MSc in Electrical Engineering - Smart Grids
The MSc in Electrical Engineering - Smart Grids at Tampere Uni...
Master of Science in Biomedical Technology - Biomedical Informatics
Kauppi
INTAKE: September
Program Overview
The Master of Science in Biomedical Technology - Biomedical Informatics program at Tampere University, Finland, is designed to equip students with the expertise needed to integrate advanced information technologies into healthcare and biomedical sciences. This interdisciplinary program focuses on the application of informatics to manage, analyze, and interpret complex biomedical data, aiming to improve healthcare systems and clinical outcomes. It combines knowledge of medical technologies, health data management, and software engineering to prepare students for careers in the rapidly evolving field of biomedical informatics. Graduates are equipped to work in research, healthcare institutions, or medical technology companies, contributing to the development of intelligent healthcare solutions.
Curriculum: The curriculum for the Master of Science in Biomedical Technology - Biomedical Informatics program at Tampere University is designed to provide a deep understanding of both the biological sciences and the technological advancements that support modern healthcare. The program includes core courses in biomedical data analysis, health informatics, medical image processing, and machine learning. Students gain practical skills in programming, database management, and system design, enabling them to work with large-scale health data sets and develop software tools for clinical applications. Elective courses allow students to specialize in areas such as personalized medicine, artificial intelligence in healthcare, and digital health solutions. The curriculum also includes a Master's thesis project, where students apply their knowledge to real-world biomedical informatics challenges, contributing to cutting-edge research in the field.
Research Focus: The research focus of the Biomedical Technology - Biomedical Informatics program at Tampere University is rooted in the integration of technology with healthcare to solve complex medical problems. The university is at the forefront of research in fields like artificial intelligence, machine learning, and data mining, specifically tailored for the healthcare and biomedical sectors. Ongoing research projects focus on developing algorithms for personalized medicine, improving electronic health record systems, and optimizing medical imaging technologies. Additionally, researchers at Tampere University are exploring innovative ways to leverage big data and advanced analytics to predict disease outcomes, optimize treatment plans, and enhance healthcare delivery. Students have opportunities to collaborate on these research projects, gaining valuable hands-on experience in the application of biomedical informatics.
Industry Engagement: The Biomedical Technology - Biomedical Informatics program emphasizes strong industry engagement, ensuring that students are prepared to meet the demands of the rapidly evolving healthcare technology sector. Tampere University collaborates with leading health tech companies, hospitals, and research institutions to provide students with internships, projects, and opportunities for collaborative research. These partnerships allow students to gain real-world experience in biomedical data analysis, medical software development, and the implementation of informatics tools in clinical environments. Additionally, the university’s proximity to Finland’s growing health tech industry offers networking opportunities and potential career placements. Students benefit from direct exposure to industry practices, ensuring they are well-equipped for the workforce upon graduation.
Global Perspective: Tampere University’s Master of Science in Biomedical Technology - Biomedical Informatics program offers a global perspective, reflecting the international nature of the healthcare and technology industries. The program attracts students from around the world, fostering a multicultural learning environment. The global focus is also reflected in the curriculum, which covers international trends in health technology, telemedicine, and digital health innovations. Students are exposed to global challenges in healthcare, such as the need for scalable, data-driven health solutions and the integration of diverse healthcare systems. Through collaborative projects with international partners, students gain an understanding of how biomedical informatics can be applied in different regions and healthcare settings, preparing them to work in a global context. The program encourages students to consider the global implications of emerging health technologies and the role of informatics in addressing worldwide health challenges.
Location
Kauppi
Score
Tuition Fee
€ 12000
Postgraduate Entry Requirements
Application Fee: €100
Academic Qualifications: Applicants for postgraduate programs typically require a minimum academic achievement of 60% or above in their bachelor's degree.
English Language Proficiency:
- English language test waiver is applicable if the Bachelor's, Master's, Licentiate, or Doctoral degree is in English language.
Tampere University in Finland offers various scholarship opportunities to help international students finance their education and living costs. The university is supporting talented and motivated students from around the world, ensuring that financial constraints do not prevent them from pursuing higher education in Finland.
Tampere University Scholarships for Non-EU/EEA Students: Tampere University offers scholarships to international students from non-EU/EEA countries applying to Master's degree programs. These scholarships are designed to cover tuition fees and help students with the cost of living in Finland. The scholarship covers either partial or full tuition fees, depending on the student's academic merit and the specific program applied to.
Tampere University Scholarship for Excellence: The Tampere University Scholarship for Excellence is awarded to exceptional students based on their academic achievements. This scholarship aims to recognize the outstanding academic performance of students during their studies and provide them with additional financial support. The scholarship amount varies depending on the level of achievement, and students who maintain excellent academic performance may be eligible for renewal during their studies.
