Twins have long been the subject of studies in the quest to determine the influences of nature vs. nurture. Genetic influence on cerebral glucose metabolism played a major role in the bilateral parietal lobes and the left temporal lobe of the human brain, while environmental influences after birth dominated in other regions, suggested a new study, reported in The Journal of Nuclear Medicine.
An earlier study, published in the 'Nature Genetics' in May 2015, examined more than half a century of research collected on 14.5 million pairs of twins and concluded that the nature versus nurture debate is a draw; both have nearly identical influences on a person's traits and diseases. But we still didn't know specifically how nature and environment can affect our brains.
Now, researchers at Osaka University Graduate School of Medicine in Japan have begun to focus in on just that. In their study of 40 monozygotic (identical) and 18 dizygotic (fraternal) twin pairs, ages 30 or older, they used positron emission tomography (PET) scans with the radiopharmaceutical 2-deoxy-2-F-18-fluoro-D-glucose (FDG) targeting regional cerebral glucose metabolism. Eighteen control pairs matched genetically unrelated individuals of the same age and gender as the twins in the study.
They evaluated the F-18 FDG uptake in each cerebral lobe for the identical and fraternal twins as well as the controls. By comparing differences, they could estimate the genetic and environmental contributions.
Hatazawa notes that previous studies have revealed strong genetic influence on the volume of frontal gray matter, whereas this study shows that frontal glucose metabolism is preferentially influenced by environmental factors. Knowing which areas of the brain are more influenced by the environment will help with understanding particular neurological and psychiatric disorders.
He states, "The frontal lobes of monozygotic twins are anatomically identical, but they are metabolically and functionally different under environmental influences. This twin-imaging research can be applied to amyloid imaging in Alzheimer's disease and neurotransmitter-receptor imaging in psychiatric disorders where genetic, epigenetic and environmental influences remain unknown. In future twin studies, we may be able to identify specific environmental risk factors."