«Let them eat xylose: Yeast engineered to grow efficiently on novel nutrients: Discoveries may lead to faster growth and higher cell densities in
biological engineering applications.»
Not exact matches
Shyam Sablani, associate chair of
biological systems
engineering at Washington State University in Pullman, whose program not only doesn't require GRE scores but doesn't include them on the
application form that the faculty sees, says that the question to bring back the requirement has been raised twice in the 10 years he has been with the department.
Bioengineering — the
application of
engineering principles to
biological problems related to the human body — is a relatively new but very wide field.
The
applications for
biological engineering, then, are limited only by our collective imagination.
Mechanical
engineering has always been associated with manufacturing, aircraft design, automotive production, and so on, but it also has very strong
applications in
biological systems such as our muscles and limbs.
«We believe this new field of «living» materials and devices will find important
applications at the interface between
engineering and
biological systems.»
[Box 14] Academy of Independent Scholars American Association of Engineering Societies (AAES) American Association for Higher Education American Association of Physics Teachers American Association of University Professors (AAUP) American Astronomical Society American Chemical Society (ACS) American Enterprise Institute for Public Policy Research American Geophysical Union American Institute of
Biological Sciences (AIBS) American Institute of Chemical
Engineers (AICE) American Institute of Chemists (AIC) American Institute of Industrial
Engineers American Institute of Physics (AIP) American Mathematical Society American Meteorological Society American Nuclear Society American Physical Society The American Political Science Association American Psychiatric Association American Psychological Association American Science Film Association American Society for Cybernetics American Society for Engineering Education (ASEE) American Society for Horticultural Science (ASHS) American Society for Humanistic Aerospace Research and
Application American Society for Information Science (ASIS) American Society for Microbiology American Society for Public Administration (ASPA) American Society for Testing and Materials American Society for Association Executives American Society of Civil
Engineers (ASCE) American Society of Mechanical
Engineers (ASME) Associated Universities, Inc..
The Institute: brings together a wide range of scientists, including physicists,
engineers, chemists, biologists as well as HMS clinicians to address fundamental questions about the behavior and functioning of
biological systems; allows biologists,
engineers, and clinicians to potentially use such knowledge to foster
applications and new technologies; and provides a way for the tool - developers (physicists,
engineers, computer scientists) to work with the tool - users (biologists, chemists, clinicians) in the early stages of scientific inquiry and encourage scientific collaboration at the innovation stage of tool development.
Rapid developments in the field of synthetic biology and its associated tools and methods, including more widely available gene editing techniques, have substantially increased our capabilities for bioengineering — the
application of principles and techniques from
engineering to
biological systems, often with the goal of addressing «real - world» problems.
Within the field of medical,
biological and clinical
engineering IFMBE's aims are to encourage research and
application of knowledge, and to disseminate information and promote collaboration.
Topics ranging from systems and synthetic biology, digital healthcare, cancer, genomics, immunology,
biological engineering, microbiology, and cell biology will be covered, but anyone interested in interdisciplinary life sciences research and its
applications should attend.
At Purdue, he is a professor of agriculture and
biological engineering, as well as co-director of the Physiological Sensing Facility, which fosters interdisciplinary engagement between bioscientists and
engineers to drive sensor development and
application.
In the Commonwealth Government's Excellence in Research for Australia 2012 National Report, JCU research received the highest ranking of «well above world standard» (rating 5) in the areas of environmental science and management, ecological
applications and medical microbiology.The University also received an «above world standard» ranking for research in the areas of materials
engineering, immunology, tourism,
biological sciences, agricultural and veterinary sciences, fisheries sciences, veterinary sciences, inorganic chemistry, earth sciences, geochemistry, and geology.
Kinnari graduated from Princeton University in 2014 with a BSE in chemical and
biological engineering (with a concentration in energy technologies) and a Certificate in
Applications of computing.
Professional Duties & Responsibilities Biomedical and biotechnology
engineer with background in design of biomaterials, biosensors, drug delivery devices, microfrabrication, and tissue
engineering Working knowledge of direct cell writing and rapid prototyping Experience fabricating nanocomposite hydrogel scaffolds Proficient in material analysis, mechanical, biochemical, and morphological testing of synthetic and
biological materials Extensive experience in bio-imaging processes and procedures Specialized in mammalian, microbial, and viral cell culture Working knowledge of lab techniques and instruments including electrophoresis, chromatography, microscopy, spectroscopy, PCR, Flow cytometery, protein assay, DNA isolation techniques, polymer synthesis and characterization, and synthetic fiber production Developed strong knowledge of FDA, GLP, GMP, GCP, and GDP regulatory requirements Created biocompatible photocurable hydrogels for cell immobilization Formulated cell friendly prepolymer formulation Performed surface modification of nano - particle fillers to enhance their biocompatibility Evaluated cell and biomaterial interaction, cell growth, and proliferation Designed bench - top experiments and protocols to simulate in vivo situations Designed hydrogel based microfluidic prototypes for cell entrapment and cell culture utilizing computer - aided robotic dispenser Determined various mechanical, morphological, and transport properties of photocured hydrogels using Instron, FTIR, EDX, X-ray diffraction, DSC, TGA, and DMA Assessed biocompatibility of hydrogels and physiology of entrapped cells Evaluated intracellular and extracellular reactions of entrapped cells on spatial and temporal scales using optical, confocal, fluorescence, atomic force, and scanning electron microscopies Designed various biochemical assays Developed thermosensitive PET membranes for transdermal drug delivery
application using Gamma radiation induced graft co-polymerization of N - isopropyl acylamide and Acrylic acid Characterized grafted co-polymer using various polymer characterization techniques Manipulated lower critical solution temperature of grafted thermosensitive co-polymer Loaded antibiotic on grafted co-polymer and determined drug release profile with temperature Determined biomechanical and biochemical properties of
biological gels isolated from marine organisms Analyzed morphological and mechanical properties of metal coated yarns using SEM and Instron Performed analytical work on pharmaceutical formulations using gas and high performance liquid chromatography Performed market research and analysis for medical textile company Developed and implement comprehensive marketing and sales campaign