University certificate
The world's largest faculty of medicine”
Description
Access the latest developments in this field thanks to this update program and learn more about the use of software for biomedical signal processing"
The integration of new technological tools in the biomedical field has led to rapid progress in this discipline. For this reason, in recent years, biomedical engineering has emerged as one of the most cutting-edge fields of healthcare, as it incorporates the most promising scientific advances to respond to a whole series of current medical challenges. Therefore, the specialist needs access to an up-to-date program such as this one to keep abreast of the latest developments in this field.
This professional master’s degree in Biomedical Engineering delves into innovations and in areas such as biodevices and biosensors, fluid mechanics within the field of biomechanics, nanoparticles, metallic biomaterials, computed tomography, the application of artificial intelligence through the field of artificial vision to the medical field or the use of databases, among many others.
All this, following a 100% online learning methodology that allows the professional to choose the time and place to study, since it adapts to their personal circumstances. In addition, a high-level teaching staff specialized in biomedical engineering will guide the physician using numerous multimedia teaching resources such as video procedures and techniques, analysis of clinical cases, theoretical and practical exercises, interactive summaries and master classes.
Delve into the latest advances in nanoparticles thanks to this innovative online teaching methodology, which allows you to decide when and where to study"
This professional master’s degree in Biomedical Engineering contains the most complete and up-to-date scientific program on the market. The most important features include
- Case studies presented by experts in Biomedical Engineering
- The graphic, schematic, and practical contents with which they are created, provide scientific and practical information on the disciplines that are essential for professional practice
- Practical exercises where the self-assessment process can be carried out to improve learning
- Its special emphasis on innovative methodologies
- Theoretical lessons, questions to the expert, debate forums on controversial topics, and individual reflection assignments
- Content that is accessible from any fixed or portable device with an Internet connection
This program will provide you with an expert and highly experienced teaching staff, and numerous multimedia teaching resources with which you can quickly update your knowledge"
The program’s teaching staff includes professionals from the sector who contribute their work experience to this training program, as well as renowned specialists from leading societies and prestigious universities.
The multimedia content, developed with the latest educational technology, will provide the professional with situated and contextual learning, i.e., a simulated environment that will provide immersive training programmed to train in real situations.
This program is designed around Problem-Based Learning, whereby the professional must try to solve the different professional practice situations that arise during the academic year. For this purpose, the student will be assisted by an innovative interactive video system created by renowned and experienced experts.
With this professional master’s degree, you will be able to incorporate the latest techniques in biomedical engineering into your professional practice.
Get up to date with the latest scientific evidence on issues such as bio-devices or biomedical signals.
Objectives
The main objective of this professional master’s degree in Biomedical Engineering is to offer physicians the latest innovations in this discipline, so that they can incorporate them into their professional practice and update their knowledge. This is a very complex field and undergoes continuous transformations, so it requires, on the part of the specialist, an update and this program offers it. Therefore, upon completion, the physician will be in possession of the most advanced techniques in this booming field.
Integrate the most innovative scientific postulates of Biomedical Engineering into your daily work and use them in your diagnoses and treatments"
General Objectives
- Examine the different tissues and organs directly related to tissue engineering
- Analyze tissue balance and the role of the matrix, growth factors and the cells themselves in the tissue microenvironment
- Develop the basis of tissue engineering
- Analyze the relevance of biomaterials today
- Develop a specialized view of the types of biomaterials available and their main characteristics
- Generate specialized knowledge on cell biology and the interaction between biomaterials and tissues
- Generate specialized knowledge on the main types of biomedical signals and their uses
- Develop the physical and mathematical knowledge underlying biomedical signals
- Fundamentals of the principles governing signal analysis and processing systems
- Analyze the main applications, trends and lines of research and development in the field of biomedical signals
- Develop expertise in classical mechanics and fluid mechanics
- Analyze the general functioning of the motor system and its biological mechanisms
- In-depth study of biofluidics and transport systems
- Addressing real case studies
- Develop models and techniques for the design and prototyping of interfaces, based on design methodologies and their evaluation
- Provide the student with critical skills and tools for interface assessment
- Fundamentals of design theory principles and their application to the biomedical field
- Determine the needs and differences of UX/UI design in the healthcare context
- Explore the interfaces used in pioneering technology in the biomedical sector
- Analyze the fundamentals of medical imaging acquisition, inferring its social impact
- Develop specialized knowledge about the operation of the different imaging techniques, understanding the physics behind each modality
- Identify the usefulness of each method in relation to its characteristic clinical applications
- Research post-processing and management of acquired images
- Use and design biomedical information management systems
- Analyze current digital health applications and design biomedical applications in a hospital setting or clinical center
- Examining the variety and use of biodevices
- Analyze the different data and database systems
- Determine the importance of data in health
- Develop the fundamentals of data analysis
Specific Objectives
Module 1. Tissue Engineering
- Generate specialized knowledge on histology and functioning of the cellular environment
- Review the current status of tissue engineering and regenerative medicine
- Address the main challenges facing tissue engineering
- Present the most promising techniques and the future of tissue engineering
- Develop the main trends of the future of regenerative medicine
- Examine the interaction of biomaterials with the cellular environment and the complexity of this process
Module 2. Biomaterials in Biomedical Engineering
- Analyze biomaterials and their evolution throughout history
- Examining traditional biomaterials and their uses
- Determine the biomaterials of biological origin and their applications
- Deepen the knowledge of polymeric biomaterials of synthetic origin
- Determine the behavior of biomaterials in the human body, with special emphasis on their degradation
Module 3. Biomedical Signals
- Distinguish the different types of biomedical signals
- Determine how biomedical signals are acquired, interpreted, analyzed and processed
- Analyze the clinical applicability of biomedical signals through practical case studies
- Apply mathematical and physical knowledge to analyze signals
- Examine the most common signal filtering techniques and how to apply them
- Develop fundamental engineering knowledge of signals and systems
- Understand the operation of a biomedical signal processing system.
