why study biomedical engineering essay

Colorado State University

Walter scott, jr. college of engineering.

• College Faculty and Staff Award Recipients
• Departments and Programs
• Engineering at CSU Spur
• Dean’s Office
• Find your way around campus
• Website map
• Scott Undergraduate Research Experience
• SURE Poster Fair & Celebration
• Walter Scott, Jr. Undergraduate Scholarship
• Faculty Directory
• Academic Advising
• Education Abroad
• Engineering Exploration Day: Fall 2024
• Engineering Residential Learning Community
• Undergraduate Programs
• Graduate Programs
• Transfer Students
• Department and unit committees
• Diversity Initiatives
• Engage Diversity Events
• Distinguished Researchers and Honors
• Engineering AI
• Laboratories and Facilities
• Engineering Success Center
• Career Advising
• Career Fair
• Cooperative education program
• Financial aid and Scholarships
• Student Awards and Recognition
• Student Organizations
• College Events Calendar
• Commencement
• Students: Fall 2024 Engineering Exploration Day
• Engineering Days
• On-campus tours and visits
• Faculty and Staff Resources
• Orientation
• Educators: Spring 2025 Engineering Exploration Day
• ENcourage Engineering Math Program
• ENpower Bridge Program
• Summer Programs
• Alumni and Giving

Popular Pages

• Tours and Visits

A Love Letter to Biomedical Engineering: Why I Chose BME

Hello there, reader. My name is Michelle  Hefner  and I am a fourth-year student in Biomedical Engineering and Chemical and Biological Engineering here at CSU .    

The impact of BME

Imagine having the power to make a difference in millions of people’s lives around the world by innovating and advancing the way we as a human rac e approach our most complex problems in human health. Imagine being able to wake up every day and learn from people who believe in and aspire to achieve these same goals as you. Well, that’s kind of how I feel about studying biomedical engineering  here in the Walter Scott, Jr. College of Engineering .    

There are so many incredible topics  to study ,  amazing  professors, and  impressive  researchers in the School of Biomedical Engineering (SBME) that create such a beautiful environment  that exudes  inspiration.  I  won ’t   lie –the  coursework  is not easy–but it  isn’t  as hard to stay motivated and determined to get through and excel in my degree   program  when I know the outcome will be changing people’s lives in ways I cannot even fathom. And  that’s  exactly how I knew I wanted to study something to make an impact  that big  in the world , about 12 years ago.   

There’s a silver lining in every dark cloud

When I was 10 years old, life was pretty sweet. There wasn’t much to worry about besides not being late to basketball practice, filling out my reading log every night for school, and whether or not the kids in my neighborhood could go ride bikes with my sister and me in the evenings– you know, the co olest thing to do before social media was a big deal.

That is until one day  when  I came home from school and my mom  and dad , with a quiet, somber demeanor, sat us down and told us  my mom had gone  to the doctor earlier that day and  had  been diagnosed with thyroid cancer. Yup, the c-word that  scares us all as adults and is all the more confusing to a 10-year-old. 

...one day when I came home from school and my mom and dad, with a quiet, somber demeanor, sat us down and told us my mom had gone to the doctor earlier that day and had been diagnosed with thyroid cancer

At first, I didn’t really understand. Was my mom in pain? Can the doctor fix it? Was she going to die??  I mean what are you supposed to think about a parent being diagnosed with cancer when you’re 10? To be honest, I don’t truly remember my initial reaction, but I  do remember  I  was heart-broken, upset, and very confused.  My mom did everything in her power, though, to make sure that we knew she was going to get through  it ,  and everything was going to be okay. 

Fast forward to my mom going through various  radiation treatments , surgery to remove her  entire  thyroid, and a lot of doctor’s visits , and she finally beat the cancer .   

Witnessing  all of it was  the most difficult thing I had to go through as a kid ,  but it also showed me that a huge part of the reason my mom  was okay in the end was thanks to all the medical technology available. All the diagnostic imaging, surgical tools, treatments, and medications were used seamlessly by the medical professionals and I was so interested in how people invented and built these instruments and tools in the first place. Their ideas and inventions have truly saved so many lives –like my mother’s– while improving the quality of others, and I felt in my heart that that was the kind of impact I wanted to have  on the world  during my lifetime .   

I felt in my heart that that was the kind of impact I wanted to have on the world during my lifetime

“OK Google, what is a biomedical engineer?”

So, no, I didn’t immediately think “I’m going to be a biomedical engineer  now ” when I was 10 years old, but I knew that I wanted to have a career someday where I could  have the opportunity  to  create, research, and even invent  some kind of  medical technology  or medicine in the future.  That feeling of wanting to make a difference  in this way  never  escaped  my mind , and sure enough in high school I felt the same and knew I wanted to prepare for a career like this by going to  a  university .

That feeling of wanting to make a difference in this way never escaped my mind

I thought engineering would be a good place to look for majors  since I enjoyed math and science , but I didn’t know how exactly the medical aspect could be incorporated. So  I reached out to my good friend, the internet, and quite literally googled “types of engineering.” It was there that I found biomedical engineering was something I could major in at a number of universities across the nation.

The rest is history and I enrolled in to  a biomedical engineering degree  program my first year of unive rsity,  although I did not end up at CSU right after high school –but that’s for another blog post. 

Finding my niche

Currently I am in my 4 th  year (out of 5) in the biomedical engineering  and  chemical and biological engineering degree program here in  the Walter Scott, Jr. College of Engineering.  I have taken every opportunity I can to explore my interests  using the different skills I acquire in my coursework,  and  in my third year I  found myself in a laboratory in the College of Health and Human Sciences as an undergraduate researching  computational neuroscience and machine learning techniques for data-driven approaches for understanding aging in the human brai n. I love what I do, and I haven’t looked back since .

For future plans, I hope to further my study and research in computational neuroscience or bioinformatics in graduate school.   Ultimately, I would like to have a professional research career where I can work to improve imaging for diagnosing life-threatening or debilitating diseases   like my mom’s cancer,  except related to aging in the human brain.   

I would like to have a professional research career where I can work to improve imaging for diagnosing life-threatening or debilitating diseases like my mom’s cancer

Advice to young students seeking a degree in biomedical engineering

I know for a fact that my story of how I came to choose to study biomedical engineering is surely different than most, but, in my opinion, that doesn’t mean you have to have some unique moment in which you have a revelation and decide that you want to study biomedical engineering. The discipline itself is so fascinating and fulfilling that I think any reason is a good reason to study and pursue a degree in  biomedical engineering .   

Like all other eng ineering disciplines, through our work we can bring people together, make the world safer, help the world learn, keep people healthy, and keep things running smoothly . At least to me, there is no better reward and that is beautiful.   

Thinking of biomedical engineering? You can see if the program or path is right for you here:  https://www.engr.colostate.edu/sbme/  

Author: Michelle Hefner

Michelle is a fourth-year undergraduate student in the Biomedical Engineering dual-degree program with a partner major of Chemical and Biological Engineering. She enjoys  playing basketball,  ma king her coworkers laugh, leading the Society of Hispanic Professional Engineers student chapter, and listening to a  variety of music.  Michelle has career goals of  pursuing a  Ph.D  and  becoming a research scientist in neural engineering.   

If you have any questions, please feel free to reach out to the engineering ambassador team at [email protected] !

Science | Technology | Engineering | Mathematics

Stem student stories from king's college london, why i chose to study biomedical engineering.

January 24, 2020 Anjali Rajah Biomedical Engineering , Careers , Why I Chose King's 0

While Biomedical Engineering (BME) is a challenging areas of study, I’m really glad I chose this degree!  

