Facilities

The research labs of our graduate faculty members provide a wide range of facilities for research in biological, physical, and computational sciences. The following – non exhaustive – list describes the research facilities available in the labs of some of our graduate faculty members:

  • Dr. Ackerman's Physical Ecology lab (SCIENCE COMPLEX 2407 and AQUALAB 163, Department of Integrative Biology) is equipped to examine small and large scale fluid dynamic processes in laboratory flow chambers and in the field. Acoustic Doppler Velocimeter, Constant Temperature Anemometer, Digital Particle Imaging Velocimeter, and Laser Induced Fluorometry can be used in a number of custom flow chambers.  A Imaging Flow Cytometer can be used in the lab and/or in the field along with uSquid Eddy Covariance System, Acoustic Doppler Velocimeter, Ultrasonic Doppler Velocimeters, Acoustic Doppler Current Profiler, DO Loggers, Fluorometers, Weather station, Turbidity Loggers and a variety of other instruments. Computational Fluid Dynamic Modelling software (COMSOL, MATLAB) is run on a DELL Xenon workstation (16G Ram) and via ANSYS on a supercomputing facilities.
  • Dr. Anand's Forest Ecology Laboratory (Bovey building 1233, School of Environmental Sciences) is equipped with electronic scales, grinders, data loggers, meteorological equipment, field equipment, computers and scanners for leaf area and tree ring measurements. Her computational lab (Bovey building 2102, School of Environmental Sciences) is equipped with 7 enhanced Apple MacPro computer workstations that are networked locally to create a local high performance computing facility. Specialized software in data management and processing, as well as for model development include MATLAB, Mplus, CORMAS, NETLOGO –agent-based modeling platforms, and R project.
  • Dr Ashlock's lab maintains two computers each with eight processors for running simulations connected with student research. One is located in 521 MacNaughton (Dept. Math & Stats) and accessible through the net, the other is maintained off site and accessible through e-mail only.
  • Dr. Bent’s Neurophysiology lab (Animal Science and Nutrition building, room 373, Department Human Health and Nutritional Science) studies the neural mechanisms of human movement from peripheral to central with focus on the cutaneous and vestibular systems. As such the lab is equipped with a microneurography facility to perform single nerve recordings including Cambridge electronic design (CED) interface (spike 2 version7 software), WPI amplifiers and a Grass stimulator(S88). We research sensory input, including vibration, using a mini shaker system (Bruel&Kjaer 4810) interfaced with vibration view software. The lab also looks at whole body postural control using a 3D optotrak system, AMTI forceplate, Bortec EMG system and can test the system using Galvanic Vestibular Stimulation (GVS) and Transcranial Magnetic Stimulation (TMS).
  • Dr. (Leonid) Brown's lab (MacNaughton 022(shared)/024/025, Dept. Physics) is equipped with advanced equipment for spectroscopic characterization of membrane proteins as well as with general purpose equipment for biological sample preparation. The spectroscopic equipment includes UV-Vis spectrophotometer, time-resolve laser spectrometer in the visible range, time-resolved FTIR spectrometer, and FT-Raman spectrometer. The biological sample preparation equipment includes temperature controlled shakers, numerous centrifuges, freezers, autoclave, thermal cycler, electrophoresis set-up, incubators, gel-imager, French press, and sonic dismembrator.
  • Dr (Steve) Brown’s Spine and Muscle Biomechanics lab (ANNU 358/362, Dept Human Health & Nutritional Sciences) is equipped for both human and animal/tissue testing. The human lab is comprised of state of the art systems to record human movement (motion capture), forces (force plates and transducers), muscle activation (electromyography), and tissue images (ultrasound). The animal/tissue lab is comprised of systems to test the mechanical properties of muscle cells and other soft tissues, including the measurement of muscle sarcomere lengths via laser diffraction. Finally, computer software (Matlab, LabView) is used for computational modeling of biomechanical systems.
