Bachelor of Engineering in Biomedical Engineering

Limerick

 

INTAKE: September

Program Overview

The Bachelor of Engineering in Biomedical Engineering program at the University of Limerick is designed to provide students with a strong foundation in engineering principles and their application in the healthcare industry. This interdisciplinary program integrates engineering, biology, and medicine to develop innovative solutions for healthcare challenges. Students learn to design, develop, and evaluate medical devices, diagnostic tools, and healthcare technologies that improve patient care and quality of life. The program emphasizes hands-on learning, project-based activities, and clinical experience to prepare graduates for careers in biomedical engineering and related fields.

Curriculum: The curriculum of the Bachelor of Engineering in Biomedical Engineering program at the University of Limerick is structured to cover a wide range of topics relevant to biomedical engineering. Core modules include engineering mathematics, physics, mechanics, materials science, and electrical circuits, providing students with a solid foundation in engineering fundamentals. Specialized modules focus on biomedical instrumentation, medical imaging, biomaterials, biomechanics, and regulatory affairs. Practical components of the curriculum include laboratory experiments, design projects, and clinical placements, allowing students to apply their knowledge and skills to real-world healthcare challenges.

Research Focus: Research is a key component of the Bachelor of Engineering in Biomedical Engineering program at the University of Limerick. Faculty members are actively engaged in research projects spanning a wide range of areas, including medical device development, tissue engineering, rehabilitation engineering, and healthcare informatics. Students have the opportunity to participate in research activities, collaborate with faculty members on research projects, and contribute to advancements in biomedical engineering through research-focused modules and undergraduate research projects. The program encourages critical thinking, creativity, and innovation in addressing current and future healthcare needs.

Industry Engagement: The University of Limerick has strong connections with industry partners in the biomedical engineering and healthcare sectors, providing students with valuable industry exposure and opportunities for professional development. The Bachelor of Engineering in Biomedical Engineering program includes industry placements, internships, and industry-led projects, allowing students to gain practical experience in biomedical companies, hospitals, and research laboratories. Additionally, guest lectures, industry seminars, and networking events organized in collaboration with industry partners provide students with insights into current practices, emerging technologies, and career opportunities in biomedical engineering.

Global Perspective: The Bachelor of Engineering in Biomedical Engineering program at the University of Limerick emphasizes a global perspective, preparing students to work in diverse and multicultural healthcare environments. The curriculum includes modules on global health challenges, healthcare disparities, and cross-cultural communication, allowing students to understand and address the complexities of providing healthcare on a global scale. The university also facilitates international exchange programs, study abroad opportunities, and collaborative projects with international partners, providing students with exposure to different healthcare systems, cultural practices, and healthcare technologies around the world.

Pollster Education

Location

Limerick

Pollster Education

Score

IELTS 6.5

Pollster Education

Tuition Fee

€ 21000

Undergraduate Entry Requirements 

Application Fee: € 50

Academic Qualifications: Applicants for undergraduate programs typically require a minimum academic achievement of 70% or above in their previous academic qualifications.

English Language Proficiency:

  • IELTS: Overall band score of 6.0 or 6.5 with a minimum of 5.5 in each component.
  • TOEFL: Overall score of 90 with a minimum of 21 in each section.
  • PTE: Overall score of 61 with a minimum of 59 in each section.
  • DET: Overall score of 120 with no section score below 110 is required.

Students must provide:

  • academic marksheets & transcripts
  • letters of recommendation
  • a personal statement - SOP
  • passport
  • other supporting documents as required by the university.

It's important to note that entry requirements can vary by program and may change over time. Additionally, some programs may have additional requirements, such as interviews, portfolios, or work experience.

The University of Limerick (UL) is supporting the academic aspirations of international students by offering various scholarship opportunities that recognize academic excellence, talent, and diverse backgrounds.

Merit-Based Scholarships: UL provides a range of merit-based scholarships for international students based on academic achievements, varying from undergraduate to postgraduate levels. These scholarships are awarded to high-achieving students who demonstrate exceptional academic performance.

