Low-Carb Diets Linked to Atherosclerosis and Impaired Blood Vessel Growth
Even as low-carbohydrate/high-protein diets have proven successful at helping individuals rapidly lose weight, little is known about the diets’ long-term effects on vascular health.
Now, a study led by a scientific team at Beth Israel Deaconess Medical Center (BIDMC) provides some of the first data on this subject, demonstrating that mice placed on a 12-week low carbohydrate/high-protein diet showed a significant increase in atherosclerosis, a buildup of plaque in the heart’s arteries and a leading cause of heart attack and stroke. The findings also showed that the diet led to an impaired ability to form new blood vessels in tissues deprived of blood flow, as might occur during a heart attack.
Described in today’s Online Version of the Proceedings of the National Academy of Sciences (PNAS), the study also found that standard markers of cardiovascular risk, including cholesterol, were not changed in the animals fed the low-carb diet, despite the clear evidence of increased vascular disease.
“It’s very difficult to know in clinical studies how diets affect vascular health,” says senior author Anthony Rosenzweig, MD, Director of Cardiovascular Research in BIDMC’s CardioVascular Institute and Professor of Medicine at Harvard Medical School. “We, therefore, tend to rely on easily measured serum markers [such as cholesterol], which have been surprisingly reassuring in individuals on low-carbohydrate/high-protein diets, who do typically lose weight. But our research suggests that, at least in animals, these diets could be having adverse cardiovascular effects that are not reflected in simple serum markers.”
Rosenzweig and his coauthors found that the increase in plaque build-up in the blood vessels and the impaired ability to form new vessels were associated with a reduction in vascular progenitor cells, which some hypothesize could play a protective role in maintaining vascular health.
“A causal role for these cells has not yet been proven, but this new data is consistent with the idea that injurious stimuli may be counterbalanced by the body’s restorative capacity,” he explains. “This may be the mechanism behind the adverse vascular effects we found in mice that were fed the low-carb diets.”
The study’s first author Shi Yin Foo, MD, PhD, a clinical cardiologist in the Rosenzweig laboratory at BIDMC, first embarked on this investigation after seeing heart-attack patients who were on these diets – and after observing Rosenzweig himself following a low-carbohydrate regimen.
“Over lunch, I’d ask Tony how he could eat that food and would tell him about the last low-carb patient I’d admitted to the hospital,” says Foo. “Tony would counter by noting that there were no controls for my observations.”
“Finally,” adds Rosenzweig, “I asked Shi Yin to do the mouse experiment – so that we could know what happens in the blood vessels and so that I could eat in peace.”
The investigators proceeded to study a mouse model of atherosclerosis. These “ApoE” mice were fed one of three diets: a standard diet of mouse “chow” (65 percent carbohydrate; 15 percent fat; 20 percent protein); a “Western diet” in keeping with the average human diet (43 percent carbohydrate; 42 percent fat; 15 percent protein; and 0.15 percent cholesterol); or a low-carb/high-protein diet (12 percent carbohydrate; 43 percent fat; 45 percent protein; and 0.15 percent cholesterol).
“We had a diet specially made that would mimic a typical low-carb diet,” explains Foo. “In order to keep the calorie count the same in all three diets, we had to substitute a nutrient to replace the carbohydrates. We decided to substitute protein because that is what people typically do when they are on these diets.”
The scientists then observed the mice after six weeks, and again at 12 weeks. Consistent with experience in humans, the mice fed the low-carb diet gained 28 percent less weight than the mice fed the Western diet. However, further probing revealed that the animals’ blood vessels exhibited a significantly greater degree of atherosclerosis, as measured by plaque accumulation: 15.3 percent compared with 8.8 percent among the Western diet group. (As expected, the mice on the chow diet showed minimal evidence of atherosclerosis compared with either of the other two groups.)
“Our next question was, ‘Why do the low-carb mice have such an increase in atherosclerosis?’” says Foo. Searching for an explanation, she and her coauthors proceeded to measure the usual markers thought to contribute to vascular disease, including the animals’ cholesterol and triglyceride levels, oxidative stress, insulin and glucose, as well as levels of some inflammatory cytokines.
“In each case, there was either no difference in measurements compared with the mice on the Western Diet [which contains the same amount of fat and cholesterol] or the numbers slightly favored the low-carb cohort,” she adds. “None of these results explained why the animals’ blood had more atherosclerotic blockages and looked so bad.”
Since there was no difference in the noxious or inflammatory stimuli that the animals’ blood vessels were exposed to, Foo wondered whether the restorative capacity of the animals might be contributing to the difference. The investigators, therefore, looked at the animals’ endothelial or vascular progenitor cell (EPC) counts. Derived from bone marrow, the EPC cells may play a role in vessel regrowth and repair following injury.
“Examinations of the animals’ bone marrow and peripheral blood showed that the measures of EPC cells dropped fully 40 percent among the mice on the low-carb diet – after only two weeks,” says Rosenzweig. “Although the precise nature and role of these cells is still being worked out – and caution is always warranted in extrapolating from effects in mice to a clinical situation – these results succeeded in getting me off the low-carb diet.”
Even more important, he notes, the findings point out that there can be a disconnect between weight loss or serum markers and vascular health, and that vascular health can be affected by macronutrients other than fat and cholesterol – in this case, protein and carbohydrates.
“Understanding the mechanisms responsible for these effects, as well as the potential restorative capacity that may counteract vascular disease, could ultimately help guide doctors in advising their patients,” adds Rosenzweig. “This issue is particularly important given the growing epidemic of obesity and its adverse consequences. For now, it appears that a moderate and balanced diet, coupled with regular exercise, is probably best for most people.”
In addition to Rosenzweig and Foo, study coauthors include BIDMC investigators Joanna Wykrzykowska and Christopher J. Sullivan, and Massachusetts General Hospital investigators Eric R. Heller, Jennifer J. Manning-Tobin, Kathryn J. Moore and Robert E. Gerszten.
This study was supported by the Leducq Foundation Network of Research Excellence, an American Heart Association Grant-in-Aid, grants from the National Institutes of Health, and support from Judith and David Ganz and the Maxwell Hurston Charitable Foundation. Shi-Yin Foo is a trainee of the Clinical Investigators Training Program, jointly sponsored by BIDMC and Harvard/Massachusetts Institute of Technology Health Sciences and Technology in collaboration with Pfizer Inc. and Merck and Co.
Beth Israel Deaconess Medical Center is a patient care, teaching and research affiliate of Harvard Medical School and consistently ranks in the top four in National Institutes of Health funding among independent hospitals nationwide. BIDMC is a clinical partner with the Joslin Diabetes Center and is a research partner of the Dana-Farber/Harvard Cancer Center. BIDMC is the official hospital of the Boston Red Sox.
Source: Beth Israel Deaconess Medical Center