The Signal Processing and Instrumentation Section (SPIS) provides electrical, electronic, electro-optical, computer, and software engineering expertise to the NIH Intramural Research program for projects that require the development of biomedical instrumentation and signal processing systems. These SPIS collaborations involve advanced real-time signal transduction, signal processing, and control systems; and result in the creation of new biomedical instrumentation technologies. Example technology developments and projects include: cDNA and protein microarray; tissue microarray; laser capture microdissection (LCM); expression microdissection (xMD); chromosome microdissection; microfluidics, microfabrication, and microanalysis; single molecule, DNA, and chromatin fiber mechanics and manipulation; high-speed scanning spectrometry; atomic force microscopy (AFM); electron paramagnetic resonance (EPR) imaging; magnetic resonance imaging (MRI) and functional MRI (fMRI) methodologies and devices; magnetic resonance elastography (MRE) imaging; ultrasound imaging; positron emission tomography (PET) imaging; infrared fluorescence imaging; speech acquisition and real-time adaptive processing; mouse pain model; and sinus cavity acoustic characterization. These SPIS capabilities and accomplishments have established the group as the focal point for this type of electrical engineering research and development at the NIH. The research and development activities of the section are collaborative efforts with NIH Institute scientists, and often result in the development of unique, specialized biomedical instruments. Other projects involve signal processing algorithm development required for system simulation and signal analysis. Section goals necessitate design expertise in advanced analog and digital circuitry, biophysical signal transduction techniques, radio-frequency and telemetry systems, digital signal processing hardware and software, programmable logic devices, printed circuit board development, opto-electronics, and computer based instrumentation for signal processing and control.
Subramanian, Sankaran; Koscielniak, Janusz W; Devasahayam, Nallathamby et al. (2007) A new strategy for fast radiofrequency CW EPR imaging: direct detection with rapid scan and rotating gradients. J Magn Reson 186:212-9 |
Vogel, Abby; Chernomordik, Victor V; Riley, Jason D et al. (2007) Using noninvasive multispectral imaging to quantitatively assess tissue vasculature. J Biomed Opt 12:051604 |
Hassan, Moinuddin; Riley, Jason; Chernomordik, Victor et al. (2007) Fluorescence lifetime imaging system for in vivo studies. Mol Imaging 6:229-36 |
Finkel, Julia C; Besch, Virginia G; Hergen, Adrienne et al. (2006) Effects of aging on current vocalization threshold in mice measured by a novel nociception assay. Anesthesiology 105:360-9 |
Grover, Amelia C; Tangrea, Michael A; Woodson, Karen G et al. (2006) Tumor-associated endothelial cells display GSTP1 and RARbeta2 promoter methylation in human prostate cancer. J Transl Med 4:13 |
Husain, Fatima T; Fromm, Stephen J; Pursley, Randall H et al. (2006) Neural bases of categorization of simple speech and nonspeech sounds. Hum Brain Mapp 27:636-51 |
Pursley, Randall H; Salem, Ghadi; Devasahayam, Nallathamby et al. (2006) Integration of digital signal processing technologies with pulsed electron paramagnetic resonance imaging. J Magn Reson 178:220-7 |
Pursley, Randall H; Salem, Ghadi; Pohida, Thomas J et al. (2005) Direct detection and time-locked subsampling applied to pulsed electron paramagnetic resonance imaging. Rev Sci Instrum 76:1-6 |
Tangrea, Michael A; Chuaqui, Rodrigo F; Gillespie, John W et al. (2004) Expression microdissection: operator-independent retrieval of cells for molecular profiling. Diagn Mol Pathol 13:207-12 |
Pollock, Pamela M; Harper, Ursula L; Hansen, Katherine S et al. (2003) High frequency of BRAF mutations in nevi. Nat Genet 33:19-20 |
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