  • Dr Chiu's involvement in the program is supported by the  School of Computer Science by providing the following hardware and software support for research: 1) Virtual Machines to provide graduate students with a platform to perform research, 2) Software through the CCS software distribution site (being a student with SoCS as home department includes a subscription to Dreamspark Premium, which other departments may not offer), 3) Grad students also have access to our undergraduate lab facilities, including our computer labs, git server, svn server, database server, etc.
  • Dr Dutcher's Soft Matter and Biological Physics Lab (MacNaughton 532/534/537/015/016/017/022, Dept. of Physics) is equipped with a large amount of research infrastructure for use by Dr. Dutcher's students in biological physics. The instrumentation includes four atomic force microscopes (Bruker, Agilent, Asylum and JPK); four optical microscopes (Olympus, Nikon; fluorescence, total internal reflection fluorescence); custom self-nulling ellipsometer; custom surface plasmon resonance imaging system; dynamic light scattering spectrometer (Brookhaven); attenuated total reflection FTIR spectrometer (Bruker); two UV-Vis-NIR spectrophotometers (Thermo Scientific, Ocean Optics); spin-coater (Headway); high pressure emulsifier (Bee International); ultrapure water facility (Millipore); -80 deg C freezer (Thermo Scientific); incubator/shakers (Thermo Scientific); autoclave (Tuttnauer); biological safety cabinet (Thermo Scientific); ultracentrifuge (Thermo Scientific); Langmuir trough (KSV); lyophilizer; ultrafiltration system (Pall).
  • Dr. Eberl's Computational Biomathematics Lab (MacNaughton 501/505/506, Dept. Mathematics and Statistics) is equipped with several highend linux workstations for computational work. Research and development specific software include compilers (Intel, gnu, Portland Group, python), visualisation software (paraview, gnuplot), general purpose scientific software (R, Octave, Scilab, Matlab), and special purpose scientific software (AdinaFSI, OpenFOAM, DiDo).
  • Dr Fudge’s Comparative Biomaterials Lab (SSC 3409/10, Dept of Integrative Biology) is equipped with an Instron Universal Testing Machine, an MTS NanoBionix tensile tester, a Nikon Eclipse 90i upright motorized epifluorescent microscope and imaging system, as well as cell culture facilities.
  • Dr. Graether’s Structural Biology Lab (SSC 2205, 2225, Department of Molecular and Cellular Biology) is equipped with all the equipment for the expression, purification and biochemical characterization of recombinant proteins. NMR data collection occurs at the University of Guelph NMR Centre, a world-class facility with several high field magnets (two 600 MHz, one 800 MHz and a 600 MHz with dynamic nuclear polarization capability). We perform structural and bioinformatical analysis on several systems with specialized software (TopSpin, nmrPipe, CCPN suite, CNS, MEME, HADDOCK) and in-house written software. Departmental equipment includes access to fluorescence and circular dichroism spectrometers with stop-flow capabilities.
  • Dr. Harauz's primary lab infrastructure (SCIE 3404 and associated support rooms in SCIE, Dept. Molecular and Cellular Biology) includes protein over-expression (E. coli) and purification (HPLC and FPLC), spectroscopy (fluorescence, CD, FTIR/ATR, simple solution EPR), isothermal titration calorimetry (ITC), differential scanning calorimetry (DSC), dynamic light scattering (DLS), and microscopy (immunofluorescence, multiphoton confocal, scanning probe, and electron). Our NMR Centre has dedicated Bruker Avance NMR spectrometers: 500, 600, and 800 MHz solid-state, and 600 MHz solution state with cryoprobe. A new DNP (dynamic nuclear polarization) NMR spectrometer provides significant enhancements in sensitivity of ssNMR measurements. Computational facilities for data analysis and molecular dynamics (MD) simulations are in-house (Linux workstations), with access to the SharcNet high-performance computing network.
