There are several physiological reasons why biological organisms sleep. One key one concerns brain metabolism. In our article we discuss the role of metabolism in myelin, based on the recent discovery that myelin contains mitochondrial components that enable the production of adenosine triphosphate (ATP) via oxidative phosphorylation (OXPHOS). These mitochondrial components in myelin probably originate from vesiculation of the mitochondrial membranes in form from mitochondrial derived vesicles (MDVs). We hypothesize that myelin acts as a proton capacitor, accumulating energy in the form of protons during sleep and converting it to ATP via OXPHOS during wakefulness. Empirical evidence supporting our hypothesis is discussed, including data on myelin metabolic activity, MDVs, and allometric scaling between white matter volume and sleep duration in mammals.

Vision is one of the most crucial human senses, yet more than 300 million people worldwide are at risk of vision loss due to various retinal diseases. While recent advancements in retinal disease treatments have successfully slowed disease progression, no effective therapy has been developed to restore already lost vision—until now.

KAIST researchers led by Professor Jinwoo Kim from the Department of Biological Sciences have successfully developed a novel drug to restore vision through retinal nerve regeneration. The research is published in the journal Nature Communications. The study was co-authored by Dr. Eun Jung Lee of Celliaz Inc. and Museong Kim, a Ph.D. candidate at KAIST, as joint first authors.

The research team successfully induced neural regeneration and vision recovery in a disease-model mouse by administering a compound that blocks the PROX1 (Prospero Homeobox 1) protein, which suppresses retinal regeneration. The effect lasted for more than six months.

Statistics suggest that the size of families in many countries is shrinking and a growing number of parents worldwide either willingly or unwillingly end up only having one child. While many psychology studies have explored the differences between individuals who have siblings and those who don’t, the effects of not having any brothers or sisters on people’s brains and behavior are not yet fully understood.

Past research has yielded varying and sometimes contradictory results, which sometimes hinted at negative effects of being an only child and other times highlighted its positive implications. In addition, these negative and positive effects were found to be inconsistent across studies, with some studies suggesting that only children tend to do better at school, are more pro-social and less problematic, while others showed the opposite.

Researchers at Tianjin Medical University General Hospital and other institutes in China recently carried out a study aimed at better understanding how being an only child affects people’s brain and behavior during adulthood. Their findings, published in Nature Human Behaviour, highlight specific patterns in the brain’s development and activity, as well as behavioral tendencies, that are commonly observed in adults who grew up without siblings.