ADHD is a neurodevelopmental disorder with a high heritability, in which the genetic component consists of thousands of genetic variants. Most variants only slightly increase the likelihood of receiving the diagnosis. Now an international study led by researchers from iPSYCH at Aarhus University has shown that rare high-effect genetic variants also play an important role.

The study has been published in Nature, and the researchers have found a markedly increased likelihood of developing ADHD among individuals carrying rare variants in three genes—MAP1A, ANO8 and ANK2—in some cases by up to 15 times.

These genetic variants are very rare, but when present, the study shows that they strongly affect genes expressed in the brain’s nerve cells. In individuals carrying these variants, the development and communication between nerve cells may therefore be disrupted, which can result in ADHD.

By: Alastair Waterman https://www.facebook.com/share/p/1N1TBvEKuF/

Why does red feel exactly like red, green exactly like green, and why can these two experiences never, ever swap places?

Most current theories of consciousness have no real answer. They explain how the brain detects wavelength, but not why one neural pattern feels “red” and its literal opponent feels “green”

Refusal-Driven Dimensionality Reduction Theory (RDRT) offers the first direct mechanism.

Colour vision is opponent at every level: red and green are mutually exclusive from retina → LGN → V1 → V4 → inferotemporal cortex.

This hard-wired mutual exclusion is a multi-level structural refusal.

The claim: The specific feeling of redness is not the spikes that are transmitted.

It is the precise, reproducible shape of what is refused transmission — a stable ~55–65-event “hole” carved into each gamma cycle in the anterior cingulate cortex and self-monitoring networks.

Sea urchins may just look like a ball of spikes waiting to be stepped on at the tide pool, but there’s much more to these barbed beasts than just roe and teeth.

New research reveals sea urchin nervous systems are far more complex than we knew. These creatures, it turns out, possess ‘all-body brains’ and, at least in their genetic layout, they are remarkably similar to our own.

A team of scientists led by developmental biologist Periklis Paganos from Stazione Zoologica Anton Dohrn in Italy made the discovery while investigating metamorphosis in purple sea urchins (Paracentrotus lividus), which transform from free-swimming, planktonic larvae to the mature, spine-encrusted form we’re more familiar with.

Tools that track specific molecules in neurons have enabled researchers to probe previously unexplored aspects of neurobiology — although important caveats remain.