  • Dr. Hurtig's Canadian Arthritis Network Preclinical laboratory (Ontario Veterinary College, Building #123, Department of Clinical Studies) is equipped with a three axis semi-automated biomechanical testing device (Mach-1) with computational software for triphasic modelling of soft tissues, a microCT imaging device (27 micron resolution), as well as histology, morphometry, immunohistochemistry, tissue culture and biochemistry facilities for characterizing tissue. Animal care and surgical facilities are also available.
  • Dr. Jelokhani-Niaraki’s Biophysical Chemistry Lab (Science Research Centre SR421 and SR424, Dept. Chemistry and Biochemistry, Wilfrid Laurier University, Waterloo) is equipped with a molecular biology setup for recombinant protein expression and purification, as well as a setup for peptide synthesis and purification (including HPLC, LC-Mass Spectrometer and a peptide synthesizer). This Lab is also equipped with modern biophysical instrumentation including circular dichroism, UV-visible and fluorescence spectrometers, a patch-clamp setup, a micro Langmuir trough, a surface plasmon resonance instrument, an isothermal titration calorimeter and a Silicon Graphics workstation for molecular modelling.
  • Dr. Khursigara’s Lab works closely with the UoG Molecular and Cellular Imaging Facility. The facility hosts a wide range of optical microscopes including a state of the art spinning-disk confocal/super-resoltuon imaging system (Quorum), a Leica SP5 confocal laser scanning microscope and an array of other fluorescence scopes dedicated to fixed and live cell imaging. The facility also boasts two transmission electron microscopes (FEI TF20 and CM10), which offer a wide range of imaging solutions for both material and biological sciences, including cryogenic specimens and tomography. A scanning electron microscope (FEI Quanta 250 FEG) rounds out the electron imaging capabilities of the lab.
  • Dr. Ladizhansky's group uses the University of Guelph nuclear magnetic resonance centre, which is part of the Advanced Analysis Centre, located in the Science Complex and in the McNaughton building. His group uses an array of solid state NMR spectrometers operating at fields ranging from 500 MHz to 800 MHz, and the only in Canada Dynamic Nuclear Polarization NMR machine. Research equipment available to his group also includes wet lab located in the Science Complex, as well as common sample preparation lab in the Department of Physics (shakers, freezers, centrifuges, etc).
  • Dr. Marangoni's Food and Soft Materials Laboratory (Food Science 223/229) is equipped with state of the art soft materials characterization instruments including powder X-ray diffraction, small deformation oscillatory rheology, large deformation mechanical testing, all forms of electron microscopy and cryogenic scanning electron microscopy, time-resolved pulsed NMR, refractometry, turbidimetry, differential scanning calorimetry, ultrasonic spectrometry and static dielectric spectrometry. The laboratory is managed by a permanent research associated in charge of developing and updating standard operating procedures, maintaining and updating equipment, and training all personnel. The laboratory also has access to confocal microscopes, transmission electron microscopes and synchrotron X-ray diffraction facilities.
  • Dr. Neethirajan's BioNano Lab at the School of Engineering (Thornbrough, Room 2133) is a state-of-the-art laboratory. With 1200 Sq.ft. of laboratory space including bacterial and tissue culture space, the infrastructure includes an Atomic Force Microscopy with Kelvin Probe and Conductive Scanning Probe Microscopy, Nikon Ti-Eclipse Inverted Microscope for live-cell fluorescence imaging, a table top Scanning Electron Microscope, a suit of photo-lithography instruments and equipment. The laboratory can accommodate up to 11 people, and is equipped with one 4-ft biohazard hoods for bacterial, fungi and tissue culture work and incubators. In addition, a 300 sq. ft. space is also available for growing cells in shaker flasks. The lab is also equipped with Mac and Windows desktop and laptop computers, which are sufficient for word processing, data analysis, and relevant computational needs required for this project.
