| Study Location | Kyiv |
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| Academic Field | G22 Biomedical engineering |
| Type | Undergraduate, Full time (on-line study is available) |
| Nominal Duration | 4 years (240 ECTS) |
| Study Language | English |
| Awards | Bachelor of Biomedical engineering |
| Entry qualification | The certificate of Completed Secondary Education is required. Compulsory entrance exam. The entry qualification documents are accepted in English (except for documents issued in Ukraine upon completion of studies at local educational institutions) . In most cases you can request a suitable transcript from your school. If this is not the case, you will need official translations along with verified copies of the original. You must take the original & legalized (according to the international agreements) entry qualification documents along with you when you finally enter the university. |
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| Territory requirements | General entry requirement - Student visa. Citizens of the Russia, Iran, Belarus and North Korea who do not hold a permanent residence permit in Ukraine may be admitted for studies only with an individual authorization from the Ministry of Education and Science of Ukraine. |
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| Language Requirements | English (B1/B2) |
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Entrance Exam Description
During the selection process we examine the competency of the applicant in two ways:
The faculty decides about the eligibility of the applicant by examining the documents of previous studies (degree, subject, results). This is followed by an entrance exams that evaluate the level of study-language and basic subjects depends on speciality.
The exams can be conducted online. In order to validate the entrant’s person, exams taken remotely are recorded on video, as is the person verification process. The recording is archived for at least five years on University’s grounds and the link to that recording is available in the united base of Ministry of Education of Ukraine.
Program Structure
Year 1 – Foundations of Engineering and Biology
Students develop essential knowledge in mathematics, physics, biology, and engineering principles to prepare for biomedical applications.
Typical subjects: Higher Mathematics, Physics for Engineers, General Biology and Human Anatomy, Chemistry for Biomedical Applications, Computer Technologies and Programming, Technical Drawing & CAD Basics, Electrical Engineering Fundamentals, English for Professional Communication, Safety and Environmental Studies.
You start by learning the science behind life and technology. This year gives you the math, physics, biology, and technical skills to understand how engineering can improve healthcare.
Year 2 – Biomedical Systems & Instrumentation
Focus shifts to understanding medical devices, biomedical electronics, and measurement systems.
Typical subjects: Biomedical Instrumentation; Electronics and Sensors for Healthcare; Human Physiology for Engineers; Mechanics and Material Science for Biomedical Devices; Signals and Systems; Measurement and Control Techniques; Computer-Aided Design (CAD); Technical English for Biomedical Engineering.
You learn how medical devices work, from sensors to electronic systems. Practical exercises let you explore how engineering supports diagnostics, monitoring, and treatment.
Year 3 – Diagnostics, Rehabilitation & Medical Technologies
Students focus on practical biomedical engineering, device diagnostics, and rehabilitation technologies.
Typical subjects: Medical Imaging Systems, Diagnostic Equipment and Techniques, Rehabilitation and Prosthetic Devices, Automation and Control in Biomedical Systems, Reliability and Safety of Medical Devices, Laboratory and Practical Training, Regulatory Standards for Medical Technology.
You start working with real biomedical devices and systems. You learn to maintain, test, and improve medical technologies that help patients, from prosthetics to imaging equipment.
Year 4 – Advanced Biomedical Engineering & Professional Practice.
The final year emphasizes professional experience, advanced design, and integration of all skills.
Typical subjects: Advanced Biomedical Device Design, Healthcare Technology Innovations, Medical Equipment Management, Internship / Industry Practice, Bachelor Thesis / Final Project, Technical Documentation and International Standards (ISO/IEC/IEC).
You apply all your knowledge during internships and final projects. By graduation, you can design, test, and maintain advanced medical devices, ready to work in hospitals, labs, or biomedical companies worldwide.
Overview
The program trains students to design, develop, and maintain advanced medical devices and healthcare technologies. Students learn to combine principles of engineering, biology, electronics, and computer science to create innovative solutions that improve patient care, medical diagnostics, and treatment efficiency.
This program is ideal for students who want to work at the intersection of technology and healthcare, designing devices like medical imaging systems, prosthetics, rehabilitation equipment, and wearable health technologies. Students gain both theoretical knowledge and practical skills, with hands-on labs, simulation exercises, and exposure to real biomedical systems.
Career Opportunities
Graduates of Biomedical Engineering can work in: Medical device design and manufacturing companies; Hospitals and healthcare technology departments; Research and development laboratories; Rehabilitation and prosthetics centers; Biomedical instrumentation and diagnostics firms; Regulatory and quality assurance organizations.
Roles may include: Biomedical engineer; Medical equipment specialist; Healthcare technology consultant; Rehabilitation and prosthetics engineer; Laboratory equipment maintenance engineer.
Graduates gain practical experience, technical expertise, and international-standard skills, preparing them for careers in the rapidly growing biomedical and healthcare technology industry worldwide.