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Maybe you will be the one to create an artificial heart? Yes – it’s possible here in Lithuania. Modern medicine would be unthinkable without engineering. Medical engineers are at the heart of healthcare innovation: they design artificial organs and assistive devices, develop advanced imaging methods, and create systems that improve diagnosis, treatment, and patient care. Did you know? In Lithuania alone, an average of 115 hip joints are replaced every day with endoprostheses designed and manufactured by medical engineers.
As a graduate, you will be able to: • Combine knowledge of sciences, anatomy, biomechanics, and engineering to solve medical problems • Identify challenges in medicine and healthcare, and solve them with modelling, IT, and analytical methods • Plan and conduct experimental research, analyze data, and use engineering equipment effectively • Design and develop innovative technologies, devices, and systems to improve healthcare • Create medical equipment with attention to ethics, sustainability, and societal needs • Conduct research to advance medical technology and improve existing solutions • Work creatively, critically, and responsibly while growing as a professional and team player.
What will students learn?
The programme trains future medical engineers to bridge the gap between technology, biology, and healthcare. You will learn to: • Apply engineering, anatomy, and biomechanics knowledge to solve medical challenges; • Use advanced technologies, analytical methods, and creative design approaches; • Innovate responsibly, with attention to ethics, sustainability, and patient well-being; • Grow as a professional equipped for teamwork, lifelong learning, and leadership. Graduates of this programme don’t just design devices — they help transform lives.
What about career opportunities after Bachelor's degree studies?
Medical engineers are in demand across a wide range of industries and institutions, including: • Hospitals, rehabilitation, and sports medicine centres using advanced medical equipment • Companies designing and manufacturing medical and rehabilitation technologies • Quality and certification companies testing medical devices for safety and compliance • International medical technology firms represented in Lithuania and abroad; • Orthopaedic companies designing and manufacturing prostheses, orthopaedic footwear, insoles, and splint • As medical engineers responsible for installing and maintaining complex equipment, training healthcare staff, troubleshooting, and managing production processes — with opportunities to advance into managerial roles. Graduates may continue their studies at the Master’s level.
Programme overview
Degree
BEng
Study Level
Undergraduate
Study Mode
On Campus
Maybe you will be the one to create an artificial heart? Yes – it’s possible here in Lithuania. Modern medicine would be unthinkable without engineering. Medical engineers are at the heart of healthcare innovation: they design artificial organs and assistive devices, develop advanced imaging methods, and create systems that improve diagnosis, treatment, and patient care. Did you know? In Lithuania alone, an average of 115 hip joints are replaced every day with endoprostheses designed and manufactured by medical engineers.
As a graduate, you will be able to: • Combine knowledge of sciences, anatomy, biomechanics, and engineering to solve medical problems • Identify challenges in medicine and healthcare, and solve them with modelling, IT, and analytical methods • Plan and conduct experimental research, analyze data, and use engineering equipment effectively • Design and develop innovative technologies, devices, and systems to improve healthcare • Create medical equipment with attention to ethics, sustainability, and societal needs • Conduct research to advance medical technology and improve existing solutions • Work creatively, critically, and responsibly while growing as a professional and team player.
What will students learn?
The programme trains future medical engineers to bridge the gap between technology, biology, and healthcare. You will learn to: • Apply engineering, anatomy, and biomechanics knowledge to solve medical challenges; • Use advanced technologies, analytical methods, and creative design approaches; • Innovate responsibly, with attention to ethics, sustainability, and patient well-being; • Grow as a professional equipped for teamwork, lifelong learning, and leadership. Graduates of this programme don’t just design devices — they help transform lives.
What about career opportunities after Bachelor's degree studies?
Medical engineers are in demand across a wide range of industries and institutions, including: • Hospitals, rehabilitation, and sports medicine centres using advanced medical equipment • Companies designing and manufacturing medical and rehabilitation technologies • Quality and certification companies testing medical devices for safety and compliance • International medical technology firms represented in Lithuania and abroad; • Orthopaedic companies designing and manufacturing prostheses, orthopaedic footwear, insoles, and splint • As medical engineers responsible for installing and maintaining complex equipment, training healthcare staff, troubleshooting, and managing production processes — with opportunities to advance into managerial roles. Graduates may continue their studies at the Master’s level.
Admission Requirements
Secondary School Graduation Certificate with good results (minimum 60% CGPA)
Entrance score (KB) consists of grades in three subjects: mathematics (M), physics/another science subject/social science subject (F) and English language (A). The entrant's grades are normalized to the maximum possible grade. The normalized grades of individual subjects are multiplied by the weighting factor and added up (formula below).
Applications must be accompanied by legalized English translations of all transcripts. Unofficial copies are not accepted. Please check country specific requirements for detailed information.
English language proficiency.
Due to significant differences in applicants' achievements in Mathematics, applicants who have graduated from secondary or vocational schools in Pakistan, Bangladesh, or Nepal are required to take the Mathematics entrance exam organized by OMPT. The exam grade will be included in the Entrance score in place of the mathematics grade. The exam must be passed with a result of no less than 60% for admission to university-level Bachelor's degree study programmes and 50% for admission to professional Bachelor's degree study programmes.
15 Jun 2026
Sep
Candidates are required to submit an essay(s) for acceptance
Domestic
4,000 EUR
International
4,950 EUR
Scholarships
Selecting the right scholarship can be a daunting process. With countless options available, students often find themselves overwhelmed and confused. The decision can be especially stressful for those facing financial constraints or pursuing specific academic or career goals.
