Biomedical Engineering Degrees

The Advantages To Earning Biomedical Engineering Degrees

A biomedical engineering degree offers individuals the knowledge and ability to function as professionals within the quickly evolving fields of health care and technology. Biomedical engineering degree programs are based in one of the most innovative and specialized fields of engineering, computer science, research, biology, and mechanical systems. Courses within biomedical engineering programs feature: mathematics, anatomy, biology, computer aided design, biomechanics, image processing, circuitry, 3D modeling, biochemistry, physiology, computer science, health care, medical information, health management, instrumentation, and technology. Graduates from biomedical engineering programs advance to employment within a number of organizations as researchers, designers, developers, and engineers within the biological and health care industries.

Many students manage work and family obligations in addition to educational responsibilities. In response, most colleges and universities have developed innovative online programs to extend instruction beyond traditional, on campus locations. Online programs feature virtually the same educational materials, instruction, and information as on campus programs. Online classes also provide students with the added benefits of a more personalized education and increased flexibility in course scheduling. Online courses also offer students the ability to learn within smaller classes, in groups of 25 students or less, and increased interactions with other classmates and professors through one on one Internet chats. Online programs are generally one of the most convenient, affordable and efficient means of acquiring knowledge and strengthening skills necessary to advance personal and professional goals.

What Students Learn Within Biomedical Engineering Degree Programs

Students within engineering degree programs gain a versatile, liberal arts based education as well as specialized studies devised to strengthen research and critical thinking skills. Most biomedical engineering programs consist of courses in the theories and application of engineering, biomechanical principles, biology, physiology, medicine, computer science, and health care management and delivery. Biomedical engineering programs also offer students the ability to participate in concentrations like robotics, nanotechnology, genetic research, and other fields. Professionals employed within biomedical engineering occupations are generally required to possess a minimum of a bachelor degree to qualify for entry level employment though most employers seek candidates with a master’s degree or higher.

Many students begin studies within associate degree programs to gain a basic understanding of the engineering and health care industries. Associate level courses in the discipline of health care technology include: introduction to biomedical engineering technology, Algebra and trigonometry, precalculus, discovering technology, introduction to engineering technology, digital fundamentals, accounting, technical report writing, elementary composition, introduction to circuit analysis, digital fundamentals, fundamentals of speech communications, introduction to medical electronics, ethics microprocessor applications, general physics, electronics circuit analysis, technical communication in health care professions, AC electronic circuits analysis, computer hardware and software architecture, introduction to psychology, introduction to philosophy, elementary statistics, Western civilization Ancient to Medieval, mathematical and quantitative reasoning, human growth and development, biological diversity, U.S. history and government, introduction to microbiology, and an internship. Graduates who complete associate degree programs may advance to employment or continue studies within higher degree programs.

Bachelor degree programs in the discipline of biomedical engineering provide students with an expanded understanding of the field as well as the ability to supplement their education within a variety of electives and concentrations. Courses at a bachelor level include: calculus, quantitative methods, technical and special patient populations, computer communications, written communications for science and industry, applied human biology, codes requirements and patient safety, project planing and design, microprocessor applications, ethics and professionalism for biomedical technology electronics technology, the chemistry of life, networking fundamentals with microcontrollers, special topics in biomedical engineering technology, psychology as a social science, abnormal psychology, genetics, cellbiology, pharmacology, gross anatomy, public and preventative health, bioethics, applied microbiology, introduction to psychology, abnormal psychology, U.S. government, bioelectric engineering, biological imaging, biomechanics, instrumentation, biomedical imaging and computing, biomedical systems and computational biology, drug delivery, polymeric biomaterials, orthopedic biomaterials, tissue engineering, and an internship. Graduates who bachelor degree programs may advance to employment or continue studies within a master’s degree program.

A master’s degree in biomedical engineering offers students the ability to specialize training necessary to advance to a number of upper level positions within the health care and engineering industries. Courses at a master’s level include: organic chemistry; general applied mathematics; physiology for applied biomedical engineering; molecular biology; medical sensors and devices; mathematical methods for applied biomedical engineering; medical imaging; medical image processing; medical imaging II: MRI; biomaterials; cell mechanics; biochemical sensors; practices of biomedical engineering; applications of physics and technology to biomedicine; biological fluid and solid mechanics; orthopedic biomechanics; neural prosthetics: science, technology, and applications; biomimetics in biomedical engineering; biophotonics, special project in applied biomedical engineering, directed studies in applied biomedical engineering; structure and function of the audiotory and vestibular systems; modeling the auditory system; ionic channels in excitable membranes; molecular and cellular systems in physiology laboratory; cellular and tissue engineering; cell mechanics and motility; cellular engineering; tissue engineering; neural control of movement and vocalization; introduction to nonlinear dynamics in physiology; advanced seminar in magnetic resonance imaging; computational models of the cardiac myocyte; high performance computing in biology; experimental foundations for neural models; foundations of computational biology and bioinformatics; systems biology of cell regulation; neuroengineering; and an internship. Graduates who complete master’s degree programs may advance to employment or continue studies within doctoral degree programs.

