Consistently ranked as one of the top analytical divisions in the United States, ranked number 1 for the fifth year in a row by U.S. News and World Report magazine in its 2011 edition of "America's Best Graduate Schools," the analytical division is recognized as a world leader in this scientific area.
Following the tradition set by the late Professor Charles N. Reilley, the division extends the frontier of the field through a focus on fundamental studies related to chemical analysis and the development of innovative instrumentation. All traditional areas of research are represented, including electrochemistry, mass spectrometry, microscopy, sensors, separations and spectroscopy.
Research projects span a wide range of chemical analysis science and include, but are not limited to, biosensors, nanoscopic materials, neurochemistry, microvolume separations and analysis, protein adsorption, supercritical fluids and single-molecule analysis; for examples of currently active research projects please see the list below. The division has strong relationships with a large number of companies in the pharmaceutical, chemical and scientific instrumentation industries, which provide continued support of research fellowships and the Analytical Seminar series.
New advances enable long-term organotypic culture of colonic epithelial stem cells that develop into structures known as colonoids. Colonoids represent a primary tissue source acting as a potential starting material for development of an in vitro model of the colon. Key features of colonic crypt isolation and subsequent colonoid culture have not been systematically optimized compromising efficiency and reproducibility. Research from the Allbritton Group, published in the Journal of Biological Engineering, show how murine crypt isolation yield and quality can be optimized, and colonoid culture efficiency measured in microfabricated culture devices.
Improved crypt isolation and 3-D colonoid culture, along with an understanding of colonic epithelial cell behavior in the presence of microfabrication substrates will support development of "organ-on-a-chip" approaches for studies using primary colonic epithelium.
The process of immobilizing enzymes onto solid supports for bioreactions has some compelling advantages compared to their solution-based counterpart including the facile separation of enzyme from products, elimination of enzyme autodigestion, and increased enzyme stability and activity. Researchers in the Soper Group, published in Analytical Chemistry report the immobilization of λ-exonuclease onto poly(methylmethacrylate) (PMMA) micropillars populated within a microfluidic device for the on-chip digestion of double-stranded DNA.
The group's results suggest that the efficiency for the catalysis of dsDNA digestion using λ-exonuclease, including its processivity and reaction rate, were higher when the enzyme was attached to a solid support compared to the free solution digestion. The results from this work will have important ramifications in new single-molecule DNA sequencing strategies that employ free mononucleotide identification.
Small Sample Sorting of Primary Adherent Cells by Automated Micropallet Imaging and Release. Pavak K. Shah, Silvia Gabriela Herrera-Loeza, Christopher E. Sims, Jen Jen Yeh, and Nancy L. Allbritton. Cytometry Part A, Volume 85, Issue 7, pages 642–649, July 2014.
Optimization of 3-D Organotypic Primary Colonic Cultures for Organ-on-Chip Applications. Asad A Ahmad, Yuli Wang, Adam D Gracz, Christopher E Sims, Scott T Magness and Nancy L Allbritton. Journal of Biological Engineering 2014, 8:9.
Immobilization of Lambda Exonuclease onto Polymer Micropillar Arrays for the Solid-Phase Digestion of dsDNAs. Nyoté J. Oliver-Calixte, Franklin I. Uba, Katrina N. Battle, Kumuditha M. Weerakoon-Ratnayake, and Steven A. Soper. Anal. Chem., 2014, 86 (9), pp 4447–4454.
Chemical Vapor Deposition of Aminopropyl Silanes in Microfluidic Channels for Highly Efficient Microchip Capillary Electrophoresis-Electrospray Ionization-Mass Spectrometry. Nicholas G. Batz, J. Scott Mellors, Jean Pierre Alarie, and J. Michael Ramsey. Anal. Chem., 2014, 86 (7), pp 3493–3500.
Micropallet Arrays for the Capture, Isolation and Culture of Circulating Tumor Cells from Whole Blood of Mice Engrafted with Primary Human Pancreatic Adenocarcinoma. Guohua Xu, Yansheng Ye, Xiaoli Liu, Shufen Cao, Qiong Wu, Kai Cheng, Maili Liu, Gary J. Pielak, and Conggang Li. Biosensors and Bioelectronics, Volume 54, 15 April 2014, Pages 476–483.
Fluorous Enzymatic Synthesis of Phosphatidylinositides. Weigang Huang, Angela Proctor, Christopher E. Sims, Nancy L. Allbritton, and Qisheng Zhang. Chem. Commun., 2014,50, 2928-2931.
Response of Single Leukemic Cells to Peptidase Inhibitor Therapy Across Time and Dose Using a Microfluidic Device. Michelle L. Kovarik, Alexandra J. Dickinson, Pourab Roy, Ranjit A. Poonnen, Jason P. Fine and Nancy L. Allbritton. Integr. Biol., 2014, 6, 164-174.
Ex Vivo Chemical Cytometric Analysis of Protein Tyrosine Phosphatase Activity in Single Human Airway Epithelial Cells. Ryan M. Phillips, Lisa A. Dailey, Eric Bair, James M. Samet, and Nancy L. Allbritton. Anal. Chem., 2014, 86 (2), pp 1291â€“1297.
Capture and 3D Culture of Colonic Crypts and Colonoids in a Microarray Platform. Yuli Wang, Asad A. Ahmad, Pavak K. Shah, Christopher E. Sims, Scott T. Magness and Nancy L. Allbritton. Lab Chip , 2013, 13, 4625-4634.
Flexible Software Platform for Fast-Scan Cyclic Voltammetry Data Acquisition and Analysis. Elizabeth S. Bucher, Kenneth Brooks, Matthew D. Verber, Richard B. Keithley, Catarina Owesson-White, Susan Carroll, Pavel Takmakov, Collin J. McKinney, and R. Mark Wightman. Anal. Chem., 2013, 85 (21), pp 10344â€“10353.