  • Dr. Oliver’s Biomechanics research space (Thornbrough 1131/1311/1108, School of Engineering) is equipped with a variety of cutting edge equipment including a 6 degree of freedom hexapod robot dynamic heavy equipment/car simulator coupled with a 7 Bonita camera VICON motion capture system. Oliver is one of three faculty members which comprise the DRiVE Lab (Driving Research in Virtual Environments). The DRiVE lab is equipped with a full sized Pontiac G6 OKTAL static car simulator as well as a 12 T-160 camera VICON motion capture system.  Both simulator laboratories incorporate visual as well as haptic feedback. The dynamic simulator includes a pair of haptic controls coupled with a virtual reality head mount display whereas the OKTAL simulator uses 6 high definition projectors to provide 300 degrees of coverage on the wrap around screens.  Other general laboratory equipment include a servohydraulic Instron Materials testing machine housed in a level 2 biohazard laboratory, two Delsys and one Noraxon surface electromyography systems, and a Chatillon Force gauge.
  • Research done by Dr. Pink's group utilizes the ACEnet (Compute Canada) clusters or the high end work stations of his colleagues. These linux-based systems possess all software for atomic scale molecular dynamics, dissipative particle dynamics, and Monte Carlo simulations together with analysis software. They are located at various places in Canada and are set up to be accessed remotely.
  • Dr (William) Smith's Molecular Simulation Laboratory (MacNaughton 553, Dept. Mathematics and Statistics) is equipped with several Windows PCs with internet  access.  They are networked and equipped with software used for data manipulation and visualization, manuscript preparation, and software development (SigmaPlot, MATLAB, Absoft FORTRAN, Endnote, Adobe Professional, various MS Windows utility software). Large-scale computations are run on the SHARCNET grid computing network.
  • Dr. Jeff Thomason's lab, which is focused on the Biomechanics of Equine Locomotion ( OVC-Biomedical Sciences 2605-07), contains amplifying and datalogging equipment (National Instruments and DTS) for collecting biomechanical data from the limbs of exercising horses in the field, and mid-range computers for data reduction and analysis in the lab. Acquisition software is proprietary (DTS) or written in LabView or Matlab; analysis uses routines in Matlab, SAS and Excel.
  • Dr. Vallis' Gait Bomechanics Laboratory (Animal Science building Room 273; Dept. Human Health & Nutritional Science) is equipped with several high speed 3D cameras (Northern Digital, Inc) for capturing Kinematic data during human movement as well as a visual gaze monitoring system (ISCAN, Inc), a portable force plate (AMTI Accugait), a 7-meter long instrumented carpet for monitoring spatial temporal parameters of gait (GaitRite) as well as workstations for computational work. Research specific software include First Principles, Visual 3D, Labview and MatLab.
  • Dr. Wickham's Computational Soft Materials and Biophysics group in the Dept. of Physics uses the  SHARCNET facility for computational work. Techniques include molecular dynamics, Monte Carlo, dynamical self-consistent field theory, and finite-difference approaches to field theory. These are applied to problems in biophysics and polymer physics.
  • Dr Wood's laboratory (SSC4205B, Dept. of Molecular and Cellular Biology) is equipped for biophysical, biochemical, molecular biological, genetic and microbiological studies on the structure and function of bacterial membrane proteins. Capabilites include the genetic engineering and culturing of organisms to produce membrane proteins and their variants, purification and reconstitution of those proteins in artificial membrane systems, and analysis of protein structure and function via radioisotope uptake assays and the application of biophysical tools available through the Advanced Analysis Centre and other BIG labs.
  • Dr. Zettel's Movement and Posture Lab (Maple) studies the underlying organization of motor control of human movement, from both a mechanical and sensorimotor perspective. Sophisticated equipment for movement analysis includes high-precision kinematic systems (Optitrack, Optotrak), force plates, and electromyography units. A focal feature of the lab are studying balance reaction responses: a large (2x6m) moveable platform translates to generate balance perturbations to participants standing atop it, and can be done in different conditions (e.g. standing, gait) and different populations (e.g. older adults, Parkinson's). Analysis is conducted in accompanying neuro-mechanical software (Visual3D), as well as custom programs (MATLAB, LabVIEW).