Biomedical Sciences & Life Sciences

 NameResearch Interests
Asst Prof Ajai VyasMy lab works at the interface of neurobiology (approach and avoidance behaviors) and parasitology (behavioral manipulation of host by parasites). Majority of work will relate to behavioral manipulation of rodents by Toxoplasma. My research program is inspired the fact that a parasite, Toxoplasma gondii, can invade rat brain and removes deep-seated fears from a rat?s psyche. Why? So that parasite can hitch-hike a ride to cat intestines (when fearless rat is eaten by the cat) and reproduce there. This paradigm allows access to a really specific perturbation system for fear. Knowledge of proximate mechanisms will come handy for understanding generation of fear and management of abnormal fear. Apart from that, Toxoplasma infects humans with remarkable frequency. Effects of such infection range from mild personality changes to active brain lesions in immuno-compromised patients to possibly some cases of Schizophrenia. These are a few of my incentives in studying proximate mechanisms of Toxoplasma infection, apart from inherent beauty of co-evolution and arms race between hosts and parasites. Recently, I have observed that Toxoplasma infection causes male rats to become more attractive to female rats. I also intend to search for proximate mechanisms of this very baffling effect. Feel free to drop me an email if you would like to talk science or if you are interested to be part of this interesting research.
Asst Prof Ali Gilles Tchenguise MiserezStructural properties of biological materials from the macro-scale to the nano-scale Abrasion and wear mechanisms of non-mineralized biocomposites and of biominerals Elastomeric and structural properties of oviparous egg capsules materials Protein chemistry of sclerotized hard-tissues from marine organisms, such as Cephalopod Single-molecular force spectroscopy of structural and elastic proteins Underwater adhesion mechanisms of adhesive proteins Bio-fouling Advanced Metal/Ceramic composites Experimental Fracture Mechanics
Assoc Prof Bertil Schmidt- High Performance Computing - Bioinformatics - Computational Sciences - Reconfigurable Computing - GPGPU
Asst Prof Bjoern Holger NeuDr. Neu's areas of expertise are Biophysics and Biorheology. His research work focuses on the stabilization and destabilization of blood and its clinical significance in diseases, blood cell mechanics, cell interactions with biomaterials and the fabrication of multifunctional nano- and microcapsules for biotechnological applictions.
Assoc Prof Bogdan Jaroslaw FalkowskiAssoc. Prof. Bogdan J. Falkowski's areas of expertise are Electronic Design Automation Tools and Systems for Digital Logic Design and Optimization, Spectral and Discrete Representations of Multiple-Valued and Binary Functions, Design of Algorithms and Discrete Transforms, Design for Testability, Simulation, and Verification, Digital Signal and Image Processing Algorithms and Implementations in ASICs and FPGAs, Biomedical Image Compression and Watermarking.
Asst Prof Boon Chirn Chye(1) Awards: · PI: Ultra-low Power Fully Integrated CMOS 24GHz Receiver, $0.208mil ($0.323mil including scholarship), March 2008 to February 2011, AcRF Tier 1 MOE. · PI: Batteryless Flexible Transceiver for Biomedical Applications. $0.765mil ($0.995mil including scholarships), May 2009 to April 2012, AcRF Tier 2 MOE. · Co-PI: An Ultra Low-Power RFIC Chip For Wireless and Communication Applications S$1.2 mil, March 2006 to February 2009, funded by Agency for Science, Technology and Research (A*STAR). · Co-PI: System-on-chip: Realization of Software Radio, S$0.3 mil, 3 December 2008 to 2 December 2009, University of Electronic Science and Technology (UEST) of China-NTU Joint R&D, jointly funded by UEST and NTU. · Co-PI: An Ultra Low-Power RF Transceiver Chip towards a New Paradigm of Life Quality, $0.25 mil, 3 December 2008 to 2 December 2009, NRF. (2) Research Interest My research interests are in the areas of radio frequency (RF) circuits and systems design for Biomedical and Communications applications. For example ECG/Wheeze (Asthma)/Anti-Fall RF sensor network, next generation hand-phone and wireless local-area network (WLAN) design. I have been looking at methods to improve the design of transceivers (radios) for the above applications in order to achieve ultra-low power, low cost, small die size and good performance. Below is the brief description of my current works. (1) Transceiver Design for ultra-low power application. An example of my work in this area is in the ultra low-power voltage-controlled oscillator (VCO) design. This work was published in IEEE Transaction year 2004 and has six citations (ISI) so far. Another work which is on Low power LNA by my part-time PhD student (Aaron) was published in IEEE Transaction year 2008. (2) High Frequency Effects on Circuit Operation: Study and Solution Two examples of my work on this topic were published in IEEE Transaction year 2005 and IET Proceeding year 2004. (3) RF Components Modeling and Innovation Recently we have filed a patent together with our industry partner, Chartered Semiconductor on a new invention that will allow the quality factor of an integrated inductor to achieve 1000 times higher than conventional inductor. This work currently being pursued by my PhD student (Qiu Ping) is set to revolutionize the RFIC industry. (4) Next Generation High Frequency Circuit Design: Theory and Design A novel circuit was designed, fabricated and tested at 23GHz. This work was published in the last edition of E3 World (an EEE-NTU's publication).
Asst Prof Brendan Patrick OrnerThe overall research undertaken in our lab has two fundamental goals, both focused on the chemistry/biology interface. One goal is to develop new methods and technologes, while the second goal is to investigate fundamental questions. The philosophy of the lab is to mesh each of the goals so that they can feed into the other in a smooth and dynamic manner. The new technologies will be utilized to help answer fundamental questions and this basic research will necessitate the development of additional methods. The novel techniques will be developed with an eye on generality and additional applications. They will initially focus on combinatorial techniques that not merely employ vast collections of molecules, but unleash the power and intellectual statisfaction of focused design. The fundamental biological systems of interest will be focused on understanding the role protein-protein interactions play in the key cellular process of apoptosis (controlled cell death), how primary, secondary, and tertiary structure of proteins afeect their quaternary structure and self assembly proceses, and wheter it is possible to convert overly reactive, non-specific compounds into specific ones that target key HIV and Alzheimer's Disease proteins.
Assoc Prof Chai Gin BoayComposite Materials & Structures, Buckling and Failure of Structures, Practical Application of Finite Element softwares (ANSYS, ABAQUS, MARC/MENTAT).
Asst Prof Chan Chi ChiuHis research areas are optical fiber sensing system, fiber Bragg grating device, fiber optics chemical sensors, photonics crystal fiber biosensor, digital signal processing, such as artificial neural network, fuzzy logic, genetic algorithm, wavelet, etc., on smart structures, fiber optics chemical and biomedical sensing areas.
Asst Prof Chang Wook, MatthewProf. Chang's areas of expertise are systems biology, metabolic engineering, and engineering biology. His current research works focus on elucidating genetic regulatory networks and relevant cellular mechanisms in bacteria. The research group website: http://www.changlab.com/
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