University of California San Francisco / Biochemistry University of Texas / /
IndustryTerm
typical algorithm / natural genetic regulatory networks / encoded edge detection algorithm / Chemical synthesis / neural network systems / biotechnology / physical-chemical model / predictive mathematical tools / signal processing algorithm common / Amorphous computing / biological systems / silico edge detection algorithms / host systems / regulatory networks / natural systems / pulse-generating networks / silico image processing applications / natural regulatory systems / model solution / model solutions / synthetic mammalian gene network / search process results / genetic edge detection algorithm / energy resources / gene products / Synthetic systems / genetic networks / parallel edge detection algorithm / weak ribosome binding site / biological edge detection algorithm / image processing / information-processing requirement / gene regulatory networks / distributed processors / natural genetic systems / engineered gene networks / detection algorithm / signal processor / diffusible chemical signal / acyl-homoserine lactone inactivation products / synthetic oscillatory network / /
Organization
National Institute of Health / office of Naval Research / National Science Foundation / Kirschstein National Research Service / MIT / School of Pharmacy / Miller Unit / University of California San Francisco / San Francisco / Directional Movement / University of Texas / /
Person
Jeffrey J. Tabor / Nat / Wayne Rasband / Edmund Optics / / /
Position
Quantitative model for gene regulation by lambda phage repressor / physical-chemical model for gene regulation / forward / reporter / /
Product
Franklin / /
ProvinceOrState
Texas / New Jersey / S.K. / M.B. / South Carolina / California / Ontario / /
PublishedMedium
Lecture Notes In Computer Science / Molecular Biology / /
A Synthetic Genetic Edge Detection Program