Doctoral degree programs offer students the ability to be qualified as experts in the field of biomedical engineering. Courses include: anatomy and physiology; epidemiology; pharmacology; cell physiology; metabolism; biophysics; genetics; immunology; micro/infectious disease; hermatology/oncology; brain and mind behavior; nervous systems and special senses; organ systems; systems bioengineering; quantitative biomedical engineering methods; neuroscience cognition; macromolecular structure and analysis; biochemical and biophysical principles; genetics; molecular biology and genomics; organic mechanisms in biology; pathways and regulation; cell structure and dynamics; bioinformatics; modeling dynamics and control for chemical and biological systems; physiological fluid mechanics; computational functional genomics; ion channels; theoretical neuroscience; bioelectromagnetic phenomena; feedback control in biological signaling pathways; models of neuron; compuational models of the cardiac myocyte; foundations of compuational biology; systems biology of cell regulation; learning theory; complex variables; introduction to stochastic processes; introduction to statistics; statistics information and vision; combinatorial analysis; applied analysis for engineers and scientists; probability theory; stochastic processes; statistical theory; statistical inference; multivariate statistical inference; graph theory; matrix analysis and linear Algebra; Markov chains; introduction to information theory and coding; introduction to linear dynamical systems; nonlinear system theory; random signals; applied analysis for engineers and scientists; finite element methods; mathematical methods of engineering; introduction to numerical methods; advanced transport phenomena; and a clinical experience. Doctoral degree graduates advance to employment as experts within educational and/or research institutions and facilities.

Prospective Jobs For Graduates With Biomedical Engineering Degrees

Graduates who complete biomedical engineering degrees utilize the knowledge gained through educational programs to advance to a number of careers within health care, engineering, and technological industries. Employment for biomedical engineering degree graduates is based upon factors like education level, area/s of specialty, and related work experience. Graduates who complete studies within associate degree programs advance to employment as biomedical engineering technicians, instrument calibration technicians, medical equipment repairers, medical office workers, medical technicians, medical assistants, biomedical equipment technicians, or administrative assistants within health care or pharmaceutical organizations. Bachelor degree graduates generally work as biomedical engineers, public health representatives, medical products design engineers, biotechnology product engineers, consumer products manufacturing engineers, application engineers within health care facilities, medical device engineers, pharmaceutical sales engineers, or medical technicians. Graduates with master’s degrees often gain employment biomedical engineers, health inspectors, assistant professors within colleges and universities, researchers within scientific laboratories, engineering specialists, or administrators within health care organizations. Doctoral degree graduates are considered experts in the field and work as lead researchers, laboratory directors, educators, or consultants within medical organizations, colleges or universities, and private or public firms.

Salary Range For Biomedical Engineering Degree Graduates

Biomedical engineering degree graduates gain the skills and knowledge during formal educational programs required to establish long term and lucrative careers. The field of biomedical engineering is rapidly evolving and offers a number of employment options with salaries based upon candidates’ education levels, area/s of speciality, related work experience, and organization of employment. The U.S. Bureau of Labor and Statistics reports average earnings for biomedical engineers ranges from $59,420 to $77,400 annually. Associate degree graduates employed as biomedical engineering technicians earn $41,550 to $64,120 annually. Graduates with bachelor degrees who work as medical sales representatives earn $36,460 to $75,120 annually. Master’s degree graduates who gain employment as generally earn salaries of $59,030 to $96,210 annually. Graduates with doctoral degrees who advance to positions as college or university professors earn $45,977 to $92,257 annually.

Career Outlook and Advancement Opportunities For Biomedical Engineering Degree Graduates

Graduates who complete biomedical engineering degree programs gain the educational basis necessary for secure careers in rapidly expanding health care and technological industries. The U.S. Bureau of Labor and Statistics reports job growth for professionals within the field of biomedical engineering to increase by 72% through 2018 at a tremendously faster than average rate in comparison to other occupations. Factors like an aging population, technological and medical advances, an increasing awareness toward improving health, and the demand to treat health issues while maximizing cost efficiency will increase the demand for qualified professionals in the field of biomedical engineering. Associate degree graduates who begin employment within entry level engineering technician positions gradually advance to positions with increased responsibility and higher salaries upon continuing education and gaining experience.

Most biomedical engineering graduates with bachelor degrees begin employment within entry level, highly supervised positions and advance to positions with greater responsibilities and more complex projects upon gaining relevant training, knowledge and experience. Master’s degree graduates often begin employment within entry level engineering manager positions or as technical specialists and advance upon gaining experience and continuing education to positions as instructors within vocational or secondary schools. Doctoral degree graduates often work as directors of biomedical engineering facilities or as professors within smaller colleges or universities and advance to positions within more prestigious laboratories or educational institutions upon gaining experience. Some graduates may also leave the field and establish self owned consulting companies upon securing adequate funding, experience, and training.

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