Posts

Analog synthetic biology.

Sarpeshkar R.  2014.  Analog synthetic biology. Philos Trans A Math Phys Eng Sci. 372(2012):20130110. Google Scholar  PubMed

A method for determining the robustness of bio-molecular oscillator models.

Ghaemi R, Sun J, Iglesias PA, Del Vecchio D.  2009.  A method for determining the robustness of bio-molecular oscillator models. BMC Syst Biol. 3:95. Google Scholar PubMed

DESHARKY: automatic design of metabolic pathways for optimal cell growth.

Rodrigo G, Carrera J, Prather KJones, Jaramillo A.  2008.  DESHARKY: automatic design of metabolic pathways for optimal cell growth. Bioinformatics. 24(21):2554-6. Google Scholar PubMed

Evaluation of companding-based spectral enhancement using simulated cochlear-implant processing.

Oxenham AJ, Simonson AM, Turicchia L, Sarpeshkar R.  2007.  Evaluation of companding-based spectral enhancement using simulated cochlear-implant processing. J Acoust Soc Am. 121(3):1709-16. Google Scholar PubMed

A low-power asynchronous interleaved sampling algorithm for cochlear implants that encodes envelope and phase information.

Sit J-J, Simonson AM, Oxenham AJ, Faltys MA, Sarpeshkar R.  2007.  A low-power asynchronous interleaved sampling algorithm for cochlear implants that encodes envelope and phase information. IEEE Trans Biomed Eng. 54(1):138-49. Google Scholar PubMed

An ultra-low-power programmable analog bionic ear processor.

Sarpeshkar R, Salthouse C, Sit J-J, Baker MW, Zhak SM, Lu TKT, Turicchia L, Balster S.  2005.  An ultra-low-power programmable analog bionic ear processor. IEEE Trans Biomed Eng. 52(4):711-27. Google Scholar PubMed

3D accordion spectroscopy for measuring 15N and 13CO relaxation rates in poorly resolved NMR spectra.

Carr PA, Fearing DA, Palmer AG.  1998.  3D accordion spectroscopy for measuring 15N and 13CO relaxation rates in poorly resolved NMR spectra. J Magn Reson. 132(1):25-33. Google Scholar PubMed