To help students navigate this challenging process, we recommend the following articles:
Medical Engineering
Plytinės, Vilnius, Lithuania
4,950 EURTuition Fee/year
15 Jun, 2026Application Deadline
Programme overview
Degree
BEng
Study Level
Undergraduate
Study Mode
On Campus
Maybe you will be the one to create an artificial heart? Yes – it’s possible here in Lithuania. Modern medicine would be unthinkable without engineering. Medical engineers are at the heart of healthcare innovation: they design artificial organs and assistive devices, develop advanced imaging methods, and create systems that improve diagnosis, treatment, and patient care.
Did you know? In Lithuania alone, an average of 115 hip joints are replaced every day with endoprostheses designed and manufactured by medical engineers.
As a graduate, you will be able to:
• Combine knowledge of sciences, anatomy, biomechanics, and engineering to solve medical problems
• Identify challenges in medicine and healthcare, and solve them with modelling, IT, and analytical methods
• Plan and conduct experimental research, analyze data, and use engineering equipment effectively
• Design and develop innovative technologies, devices, and systems to improve healthcare
• Create medical equipment with attention to ethics, sustainability, and societal needs
• Conduct research to advance medical technology and improve existing solutions
• Work creatively, critically, and responsibly while growing as a professional and team player.
What will students learn?
The programme trains future medical engineers to bridge the gap between technology, biology, and healthcare. You will learn to:
• Apply engineering, anatomy, and biomechanics knowledge to solve medical challenges;
• Use advanced technologies, analytical methods, and creative design approaches;
• Innovate responsibly, with attention to ethics, sustainability, and patient well-being;
• Grow as a professional equipped for teamwork, lifelong learning, and leadership.
Graduates of this programme don’t just design devices — they help transform lives.
What about career opportunities after Bachelor's degree studies?
Medical engineers are in demand across a wide range of industries and institutions, including:
• Hospitals, rehabilitation, and sports medicine centres using advanced medical equipment
• Companies designing and manufacturing medical and rehabilitation technologies
• Quality and certification companies testing medical devices for safety and compliance
• International medical technology firms represented in Lithuania and abroad;
• Orthopaedic companies designing and manufacturing prostheses, orthopaedic footwear, insoles, and splint
• As medical engineers responsible for installing and maintaining complex equipment, training healthcare staff, troubleshooting, and managing production processes — with opportunities to advance into managerial roles. Graduates may continue their studies at the Master’s level.
Programme overview
Degree
BEng
Study Level
Undergraduate
Study Mode
On Campus
Maybe you will be the one to create an artificial heart? Yes – it’s possible here in Lithuania. Modern medicine would be unthinkable without engineering. Medical engineers are at the heart of healthcare innovation: they design artificial organs and assistive devices, develop advanced imaging methods, and create systems that improve diagnosis, treatment, and patient care.
Did you know? In Lithuania alone, an average of 115 hip joints are replaced every day with endoprostheses designed and manufactured by medical engineers.
As a graduate, you will be able to:
• Combine knowledge of sciences, anatomy, biomechanics, and engineering to solve medical problems
• Identify challenges in medicine and healthcare, and solve them with modelling, IT, and analytical methods
• Plan and conduct experimental research, analyze data, and use engineering equipment effectively
• Design and develop innovative technologies, devices, and systems to improve healthcare
• Create medical equipment with attention to ethics, sustainability, and societal needs
• Conduct research to advance medical technology and improve existing solutions
• Work creatively, critically, and responsibly while growing as a professional and team player.
What will students learn?
The programme trains future medical engineers to bridge the gap between technology, biology, and healthcare. You will learn to:
• Apply engineering, anatomy, and biomechanics knowledge to solve medical challenges;
• Use advanced technologies, analytical methods, and creative design approaches;
• Innovate responsibly, with attention to ethics, sustainability, and patient well-being;
• Grow as a professional equipped for teamwork, lifelong learning, and leadership.
Graduates of this programme don’t just design devices — they help transform lives.
What about career opportunities after Bachelor's degree studies?
Medical engineers are in demand across a wide range of industries and institutions, including:
• Hospitals, rehabilitation, and sports medicine centres using advanced medical equipment
• Companies designing and manufacturing medical and rehabilitation technologies
• Quality and certification companies testing medical devices for safety and compliance
• International medical technology firms represented in Lithuania and abroad;
• Orthopaedic companies designing and manufacturing prostheses, orthopaedic footwear, insoles, and splint
• As medical engineers responsible for installing and maintaining complex equipment, training healthcare staff, troubleshooting, and managing production processes — with opportunities to advance into managerial roles. Graduates may continue their studies at the Master’s level.
Admission Requirements
Domestic
International
Scholarships
Selecting the right scholarship can be a daunting process. With countless options available, students often find themselves overwhelmed and confused. The decision can be especially stressful for those facing financial constraints or pursuing specific academic or career goals.
To help students navigate this challenging process, we recommend the following articles:
How to get a full scholarship
Looking for a fully-funded scholarship to see you into university? Find out how to boost your chances of getting one.
Scholarships to study abroad
Find scholarships to study abroad with our lists of international scholarships – categorized by country, by subject, and by type of student.
Scholarship Applications: Frequently Asked Questions
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