Our research focuses on determining the structures and interactions of macromolecules by ion mobility / mass spectrometry.
In our laboratory we bring together skills in nuclear magnetic resonance (NMR) spectroscopy, membrane and computational biophysics, and biomathematics.
The Lazenby laboratory focuses on electroanalytical techniques and scanned probe electrochemical microscopy, for analytical applications in imaging, chemical sensing, health and materials characterization.
The principle that guides my research is that biological macromolecules are chemicals and biological processes are chemical processes; we should be able to understand them...
Our research consists of the continuing development of new theory, techniques, and analytical/biological/environmental applications of Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometry.
We focus on understanding, controlling and tailoring the interfaces between inorganic nanomaterials and various systems, including biological materials, metal complexes and fluorescent compounds.
The Roper laboratory develops new analytical methods and techniques to investigate biological signaling.
The Sang research team investigates biomarkers and biochemical mechanisms of stem cell differentiation and tissue engineering, cancer metabolism, angiogenesis, progression, invasion, and metastasis.
The Stagg research group focusses on determining the structural mechanisms that facilitate membrane trafficking in cells and methods for high-throughput high-resolution cryo-EM.
Our research interest is in the development and application of state-of-art multi-spectrum atomistic simulation techniques to understand the hidden nature of complex biological phenomena.
The Zhu group is interested in solving fundamental problems in chemistry and developing new technologies using the tools in supramolecular chemistry.