I chose to pursue BME because I had always liked both medicine and engineering, and couldn’t choose  between the two when it came to what I wanted to study at university. That’s why when I learned about biomedical engineering, it seemed like the perfect degree for me! Biomedical engineering is about the technical applications of engineering principles in medicine. As we know, medicine is an ever-evolving field. Looking forward, it’s notable that technology is playing an increasingly important role in medicine, which makes biomedical engineering a very practical and in-demand degree to be equipped with.

BME is especially great at King’s, because it is research-i ntensive. The professors in the department are all experts in  a range of research areas  that will surely cover whatever it is you may be interested in. King’s has a rich history of notable researchers, one example being Rosalind Franklin who helped discover the structure of DNA whilst at King’s! It’s exciting to know that you are walking in the footsteps of great legacies. 

In addition, King’s BME students also have access to fantastic state-of-the-art resources at facilities such as St. Thomas’ hospital (which has i ts own MRI and PET facility), that can be used in the later years of the degree. With this degree, you really get to learn first hand  and be involved with all kinds of projects.  

Another reason why BME is so great is that the de gree is quite multidisciplinary , and gives a good foundation in maths , physics, programming, and biology, which gives you plenty of career opportunities! Biomedical engineering graduates from King’s have gone to work in top companies and  organisations in finance, banking, IT, or stayed in the biomedical engineering field as a clinical engineer at a hospital. Some even pursue further education like a medical degree or go into research and academia. So as you can see, the options with a biomedical degree are really endless! 

Find out about careers that you can pursue with a degree in Biomedical Engineering 

Check out Lana’s Global Summer Experiences at King’s

Find out more about King’s  School of Biomedical Engineering & Imaging Sciences

• Biomedical Engineering

Be the first to comment

Leave a reply cancel reply.

Your email address will not be published.

Save my name, email, and website in this browser for the next time I comment.

Copyright © 2024 | WordPress Theme by MH Themes

Home — Essay Samples — Science — Biomedical Engineering — The Impact Of Biomedical Engineering

The Impact of Biomedical Engineering

• Categories: Biomedical Engineering

About this sample

Words: 599 |

Published: Mar 13, 2024

Words: 599 | Page: 1 | 3 min read

Table of contents

Improving patient care, advancing medical technology, shaping the future of healthcare.

Cite this Essay

Let us write you an essay from scratch

• 450+ experts on 30 subjects ready to help
• Custom essay delivered in as few as 3 hours

Get high-quality help

Dr. Heisenberg

Verified writer

• Expert in: Science

+ 120 experts online

By clicking “Check Writers’ Offers”, you agree to our terms of service and privacy policy . We’ll occasionally send you promo and account related email

No need to pay just yet!

Related Essays

3 pages / 1416 words

2 pages / 817 words

3 pages / 1570 words

2 pages / 1123 words

Remember! This is just a sample.

You can get your custom paper by one of our expert writers.

121 writers online

Still can’t find what you need?

Browse our vast selection of original essay samples, each expertly formatted and styled

Related Essays on Biomedical Engineering

Animal cell research has been at the forefront of biomedical science for decades, unraveling the secrets of life at its most fundamental level. This essay explores the profound significance of animal cell research in advancing [...]

I am writing this letter with a strong will to apply for the PhD position in UMC university. The reasons that motivated me to choose this program is, due to both the educational quality of Dutch institutions and the cultural [...]

Growing up, I always had the desire of becoming a doctor. But, during my undergraduate application in 2010 to Jordan University of Science and Technology (JUST), I got introduces to the Medical Laboratory profession. I found out [...]

Ava Jones is a four-year old girl who is in severe renal failure. Severe renal failure results in the gradual decrease of the kidney’s functioning, and leads to the inability to filter waste from the blood (Johns, 2018). Ava’s [...]

Most of The tumors have markers in blood and serum which can be monitored . An electrochemical immunosensor is special device applied for tracking of some diseases, in which a sandwich immunoreaction is commonly applied on an [...]

The hydro plants require less starting time and take a load in a very short time as compared to thermal plants which take several time to make the boilers, superheater and turbine system ready to take the load. Hydro plants have [...]

Related Topics

By clicking “Send”, you agree to our Terms of service and Privacy statement . We will occasionally send you account related emails.

Where do you want us to send this sample?

By clicking “Continue”, you agree to our terms of service and privacy policy.

Be careful. This essay is not unique

This essay was donated by a student and is likely to have been used and submitted before

Download this Sample

Free samples may contain mistakes and not unique parts

Sorry, we could not paraphrase this essay. Our professional writers can rewrite it and get you a unique paper.

Please check your inbox.

We can write you a custom essay that will follow your exact instructions and meet the deadlines. Let's fix your grades together!

Get Your Personalized Essay in 3 Hours or Less!

We use cookies to personalyze your web-site experience. By continuing we’ll assume you board with our cookie policy .

• Instructions Followed To The Letter
• Deadlines Met At Every Stage
• Unique And Plagiarism Free

Calculate for all schools

Your chance of acceptance, your chancing factors, extracurriculars, writing a biomedical engineering essay - need ideas.

Hey, I'm currently a high school junior and I'm working on an essay about why I want to major in biomedical engineering. Could you guys give me some inspiration or key points that I should include in my essay to make it stand out? Thanks!

Hey! Biomedical engineering is a fascinating field, and I'm glad to see you're interested in it. To make your essay stand out, consider focusing on a few key aspects:

1. Personal Connection: Explain how your own experiences or interests have led you to pursue a biomedical engineering major. This could be a family member's health issue, a personal passion for healthcare, or an inspiring experience like an internship or biomedical-related project you've completed.

2. Specific Applications: Discuss some niche areas within biomedical engineering that you're particularly interested in, such as prosthetics, tissue engineering, or medical imaging. Connecting these applications to real-world problems or innovations can help demonstrate your knowledge of the field and your eagerness to contribute to its growth.

3. Unique Perspective: How do you plan to make a difference in the world of biomedical engineering? Explain why your experiences, values, and goals could help you develop unique solutions to complex biomedical challenges. This may involve discussing an interdisciplinary approach, connecting biomedical engineering with other fields, or exploring ethical considerations within the industry.

4. Research Opportunities: Mention some specific research projects or faculty members at the college/university you're applying to that you'd like to work with. This shows genuine interest in their program and demonstrates that you've done your research on the opportunities available for biomedical engineering majors at that institution.

5. Future Goals: Discuss your long-term goals, such as pursuing advanced degrees, starting a biomedical engineering company, or conducting groundbreaking research in a particular area. Having a clear vision of your future in the field can leave a strong impression on the admissions officers.

To learn more about writing a "Why this Major" essay, read this blog post: https://blog.collegevine.com/why-this-major-college-essay/

Remember to be authentic and focus on the aspects that genuinely reflect your passion and motivation for biomedical engineering. Good luck with your essay!

About CollegeVine’s Expert FAQ

CollegeVine’s Q&A seeks to offer informed perspectives on commonly asked admissions questions. Every answer is refined and validated by our team of admissions experts to ensure it resonates with trusted knowledge in the field.

Essay on Biomedical Engineering

Students are often asked to write an essay on Biomedical Engineering in their schools and colleges. And if you’re also looking for the same, we have created 100-word, 250-word, and 500-word essays on the topic.

Let’s take a look…

100 Words Essay on Biomedical Engineering

Understanding biomedical engineering.

Biomedical engineering is a special branch of engineering. It combines the principles of both medicine and engineering. The main goal of this field is to create and improve medical equipment and devices. This helps doctors diagnose and treat diseases more effectively.

Role of Biomedical Engineers

Biomedical engineers work on creating new medical devices. These can be artificial organs, prosthetics, or even machines for medical testing. They also repair and maintain medical equipment. In addition, they play a vital role in researching and developing new medical treatments.

Importance of Biomedical Engineering

Biomedical engineering is very important in modern medicine. It helps in creating advanced tools and technologies. These advancements make it easier to diagnose and treat different diseases. This field has a great impact on improving the quality of healthcare.

