Advances to the Biochemical, Genetic and Genomic (BiGG) Database

submitted by: jypark
The BiGG database is a widely used resource for sharing genome-scale metabolic reconstructions. BiGG integrates several published genome-scale metabolic networks into one resource with standard nomenclature which allows components to be compared across different species. Furthermore, BiGG contains links to several publicly available databases where additional information can be found and integrated. In addition, BiGG contains a customized export tool that enables the generation of SBML...

How Real Can We Be? Experiencing the Virtual Reality: A Dynamic 3D Model of the Calit2 Building

submitted by: zmz45

Building from an existing project in the Calit2 Immersive Visualization Lab, this research continues to develop a 3D digital model of the Calit2 building and its surroundings, where dynamic elements such as light sources, operating elevators, and automatic doors were added to offer a realistic sense to the artificial model.

D1.3.9-v1-Simulation and evaluation of realistic MEU ad-hoc communications in CARLINK scenarios by using VanetMobiSim/Ns-2

submitted by: jamal.toutouh

This video is part of CARLINK PROJECT simulation videos. It presents the performance of communications in Vehicular Ad-hoc Networks (VANETs) using the IEEE 802.11b standard in the transmission of files located in real enironments based on real areas of Malaga.
- Jamal Toutouh -

Tumour cords' growth in a vascular network

submitted by: sast
Evolutions of oxygen concentration and formation of hypoxic zones during tumour growth in the vascular network . This simulation was produced with an experimental modification to the model, where vessels are oxygen sources inside the simulation domain, cells do not switch to anaerobic metabolism in this simulation. For more information refer to http://code.google.com/p/cord/ .

1.3.6.-v2-Multi-hop VANETs Simulation using VanetMobiSim/Ns-2 (Scenario B)

submitted by: jamal.toutouh

This video is part of CARLINK PROJECT simulation videos. It presents the performance of communications in Vehicular Ad-hoc Networks (VANETs) using the IEEE 802.11b standard in the transmission of files.
- Jamal Toutouh -

ATP deficit in oxygen-limited tumour cord growth (FF++)

submitted by: sast
This is a simulation of tumour cord growth , where cells suffer from hypoxia (energy deficit shown with colour). The tumour grows along the blood vessel (coincides with x -axis). Red line shows the position of the tumour–host interface. This particular simulation was programmed in FreeFEM++ out of curiousity. The source code for simulation may be found at http://code.google.com/p/cord . This video reflects work in progress and may be different from the final results .

1.3.6.-v1-Multi-hop VANETs Simulation using VanetMobiSim/Ns-2 (Scenario A)

submitted by: jamal.toutouh

This video is part of CARLINK PROJECT simulation videos. It presents the performance of communications in Vehicular Ad-hoc Networks (VANETs) using the IEEE 802.11b standard in the transmission of files.
- Jamal Toutouh -

Modern Transportation and Infectious Disease – MWV15

submitted by: MicrobeWorld
From your local bus route to international air travel, infectious diseases can spread across the globe in a matter of hours. In this video podcast episode filmed at the Koshland Science Museum in Washington, D.C., Stephen Eubank from the Virginia Bioinformatics Institute of Virginia Tech and Daniel Lucey from Georgetown University discuss the role of transportation in the spread of disease and examine the effectiveness of various measures to curb transmission. Stephen Eubank, Ph.D., is a...

Vehicular Ad-hoc Network Simulations with JANE

submitted by: sebastian

In this video we use the JANE simulator to present the relation between the performance of the IEEE 802.11b standard and the number of hops involved in the transmission of files when using car-to-car communications in Vehicular Ad-hoc Networks (VANETs). For more info, please visit: CARLINK

Tissue movement in bipopulation tumour cord growth

submitted by: sast

Simulation of tumour cord growth where conversion of the tumour to glycolytic (anaerobic) metabolism takes place under hypoxia. This video shows volume fraction of glycolytic cell population and velocity of tissue movement. Isolines show hypoxia limits for aerobic and anaerobic cell lines respectively. This video reflects work in progress and may be different from the final results.