Summary: New research revealed compelling evidence that caregiver speech significantly enhances infants’ brain development and long-term language abilities.
Using MRI and audio recordings, the researchers demonstrated a clear association between the amount of words infants hear from their caregivers and the development of their brain’s white matter, which facilitates information processing.
The study suggests that parental engagement in the form of verbal interaction can be a potent tool in fostering their children’s cognitive development. This work emphasizes the role of parents as agents of change in their children’s lives.
Key Facts:
- The study utilized MRI and audio recordings to demonstrate that caregiver speech boosts infants’ brain development, particularly in the areas associated with long-term language abilities.
- The researchers found that infants who heard more words had lower fractional anisotropy (FA) values, indicating slower development of white matter – this is associated with better language performance as they grow.
- The study highlights the potential of parents as significant change agents in their children’s development.
Source: UT Dallas
A team led by a University of Texas at Dallas neurodevelopment researcher has uncovered some of the most conclusive evidence yet that parents who talk more to their infants improve their babies’ brain development.
The researchers used MRI and audio recordings to demonstrate that caregiver speech is associated with infant brain development in ways that improve long-term language progress. Dr. Meghan Swanson, assistant professor of psychology in the School of Behavioral and Brain Sciences, is corresponding author of the study, which was published online April 11 and in the June print edition of Developmental Cognitive Neuroscience.
“This paper is a step toward understanding why children who hear more words go on to have better language skills and what process facilitates that mechanism,” Swanson said.
“Ours is one of two new papers that are the first to show links between caregiver speech and how the brain’s white matter develops.”
White matter in the brain facilitates communication between various gray matter regions, where information processing takes place in the brain.
The research included 52 infants from the Infant Brain Imaging Study (IBIS), a National Institutes of Health-funded Autism Center of Excellence project involving eight universities in the U.S. and Canada and clinical sites in Seattle, Philadelphia, St. Louis, Minneapolis, and Chapel Hill, North Carolina.
Home language recordings were collected when children were 9 months old and again six months later, and MRIs were performed at 3 months old and 6 months old, and at ages 1 and 2.
“This timing of home recordings was chosen because it straddles the emergence of words,” Swanson said. “We wanted to capture both this prelinguistic, babbling time frame, as well as a point after or near the emergence of talking.”
It’s long been known that an infant’s home environment — especially the quality of caregiver speech — directly influences language acquisition, but the mechanisms behind this are unclear. Swanson’s team imaged several areas of the brain’s white matter, focusing on developing neurological pathways.
“The arcuate fasciculus is the fiber tract that everyone in neurobiology courses learns is essential to producing and understanding language, but that finding is based on adult brains,” Swanson said.
“In these children, we looked at other potentially meaningful fiber tracts as well, including the uncinate fasciculus, which has been linked to learning and memory.”
The researchers used the images to measure fractional anisotropy (FA). This metric for the freedom or restriction of water movement in the brain is used as a proxy for the progress of white matter development.
“As a fiber track matures, water movement becomes more restricted, and the brain’s structure becomes more coherent,” Swanson said. “Because babies aren’t born with highly specialized brains, one might expect that networks that support a given cognitive skill start out more diffuse and then become more specialized.”
Swanson’s team found that infants who heard more words had lower FA values, indicating that the structure of their white matter was slower to develop. The children went on to have better linguistic performance when they began to talk.
The study’s results align with other recent research showing that slower maturation of white matter confers a cognitive advantage.
“As a brain matures, it becomes less plastic — networks get set in place. But from a neurobiological standpoint, infancy is unlike any other time. An infant brain seems to rely on a prolonged period of plasticity to learn certain skills,” Swanson said.
“The results show a clear, striking negative association between FA and child vocalization.”
Sharnya Govindaraj, co-first author of the paper, a cognition and neuroscience doctoral student and a member of Swanson’s Baby Brain Lab, said at first she was surprised by the results.
“We initially didn’t know how to interpret these negative associations that seemed very counterintuitive. The whole concept of neuroplasticity and absorbing new knowledge had to fall into place,” she said. “Which ability we’re looking at also matters a great deal, because something like vision matures much earlier than language.”
As the parent of a toddler in a bilingual household, Swanson was curious about how this relationship functions for infants exposed to more than one language.
“Raising a bilingual child, it is remarkable how she is not confused by languages, and she knows who she can use which language with,” Swanson said.
Swanson said she also has gained a deeper level of appreciation and gratitude for what she, as a researcher, asks parents in her studies to do.
“When participants sign up, I’m asking them to commit to a year and a half,” she said. “Because of the commitment of all the parents in prior studies, I and others have the knowledge that allows us to communicate with our children in a way that supports their development.”
Swanson said the take-home message is that parents have the power to help their children develop.
“This work highlights parents as change agents in their children’s lives, with the potential to have enormous protective effects,” Swanson said. “I hope our work empowers parents with the knowledge and skills to support their children as best they can.”
Other authors of the paper associated with UT Dallas are co-first author Katiana Estrada MS’22, now a doctoral student at Purdue University; professor of psychology Dr. Hervé Abdi; and Luke Moraglia, a cognition and neuroscience doctoral student.
Additional authors are from the University of North Carolina at Chapel Hill, the University of Minnesota Twin Cities, the University of Washington in Seattle, Washington University School of Medicine in St. Louis, the University of Alberta, and the National Institute of Mental Health and Neuro-Sciences in India.
Funding: This work was funded in part by a Pathway to Independence Award (K99MH108700, R00MH108700) from the National Institute of Mental Health, a component of the NIH.
About this neurodevelopment research news
Author: Stephen Fontenot
Source: UT Dallas
Contact: Stephen Fontenot – UT Dallas
Image: The image is credited to Neuroscience News
Original Research: Open access.
“Language exposure during infancy is negatively associated with white matter microstructure in the arcuate fasciculus” by Meghan Swanson et al. Developmental Cognitive Neuroscience
Abstract
Language exposure during infancy is negatively associated with white matter microstructure in the arcuate fasciculus
Decades of research have established that the home language environment, especially quality of caregiver speech, supports language acquisition during infancy.
However, the neural mechanisms behind this phenomenon remain under studied. In the current study, we examined associations between the home language environment and structural coherence of white matter tracts in 52 typically developing infants from English speaking homes in a western society. Infants participated in at least one MRI brain scan when they were 3, 6, 12, and/or 24 months old.
Home language recordings were collected when infants were 9 and/or 15 months old. General linear regression models indicated that infants who heard the most adult words and participated in the most conversational turns at 9 months of age also had the lowest fractional anisotropy in the left posterior parieto-temporal arcuate fasciculus at 24 months.
Similarly, infants who vocalized the most at 9 months also had the lowest fractional anisotropy in the same tract at 6 months of age. This is one of the first studies to report significant associations between caregiver speech collected in the home and white matter structural coherence in the infant brain.
The results are in line with prior work showing that protracted white matter development during infancy confers a cognitive advantage.