Future of Biomedical Engineering

The future of biomedical engineering is very promising. With the rapid advancements in technology, this field is expected to grow even more. It will continue to bring new and improved medical devices and treatments. This will greatly benefit the medical field and patients.

250 Words Essay on Biomedical Engineering

What is biomedical engineering, work of biomedical engineers.

Biomedical engineers design medical equipment. This can be anything from tiny devices like pacemakers to large machines like MRI scanners. They also create software to run these machines. Sometimes, they even design artificial body parts like knees or hips.

Biomedical engineering is very important in the medical field. It helps to make treatments safer and more effective. For example, a biomedical engineer might design a new kind of heart monitor. This monitor could help doctors keep a closer eye on their patients.

Education for Biomedical Engineers

To become a biomedical engineer, you need to study a lot. First, you need to finish high school with good grades in science and math. Then, you need to go to college. There, you will study subjects like biology, chemistry, and physics. You will also learn about engineering principles.

In conclusion, biomedical engineering is a fascinating field. It combines science, medicine, and engineering to improve healthcare. It’s a challenging career, but also very rewarding. If you love science and want to help people, biomedical engineering could be a great choice for you.

500 Words Essay on Biomedical Engineering

Biomedical Engineering is a special type of engineering. It combines biology and medicine with engineering principles. The main goal of this field is to create solutions for many health problems. It’s all about improving patient care, including diagnosis, monitoring, and therapy. Biomedical engineers use their skills in both engineering and the medical sciences.

The Role of Biomedical Engineers

Specializations in biomedical engineering.

There are many special areas in biomedical engineering. Some engineers focus on creating better medical imaging machines. These machines help doctors see inside the body without needing to do surgery. Other engineers work on biomaterials. These are materials made for use in the body. They can be used to replace parts of the body, like bones or organs.

Another important area is tissue engineering. This is about creating new tissues or organs in the lab. This could help people who need organ transplants. Biomedical engineers also work on genetic engineering. They study and change the genes in our bodies to help cure diseases.

Biomedical engineering also helps us understand our bodies better. By studying how our bodies work, engineers can come up with new ways to help us stay healthy or to treat diseases.

The future of biomedical engineering looks very exciting. Engineers are working on many new projects. They are trying to make better medical devices and treatments. They are also working on ways to grow organs in the lab. This could help many people who need organ transplants.

If you’re looking for more, here are essays on other interesting topics:

Apart from these, you can look at all the essays by clicking here .

Leave a Reply Cancel reply

Save my name, email, and website in this browser for the next time I comment.

• Whiting School of Engineering
• Johns Hopkins School of Medicine

• Johns Hopkins Biomedical Engineering
• Prospective Students

What is BME?

Biomedical engineering (BME) is an interdisciplinary field that bridges engineering, math, and physics with biology and the life sciences. Biomedical engineers apply their expertise in these areas to solve problems related to medicine and healthcare, developing new technologies to understand, diagnose, and treat disease. Biomedical engineering is a broad and growing field that encompasses everything from surgical robotics and prosthetics to drug delivery systems and artificial organs.

Hopkins BME offers a variety of focus areas that have immense potential to impact patient lives, such as Biomedical Data Science, Computational Medicine, Genomics & Systems Biology, Imaging & Medical Devices, Immunoengineering, Neuroengineering, and Translational Cell & Tissue Engineering.

Natalia Trayanova – Pioneering Cardiovascular Engineering

Warren Grayson – Pioneering Musculoskeletal Regeneration

Read the Johns Hopkins University privacy statement here .

• Skip to main content
• All Articles
• Study abroad info Articles
• Study abroad info Subject guides

• Choosing where to study
• Applying to a university
• Financing your studies
• Getting your visa
• Before you leave
• Housing & accommodation
• Once you arrive
• Post-study life

Why study biomedical engineering at degree level?

Why study Biomedical engineering? We explore the reasons to take this interesting field of study to a degree level.

Biomedical engineering , also known as bioengineering, biomed or BME, refers to the field of study that merges biology and engineering. This unique field that incorporates various fields of study allows you to cover a wider range of subjects, where you use the in-depth understanding that you have of engineering to solve medical and biological problems.

With technology advancing at such a rapid pace, it is no wonder that developments in science and engineering are being integrated into the medical sector. This integration has given rise to the field of biomedical engineering and as a result, created biomedical engineering jobs.

Prominent breakthroughs in the biomedical engineering field include life-saving and life-changing technology such as artificial organs, prosthetics, surgical devices, pacemakers, EEGs, regenerative tissue growth, pharmaceutical drugs, kidney dialysis. Some of the earlier inventions that you know about today include crutches, dentures and platform shoes.e.

Biomedical engineering explained

In short, it is the application of engineering principles to medicine and biology. Biomedical engineering bridges the gap between engineering and medicine, combining the design and problem-solving skills of engineering with medical and biological sciences in order to improve healthcare diagnosis, monitoring and therapy.

What are the kinds of sub-disciplines within biomedical engineering?

There are many sub-disciplines within this field, these include:

Biomedical electronics

Biomechatronics

Bioinstrumentation

Biomaterials

Biomechanics

Computational biology

Cellular, tissue and genetic engineering

Clinical engineering

Medical imaging

Orthopaedic bioengineering

Rehabilitation engineering

System physiology

Bionanotechnology

Neural engineering

Types of skills needed

Below are some of the skills needed when pursuing a degree in bioengineering:

Analytical skills- Biomedical engineers are expected to analyse and understand the needs of patients and customers to design appropriate solutions.

Creativity- Occasionally, thinking outside of the box or beyond normal convention is required so that you can come up with novel and integrative advances in healthcare equipment and devices.

Communication skills- You will sometimes work with patients and often with other teams , you will need to be able to express thoughts clearly. Look at the ideas from others and incorporate those into the problem-solving process.

Mathematic skills- Biomedical engineers need to utilise principles of calculus and other advanced mathematics techniques (this includes statistics) for analysis, design and troubleshooting your work.

Problem-solving skills- You will typically deal and solve problems in complex biological systems, so what might work for one issue might lead to a side effect that will cause problems for the patient.

What kind of qualifications are required?

Image copyright: American Institute for Medical and Biological Engineering

Biomedical engineers typically have a Master’s (M.S., M.S.E., or M.Eng.) or a Doctorate (Ph.D.) in BME (biomedical engineering). Many universities offer undergraduate (B.S., B.Eng or B.S.E.) programmes in biomedical engineering to help students realise their dream of becoming a bioengineer. Employers also look for good communication skills in candidates as bioengineers provide a link among professionals with medical, technical and other backgrounds.

Is bioengineering the right major for you?

Are you interested in making a difference and helping improve the lives of millions of people? As a bioengineer, you are given the incredible opportunity to create life-changing and even life-saving devices.

Internship opportunities

Quite a lot of universities today provide plenty of internship opportunities for their biomedical engineering students. For example, the University of Illinois at Urbana-Champaign encourages their students to take up research projects either during their holidays or during their course. You can even opt to do a semester abroad to develop a broader understanding of the subject and how it is applied and taught in other parts of the world.

Students can speak to  their university, who will help pair them up with suitable researchers. Meanwhile, the University of Pittsburgh collaborates with Human Engineering Research Laboratories to provide placements for their students so that they can gain valuable industry experience. Alternatively, you could also opt to seek independent internships on your own. Medical companies and government agencies such as the National Institute of Biomedical Imaging and Bioengineering in the US are constantly on the lookout for interns.

To find out more information regarding the kinds of internship programmes that universities or colleges have, you can contact them directly. We advise students to complete at least one internship or placement during the course of your study to better your chances at being hired when you enter the highly competitive job market. Internships and placements provide you with the perfect platform to network with industry experts and see how bioengineering is applied in a real-world setting. Who knows, your internship might turn into a full-time job once you graduate!