Country-Specific Scholarships: The university also offers scholarships specifically tailored to students from certain countries or regions. These scholarships aim to encourage diversity and attract exceptional talent from different parts of the world, providing financial support to deserving candidates.

Sports Scholarships: UL values sporting achievements and offers scholarships to international students who excel in sports. These scholarships support athletes pursuing their academic goals while representing the university in various sporting events.

Graduates of the Bachelor of Engineering in Biomedical Engineering program from the University of Limerick possess a diverse skill set that allows them to pursue careers in various sectors of the healthcare industry. 

Biomedical Engineer: Biomedical engineers design, develop, and maintain medical devices and equipment used in healthcare settings. They work on projects involving prosthetics, implants, diagnostic equipment, medical imaging devices, and assistive technologies. Biomedical engineers collaborate with healthcare professionals, researchers, and manufacturers to improve patient care and develop innovative healthcare solutions.

Clinical Engineer: Clinical engineers work in hospitals, clinics, and healthcare facilities, managing medical equipment, systems, and technologies. They ensure that medical devices meet regulatory standards, perform maintenance and calibration procedures, and provide technical support to healthcare staff. Clinical engineers may also be involved in the evaluation and procurement of medical equipment and the implementation of healthcare technology systems.

Medical Device Engineer: Medical device engineers design, test, and manufacture medical devices and instruments used in the diagnosis, treatment, and monitoring of medical conditions. They work on projects involving product development, validation testing, regulatory compliance, and quality assurance. Medical device engineers collaborate with cross-functional teams to bring new medical devices to market and improve existing products.

Regulatory Affairs Specialist: Regulatory affairs specialists ensure that medical devices and healthcare products comply with regulatory requirements and standards. They prepare and submit regulatory filings, manage regulatory submissions, and communicate with regulatory agencies to obtain approvals and certifications. Regulatory affairs specialists also monitor changes in regulations and provide guidance on compliance issues to internal teams and external partners.

Biomechanical Engineer: Biomechanical engineers study the mechanics of the human body and design biomechanical systems and devices to address musculoskeletal disorders, injuries, and disabilities. They work on projects involving orthopedic implants, prosthetics, rehabilitation equipment, and ergonomic design. Biomechanical engineers collaborate with healthcare professionals, researchers, and patients to develop personalized solutions for mobility and rehabilitation.

Research and Development (R&D) Engineer: R&D engineers work in research laboratories, academic institutions, and industry research centers, conducting research and development activities in biomedical engineering fields. They design experiments, collect and analyze data, and develop prototypes and proof-of-concept devices for medical applications. R&D engineers contribute to advancements in biomedical technology and translation of research findings into clinical practice.

Quality Assurance (QA) Engineer: QA engineers ensure the quality and safety of medical devices and healthcare products throughout the product lifecycle. They develop and implement quality management systems, perform risk assessments, and conduct audits and inspections to ensure compliance with regulatory standards and industry best practices. QA engineers also investigate product complaints and non-conformities and implement corrective and preventive actions to maintain product quality.

Healthcare Technology Consultant: Healthcare technology consultants provide consulting services to healthcare organizations, medical device companies, and government agencies on issues related to healthcare technology management, strategy, and implementation. They assess technology needs, develop technology roadmaps, and recommend solutions to improve patient care, enhance operational efficiency, and reduce healthcare costs.

Product Manager: Product managers oversee the development and commercialization of medical devices and healthcare products, from concept to market launch. They define product requirements, develop product strategies, and collaborate with cross-functional teams to bring products to market on time and within budget. Product managers also conduct market research, analyze competitive landscapes, and identify opportunities for product innovation and differentiation.

Entrepreneur/Startup Founder: Graduates with entrepreneurial ambitions may start their own companies or startups, developing innovative medical devices, healthcare technologies, or digital health solutions. They may identify unmet needs in the healthcare market, secure funding, build teams, and navigate regulatory pathways to bring new products and technologies to market and make a positive impact on patient care and healthcare delivery.


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