A study led by McGill University researchers has demonstrated that small differences between individuals at the DNA level can lead to dramatic differences in the way genes produce proteins. These, in turn, are responsible for the vast array of differences in physical characteristics between individuals. The study, part of the Genome Regulators in Disease (GRID) Project funded by Genome Canada and Genome Quebec, was led by Dr. Jacek Majewski of McGill University’s Department of Human Genetics and the McGill University and Genome Quebec Innovation Centre, and first-authored by his research associate Dr. Tony Kwan. It was published January 13 in the journal Nature Genetics.

The human brain is capable of detecting the slightest visual and auditory changes. Whether it is the flash of a student’s hand into the air or the faintest miscue of a flutist, the brain instantaneously and effortlessly perceives changes in our environment. Several studies have indicated, however, that even a small span of time in between pre- and post-change images can disturb the brain’s ability to detect visual discrepancies.

Umeå findings raise the question: Can hantavirus infection spread among humans?

Genetically engineered products have become indispensable. For example, genetically modified bacteria produce human insulin. In future, gene therapy should make it possible to introduce genes into the cells of a diseased organism so that they can address deficiencies to compensate for malfunctions in the body. In order for this to work, foreign (or synthetic) DNA must be introduced into host cells, which is not exactly a trivial task. Japanese researchers have now developed a method which could represent a true alternative to conventional processes. As described in the journal Angewandte Chemie, the cells are “bombarded” with water droplets produced and accelerated by electrospray.

The full recovery of ecological systems, following the most devastating extinction event of all time, took at least 30 million years, according to new research from the University of Bristol.

Researchers from the Université de Montréal have used a supercomputer to conduct the largest-ever mathematical simulation of the electrical activity of a human heart – a 2 billion element model – to provide new insight into cardiac and other illnesses. Until recently, the world’s largest simulated hearts had a few million elements at most. The UdeM simulation was up to 1,000 times more detailed than previous models and will enable new scientific discoveries that would never have been possible otherwise.