Career paths

As you can probably guess, something this important is highly sought-after, biomedical engineers are employed in top pharmaceutical companies, hospitals, research facilities, government agencies, universities and many more.  Biomedical engineering jobs can include performance testing of new or proposed products, teaching and research, becoming technical advisors or inventing a new machine for medical purposes and so on. This field is still evolving, and you never know what sort of doors will be open once you graduate!

Here are some of the industries/places that need your expertise:

Manufacturing.

Universities.

Private or government funded research facilities (you are normally required to have a PhD for positions here).

Education and medical institutions.

Some of the interesting things that you can do:

Design equipment, devices and machines.

Install, adjust, maintain and repair biomedical equipment.

Evaluate the quality, safety, efficiency and effectiveness of biomedical equipment.

Train clinicians and other hospital staff the proper use of complex biomedical equipment.

Work with chemists, life and medical scientists to research engineering aspects of human and animal biological systems.

Formulate procedures, write technical reports, publish research papers and make recommendations based on your research results.

Present these results to both the scientific and non-scientific communities.

Some of the senior posts in the private industry include:

Management marketing.

Product manager.

Quality assurance consultant.

Technical advisor.

Your options aren’t just limited to the bioengineering field. You can choose to obtain a graduate degree to lead a research team or take a law degree to become a patent attorney. Alternatively, you could opt to pursue a master’s degree in business administration (MBA) and move into more lucrative managerial positions.

Bioengineers are in demand

With the world’s population ageing and a low birth rate in developed countries, bioengineers are best equipped to meet these rising demands. Bioengineers are needed to drive rapid innovations in medical technologies, such as 3-D printing and micro-electro-mechanical systems (MEMS). Many countries are seeing an increase in the demand for bioengineers.

In Australia for instance, several biomedical giants have set up shop in the country, such as Cochlear (a company that develops cochlear implants), Resmed (a company that creates devices to treat sleep apnea) and Ventracor (as the name suggests, develops artificial hearts). Meanwhile in the UK, numerous state-of-the-art research facilities have been created, including institutes of biomedical engineering at both Imperial College London and the University of Oxford .

Specialisations in biomedical engineering

Bioinstrumentation- this area uses electronics and computer science to create devices that are used to diagnose and treat diseases

Biomaterials - you will look at natural or laboratory-designed materials that are used in medical devices or as implantation materials such as stitches that dissolve on their own etc

Biomechanics - this is the study of mechanics, for instance, thermodynamics and its application/impact on solving biological and/or medical problems

Clinical Engineering - as the name states, you will apply medical technology to improve and optimise healthcare delivery

Rehabilitation engineering - similarly, with this specialisation, you will study engineering and computer science with the sole purpose of inventing devices that can help individuals with physical and cognitive impairments

Systems physiology- here, you will be taught how to use engineering tools to understand how systems within living organisms (for example- bacteria, animals and humans) function and respond to changes in their environment

Average pay for biomedical engineers

According to the U.S Bureau of Labour Statistics report in 2018, the median income for bioengineers is USD 88,550. To give you a more accurate picture, the top 10 per cent of earners draw a little over USD 144,350.

Find out more  on biomedical engineering degree programmes at undergraduate level. 

Have a look...

• Related courses are available in 1638 universities

The top benefits of becoming a lawyer

Studying law and becoming a lawyer remains a respected and sought-after path and profession for international students. Law is one of the oldest academic fields and has attracted many famous names, including Nelson Mandela, Barack Obama, and Benazir Bhutto. Motivations for studying law may differ. For some, it is a calling to uphold justice, while for others, it is to protect human and environmental rights. What law does provide is the potential to make a difference

What is a pre-masters course?

If you have had your eye on studying a postgraduate qualification, and particularly a master’s degree you would have encountered pre-master’s programmes in your research. Sometimes it’s not always easy to understand the differences between the qualifications and courses on offer and why you would apply or enrol for a pre-master’s programme. We take a closer look at pre-master’s courses and programmes, demystifying the details.     What is a

What course should I take at university?

Feeling lost about which university course you should choose for your study abroad journey? We feel you. Picking the wrong course can be costly and time-consuming if you end up having to switch, so it's crucial to weigh your options carefully to ensure you don't regret your decision.   To give you a hand in selecting a subject that's right for you, we have compiled a list of factors to consider, coupled with insights from our experts. Read

MA vs MSc: What is the best choice?

If you’ve been considering studying for a master’s degree, you would likely have come across a few different options. This can initially seem confusing. You may think that the degrees are pretty much the same. However, there are some key differences between two of the most popular master’s qualifications, namely an MA and an MSc. In this article, we explain what these degrees are, what it takes to study them and what careers they can lead to.    

Get in touch

• Master of Engineering
• MS in Biomedical Engineering
• MS in Mechanical Engineering
• MS in Systems & Control Engineering
• State Authorization
• Technology Requirements
• Tuition and Financial Aid
• Class Profile
• Online Experience

How Important Is Biomedical Engineering Today?

With expertise spanning physiology, biology, healthcare and health informatics, mechanics, and engineering, biomedical engineers can combine their diverse skills to create solutions to continuing worldwide health issues, helping to change how patients are treated and lowering the cost of care.

As our population lives longer, the demand for biomedical devices and procedures is expected to grow. 1 Driven by access to by-the-minute news, the tech-savvy public is more aware of breakthroughs in medical technology and advancements than ever before.

Because of this awareness, more and more people will continue to seek out biomedical solutions to their complex health concerns, each time expecting a newer, more convenient and more advanced means of treatment. 1

With technology advancing and the demand for cutting-edge medical equipment and devices expanding, biomedical engineering, sometimes called bioengineering, is a rapidly growing field. From 2014 to 2024, employment for biomedical engineers is projected to grow a staggering 23 percent, growing more than three times faster than other careers. 2

In our video below, professor Dominique Durand , program director of the online Master of Science in Biomedical Engineering program at Case Western Reserve University, explains how critically important biomedical engineering is to healthcare and the medical community today. As one of the best biomedical engineering schools in the United States, Case Western Reserve University strives to use our partnerships in the industry to research and develop innovative solutions to serious health concerns , helping to improve how doctors diagnose and treat patients.

The invaluable role of perspective and curiosity in engineering is immeasurable. All good engineers know to question what they believe and to push the limits in their studies and theories until they’re groundbreaking. Our researchers, professors and students are trying to find innovative solutions by asking questions, such as:

• Would better communication with nervous systems potentially improve recovery results for patients with epilepsy and paralysis?
• Could we utilize an interactive, anatomically correct holographic rendering of the body and its organs to help medical students and practicing physicians learn or improve surgical practices?
• How can we make life safer for active firefighters ?
• Can we better protect our athletes with a digital concussion monitoring system ?

And these are just some of the innovative research questions Case Western Reserve's Department of Biomedical Engineering is asking. Imagine what you could do if you studied at CWRU and joined such a game-changing field. Now that you know how important the field is, learn more about the importance of a master’s degree in biomedical engineering .

• Retrieved on August 23, 2017, from www.bls.gov/ooh/architecture-and-engineering/biomedical-engineers.htm#tab-6
• Retrieved on August 23, 2017, from www.bls.gov/ooh/architecture-and-engineering/biomedical-engineers.htm

Return to Online Engineering Blog

Complete the form below before proceeding to the application portal.

Case Western Reserve University has engaged Everspring , a leading provider of education and technology services, to support select aspects of program delivery.

What are your chances of acceptance?

Calculate for all schools, your chance of acceptance.

Your chancing factors

Extracurriculars.

