This term basically refers to the biological systems engineering. Bioengineering typically involves branches such as biology, physics, mathematics and computers to devise concepts and ideas to solve complex real time problems and to implement the ideas for the biological systems development. Primarily the studies like molecular biology form the basis of the bioengineering. Applications of bioengineering ranges from cost effective analysis of the systems and the development of those trends to further enhance the effectiveness as desired. One such example is the application of bioengineering technology in human health. Romania is registering an improvement in the demand of good quality health care services, financial accessible, safety and always reliable, in a moment when there is a significant pressure over the public expenses. Therefore, it's time that Romania reconsider her health care systems in a way of making them accessible for everyone, efficient and sustainable, allocating enough resources. For a healthier population, we need approaches at the engineering systems' levels, in which the health care methodology should redesign, in the same time with the changing of needs, and also, to integrate locally, regionally, national and globally health care informatics networks. The following presentation shows the use and benefits of quality management in biomedical engineering industry, a field still unknown for many.Biological Engineering is an interdisciplinary area focusing on the application of engineering principles to analyze biological systems and to solve problems in the interfacing of such systems -- plant, animal or microbial--with human-designed machines, structures, processes and instrumentation. The biological revolution continues to mature and impact all of us. Human-based gene manipulation affects nearly all North American food supplies. Plants and animals are already being defined on a molecular basis. Living organisms can now be analyzed, measured and "engineered" as never before. Designer "bugs" are being produced to enhance biological processes. These changes continue to redefine our research and graduate programs that continue to emphasize biological, environmental and food and fiber engineering. Our connections to agriculture and food systems remain, but modern agriculture is greatly influenced by biotechnology, and our connections to agriculture reflect this fact. A basic goal is to design technology that operates in harmony with the biology of living systems. In many cases, currently available knowledge is inadequate to support engineering design of food and biological processes. Hence, greater fundamental knowledge of biology and its potential applications are also of concern to the biological engineer.Work with engineering DNA into a nanomaterial for real world applications including drug (DNA/siRNA/cell) delivery, molecular sensing, cell-free protein production, protein engineering and nanoparticle-based photonic/optoelectronic/photovoltaic devices.Bioenergetics involves development of mechanistic models to predict energy budget of endotherms for virtually any thermal conditions. Stress factors in livestock involves time series analyses of thermal data (temperature, relative humidity, wind speed and solar radiation), physiological responses data (internal body temperature, respiration rate, sweating rate, etc) and physical and optical properties of hair coat (fur layer) in defining stress and stress levels of livestock in hot and dry, and hot and humid environments.A systematic approach to future energy needs. Projects within this area include: Developing and validating system models of material, energy and monetary flows for cellulosic and corn ethanol and application of models to assess system energetics, economics, and carbon balance; Developing frameworks for integration of uncertain wind resources into existing electric power grids through the use of optimization in conjunction with simulations on a simplified power system.Biosensors, bioassays and microfluidic lab-on-a-chip systems will be developed for the detection of pathogenic organisms, toxins, and clinically relevant markers. Applications of the sensors will be toward clinical diagnostics, food safety, environmental protection or biosecurity.xperiment with measurement and modeling of physiological functions in animals and plants. A broad range of projects are possible and can involve physiological functions at the cellular level as well as larger more complex systems.