Finland Scholarship: The Finland Scholarship is a government-funded initiative aimed at attracting top talent to Finland from abroad. Tampere University participates in this scholarship program, which is available to non-EU/EEA students who apply for Master's degree programs in Finland. The Finland Scholarship covers tuition fees and provides an additional grant to help with living expenses during the first year of study. This scholarship is awarded based on academic merit and is designed to make studying in Finland more accessible to international students.
Scholarships for Exchange Students: Tampere University also offers limited scholarships for exchange students from partner universities. These scholarships help cover travel costs, accommodation, and other living expenses during the exchange period. Exchange students should check with their home university’s exchange program office to inquire about the available scholarship opportunities.
External Scholarships and Funding: In addition to university-specific scholarships, international students can explore external scholarship opportunities provided by the Finnish government, private organizations, and other funding bodies. These scholarships may be available for both undergraduate and graduate students. International students are encouraged to research and apply for other scholarships to support their studies in Finland.
Graduates of the Master of Science in Biomedical Technology - Biomedical Informatics program at Tampere University, Finland, are equipped with the necessary skills and expertise to pursue a wide range of career opportunities in the rapidly evolving fields of healthcare technology, biomedical informatics, and data science. With the growing demand for professionals who can bridge the gap between technology and healthcare, the career options for graduates are both diverse and rewarding.
Biomedical Informatics Specialist: Graduates can work as biomedical informatics specialists, where they utilize their knowledge of data analysis, machine learning, and health informatics to support healthcare providers. They play a vital role in managing and analyzing patient data, improving healthcare systems, and optimizing decision-making processes.
Health Data Scientist: As health data scientists, graduates can work with large medical datasets to uncover patterns, trends, and insights that can improve patient outcomes and healthcare services. They may apply statistical and machine learning models to predict disease patterns, analyze treatment efficacy, and support clinical decision-making.
Medical Software Developer: Graduates with strong programming skills can pursue careers as medical software developers. They design and develop software tools that are used in healthcare settings, such as electronic health records (EHR), medical imaging systems, and telemedicine platforms. Their work enhances the efficiency and functionality of healthcare IT systems.
Clinical Informaticist: Clinical informaticists focus on improving clinical workflows by applying informatics principles. They work to integrate new technologies into clinical practice, optimizing the use of electronic health records and other health IT systems to improve patient care and operational efficiency.
Healthcare IT Consultant: Graduates can work as healthcare IT consultants, advising hospitals, clinics, and healthcare organizations on how to implement and manage healthcare technologies. They provide guidance on system integration, data management, cybersecurity, and improving the use of health informatics to enhance patient care and organizational efficiency.
Medical Researcher: Biomedical informatics graduates can engage in medical research, focusing on how technology and data can advance scientific knowledge in the medical field. They may conduct studies in areas like personalized medicine, health data analytics, or bioinformatics, contributing to the development of new treatments or medical technologies.
Telemedicine Specialist: With the growing use of telemedicine, graduates can work as telemedicine specialists, developing and managing telehealth platforms and solutions that allow patients and healthcare providers to connect remotely. Their work ensures that telemedicine systems are secure, efficient, and accessible.
Bioinformatics Engineer: Bioinformatics engineers develop algorithms and tools to analyze biological data, such as genomic data, which is increasingly important in medical research and personalized medicine. Graduates in this field can work in both the biotechnology and healthcare sectors, applying informatics to understand biological systems and improve treatment options.
Health IT Project Manager: Graduates can work as project managers in health IT projects, leading teams that implement new healthcare technologies or improve existing ones. This role involves coordinating with stakeholders, managing timelines and budgets, and ensuring that technology solutions meet the needs of healthcare professionals and patients.
Health Policy Analyst: With expertise in biomedical informatics, graduates can work as health policy analysts, advising governmental and non-governmental organizations on how to implement policies that utilize data and technology to improve healthcare services. They play a crucial role in shaping healthcare policies and regulations that support the integration of technology in healthcare systems.
Biomedical Device Data Analyst: Graduates can also work with biomedical device companies, analyzing data collected from medical devices. They ensure that devices are operating effectively, improve their functionality, and develop new methods for collecting and interpreting medical data to assist in treatment decisions.
AI Specialist in Healthcare: With the growing role of artificial intelligence in healthcare, graduates can specialize in applying AI to healthcare systems. They develop AI models that improve diagnostic tools, predict patient outcomes, and automate administrative tasks, revolutionizing patient care and healthcare operations.