A 200+ Word “Why Major” Essay Example and Analysis

This article was written based on the information and opinions presented by Hale Jaeger in a CollegeVine livestream. You can watch the full livestream for more info.

What’s Covered:

250 word essay example, start with an anecdote, but avoid cliches, include smooth transitions and be specific, do your research and avoid overusing phrases, be concise and emphasize school fit.

In this article, we will focus on a prompt from Duke University that is specific to the Pratt School of Engineering.

If you are applying to the Pratt School of Engineering as a first year applicant, please discuss why you want to study engineering and why you would like to study at Duke. (250 words).  

As opposed to a 100 word essay, 250 words gives you a little more space to write about your interests. Another thing to note about this prompt is that it is asking two questions: “why do you want to study at this school in particular?” and “why do you want to study engineering?” 

The extra words give you enough room to talk about the type of engineering you’re interested in, Duke specific resources, and how you grew your interest in engineering over time.  Here we will go through an example of a response to this prompt. Then for each paragraph, we’ll analyze what the essay does well and where it could be improved.

“One Christmas morning when I was nine, I opened a snap circuit set for my grandmother. Although I had always loved math and science. I didn’t realize my passion for engineering until I spent the rest of winter break creating different circuits to power various lights, alarms, and sensors. Even after I outgrew the toy, I kept the set in my bedroom at home and knew I wanted to study engineering.

Later in high school biology class, I learned that engineering didn’t only apply to circuits, but also to medical devices that could improve people’s quality of life. Biomedical engineering allows me to pursue my academic passions and help people at the same time. Just as biology and engineering interact in biomedical engineering, I am fascinated by interdisciplinary research in my chosen career path. 

Duke offers unmatched resources, such as DuHatch and The Foundry, that will enrich my engineering education and help me practice creative problem-solving skills. The emphasis on entrepreneurship within these resources will also help me to make a helpful product. Duke’s Bass Connections program also interests me; I firmly believe that the most creative and necessary problem solving comes by bringing people together from different backgrounds.

Through this program, I can use my engineering education to solve complicated societal problems, such as creating sustainable surgical tools for low income countries. Along the way I can learn alongside experts in the field. Duke’s openness and collaborative culture span across its academic disciplines, making Duke the best place for me to grow both as an engineer and as a social advocate.” 

“One Christmas morning when I was nine, I opened a snap circuit set for my grandmother. Although I had always loved math and science. I didn’t realize my passion for engineering until I spent the rest of winter break creating different circuits to power various lights, alarms, and sensors. Even after I outgrew the toy, I kept the set in my bedroom at home and knew I wanted to study engineering.”

This first paragraph does something excellent, which is it starts with an anecdote. In the introductory anecdote, the author mentions specific things like alarms, lights, and sensors, so the reader can really visualize what’s happening. 

Another strength of this excerpt is that the anecdote moves through time very quickly. It starts with Christmas morning, progresses to the rest of winter break, and then finally ends by discussing after the author outgrew the toy. That temporal growth is good because it gets a reader in and out of the anecdote quickly while feeling nostalgic. It makes the reader feel connected to the writer.

One weakness of this paragraph, however, is that the last line is a little too much; it hits you over the head with “I want to study engineering.” Admissions officers know that one experience from when you were nine years old may be too much to ascribe your passion for engineering to, so this doesn’t feel believable. Instead, this instance can be framed as a spark that ignited your passion for engineering or made you interested in learning more about engineering.

“Later in high school biology class, I learned that engineering didn’t only apply to circuits, but also to medical devices that could improve people’s quality of life. Biomedical engineering allows me to pursue my academic passions and help people at the same time. Just as biology and engineering interact in biomedical engineering, I am fascinated by interdisciplinary research in my chosen career path.” 

This paragraph does a really good job of transitioning from the anecdote to the writer’s specific and current interest in biomedical engineering. However, there are a few drawbacks from this excerpt. 

One weakness from this paragraph is that helping people is a trope that is really overused when talking about an interest in health and healthcare. You can help people in a variety of careers, so it is a bit naive to say that the only way you can help others is by pursuing a particular path. Instead, you want to make the essay sound more genuine by displaying the heart of your passion. What particular types of medical devices and interdisciplinary research is the student interested in? Which intersection of fields is the most interesting to them and why? Giving more details or even specific adjectives here would help the essay sound more informed and robust.

Another aspect of this essay that could be improved is that the author mentions their ideal career path but doesn’t elaborate on this beyond biomedical engineering as a field of study. There are many different paths you can take after studying biomedical engineering. You could go into the research and development of products, or medicine, or the research behind patient-facing studies. What about your ideal career makes you excited to pursue that given field or major?

”Duke offers unmatched resources, such as DuHatch and The Foundry, that will enrich my engineering education and help me practice creative problem-solving skills. The emphasis on entrepreneurship within these resources will also help me to make a helpful product. Duke’s Bass Connections program also interests me; I firmly believe that the most creative and necessary problem solving comes by bringing people together from different backgrounds.”

This paragraph takes on the question in the second part of the prompt by explaining explicitly why they want to study biomedical engineering at Duke. One thing this essay does very well is that it brings up Duke specific resources and opportunities – DuHatch, The Foundry, and Bass Connections. They also mention the spirit of entrepreneurship that is ingrained in the teaching at Duke and how this is important to the design process in engineering. By connecting to Duke’s academic philosophy, this shows the admissions officers that this student not only did their research but also shares values with the school itself. 

One of this paragraph’s weaknesses, however, is that the student mentions that “Duke offers unmatched resources, which is quite cliche and generic. Duke already knows that they are well regarded in the engineering field, so this is a waste of words in this essay. 

Another aspect of the essay that could be improved here is the vague and undeveloped idea of creative problem solving skills that would be honed by attending Duke. The author uses the phrase “problem solving” a couple of times and wastes some space on two transition sentences. Overusing this phrase detracts from the power of the language and weakens the general cadence of your essay.

“Through this program, I can use my engineering education to solve complicated societal problems, such as creating sustainable surgical tools for low income countries. Along the way I can learn alongside experts in the field. Duke’s openness and collaborative culture span across its academic disciplines, making Duke the best place for me to grow both as an engineer and as a social advocate.” 

This final paragraph is a strong conclusion because it is succinct and ties together all of the previous paragraphs. It makes the essay feel complete by the time the reader reaches the end. Combining engineering and social advocacy is also a great thought. It is in line with the rest of the essay and shows that this student is person-minded and not machine-minded. It demonstrates a dedication to community, which is something that Duke values as well.

However, if the author had incorporated these ideas of social advocacy earlier in the essay, this would have emphasized their fit with Duke and made the essay even stronger. Additionally, the specific idea of creating sustainable surgical tools for low income countries is very unique and would have been more powerful if it had been mentioned earlier; here it simply feels like an afterthought.

The conclusion also includes awkward wording in some of the phrases like “Duke’s openness and collaborative culture,” which could be reworded as “Duke’s open and collaborative culture.” By reducing some of the awkward phrasing, the author would have had some more space to play around with their specific interests in biomedical engineering and Duke’s programs.

Is Your “Why Major” Essay Strong Enough?

Essays account for around 25% of your admissions decision, as they’re your chance to humanize your application and set yourself apart from other applicants with strong profiles. 

The “Why Major” essay is especially important, as it allows you to reflect on your unique interests and fit with the school. Your supplement needs to demonstrate your interest in the major and paint a picture of how you’ll contribute to their program.

To understand if your essay is strong enough, we recommend using our Peer Essay Review tool , where you can get a free review of your essay from another student. You can also improve your own writing skills by reviewing other students’ essays. This tool will make it easier to understand your essay’s strengths and weaknesses, and help you make your writing even more compelling.

Related CollegeVine Blog Posts

An official website of the United States government

The .gov means it’s official. Federal government websites often end in .gov or .mil. Before sharing sensitive information, make sure you’re on a federal government site.

