Masters Degree Programme in Public Mental Health
The Master's Degree Programme in Public Mental Health at the Unive...
Masters Degree Programme in Health Technology
Turku
INTAKE: August
Program Overview
The Master's Degree Programme in Health Technology at the University of Turku is designed to equip students with the expertise needed to apply engineering and technological innovations in the healthcare industry. The program combines knowledge of health sciences, engineering, and business to prepare students for roles at the intersection of technology and healthcare. It focuses on the development, implementation, and management of health technologies, such as medical devices, health information systems, and digital health tools. Graduates are trained to work in various settings, including healthcare institutions, technology companies, and research organizations, where they can contribute to the improvement of healthcare services through innovative technological solutions.
Curriculum: The curriculum of the Master's Degree Programme in Health Technology is structured to provide a balanced mix of theoretical knowledge and practical skills. The program includes core courses in biomedical engineering, medical technologies, digital health, and health informatics. Students also study subjects like regulatory affairs, health data analysis, and project management, all of which are essential for careers in the health technology field. The curriculum is designed to give students hands-on experience in designing, testing, and implementing health technology systems, as well as providing the leadership skills necessary for managing technology-driven healthcare projects. The program also emphasizes interdisciplinary learning, ensuring that students gain exposure to the broader healthcare landscape, from clinical environments to health policy and management.
Research Focus: The Master's Degree Programme in Health Technology at the University of Turku focuses on cutting-edge research in health technologies that aim to enhance the quality, accessibility, and efficiency of healthcare services. Research areas include medical device development, eHealth solutions, wearable health technologies, and health data management. Students are encouraged to engage in research projects that explore innovations in telemedicine, personalized medicine, and AI-driven healthcare solutions. The program’s research-oriented approach prepares students to tackle real-world challenges by developing technologies that improve patient outcomes, streamline healthcare delivery, and contribute to the transformation of healthcare systems globally. The university’s collaboration with local and international research organizations enhances students' ability to conduct impactful research that drives progress in the health technology sector.
Industry Engagement: Industry engagement is a key component of the Master's Degree Programme in Health Technology, ensuring that students gain practical experience and insights into the real-world application of their skills. The program collaborates with leading healthcare organizations, medical device manufacturers, and technology companies, offering students opportunities for internships, projects, and collaborative research. These partnerships allow students to work on current challenges in health technology and gain valuable industry insights that are crucial for their future careers. Additionally, the program hosts guest lectures and workshops by experts in health technology and related fields, providing students with exposure to the latest trends and innovations in the industry. This industry engagement helps students build networks and establish connections that will be beneficial as they enter the workforce.
Global Perspective: The Master's Degree Programme in Health Technology at the University of Turku offers students a global perspective on the role of health technology in improving healthcare systems worldwide. The program emphasizes the international dimensions of healthcare, including the development of global health technologies and the management of cross-border healthcare challenges. Students gain an understanding of the global regulatory environment for medical devices and health technologies and are exposed to best practices in healthcare delivery from different countries. The university encourages international collaborations, and students have opportunities to participate in exchange programs or joint research projects with global academic and healthcare institutions. This global perspective ensures that graduates are well-prepared to work in international health technology markets and contribute to the global advancement of healthcare solutions.
Location
Turku
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.
The University of Turku offers various scholarships for international students, aimed at supporting students with the cost of their tuition fees and ensuring they have the opportunity to pursue their studies in Finland without financial concerns. These scholarships are designed to attract talented students from across the globe, particularly for Master’s degree programs, as the university has a strong international student body.
University of Turku Scholarship Scheme: The University of Turku offers a merit-based scholarship scheme for international students applying to Master’s degree programs. These scholarships cover part or all of the tuition fees for students from non-EU/EEA countries. The scholarships are competitive and are awarded based on the academic excellence and merits of the applicants. Students who are accepted to a degree program at the university are automatically considered for this scholarship.
External Scholarships: The university provides information and guidance on various external scholarships that are available to international students, including scholarships offered by Finnish government agencies and private foundations.
Erasmus+ Grants: Students who are part of the Erasmus+ exchange program may be eligible for grants to support their studies in Finland.
