunity to take this exclusive CPD course.  At 1Training, we give our fullest attention to our learners’ needs and ensure they have the necessary information required to proceed with the training.

Learners who register will be given excellent learning support, discounts for future purchases and be eligible for a TOTUM Discount card and Student ID card with amazing offers and access to retail stores, the library, cinemas, gym memberships and their favourite restaurant.

Learning outcomes

  • Gain advanced analytical and technical skills required to have a career in biomedical engineering.
  • Develop problem-solving skills
  • Gain the ability to showcase your research and communicate it in a sound manner
  • Develop modelling and prototyping skills.

Key Features

Gain an accredited UK qualification

Access to excellent quality study materials

Learners will be eligible for TOTUM Discount Card

Personalized learning experience

One year’s access to the course

Support by phone, live chat, and email

  • Learners should be over the age of 16 and have a basic understanding of English, ICT and numeracy.
  • A sound educational background is recommended

In order to pass the course ‘Biomedical Engineering and Design – Level 5’ learners will complete an online quiz which will be immediately marked, with learners knowing right away whether they’ve passed the test.

Upon the successful completion of the course, you will be awarded the Certificate for ‘Biomedical Engineering and Design – Level 5’ by CPD.

Access Duration

The course will be directly delivered to you, and you have 12 months of access to the online learning portal from the date you joined the course. The course is self-paced and you can complete it in stages, revisiting the sessions at any time.

Awarding Body

CPD is a leading awarding body in the United Kingdom that meets an excellent standard of high-quality education. CPD is committed to the enhancement of proficiency and personal skills in order to develop learners’ skills and abilities. CPD ensures that both practical and academic qualifications assist individuals to re-skill or up-skill and maintain a competitive advantage in their chosen industry.

Career Path & Progression

The Certificate for Biomedical Engineering and Design – Level 5 will improve your candidature for a number of jobs across multiple sectors.  You can study further related courses that will open the door to new and exciting opportunities and enhance your expertise in this subject, and add this as a skillset on your resume. Your skills will be recognized by leading employers and top organisations that will enable you to land a generous-paying job, plenty of benefits and a wide array of opportunities. Given below are job titles you can compete for, along with the average UK salary per annum according to https://www.glassdoor.com

  • Biomedical Engineer £44K(approximately)
  • Biomedical Technician £39K
  • Learners should be over the age of 16 and have a basic understanding of English, ICT and numeracy.
  • A sound educational background is recommended

In order to pass the course ‘Biomedical Engineering and Design – Level 5’ learners will complete an online quiz which will be immediately marked, with learners knowing right away whether they’ve passed the test.

Upon the successful completion of the course, you will be awarded the Certificate for ‘Biomedical Engineering and Design – Level 5’ by CPD.

Access Duration

The course will be directly delivered to you, and you have 12 months of access to the online learning portal from the date you joined the course. The course is self-paced and you can complete it in stages, revisiting the sessions at any time.

Awarding Body

CPD is a leading awarding body in the United Kingdom that meets an excellent standard of high-quality education. CPD is committed to the enhancement of proficiency and personal skills in order to develop learners’ skills and abilities. CPD ensures that both practical and academic qualifications assist individuals to re-skill or up-skill and maintain a competitive advantage in their chosen industry.

Career Path & Progression

The Certificate for Biomedical Engineering and Design – Level 5 will improve your candidature for a number of jobs across multiple sectors.  You can study further related courses that will open the door to new and exciting opportunities and enhance your expertise in this subject, and add this as a skillset on your resume. Your skills will be recognized by leading employers and top organisations that will enable you to land a generous-paying job, plenty of benefits and a wide array of opportunities. Given below are job titles you can compete for, along with the average UK salary per annum according to https://www.glassdoor.com

