Alistair Gardiner | February 12, 2021
Sugar is a slippery slope. On the one hand, the brain and body need it for fuel; on the other, it can act like a drug—the more we eat, the more we seem to crave.
Sugar has been considered a dietary enemy for a long time—and with good reason. Excessive consumption of sugar has been linked to a variety of adverse health outcomes, including weight gain, obesity, heart disease, type 2 diabetes, and even cognitive decline.
Understanding how sugar interacts with our brains and whether it serves as a friend or foe can help us manage our intake, sidestep the serious health consequences of eating too much of it, and win back our self-control. Here’s what the latest science says about sugar’s effect on the brain.
What sugar does to the brain
Ingesting some sugar is vital to our survival, because it’s the brain’s main source of fuel, note the authors of a review published in Frontiers in Bioscience. Sugars in the form of glucose are transported via astrocytes and epithelial cells of the blood-brain barrier, and the glucose is then absorbed by our brains’ neurons.
But sugar also triggers the mesocorticolimbic system, known as the “reward pathway,” in the brain. When we consume sugar, the prefrontal cortex, amygdala, ventral-tegmental area, and nucleus accumbens are stimulated, releasing dopamine. After sugar triggers this system, we’re left craving more, because these parts of the brain are responsible for behavior reinforcement, pleasure-seeking, and addiction, according to a study published in Neuroscience & Biobehavioral Reviews in 2019.
So what happens when we eat those sweet foods? The sugar acts on the brain’s reward pathway in ways similar to drugs like cocaine and heroin—when overstimulated, the pathway becomes primed to require that stimulus, noted the study authors.
According to another study using animal models, published in Scientific Reports in 2019, increased consumption of energy-dense foods prompts increased cravings for those foods, because of this reward pathway. Researchers examined the effects of intermittent sucrose access on a group of anesthetized mini-pigs, by monitoring their μ-opioid and dopamine D2/3 receptors with PET scan imaging over 12 days.
Findings indicated that, following that period of sucrose access, the voxel-wise binding potentials of both receptors had declined significantly in the striatum, nucleus accumbens, thalamus, amygdala, cingulate cortex, and prefrontal cortex, consistent with down-regulation of receptor densities. What does that mean? Researchers concluded that in their models, sucrose affected reward mechanisms in a manner similar to that of abusable drugs like opioids.
Findings indicated that, following that period of sucrose access, the voxel-wise binding potentials of both receptors had declined significantly in the striatum, nucleus accumbens, thalamus, amygdala, cingulate cortex, and prefrontal cortex, consistent with down-regulation of receptor densities. What does that mean? Researchers concluded that in their models, sucrose affected reward mechanisms in a manner similar to that of abusable drugs like opioids.
New research is shedding light on how this process works. For example, a 2020 study published in Nature, found that in addition to triggering specialized taste buds, sugar molecules switch on an additional neurological pathway, which begins in the intestines—known as the gut-brain axis.
Investigators monitored the brain activity of rodents, which were given sugar, artificial sweeteners, or water. They found that the caudal nucleus of the solitary tract in the brain stem of the rats responded only to the sugar. This response begins in the lining of the intestine, where signals are then sent to the brain via the vagus nerve, which provides a direct communication line between the intestines and the brain.
“This gut-to-brain circuit favors one form of sugar: glucose and similar molecules,” the study authors wrote. “It ignores artificial sweeteners—perhaps explaining why these additives can’t seem to fully replicate sugar’s appeal. It also overlooks some other types of sugar, most notably fructose, which is found in fruit.”
They continued, “Uncovering this circuit helps explain how sugar directly impacts our brain to drive consumption,” he says. “It also exposes new potential targets and opportunities for strategies to help curtail our insatiable appetite for sugar.”
The harms of excessive sugar consumption
The researchers of the 2019 Scientific Reports study made the case for the link between excess sugar consumption and the obesity epidemic. They argued that the addictive nature of sugar can result in calorie overconsumption and, ultimately, obesity.
“As a hallmark of the metabolic syndrome, obesity is associated with type 2 diabetes, cardiovascular disease, respiratory problems, and risk of depression and possibly dementia,” the authors noted.
“As a hallmark of the metabolic syndrome, obesity is associated with type 2 diabetes, cardiovascular disease, respiratory problems, and risk of depression and possibly dementia,” the authors noted.
Additionally, different forms of sugar may have different effects on our bodies. According to the previously mentioned review in Frontiers in Bioscience, foods with added fructose are particularly linked with an increased risk of symptoms like hypertension, insulin resistance, lipogenesis, diabetes and associated retinopathy, kidney disease, and inflammation.
Don’t let all the detriments of sugars put you off fruit, though. As the review authors point out, fruit features high levels of fiber antioxidants, potassium, and vitamin C, and far lower levels of fructose than, say, a soda. The fructose in a peach, for example, accounts for roughly 1% of the fruit’s weight, whereas fructose can make up as much as half the weight of sugary drinks.
Dietary goals for sugar consumption
According to the recently released Dietary Guidelines for Americans 2020-2025, added sugars make up roughly 270 calories (13.5%), or 17 teaspoons, in the average person’s diet each day. The guidelines state that, for a healthy diet, added sugars should make up less than 10% of the calories you consume.
Given its addictive nature, reducing consumption can be tricky for some, but there are easier ways than going cold turkey. New research is opening up avenues to explore ways to regulate our preference for sweet things.
A 2020 study published in Cell Metabolism identified, for the first time, the specific brain cells that respond to the hormone fibroblast growth factor 21 (FGF21). This endocrine hormone is produced by the liver and signals the brain to suppress sugar cravings and sweet-taste preference, thereby regulating nutritional intake. According to a release on the study published in Science Daily, the researchers found that FGF21 targets glutamatergic neurons and suppresses sugar cravings by enhancing the sensitivity of certain neurons in the ventromedial hypothalamus to glucose. Ultimately, this suggests that drugs based on a modified form of the hormone could be developed to help control sugar cravings.
Rather than trying to ban sugar from the diet altogether, experts recommend finding the right kinds of sugars, such as whole foods that contain sugar, like fruits, grains, and dairy. Your body digests these foods more slowly than those with refined sugars, and they provide your body with a steady supply of energy rather than a quick rush and subsequent crash. And, you can always find sugar alternatives that have fewer calories than sugar and may not be as bad for health. For example, monk fruit extract is roughly 100-250 times sweeter than regular refined white sugar. It’s also high in antioxidants called mogrosides and effectively has no calories. Another option is date sugar, which is made by grinding whole dehydrated dates. The sugar contains all the vitamins, minerals, and fiber of the original fruit—and fewer than one-third the calories of regular sugar, at only 10 calories per teaspoon. You could also try sugar alcohols, like erythritol, which have fewer calories than ordinary sugar.
Other tips to reduce sugar intake include aiming to eat more whole foods and fewer processed foods, which can include heaps of added sugar. Carefully read food labels to check on how much sugar has been added to a product—foods that may not even register as sweet, like condiments and marinades, tend to have more added sugar than you might think.