The site is secure. The https:// ensures that you are connecting to the official website and that any information you provide is encrypted and transmitted securely.

• Publications
• Account settings

Preview improvements coming to the PMC website in October 2024. Learn More or Try it out now .

• Advanced Search
• Journal List
• BMC Biomed Eng

BMC Biomedical Engineering: a home for all biomedical engineering research

Alexandros houssein.

1 Springer Nature, 4 Crinan Street, London, N1 9XW UK

Alan Kawarai Lefor

2 Department of Surgery, Jichi Medical University, Shimotsuke, Tochigi Japan

Antonio Veloso

3 Laboratory of Biomechanics and Functional Morphology, Faculty of Human Kinetics, Lisbon, Portugal

4 Department of Biomedical Engineering, University of Minnesota, Minneapolis, MN USA

Jong Chul Ye

5 Department of Bio and Brain Engineering, Korea Advanced Institute of Science and Technology, Daejeon, Republic of Korea

Dimitrios I. Zeugolis

6 Regenerative, Modular and Developmental Engineering Laboratory (REMODEL), Biomedical Sciences Building, National University of Ireland Galway (NUI Galway), Galway, Ireland

Sang Yup Lee

7 Department of Chemical and Biomolecular Engineering, Korea Advanced Institute of Science and Technology, Daejeon, Republic of Korea

Associated Data

Not applicable.

This editorial accompanies the launch of BMC Biomedical Engineering , a new open access, peer-reviewed journal within the BMC series, which seeks to publish articles on all aspects of biomedical engineering. As one of the first engineering journals within the BMC series portfolio, it will support and complement existing biomedical communities, but at the same time, it will provide an open access home for engineering research. By publishing original research, methodology, database, software and review articles, BMC Biomedical Engineering will disseminate quality research, with a focus on studies that further the understanding of human disease and that contribute towards the improvement of human health.

Introduction

Biomedical engineering is a multidisciplinary field that integrates principles from engineering, physical sciences, mathematics and informatics for the study of biology and medicine, with the ultimate goal of improving human health and quality of life.

Biomedical engineering is not a new concept; however, it was not until the 1900s when rapid technological advancements in the chemical, physical and life sciences influenced breakthroughs in the prevention, diagnosis and treatment of disease. The invention of the electrocardiograph, the concept of x-ray imaging, the electron microscope, the mechanical heart valve and human genome sequencing, are just a few examples of technological innovations that revolutionised science and medicine and changed the approach to human healthcare. Current biomedical engineering technologies are a growing part of clinical decision making, which can now be influenced from multiscale observations, ranging from the nano to the macro-scale.

Today, the need for innovation in health technologies is ever more prominent. The annual global healthcare spending has seen continued growth and is projected to reach a staggering $8.7 trillion by 2020 [ 1 ]. Global health challenges are becoming more complex, wide spread and difficult to control. Resources are scarce and with a growing population, our society has a need for affordable, portable and sustainable solutions. The World Health Organisation has pledged to make a billion lives healthier by 2023 [ 2 ], a goal that will require widespread commitment by governments, funding agencies, researchers and clinicians. Biomedical engineers will be at the heart of this movement and face a responsibility for continuous innovation. Biomedical engineering research is expected to create health technologies that will drastically improve the prevention, diagnosis and treatment of disease, as well as patient rehabilitation. As an example, the NIH 2016–2020 strategic plan focuses on point of care and precision medicine technologies including genetic engineering, microfluidics, nanomedicine, imaging, digital/mobile-Health and big data [ 3 ].

BMC Biomedical Engineering will strive to complement these efforts and provide an open access venue for the dissemination of all biomedical engineering research. As part of the BMC series, a portfolio of journals serving communities across all sciences, the Journal will act as a resource for a wide range of disciplines. It aims to support scientists, engineers and clinicians by making their research openly and permanently available, irrespective of their location or affiliation.

Aims and scope

BMC Biomedical Engineering considers articles on all aspects of biomedical engineering, including fundamental, translational and clinical research. It combines tools and methods from biology and medicine with mathematics, physical sciences and engineering towards the understanding of human biology and disease and the improvement of human health. The Journal will publish a range of article types, including research, methodology, software, database and review articles.

As part of the BMC series, a collection of open access, peer-reviewed and community focused journals covering all areas of science, editorial decisions will not be made on the basis of the interest of a study or its likely impact. Studies must be scientifically valid. For research articles this includes a scientifically sound research question, the use of suitable methods and analysis, and following community-agreed standards relevant to the research field.

BMC Biomedical Engineering aims to publish work that undergoes a thorough peer review process by appropriate peer-reviewers and is deemed to be a coherent and valid addition to the scientific knowledge. It aims to provide an open access venue which allows for immediate and effective dissemination of research and enables our readers to explore and understand the latest developments, trends and practices in biomedical engineering. We believe that open access and the Creative Commons Attribution License [ 4 ] are essential to this, allowing universal and free access to all articles published in the Journal and allowing them to be read and the data re-used without restrictions. BMC Biomedical Engineering will work closely with the rest of the journals in the BMC series portfolio [ 5 ] to help authors find the right home for their research. We will highlight selected journal content through various promotional channels to ensure the research reaches its target audience and receives the attention it deserves.

Editorial sections

Many new technologies that have revolutionised biomedical engineering require the coalition of previously independent communities. 3D bioprinting of tissues and organs brings together methods from cell biology, biomaterials, nanotechnology and engineering and is being used for the transplantation of tissues, including skin, bone, muscle, soft tissue, cartilage and others [ 6 , 7 ]. The concept of tissue and disease modelling is being driven towards drug discovery and toxicology studies, aiming to increase the yield of drug testing by tackling limitations of current cell and animal models [ 8 ].

New approaches in natural and synthetic biomaterials have redefined bioelectronics. Silk fibroins and other unconventional interfaces can form flexible electronics and challenge the use of silicon-based technologies. For biomedical applications, these new approaches present advantages not only due to their biocompatibility and low cost, but also for their electromechanical and optical virtues [ 9 ]. Implantable probes are being redesigned so that they facilitate long term stability and high resolution, without perturbing the biological system or creating an immune response. Such technologies are now able to facilitate recordings of single neurons in vivo, in a chronically stable manner, with applications to the restoration of vision and retinal prosthetics [ 10 ].

For many years biomedical imaging has been connecting microscopic discoveries with macroscopic observations. Photoacoustic tomography (PAT) is now able to image large spatial scales, from organelles to small animals, at very high speeds [ 11 ]. In fact, single-shot real-time imaging can operate at 10 trillion frames per second and is finding applications in breast cancer diagnosis [ 12 , 13 ].

In the field of medical robotics, new approaches combine machine learning and artificial intelligence to strengthen the clinician’s decision making. Others are leveraging augmented reality (AR) to facilitate better immersion and more natural surgical workflows for computer assisted orthopaedic surgery [ 14 ].

BMC Biomedical Engineering celebrates the interdisciplinary nature of the field. In order to navigate the wide range of biomedical engineering research, the Journal is structured in six editorial sections.

• Biomaterials, nanomedicine and tissue engineering
• Medical technologies, robotics and rehabilitation engineering
• Biosensors and bioelectronics
• Computational and systems biology
• Biomechanics
• Biomedical Imaging

We are delighted to welcome our founding Section Editors along with a growing international group of Editorial board Members [ 15 , 16 ]. The Journal is supported by an expert Editorial Advisory group of senior engineers and scientists, which is chaired by Distinguished Professor Sang Yup Lee. Together with the in-house Editor, this group will provide academic leadership and expertise and will work together to transverse into multiple clinical and engineering disciplines. The Editorial Board will keep growing and developing to reflect and adapt to the nature of this diverse community.

