When it comes to forming a lasting bond, our longing for a partner may be as important as鈥攊f not more important than鈥攈ow we react when we鈥檙e with them, suggests a surprising new brain imaging听听published听in the听Proceedings of the National Academy of Sciences.
鈥淚n order to maintain relationships over time, there has to be some motivation to be with that person when you are away from them,鈥 said lead author Zoe Donaldson, an assistant professor of behavioral neuroscience at CU听Boulder. 鈥淥urs is the first paper to pinpoint the potential neural basis for that motivation to reunite.鈥澨
The paper marks the latest discovery in Donaldson鈥檚听of prairie voles, one of only about 3% to 5% of mammalian species (including humans) that tend to mate for life. By observing the behavior and brain activity of the monogamous rodents, she seeks to better understand what brain regions鈥攄own to the cellular level鈥攄rive the instinct to form lasting bonds.听
Ultimately, the findings could be used to develop therapies for those with autism, severe depression and other disorders that make such emotional connections hard to come by. But right now, she said, the research also lends insight into why social distancing is so tough.
Why social distancing is so hard
鈥淲e are uniquely hardwired to seek out close relationships as a source of comfort, and that often comes through physical acts of touch,鈥 she said.听听
For the study, Donaldson used tiny cameras and a cutting-edge technology called in-vivo-calcium imaging to spy on the brains of dozens of voles at three time points: when they were just meeting another vole; three days after they had mated; and 20 days after they had essentially moved in together. Researchers also observed the animals interacting with voles who were not their mates.
Previous brain imaging research in humans has shown altered brain activity in a region called the nucleus accumbens, the same reward center that lights up during heroin or cocaine use, when the research subjects held the hand of a romantic partner versus听a stranger. So, at first, Donaldson鈥檚 team assumed the voles鈥 brain activity would be markedly different when they were huddling with their mate versus听a random vole.
鈥淪urprisingly, that is not what we found,鈥 she said.
Stranger or lover, the voles鈥 brains looked basically the same when they were together.
It was only when the voles were away from their partner and running to meet them鈥攊magine the classic romantic reunion-scene at the airport or the theme of any听number of love poems鈥攖hat a unique cluster of cells in the nucleus accumbens consistently fired up.
The longer the animals had been paired, the closer their bond became and the larger the glowing cluster of cells鈥攄ubbed the 鈥減artner approach ensemble鈥濃攐n image screens.
Notably, a completely different cluster of cells lit up when the vole approached a stranger.
鈥淭his suggests that maybe the recruitment of these cells for this new purpose is important for forming and maintaining a bond,鈥 Donaldson said.
Cracking the love code
She suspects that brain chemicals like oxytocin, dopamine and vasopressin, which have been shown in both animal and human studies to play a role in fostering trust and closeness, are involved in the process. But she doesn鈥檛 know for sure what that cluster of cells does.
It鈥檚 also not clear whether the specific 鈥渘euronal code鈥 associated with a desire to reunite in voles inspires the same emotion in people. More research is underway.
What the study does confirm is that monogamous mammals are uniquely hard-wired to be with others.
鈥淭hese negative feelings so many of us are experiencing right now may result from a mismatch: we have a neuronal signal telling us that being with loved ones will make us feel better, while practical restrictions mean this need is going unmet,鈥 Donaldson said. 鈥淚t鈥檚 the emotional equivalent of not eating when we are hungry, except now instead of skipping a meal, we are slowly starving.鈥
