Traditionally, when students are tested on a subject, they use paper and pencil, or perhaps a computer, to demonstrate what they have learned. But what if brain scans could show them in the act of acquiring knowledge and then applying it to questions and problems?
That鈥檚 the question driving research being done by , assistant professor of education and a graduate adviser in psychological brain sciences, with his team of graduate and undergraduate students at the in the .
鈥淲e are looking for patterns of brain activity that are meaningfully related to having learned something, versus not having learned it. There鈥檚 very little data on how learning something in school changes the brain, especially at the level of an individual student,鈥 says Kraemer.
Lab members use advanced technology, including fMRI scans and virtual reality devices, to map the experiences, conditions, and strategies that lead to successful learning. Kraemer works closely with and , both associate professors of computer science, among other faculty.
A common thread runs through the lab鈥檚 work: the examination of learning in the minds of individuals. But the aims of specific experiments vary widely. For example, the results of one study may help teachers teach STEM concepts more effectively. Another set of experiments could enable sign-language learners to advance more quickly. And a third project explores how to prevent people from processing information in a way that is largely biased by their prior beliefs.
Is This Bridge Going to Fall Down?
The lab鈥檚 STEM learning study, in collaboration with , a professor of engineering at , and , an associate professor of engineering at Thayer, looks at differences in the way intermediate engineering students versus peers with no advanced physics or engineering education grasp concepts relating to the stability of structures. Joshua Cetron 鈥16 also worked on this project, first for his neuroscience senior honors thesis and then as a full-time researcher in the lab.
Both groups were given a brief overview of Newton鈥檚 third law: For every action there is an equal and opposite reaction. They were then shown pictures鈥攂ridges, lampposts, buildings, and so on鈥攁nd asked whether arrows superimposed on the images accurately described the forces at work. The intermediate engineering students were correct about 75 percent of the time, while their novice peers were correct about half the time (which is the same as guessing).
The test scores correlated with brain scans. 鈥淭he two groups are literally seeing the same thing,鈥 Kraemer says, referring to sections in the scans where visual processing takes place. 鈥淏ut they are thinking about what they see in different ways.鈥
The brains of the more advanced engineering students showed neural activity in places where the beginners鈥 brains were less active: in the motor cortex, which, interestingly, controls the hands, as well as regions of visual cortex that process higher-level categorical knowledge. This raises the possibility that successful learners gain valuable information through hands-on instruction, a hypothesis the team is now testing in a follow-up study.
鈥淭he results can be pretty meaningful for developers of educational curriculums, for example,鈥 says Kraemer. 鈥淎s you鈥檙e developing an instructional approach, you might have focus groups, with one class learning in one way and another learning in a different way. You could give them a test at the end to see how much they learned, but also give them a brain scan, to see if the brain test and the traditional test together can predict which curriculum leads to better learning and long-term retention.鈥
Learning American Sign Language
Another study about cognition could change the way American sign language (ASL) is taught online. Participants wear virtual reality goggles and gloves. They learn a small set of commonly-used ASL signs, and try to use them to communicate as sensors in the gloves and in the computer camera are used to compare their hand motions to the correct positions. The study, being conducted in tandem with Gallaudet University in Washington, D.C., is in a preliminary stage, although initial pilot testing seems promising. When complete, it could enhance self-guided ASL tutorials.
Such a system would not replace face-to-face learning, Kraemer says, but it could improve practice. 鈥淎nd then the question is, can you learn from this faster than you would on your own? Down the road, we also want to learn how the brain attributes meaning to what are, initially, unfamiliar hand motions.鈥
Detecting 鈥楳otivated Reasoning鈥
Can brain imaging reveal the difference between logical thinking and using facts selectively to support a foregone conclusion? The latter is called 鈥渕otivated reasoning,鈥 and it鈥檚 the focus of work being done in the lab by Katherine Alfred, Guarini 鈥20, with additional guidance from . Participants are given sets of data relating to two very different questions: 鈥淚s this gun control legislation effective at reducing crime rates?鈥 and, 鈥淚s this skin cream effective at reducing rashes?鈥
鈥淪o then we get a really good comparison of how people approach a problem when there鈥檚 just sort of a neutral content鈥攕kin cream鈥 versus content they have strong prior beliefs about鈥攇uns,鈥 says Alfred. 鈥淲e鈥檙e looking at how the reasoning process changes depending on the topic, and at interventions designed to improve that process.鈥
All these experiments lead to a similar conclusion, says Kraemer.
鈥淲hat you鈥檝e learned about something can change the way that you look at it. 鈥滱nd somebody else can be looking at the very same thing and be thinking something very different.鈥
Charlotte Albright can be reached charlotte.e.albright@dartmouth.edu.