Biomaterials, nanomedicine and tissue engineering section

This section primarily focuses on the development of biofunctional tissue substitutes, which possess the highest level of biomimicry, through recapitulation of nature’s innate sophistication and thorough processes. It considers research, methods, clinical trials, leading opinion and review articles on the development, characterisation and application of nano- and micro- biofunctional biomaterials, cell-assembled tissue substitutes, diagnostic tools, microfluidic devices and drug/gene discovery and delivery methods. Manuscripts focusing on permanently differentiated, engineered and stem cell biology and application are welcome. This section will place a substantial focus on clinical translation and technologies that advance the current status-quo. As such, articles that enhance the scalability and robustness of tissue engineering methodologies, or that enable new and improved industrial or clinical applications of biomedical engineering discoveries, tools and technologies are strongly encouraged.

Medical technologies, robotics and rehabilitation engineering section

This section seeks to represent research in engineering that encompasses a wide range of interests across medical specialties, including orthopaedic, cardiovascular, musculoskeletal, craniofacial, neurological, urologic and other medical technologies. It will consider research on medical robotics, computer assisted technologies, medical devices, e/m-health and other medical instrumentation. It aims to improve the prevention, diagnosis, intervention and treatment of injury or disease and it welcomes articles that represent new approaches to engineering that may be useful in the care of patients. Technical and practical aspects of rehabilitation engineering, from concept to clinic and papers on improving the quality of life of patients with a disability are encouraged. The section also seeks to represent clinically important research that is based on new and emerging technologies. This could include clinical studies of new approaches to robotic-assisted surgery, clinical studies of new devices, or other studies that are close to patient care or rehabilitation.

Biosensors and bioelectronics section

This section considers articles on the theory, design, development and application on all aspects of biosensing and bioelectronics technologies. The section will consider approaches that combine biology and medicine with sensing and circuits and systems technologies on a wide variety of subjects, including lab-on-chips, microfluidic devices, biosensor interfaces, DNA chips and bioinstrumentation. It also considers articles on the development of computational algorithms (such as deep learning, reinforcement learning, etc.) that interpret the acquired signals, hardware acceleration and implementation of the algorithms, brain-inspired or brain-like computational schemes, and bioelectronics technologies that can have a wide impact in the research and clinical community. Articles on implantable and wearable electronics, low-power, wireless and miniaturised imaging systems, organic semiconductors, smart sensors and neuromorphic circuits and systems are strongly encouraged.

Computational and systems biology section

Computational, integrative and systemic approaches are at the heart of biomedical engineering. This section considers papers on all aspects of mathematical, computational, systems and synthetic biology that result in the improvement of patient health. Integrative and multi-scale approaches, in the network and mechanism-based definition of injury and disease, or its prevention, diagnosis and treatment are welcome. Papers on high precision, interactive and personalised medicine, on digital/mobile health, on complex/big data analytics and machine learning, or on systemic and informatics approaches in a healthcare or clinical setting are encouraged.

Biomechanics section

This section represents the interdisciplinary field of biomechanics and investigates the relationship of structure with function in biological systems from the micro- to the macro- world. It considers papers on all aspects of analytical and applied biomechanics at all scales of observation, that improve the diagnosis, therapy and rehabilitation of patients or that advance their kinetic performance. The topics of interest range from mechanobiology and cell biomechanics to clinical biomechanics, orthopaedic biomechanics and human kinetics. Articles on the mechanics and wear of bones and joints, artificial prostheses, body-device interaction, musculoskeletal modelling biomechanics and solid/fluid computational approaches are strongly encouraged.

Biomedical imaging section

Biomedical imaging has been connecting microscopic discoveries with macroscopic observations for the diagnosis and treatment of disease and has seen considerable advances in recent years. This section will consider articles on all biomedical imaging modalities including medical imaging (MRI, CT, PET, ultrasound, x-ray, EEG/MEG), bio-imaging (microscopy, optical imaging) and neuroimaging across all scales of observation. Its primary focus will be to foster integrative approaches that combine techniques in biology, medicine, mathematics, computation, hardware development and image processing. Articles on new methodologies or on technical perspectives involving novel imaging concepts and reconstruction methods, machine learning, sparse sampling and statistical analysis tool development are encouraged.

The motivation for the launch of BMC Biomedical Engineering is to create an authoritative, unbiased and community-focused open access journal. We are committed to working together with our authors, editors and reviewers to provide an inclusive platform for the publication of high-quality manuscripts that span all aspects of biomedical engineering research. We welcome articles from all over the world and we will devote our efforts to ensure a robust and fair peer-review process for all. We believe in continuous improvement and we encourage the community to get in touch with us to provide ideas and feedback on how to improve the Journal and serve the community better.

We hope you will find the first group of articles an interesting and valuable read, and we look forward to working with you all to disseminate research into the exciting field of biomedical engineering.

Acknowledgements

Availability of data and materials, abbreviations.

Authors’ contributions

AH wrote the introduction, aims and scope and conclusion. AH, AKL, AV, ZY, JCY, DIZ and SYL wrote the editorial sections. All authors read and approved the final version of the manuscript.

Ethics approval and consent to participate

Consent for publication, competing interests.

AH is the Editor of BMC Biomedical Engineering and an employee of Springer Nature. AL, AV, ZY, JY, DZ and SL are members of the Editorial Board of BMC Biomedical Engineering .

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Get the Reddit app

All things biomedical engineering.

Why did you go into biomedical engineering?

Hi, I am applying to universities soon and I have started to find an interest in biomedical engineering. Is anyone willing to let me know why they are interested in the field and what makes it so unique compared to other fields of engineering?

By continuing, you agree to our User Agreement and acknowledge that you understand the Privacy Policy .

Enter the 6-digit code from your authenticator app

You’ve set up two-factor authentication for this account.

Enter a 6-digit backup code

Create your username and password.

Reddit is anonymous, so your username is what you’ll go by here. Choose wisely—because once you get a name, you can’t change it.

Reset your password

Enter your email address or username and we’ll send you a link to reset your password

Check your inbox

An email with a link to reset your password was sent to the email address associated with your account

Choose a Reddit account to continue

Biomedical engineering - Why engineering? Why Duke?

maggiek3 1 / 2   Aug 14, 2011   #2 Overall, I think it's really good. You explained why you are interested in engineering and gave examples of what you would like to do within that discipline. I think there needs to be a little more depth in the why you chose Duke portion...but I think you definitely have a good start here. Hope this helps! When I view the world, I see things that I believe could be better. I'm forced to ask, "Why does this work this way? Why can't you just do this? Wouldn't it fix everything if you just moved this over here? What is the best way to make this work?" Unfortunately these are very simple questions with very complex answers. (anybody can ask "why?" that is a simple question, but obviously, in engineering, the answers are complex. Maybe here you can add a sentence or two describing your desire to be a part of finding those complex answers, then lead into how biomedical engineering is a growing field that you are interested in) I think the field of biomedical engineering is primed for huge leaps and bounds in our understanding and incredible innovations will soon follow. I want to be a part of this. My specific intrigue in the biomedical field is prosthetics . The area of biomedical engineering that is most intriguing to me is prosthetics. Replacing human organs and limbs with a non-living object is an exciting and gratifying endeavor. Specifically, I want to go into the be involved in government research projects on prosthetics to help improve the lives of wounded veterans. Again you In this field, engineers are presented with many questions, my favorite the most prominent being : "How do you get the mind and the machine to communicate effectively?" This is such an intriguing question to me ; a question that I hope to spend my college career researching trying to answer it. If While this problem is may be solved tomorrow, no problem, I feel that anytime there is an advance ment in a field, it opens up hundreds of new questions about how to make the invention more efficient, compact, reliable, and user friendly. That This is why I want to be a biomedical engineer. There will never be an end to the contributions you can make to wards help ing people. There aren't many who would question that Duke is the best biomedical engineering program in the South. To me, that had little relevance in I chose choosing the Pratt School of Engineering (because of x, y, and z. Pick out a few specific aspects of the school that you liked, i.e. the faculty has advanced degrees, the school provides tutoring services, etc. This essay is about you, not the opinions of others.) Duke gives me the opportunity, resources, and most importantly, the mentorship to make progress in answering the questions that I have. Few other s schools have undergraduate research opportunities that are as well orchestrated and are as encouraged as Duke University. Also very important to me is the opportunity to double major in biomedical engineering along with mechanical or electrical engineering so as to focus the multidisciplinary aspect of biomedical engineering into a specific engineering while still getting the background of all disciplines. These reasons , along with the atmosphere and the hundreds of opportunities to get involved around campus , are why I chose Duke as is my first choice school.

