A new font tailored for people afflicted with dyslexia is now available for use on mobile devices, thanks to a design by Abelardo Gonzalez, a mobile app designer from New Hampshire. Gonzalez, in collaboration with educators, has selected a font that many people with dyslexia find easier to read. Even better, the new font is free and has already been made available for some word processors and ebook readers. The font, called OpenDyslexic, has also been added to the font choices used by Instapaper—a program that allows users to copy a web page and save it to their hard drive.

Cognitive signals for brain–machine interfaces in posterior parietal cortex include continuous 3D trajectory commands

Cortical neural prosthetics extract command signals from the brain with the goal to restore function in paralyzed or amputated patients. Continuous control signals can be extracted from the motor cortical areas, whereas neural activity from posterior parietal cortex (PPC) can be used to decode cognitive variables related to the goals of movement. Because typical activities of daily living comprise both continuous control tasks such as reaching, and tasks benefiting from discrete control such as typing on a keyboard, availability of both signals simultaneously would promise significant increases in performance and versatility. Here, we show that PPC can provide 3D hand trajectory information under natural conditions that would be encountered for prosthetic applications, thus allowing simultaneous extraction of continuous and discrete signals without requiring multisite surgical implants. We found that limb movements can be decoded robustly and with high accuracy from a small population of neural units under free gaze in a complex 3D point-to-point reaching task. Both animals’ brain-control performance improved rapidly with practice, resulting in faster target acquisition and increasing accuracy. These findings disprove the notion that the motor cortical areas are the only candidate areas for continuous prosthetic command signals and, rather, suggests that PPC can provide equally useful trajectory signals in addition to discrete, cognitive variables. Hybrid use of continuous and discrete signals from PPC may enable a new generation of neural prostheses providing superior performance and additional flexibility in addressing individual patient needs.

Auto experts recognize cars like most people recognize faces

When people – and monkeys – look at faces, a special part of their brain that is about the size of a blueberry “lights up.” Now, the most detailed brain-mapping study of the area yet conducted has confirmed that it isn’t limited to processing faces, as some experts have maintained, but instead serves as a general center of expertise for visual recognition.

Neuroscientists previously established that this region, which is called the fusiform face area (FFA) and is located in the temporal lobe, is responsible for a particularly effective form of visual recognition. But there has been an ongoing debate about whether this area is hard-wired to recognize faces because of their importance to us or if it is a more general mechanism that allows us to rapidly recognize objects that we work with extensively.

In the new study published this week in the online early edition of the Proceedings of the National Academy of Sciences, a team of Vanderbilt researchers report that they have recorded the activity in the FFAs of a group of automobile aficionados at extremely high resolution using one the most powerful MRI scanners available for human use and found no evidence that there is a special area devoted exclusively to facial recognition. Instead, they found that the FFA of the auto experts was filled with small, interspersed patches that respond strongly to photos of faces and autos both.

The New Medicine: Hacking Our Biology is part of the series “Engineers of the New Millennium” from IEEE Spectrum magazine and the Directorate for Engineering of the National Science Foundation. These stories explore technological advances in medical inventions to enhance and extend life.

Scientists at the Universities of Sheffield and Sussex are embarking on an ambitious project to produce the first accurate computer models of a honey bee brain in a bid to advance our understanding of Artificial Intelligence (AI), and how animals think.

The team will build models of the systems in the brain that govern a honey bee’s vision and sense of smell. Using this information, the researchers aim to create the first flying robot able to sense and act as autonomously as a bee, rather than just carry out a pre-programmed set of instructions.

If successful, this project will meet one of the major challenges of modern science: building a robot brain that can perform complex tasks as well as the brain of an animal. Tasks the robot will be expected to perform, for example, will include finding the source of particular odours or gases in the same way that a bee can identify particular flowers.

It is anticipated that the artificial brain could eventually be used in applications such as search and rescue missions, or even mechanical pollination of crops.

Neuroscientists today can preserve small volumes (<1mm³) of animal brain tissue immediately after death with incredible precision — the features and structure of every synapse within these volumes is well-protected down to the nanometer scale, using an inexpensive, room-temperature process of chemical fixation and plastic embedding, or “plastination.” This image is an example of plastination and local circuit tracing, occurring in leading neuroscience labs around the world today. (Credit: Brain Preservation Foundation)

Chemical brain preservation: how to live ‘forever’ — a personal view

What the brain draws from: Art and neuroscience

The human brain is wired in such a way that we can make sense of lines, colors and patterns on a flat canvas. Artists throughout human history have figured out ways to create illusions such as depth and brightness that aren’t actually there but make works of art seem somehow more real.

And while individual tastes are varied and have cultural influences, the brain also seems to respond especially strongly to certain artistic conventions that mimic what we see in nature.

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15 Studied Effects of Classical Music on Your Brain

Classical music, whether you love it or hate it, has been a powerful cultural force for centuries. While it no longer dominates the music scene, the argument for continued appreciation of the genre goes far beyond pure aural aesthetics. Classical music has been lauded for its ability to do everything from improve intelligence to reduce stress, and despite some exaggeration of its benefits, science shows us that it actually does have a marked effect on the brain in a number of positive ways.

With September being Classical Music Month, there’s no better time to learn a bit more about some of the many ways classical music affects the brain. Over the past few decades, there have been numerous studies on the brain’s reaction to classical music, and we’ve shared the most relevant, interesting, and surprising here, some of which may motivate you to become a classical aficionado yourself.