- Identify the main components of a digital signal processing system
Module 4. Biomechanics
- Generate specialized knowledge on the concept of biomechanics
- Examine the different types of movements and the forces involved in them
- Understanding the functioning of the circulatory system
- Develop biomechanical analysis methods
- Analyze muscle positions to understand their effect on resultant forces
- Evaluate common problems related to biomechanics
- Identify the main lines of action of biomechanics
Module 5. Medical Bioinformatics
- Develop a reference framework for medical bioinformatics
- Examine computer hardware and software required in medical bioinformatics
- Generate specialized knowledge on data mining techniques in Bioinformatics
- Analyze artificial intelligence and Big Data techniques in medical bioinformatics
- Establish the applications of bioinformatics for prevention, diagnosis and clinical therapies
- Deepen in the methodology and medical bioinformatics workflow
- Assess the factors associated with sustainable bioinformatics applications and future trends
Module 6. Human-Machine Interface Applied to Biomedical Engineering
- Develop the concept of human-machine interaction
- Analyze interface typologies and their adaptation to each context
- Identify the human and technological factors involved in the interaction process
- Examine design theory and its application to interface design
- Deepen UX/UI tools in the design process
- Establish methods for evaluating and validating interfaces
- Training in the use of user-centered methodology and Design Thinking methodology
- Further study of new technologies and interfaces in the biomedical sector
- Address the importance of user perception in the in-hospital context
- Develop critical interface design skills
Module 7. Biomedical Images
- Develop specialized knowledge about medical imaging as well as the DICOM standard
- Analyze the radiological technique for medical imaging, clinical applications and aspects influencing the outcome
- Examine the technique of magnetic resonance imaging for medical imaging, clinical applications, and aspects influencing outcome
- Analyze the radiological technique for medical imaging, clinical applications and aspects influencing the outcome
- Evaluate the effect of noise on clinical images as well as different image processing methods
- Present and analyze image segmentation technologies and explain their usefulness
- Gain a deeper understanding of the direct relationship between surgical interventions and imaging techniques
Module 8. Digital Health Applications in Biomedical Engineering
- Analyze the referential framework of digital health applications
- Examine medical image storage and transmission systems
- Evaluate relational database management for digital health applications
- Establish the operation of digital health applications based on web development
- Develop web applications in a hospital or clinical center environment and telemedicine applications
- Analyze applications with the Internet of Medical Things, IoMT and digital health applications with artificial intelligence techniques
Module 9. Biomedical Technologies: Biodevices and Biosensors
- Generate specialized knowledge in the conception, design, implementation and operation of medical devices through the technologies used in this field
- Determine the main technologies for rapid prototyping
- Discover the main fields of application: diagnostic, therapeutic and support.
- Establish the different types of biosensors and their use for each diagnostic case
- Deepen the understanding of the physical/electrochemical functioning of the different types of biosensors
- Examine the importance of biosensors in modern medicine
Module 10. Biomedical and Healthcare Databases
- Data Structure
- Analyze Relational Systems
- Develop conceptual data modeling
- Designing and standardizing a relational database
- Examine functional dependencies between data
- Generate specialized knowledge on big data
- Deepen the ODMS architecture
- Learn about data integration in medical record systems
- Analyze the bases and restrictions
Achieve your goal of staying completely up to date with this innovative program"
Professional Master's Degree Proprietary Degree in Biomedical Engineering.
Biomedical engineering is a discipline that combines engineering and biology to create technological solutions to medical and health problems. This discipline focuses on applying engineering in the research, design, development and maintenance of medical equipment, devices and systems, such as prostheses, medical diagnostic equipment, therapy and rehabilitation equipment, among others.
This branch of engineering uses principles from different areas, such as mechanics, electronics, computer science, physics and chemistry, to create solutions for health and wellness problems. Biomedical engineering focuses on several areas, such as medical imaging, biomechanics, tissue engineering, bioinformatics, health systems engineering, and ergonomics, among others. Biomedical engineers work closely with physicians, scientists and technology experts to create innovative solutions that can improve patients' quality of life and assist healthcare professionals in their daily work.
Biomedical engineering focuses on many fields, including biomechanics, biocompatible materials engineering, electrical and electronics engineering, software engineering, biomedical imaging engineering and medical systems engineering.
Biomedical engineers are highly sought after by the medical industry, universities and research centers. In addition, they are recognized for their ability to develop creative and efficient solutions to medical and healthcare challenges.
TECH the world's largest digital university has a specialized Professional Master's Degree designed to provide advanced knowledge and technical skills in the field of biomedical engineering.
The aim of the Professional Master's Degree is to provide a solid understanding of biomedical engineering and its application in the design and development of biomedical devices and systems. They will learn the most advanced techniques and the most effective strategies for engineering biomedical solutions. The Professional Master's Degree is intended for graduates of engineering, life sciences and related disciplines who wish to specialize in biomedical engineering, as well as those working in the biomedical industry and research and development organizations.