Biochemical Engineering
Biochemical Engineering
Biochemical Engineering is a discipline of engineering concerned with studying, designing, and constructing biological organisms or molecules in unit processes. Chemical engineering, biochemistry, and microbiology are all part of this multidisciplinary subject. This branch aims to educate students in biotechnology, biochemical engineering, and microbial and enzyme systems. Thus, it will aid in their comprehension of the biological or biochemical phenomena in these systems. Aside from that, Biochemical Engineering is concerned with growth, death, and metabolic kinetics, agitation, fermentation, mass transfer, and enzyme technology.
Biochemical engineers study cells, viruses, proteins, and other biological substances to determine optimal growth conditions or inhibitors to stop or kill growth. They explore how raw materials interact with one another and in specific environments. Following that, they create processes for synthesizing new compounds from these materials. The unique blends are mass-produced for general public consumption. Aside from design, the Biochemical engineer must collaborate with others on the process and product development. They must collaborate with research and manufacturing personnel to prepare information about newly developed products. They collaborate with other chemists and biologists to develop new technologies and products to maintain innovation. Biochemical engineers must ensure that the outcomes of any research, experiments, or collaborations are properly recorded and documented.
Opportunities abound in the field of Biochemical Engineering. Biochemical engineers research plants that produce dyes, bio-fuels, alcohol, steroids, enzymes, bio-fertilizers, or biocatalysts used in chemotherapy or the food processing industry and fermentation processes. Aside from that, Biomechanical engineers work in sports, medicine, and rehabilitation. Medical professionals specialize in working with cells and tissues. Career advancement in Biochemical engineering is dependent on further education and updating one’s credentials, as the field is constantly changing. In this field, becoming a Registered Professional Engineer can help you advance to management positions within companies.
I want to study biochemical engineering because of the high demand in the rapidly growing biotechnology/pharmaceutical, biofuels, and biorefinery industries. As the biotechnology industry grows and matures, there is a growing demand for biochemical engineers who can take products from the research stage to the pilot scale and, eventually, large-scale manufacturing. Biochemical engineers must understand the production, purification, and regulatory issues surrounding biopharmaceutical manufacturing as they fill this need.
I chose to study at University College London (UCL) because it is a cosmopolitan and international environment. UCL is known as “London’s global university,” Its degrees are recognized and respected globally. Studying at UCL will help me understand the world’s major issues and prepare me to contribute to solutions. UCL ensures that students are ready to take on global citizenship and leadership roles. All students, at all stages of UCL degree programs, receive career counseling from the university. Employers are eager to hire UCL graduates. International students can apply for scholarships.
I am particularly drawn to Biochemical engineering because it combines medicine and engineering to improve health care quality through innovative medical devices and processes. Most Biomedical engineers work for pharmaceutical companies, scientific research and development firms, medical equipment and supply companies, and organizations that manufacture navigational, measuring, electro-medical, and control instruments. Biochemical engineering is an exciting career field that has paved the way for numerous medical breakthroughs.
Biochemical engineers, who have expertise in physiology, biology, healthcare and health informatics, mechanics, and engineering, can combine their diverse skills to create solutions to ongoing global health issues, changing how patients are treated and lowering the cost of care. The demand for biomedical devices and procedures is expected to rise as our population lives longer. Because of easy access to up-to-the-minute news, the tech-savvy public is more aware of medical technology breakthroughs and advancements than ever before. As a result of this awareness, an increasing number of people will seek biochemical solutions to their complex health concerns with each passing year.
I had been looking for a career where I could apply my skills and knowledge in Chemical Engineering & Analytical Science. Being an assistant test engineer didn’t appeal to me, but I want to make a difference in peoples’ lives. I have always enjoyed biology, so becoming a biochemical engineer seems like a logical step. With an upper second-class honors degree in Chemical Engineering and Analytical Science, I believe that this knowledge and skills can be combined with Biochemical engineering principles, as well as knowledge of mathematics and specific sciences such as chemistry, biology, and physics, to develop and operate processes that convert raw materials into products that benefit society. With my strong educational foundations in chemistry, biological sciences, and chemical process engineering, I am in an excellent position to tackle biochemical challenges. Biochemical engineers use cell and molecular biology, biochemistry, and engineering principles to create, design, scale-up, optimize, and operate processes that use living cells, organisms, or biological molecules for the production and purification of products such as monoclonal antibodies, vaccines, therapeutic proteins, antibiotics, industrial enzymes, ethanol, and more complex biofuels; and for health and environmental monitoring. Biological processes are also becoming increasingly important in traditional chemical engineering industries such as materials, chemicals, food, energy, fuels, and semiconductor processing. Biochemical engineers, for example, could design and operate processes to convert switchgrass into biofuels or mass produce antibiotics. Chemical engineering differs from other engineering disciplines in that it relies on chemical reactions and physicochemical transformations to create a wide range of important materials and products. Biochemical engineering encompasses a wide range of industrial biocatalytic, fermentation, and cell culture processes that yield products ranging from soft drink high fructose corn syrup to recombinant human insulin. Chemical and biochemical engineers learn ethical design and respect for larger issues in any scenario as part of their training, such as community health, employee safety, and the global implications of the invention.
Working as an Assistant Test Engineer for Brunp Recycling Co. Ltd, I was responsible for analyzing all types of chemical products according to test standards and issuing test reports, supervising and inspecting test processes, assisting engineers in maintaining, calibrating, using, and managing laboratory instruments and equipment, assisting in the daily purchase of materials, supplier investigation and evaluation, and acceptance and confirmation of purchase.
Master in Science (MSc) in Biochemical Engineering program focuses on the fundamental biochemical engineering principles that allow advances in the life sciences to be translated into simple processes or products. I will learn advanced engineering skills like bioprocess design, bioreactor engineering, downstream processing, cutting-edge life science techniques like molecular biology, vaccine development, microfluidics, and important business and regulatory knowledge like management, quality control, and commercialization. I’ll be able to thrive in a variety of rewarding careers as well. Skills in biomedical engineering will enable me to collaborate with scientists, medical researchers, and manufacturers to address a wide range of injuries and physical disabilities.