  • Biomedical Engineer £44K(approximately)
  • Biomedical Technician £39K
Course Curriculum Total Units : 169
1. Modeling of Biomedical Systems
1.1 Modeling of Biomedical Systems
1.2 Compartmental Models
1.3 Electrical Analog Models of Circulation
1.4 Mechanical Models
1.5 Models with Memory and Models with Time Delay
1.6 Artificial Neural Network Models
1.7 Fuzzy Logic
1.8 Model Validation
2. Heat Transfer Applications in Biological Systems
2.1 Heat Transfer Applications In Biological Systems
2.2 Introduction
2.3 Fundamental Aspects of Bioheat Transfer
2.4 Bioheat Transfer Modeling
2.5 Temperature, Thermal Property, and Blood Flow Measurements
2.6 Hyperthermia Treatment for Cancers and Tumors
3. Physical and Flow Properties of Blood
3.1 Physical and Flow Properties of Blood
3.2 Physiology of the Circulatory System
3.3 Physical Properties of Blood
3.4 Blood Flow in Arteries
3.5 Blood Flow in Veins
3.6 Blood Flow in the Microcirculation
3.7 Blood Flow in the Heart
3.8 Analog Models of Blood Flow
4. Respiratory Mechanics and Gas Exchange
4.1 Respiratory Mechanics and Gas Exchange
4.2 Anatomy
4.3 Mechanics of Breathing
4.4 Ventilation
4.5 Elasticity
4.6 Ventilation, Perfusion, and Limits
4.7 Airway Flow, Dynamics, and Stability
5. Biomechanics of the Respiratory Muscles
5.1 Biomechanics of the Respiratory Muscles
5.2 Introduction
5.3 The Respiratory Muscles
5.4 Mechanics Performance of Respiratory Muscles
5.5 Models of Chest Wall Mechanics
6. Biomechanics of Human Movement
6.1 Biomechanics of Human Movement
6.2 Why Study Human Movement?
6.3 Forward Versus Inverse Dynamics
6.4 Tools for Measuring Human Movement
6.5 Analysis of Human Motion:
6.6 An Inverse Dynamics Approach
6.7 Concluding Remarks
7. Biomechanics of the Musculoskeletal System
7.1 Biomechanics of the Musculoskeletal System
7.2 Introduction
7.3 Mechanical Properties of Soft Tissue
7.4 Body-Segmental Dynamics
7.5 Musculoskeletal Geometry
7.6 Muscle Activation and Contraction Dynamics
7.7 Determining Muscle Force
7.8 Muscle, Ligament, and Joint-Contact Forces
8. Biodynamics A Lagrangian Approach
8.1 Biodynamics a Lagrangian Approach
8.2 Motivation
8.3 The Significance of Dynamics
8.4 The Biodynamic Significance of the Equations of Motion
8.5 The Lagrangian (An Energy Method) Approach
8.6 Introduction to the Kinematics Table Method
8.7 Brief Discussion
8.8 In Closing
9. Bone Mechanics
9.1 Bone Mechanics
9.2 Introduction
9.3 Composition of Bone
9.4 Bone as a Hierarchical Composite Material
9.5 Mechanical Properties of Cortical Bone
9.6 Mechanical Properties of Trabecular Bone
9.7 Mechanical Properties of Trabecular Tissue Material
9.8 Concluding
10. Finite-Element Analysis
10.1 Finite-Element Analysis
10.2 Introduction
10.3 Geometric Concerns
10.4 Material Properties
10.5 Boundary Conditions
10.6 Case Studies
10.7 Conclusions
11. Vibration, Mechanical Shock, and Impact
11.1 Vibration, Mechanical Shock, and Impact
11.2 Introduction
11.3 Physical Measurements
11.4 Models and Human
11.5 Countermeasures
12. Electromyography as a Tool to Estimate Muscle Forces
12.1 Electromyography as a Tool to Estimate Muscle Forces
12.2 Introduction: How to Estimate Muscle Forces
12.3 The EMG Signal
12.4 Processing the EMG Signal
12.5 EMG-Driven Models to Estimate Muscle Forces
12.6 An Example
12.7 Limitations and Future Development of EMG-Driven Models
13. Biopolymers
13.1 Biopolymers
13.2 Introduction
13.3 Polymer Science
13.4 Specific Polymers
13.5 A Note on Tissue Engineering Applications
14. Biomedical Composites
14.1 Biomedical Composites
14.2 Introduction
14.3 Classification
14.4 Constituents
14.5 Processing
14.6 Physical Properties
14.7 Fracture and Fatigue Failure
14.8 Biologic Response
14.9 Biomedical Applications
15. Bioceramics
15.1 Bioceramics
15.2 Introduction
15.3 Bioinert Ceramics
15.4 Bioactive Ceramics
15.5 Ceramics for Tissue Engineering and Biological Therapies
15.6 Summary
16. Cardiovascular Biomaterials
16.1 Cardiovascular Biomaterials
16.2 Introduction
16.3 Materials
16.4 Testing
16.5 Material Processing and Device Design
17. Dental Biomaterials
17.1 Dental Biomaterials
17.2 Introduction: History of Dental Materials
17.3 Metals
17.4 Ceramics
17.5 Polymer Materials
17.6 Composites
17.7 Dental Implants
17.8 Materials Science: Biological Aspects
17.9 Biocompatibility of Dental Restorative Materials
17.10 Biomaterials Evolution: Attachment of Biomaterials to Tissue
17.11 Nanotechnology in Dentistry
18. Orthopedic Biomaterials
18.1 Orthopedic Biomaterials
18.2 Introduction
18.3 Natural Materials
18.4 Engineered Materials
18.5 Conclusion
19. Biomaterials to Promote Tissue Regeneration
19.1 Biomaterials To Promote Tissue Regeneration
19.2 Background
19.3 Structural Component
19.4 Biochemical Component
19.5 Conclusions
20. Bioelectricity and Its Measurement
20.1 Bioelectricity and its Measurement
20.2 Introduction
20.3 The Nature of Bioelectricity
20.4 Action Events of Nerve
20.5 Volume Conductor Propagation
20.6 Detection of Bioelectric Events
20.7 Electrical Interference Problems in Biopotential Measurement
20.8 Biopotential Interpretation
21. Biomedical Signal Analysis
21.1 Biomedical Signal Analysis
21.2 Introduction
21.3 Classifications of Signals and Noise
21.4 Spectral Analysis of Deterministic and Stationary Random Signals
21.5 Spectral Analysis of Nonstationary Signals
21.6 Principal Components Analysis
21.7 Cross-Correlation and Coherence Analysis
21.8 Chaotic Signals and Fractal Processes
22. Biomedical Signal Processing
22.1 Biomedical Signal Processing
22.2 Introduction
22.3 Graph Representation of Signals
22.4 Optimal Classification Algorithm
22.5 Examples
22.6 Conclusion and Research Directions
23. Biosensors
23.1 Biosensors
23.2 Introduction
23.3 Biological Sensing Mechanisms
23.4 Transduction Methods
23.5 Manufacture of Biosensors
23.6 Applications
23.7 Concluding Remarks
24. Bio Micro Electro Mechanical Systems
24.1 Bio Micro Electro Mechanical Systems
24.2 Introduction
24.3 Design of Biomems Devices
24.4 Mems Process Steps
24.5 Surgical Applications of Mems
24.6 Mems in Drug-Delivery Systems
24.7 Bioelectric Interface Devices
24.8 Application of Biomems in Diagnostics
Mock Exam
Mock Exam – Biomedical Engineering and Design – Level 5
Final Exam
Final Exam – Biomedical Engineering and Design – Level 5
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