Bioengineering is a discipline that applies engineering principles of analysis and design to biomedical technologies and biological systems. Tissue engineered organs, new medical imaging technology, and portable disease diagnostic devices are some of the examples of bioengineering research. Professionals like Curtis Cripe have dedicated a large part of their career in trying to understand the expansive possibilities for the popularity of bioengineering in the near future. Curtis is the founder of the NTL group and the Crossroads Institute.
Curtis Cripe offers an overview of the domain of bioengineering
Bioengineering is a relatively new discipline. It combines several aspects of traditional engineering domains, including mechanical, electrical, and chemical engineering. Under bioengineering, professionals make use of engineering problem-solving techniques for medicine and biology. Its effect can be seen throughout varied aspects of healthcare, right from analysis and diagnosis to treatment and recovery. Bioengineering has become pretty prominent, especially with the proliferation of implantable medical devices and futuristic technologies. These devices and technologies include pacemakers, artificial hips, stem cell engineering and the 3-D printing of biological organs.
Biomedical engineers use and apply their intimate knowledge of contemporary biology principles in the engineering design process. There are several sub-disciplines within bioengineering, including the design and development of medical imaging, orthopedic implants, as well as active and passive medical devices. Tissue and stem cell majorly work towards artificial recreation of human organs, and help several people to lead better, healthier life through transplants. Experts in medical devices can develop external and implantable devices like coronary stents, pacemakers, ambulatory devices, and prosthetics.
Biomedical signal processing and clinical engineering also come under biomedical engineering. Biomedical engineers ideally work in a variety of disciplines and settings. There are several opportunities and scope in the industry for innovation, design, and the development of brand new technology. Biomedical engineers can even become a part of academia and play a role in furthering research and pushing boundaries in regard to what is medically. They can focus on the testing, implementation, and development of new medical equipment and diagnostic tools. There is a place for biomedical engineers in the government as well, especially when it comes to establishing safety standards for medical devices. A lot of experienced and well-qualified biomedical engineers find employment in startup companies or MNCs, while some end up being entrepreneurs themselves. The scope for career growth in this field is quite dynamic.
Engineering by itself is an extremely innovative field. It is the origin point of ideas that led to the development of automobiles, aerospace, sonar, skyscrapers, and so on. Biomedical engineering is essentially more focused on the advances that help in improving healthcare and overall human well-being at all levels. According to Curtis Cripe, predictive diagnostics is one area in which bioengineering is likely to go a long way. The use of bioengineering in the diagnosis of cardiac risks or colon cancer can be considered to be the evidence for his opinion. Moreover, particular brain imaging techniques may also be helpful in finding out if an individual has Alzheimer’s disease.