• ABET Accreditation
• Diversity & Inclusion
• Seminar Series
• Upcoming Dissertation Defense
• Faculty & Student Awards
• Primary & Joint Faculty
• Graduate Students
• Research Scientists
• Postdoctoral Researchers
• Advisory Council
• Research Areas
• Undergraduate Research
• Centers & Facilities
• Undergraduate Program
• Graduate Program
• Opportunities
• Diversity Opportunities
• Make a Gift

Why Major in Biomedical Engineering?

Biomedical engineering is an emerging and rapidly expanding field where engineering and biological disciplines converge..

According to the National Institutes of Health, biomedical engineering integrates physical, chemical, mathematical, and computational sciences with engineering principles to study biology, medicine, behavior and health. It advances fundamental concepts and creates knowledge from the molecular to the organ systems levels. It develops innovative biologies, materials, processes, implants, devices, and informatics approaches for the prevention, diagnosis, and treatment of disease, for patient rehabilitation and health improvement.

The outlook for biomedical engineers is incredibly promising. The Bureau of Labor Statistics identified Biomedical Engineering as the fastest-growing occupational field, with jobs over the next decade being expected to grow by 72%. Major categories of employment include medical equipment and supplies manufacturing, scientific research and development, and pharmaceutical and drug manufacturing.

For the past few years, biomedical engineering has been ranked as one of the best jobs to have. In both 2012 and 2013 , CNNMoney named this the number one job in America because, along with being a well-paid job, it is a career that helps make the world a better place. It is also a flexible job as it opens the door to positions in universities, hospitals, labs, industry and regulatory agencies. CareerCast.com also rated biomedical engineering in the top 10% of jobs, recognizing it as a career with a bright future.

AREAS OF STUDY

• cancer diagnosis & therapy

disease modeling

musculoskeletal & neural engineering

tissue & regenerative engineering

• Government Agencies
• Medical Device
• Medical Equipment & Diagnostics
• Medical Supply
• Orthopaedics
• Pharmaceutical Manufacturing & Processing
• Public Health
• Research Laboratories
• Sports Medicine

CAREER OPTIONS

• Biomedical Engineer
• Product Development Engineer
• Design Engineer
• System Test Engineer
• Medical Device Sales
• R&D Engineering
• Product Specialist
• Technical Support Engineer
• Project Manager
• Quality Engineer
• Business Technology Analyst
• Research Scientist
• Entrepreneur
• Scientific Reviewer

GRADUATE PROGRAMS

• Masters of Science/Engineering
• Medical School
• Pharmacy School
• Dental School
• Physical Therapy
• Physicians Assistants

Industry Partners: Our Graduates Work Here

• Smith & Nephew
• Nemours AIDHC

Why Should I Study Biomedical Engineering?

By: admin | July 27th, 2020

Image Credit: UC Davis College of Engineering

When students decide what college or university to apply for, they have to think thoroughly. It’s necessary to make the right choice because it’ll determine their future career perspectives. Many youngsters want to be biomedical engineers. It’s a very important and complex profession related to saving human lives and the improvement of treatment.

There are certain reasons why it’s a good and respectful idea.

A team of professional academic writers from essay writing company AdvancedWriters.com shed some light on this essential matter. One of them has gathered the most relevant facts about the perspective of becoming a biomedical engineer. Let’s check them right now!

Biomedical engineering is a combination of medicine and engineering. This is a very important field of human activity. It creates different apparatuses and inventions to treat people and make the process of recovery faster, easier, and more effective. This field has created multiple life-saving concepts. Among such are:

• Artificially designed organs;
• Robots that conduct operations;
• Novel preparations;
• Kidney dialysis.

As you can see, each invention is of huge importance. Each has saved thousands and even millions of lives throughout the globe. Being a biomedical engineer is a very respectful job.

Job Perspectives

If you become an excellent expert in this vital industry, you have multiple options. There are various jobs you may choose. You may:

• Develop software to detect abnormalities of heart rhythms;
• Create different implants;
• Investigate and invent a revolutionary drug delivery method;
• Design new stimulators;
• Create useful technology for handicapped patients;
• Design various kinds of hospital equipment, etc.

Accordingly, you’ll be employed at a hospital or laboratory. Nonetheless, you can develop your talents in universities, governmental and private organizations, manufacturing, and so on. Your job specifications may be related to:

• Designing and development of equipment and machines;
• Installation and maintenance of apparatuses;
• Evaluation of quality and safety;
• Presentation of clinical results, etc.

There are several related fields too and you may try your hand in them. Thus, you may be employed as a marketing manager, quality insurance consultant, technical expert, and something of the kind. The salaries are dependent on the specialization you prefer. Nonetheless, your salary will be pretty high. The U.S. Bureau of Labor Statistics claims that the average salary is over $82,780 per year.

How to Be a Certified Specialist?

Everything is possible if you’re educated. Before you come into a profession, you ought to study and receive a certain graduation certificate in this vital field. There are multiple subdivisions in the field. Thus, you may prefer the following divisions:

• Biomedical Electronics;
• Rehabilitation Engineering;
• Orthopedic Bioengineering;
• Bio-nanotechnology, etc.

You’ll have to receive at least a bachelor’s degree. It takes 4 years of learning. To acquire a Master’s Degree, you’ll have to learn about 2 years more. While you learn, you’ll have to pass courses in various directions. These are chemistry, calculus (algebra, geometry, etc.), engineering analysis, biomaterials science, biomedical device engineering, and some others. Moreover, it’s also required to have an undergraduate degree in some related direction.

Important Skills to Master

True desire is not sufficient to become a specialist. You’ll have to master and develop certain skills as well. These are as follows:

• Analytical skills . You should be able to correctly assess the results of studies and experiments. It’s important to make sure you use or design adequate improvements and solutions.
• Creativity . It’s important to be capable of thinking critically and uniquely. You are expected to propose your own effective revolutionary methods instead of repeating the concepts of other scientists and engineers.
• Communication skills . This profession obliges to have advanced communication skills. You’ll interact with patients, partners, suppliers, investors, etc. Each category of people requires a certain delicate approach. Therefore, your communication is essential.
• Calculus skills . True experts will surely deal with exact sciences. The creation and implementation of different devices require precise calculations. You’ll need relevant knowledge in math, algebra, physics, trigonometry, etc. You’ll deal with statistics and analysis too.
• Problem-solving . As you’ll face multiple obstacles, it’s of huge importance to quickly seek appropriate solutions. You should be able to predict the possible outcomes to avoid any complications.

If you’ve decided to take the path of a biomedical engineer, don’t forget to read a lot about this field. It’s a very difficult and responsible specialty. Even though you may be well-educated and informed, don’t stop to learn more.

This field is on a constant move and new inventions happen every day. Find a reliable online site to learn about new developments. Some of them may be useful for your professional progress.

More articles from Industry Tap...

Get Industry Tap News

Advertisement