|
http://www.ch.cam.ac.uk/staff/oas.html
Self-Assembly: Our research interests include the synthesis of functional nanosystems, controlled polymer architectures and dynamic supramolecular assemblies through molecular recognition processes. |
|
http://www.ch.cam.ac.uk/staff/dk.html
Advanced Imaging: David is developing and applying a range of new biophysical methods, based on laser fluorescence spectroscopy and scanning probe microscopy, to important problems in biology, which have not been addressed to date due to the lack of suitable methods. While the experiments range from studies of individual biomolecules to living... |
|
http://www.biot.cam.ac.uk/at/
Anhydrobiotic Engineering: Work in Dr Tunnacliffe's laboratory aims to increase our understanding of anhydrobiosis and to examine possible cell-based applications. |
|
http://www.sanger.ac.uk/Teams/faculty/parkhill/
Pathogen Genomics: We use genome sequencing and analysis to investigate a wide range of human and animal pathogens, ranging from human and bacterial viruses, through bacteria and protist parasites to multicellular worms. We currently have over 100 ongoing projects, and we collaborate widely within the UK and world scientific community to generate... |
|
http://www.gen.cam.ac.uk/Research/archer.htm
Microbial Technology: Our research effort is directed at the following areas: Actinomycete comparative genomics; Synthesis of high value chiral products and novel therapeutics; Modelling systems control of genetic responses to environmental stimuli; Genetic technologies for the Rhodococcus complex; Directed evolution of enzyme function |
|
http://people.cryst.bbk.ac.uk/~wernisch/
Biostatistics: Research interests include: Genscend - gene-regulatory networks in single cells during neuronal development. Microarray analysis package YASMA - analysis of replicates of spotted cDNA arrays. Regulatory motifs in upstream sequences - some tools for regulatory motif detection. |
|
http://www.pdn.cam.ac.uk/groups/comp-cell/
Chemotaxis: Current work includes the development of a graphical display of swimming bacteria to test their responses to spatial gradients of attractants; use of an individual based stochastic program to analyze the responses of E. coli to conflicting gradients; and Brownian diffusion simulations of the diffusive movements of signalling proteins... |
|
http://www.bss.phy.cam.ac.uk/~jlh29/
DNA Biophysics: We use biophysical methods to study DNA architecture, and enable prediction of their structure and stability, and then to combine this work with bioinformatic analyses in order to identify and understand their functions. Ultimately this work may lead to novel insights into natural regulatory processes, as well as new targets for... |
|
http://www-control.eng.cam.ac.uk/~jmg77/
Control Theory: My research interests are in Systems Biology: modelling, analysis, and control of biological systems like circadian rhythms and gene regulatory networks. Hybrid Systems: analysis and control of hybrid and nonlinear systems using piecewise linear systems. Complex Systems: feedback limitations in complex networks. |
|
http://www.bss.phy.cam.ac.uk/~amd3/
Soft Matter Physics: The lab's work focusses on using the ideas of soft matter physics to study a wide range of systems of both synthetic and biological origin. There is an emphasis on using different types of microscopy, and in particular environmental scanning electron microscopy, and beyond. The unifying theme is understanding... |
|
http://www.gen.cam.ac.uk/Research/summers.htm
Plasmid Biology: Research in this laboratory has its roots in the study of the E. coli plasmid ColE1 and the mechanisms which ensure its efficient transmission to daughter cells at division. This has broadened into an interest in the fundamental cellular processes of site-specific recombination and cell cycle control in bacteria. These are... |
|
http://www.gen.cam.ac.uk/Research/oliver.htm
Genetic Recombination: Our current research interests involve the study of recombination and repair of DNA using the bacterium E.coli as a model system. |
|
http://www.path.cam.ac.uk/pages/fraser/
Bacterial Motility: We study cell polarity, intracellular protein targeting and export, and the co-ordination of complex cellular processes. We are also investigating flagellar type III export in Salmonella, and the interplay between transcriptional and metabolic networks and regulatory networks underlying bacterial differentiation and... |
|
http://www.neuroscience.cam.ac.uk/directory/profile.php?wolpert
Neuroscience: The group uses engineering approaches to understand how the human brain controls movement. The work includes both computational modelling and experimental approaches using robotic and virtual reality interfaces. Research areas include motor planning and optimal control, probabilistic (Bayesian) models, motor predictive and modular... |
|
http://www.damtp.cam.ac.uk/user/gold/
Biological Dynamics: Our research group focuses on understanding nonequilibrium phenomena in the natural world, with particular emphasis on biological physics. We strive for a holistic approach in which theory and experiment seamlessly coexist, and members of the group include theoretical and experimental physicists, applied mathematicians and... |
|
http://www.bioc.cam.ac.uk/uto/lipkow.html
Cellular Signalling & Architecture: In the true spirit of Systems Biology, we combine experiments and computer models to understand the functional relationship between cellular signalling and architecture. |
|
http://www.sysbiol.cam.ac.uk/index.php?page=dr-kathryn-lilley
Proteomics: The focus of my lab has emerged largely out of what can be considered to be some of the critical shortcomings of the proteomics technologies now in use. The research interests of the Cambridge Centre for Protoemics fall into two main areas and address the following fundamental questions: Where are proteins located within cellular... |
|
http://www.sysbiol.cam.ac.uk/index.php?page=prof-steve-oliver-director
Yeast Systems: My lab is dedicated to dedicated to unravelling the workings of the yeast cell, using both top-down and bottom-up systems biology strategies. We are also concerned with developing yeasts as systems to both understand and combat human diseases, including through the use of automated methods. |
|
http://lucacardelli.name/
BioComputing: Representing the structure and function of biological systems via formal languages, for description, simulation, analysis and (eventually) compilation. |
|
http://research.microsoft.com/en-us/people/hkugler/
Computational Biology: Systems Biology (modeling and analysis of biological systems) software and system engineering (statecharts, live sequence charts, formal verification, synthesis) |
Page 1 of 2