Country-Specific Scholarships: Some countries have specific scholarship agreements with Finland, and students from these countries may apply for additional financial support.
Graduates of the Master's Degree Programme in Health Technology from the University of Turku have access to a wide range of career opportunities in the rapidly evolving healthcare and technology sectors. With their specialized expertise in health technology, they can pursue impactful roles in various industries, including healthcare services, medical device companies, digital health startups, and research institutions.
Health Technology Specialist: As specialists, graduates can work for health technology companies, focusing on the development, integration, and management of healthcare technologies. Their role may include overseeing the implementation of innovative medical devices, systems, and software solutions that improve patient care and healthcare operations.
Biomedical Engineer: Graduates can work as biomedical engineers, applying their engineering skills to the development of medical devices, equipment, and software used in healthcare settings. They may work on improving existing technologies or creating new solutions that enhance patient diagnostics, treatment, and monitoring.
Digital Health Consultant: With the growing demand for digital health solutions, graduates can pursue careers as consultants, advising healthcare organizations on how to incorporate digital technologies such as telemedicine, health apps, and electronic health records (EHR) into their practices. This role involves understanding healthcare needs and recommending effective technological solutions.
Health Data Analyst: Health data analysts are responsible for collecting, analyzing, and interpreting healthcare data to help organizations improve clinical outcomes and operational efficiency. Graduates can work with healthcare providers, insurance companies, or government agencies, leveraging health data to optimize decision-making and policies.
Medical Device Development Engineer: Graduates can take on roles as engineers focused on the design and development of medical devices. This includes tasks like prototyping, testing, and ensuring that medical technologies meet safety standards and regulatory requirements while providing optimal functionality for patients and healthcare providers.
Healthcare IT Manager: As healthcare IT managers, graduates are responsible for overseeing the technology infrastructure of healthcare facilities. This includes managing electronic medical records, coordinating digital health projects, and ensuring that technology systems support healthcare operations effectively and securely.
Clinical Informatics Specialist: Graduates can work in clinical informatics, which involves applying information technology to improve healthcare delivery and clinical decision-making. This role may focus on the integration of health data systems, ensuring interoperability between devices, and improving the efficiency of healthcare services.
Regulatory Affairs Expert: In this role, graduates manage the regulatory aspects of health technologies. They ensure that medical devices, software, and digital health products comply with national and international regulatory requirements. This includes preparing documentation, submitting approvals to regulatory bodies, and guiding companies through the certification process.
Healthcare Project Manager: As project managers, graduates can oversee the implementation of health technology projects, such as new software systems, health device rollouts, or digital transformation efforts in healthcare organizations. This role involves coordinating teams, ensuring that projects are completed on time and within budget, and managing stakeholder expectations.
E-health Solutions Architect: Graduates can work as architects of e-health solutions, designing and developing integrated technology systems that facilitate patient care, health monitoring, and communication between healthcare providers and patients. These roles are key in the creation of scalable and secure healthcare platforms.
Health Innovation Researcher: Graduates interested in research can pursue careers in academic or industrial research. They may work on projects exploring innovative technologies such as AI in healthcare, wearable health devices, and robotic surgery tools. This research can lead to the development of new technologies that revolutionize the healthcare industry.
Entrepreneur in Health Technology: Graduates with an entrepreneurial mindset can launch their own health tech startups. They can create innovative solutions, such as new medical devices, telemedicine platforms, or health data analytics tools, that address current challenges in healthcare delivery and patient care.
Public Health Technologist: Graduates can work in public health organizations, using their expertise in health technology to improve healthcare access and quality in underserved populations. This may involve implementing digital health solutions or improving health system efficiency in areas such as rural health care, telemedicine, and mobile health applications.
Health Policy Advisor: With knowledge of both healthcare and technology, graduates can pursue careers in health policy, advising government agencies or NGOs on the development and implementation of policies related to health technology, digital health solutions, and healthcare innovation. Their role may involve shaping policies that regulate medical devices, data privacy, or telemedicine.
Quality Assurance Specialist in Health Technology: Graduates can work as quality assurance specialists, ensuring that health technologies meet the highest standards of safety and efficacy. They may oversee the testing and certification of medical devices or software solutions, ensuring that these technologies function properly and comply with industry regulations.
