Dietary supplements are products containing nutrients sold in various medicinal forms, and their widespread use may stem from the conviction that a preparation that looks like a drug must have therapeutic properties. The aim of this scoping review is to present what is known about the effects of using selected dietary supplements in the context of chronic diseases, as well as the risks associated with their use. The literature shows that the taking of vitamin and mineral supplements by healthy people neither lowers their risk of cardiovascular diseases nor prevents the development of malignancies. Many scientific societies recognize that omega-3 fatty acids lower blood triglycerides, but whether taking them prevents heart disease is less clear-cut. Taking weight loss supplements is not an effective method of fighting obesity. Often, some supplements are increasingly sold illegally, which is then also associated with the higher risk that they may be adulterated with banned substances, thus making them even more dangerous and potentially life-threatening. Supplements are necessary in cases of nutrient deficiency; however, even though prescription is not required, their use should be recommended and monitored by a physician.
Authors | Study Design | Participants | Type of Dietary Supplements | Duration of the Study | Results |
---|---|---|---|---|---|
The ASCEND Study Collaborative Group 2018 [18] | RCT | 15,480 patients with diabetes aged ≥ 40 years | Omega-3 fatty acids | Mean: 7.4 years | No effect on serious vascular events |
Manson et al., 2019 [19] | RCT | 25,871 patients aged ≥ 50 years | Omega-3 fatty acids | Median: 5.3 years | No effect on cardiovascular events |
Bhatt et al., 2019 [20] | RCT | 8179 patients with cardiovascular diseases or diabetes, median age: 64 years | Purified EPA ethyl ester (icosapent ethyl) | Median: 4.9 years | 25% reduction in primary endpoints: cardiovascular death, non-fatal MI, non-fatal stroke, coronary revascularization, unstable angina; 26% reduction in secondary endpoints: cardiovascular death, non-fatal MI, non-fatal stroke |
Nicholls et al., 2020 [23] | RCT | 13,078 patients with high cardiovascular risk, mean age: 62.5 years | Omega-3 fatty acids | Over 3 years | No effect on major cardiovascular events |
Rizos et al., 2012 [25] | Systematic review and meta-analysis, 20 RCTs | 68,680 patients aged 49–70 years | Omega-3 fatty acids | Median: 2.0 years | No effect on cardiac death, MI, and stroke |
Kotwal et al., 2012 [26] | Meta-analysis, 20 RCTs | 62,851 patients in primary and secondary prevention settings | Omega-3 fatty acids | 6 months–6 years | 14% reduction in vascular death; no effect on cardiovascular events, coronary events, cerebrovascular events, arrhythmia |
Kwak et al., 2012 [27] | Meta-analysis, 14 RCTs | 20,485 patients with cardiovascular diseases aged 40–80 years | Omega-3 fatty acids | 1.0–4.7 years | No effect on cardiovascular events, MI, congestive heart failure, and stroke |
Casula et al., 2013 [28] | Meta-analysis, 11 RCTs | 15,348 patients with cardiovascular diseases | Omega-3 fatty acids | 1.0–3.5 years | 32% reduction in cardiac death, 25% reduction in MI; no effect on stroke |
Wen et al., 2014 [29] | Meta-analysis, 14 RCTs | 32,656 patients with CHD | Omega-3 fatty acids | <3 months–4.6 years | 12% reduction in death from cardiac causes, 14% reduction in sudden cardiac death |
Abdelhamid et al., 2018 [31] | Meta-analysis, 79 RCTs | 112,059 adults in primary and secondary prevention settings | Omega-3 fatty acids | 12–72 months | Little or no effect on cardiovascular mortality, CHD mortality, cardiovascular events, stroke, arrhythmia |
Aung et al., 2018 [30] | Meta-analysis, 10 RCTs | 77,917 high-risk patients | Omega-3 fatty acids | 1.0–6.2 years | No effect on CHD mortality, non-fatal MI, CHD events, major vascular events |
Mazidi et al., 2019 [32] | Meta-analysis, 13 RCTs | 127,447 patients | Omega-3 fatty acids | No data | 9% reduction in CHD death, 5% reduction in major vascular event, 11% reduction in non-fatal MI, 5% reduction in all-cause mortality |
Hu et al., 2019 [33] | Meta-analysis, 13 RCTs | 127,447 patients, mean age: 64.3 years | Omega-3 fatty acids | 5 years | 8% reduction in MI, 8% reduction in CHD death, 5% reduction in total CHD, 7% reduction in CVD death, 3% reduction in total CVD |
Casula et al., 2020 [34] | Meta-analysis, 16 RCTs | 81,073 participants | Omega-3 fatty acids | ≥1 year | 9% reduction in cardiac mortality, 10% reduction in major adverse cardiovascular events, 17% reduction in MI; more benefits were seen in secondary prevention |
Lombardi et al., 2020 [35] | Meta-analysis, 14 studies | 125,763 patients | Omega-3 fatty acids | Median: 4.6 years | 21% reduction in cardiac death, 29% reduction in MI, 26% reduction in coronary revascularization, 27% reduction in unstable angina, and 22% reduction in major vascular events—for high-dose omega-3 fatty acids (> 1 g per day); 49% increase in bleeding events and 35% increase in atrial fibrillation events—for high-dose omega-3 fatty acids (> 1 g per day) |
Wang et al., 2009 [47] | RCT | 128 obese women aged 18–50 years with hypertension or/and hyperglycemia, and/or hyperlipemia | Multivitamins and minerals | 26 weeks | Significant reduction of systolic and diastolic BP |
Park et al., 2011 [51] | Cohort study | 182,099 patients aged 45–75 years | Multivitamins | Mean: 11 years | No effect on mortality from cardiovascular diseases |
Sesso et al., 2012 [52] | RCT | 14,641 males aged ≥ 50 years | Multivitamins | 10.7–13.3 years | No effect on cardiovascular events, MI, stroke, cardiovascular disease mortality |
Rautiainen et al., 2016 [46] | Prospective cohort study | 28,157 women aged ≥ 45 years free of hypertension at baseline | Multivitamins | Mean: 11.5 years | No association with the risk of hypertension |
Albert et al., 2008 [53] | RCT | 5442 women with a history of cardiovascular diseases or three or more coronary risk factors aged ≥ 40 years | Folic acid, vitamin B6, vitamin B12 | 7.3 years | No significant effect on risk of major cardiovascular events |
Galan et al., 2010 [54] | RCT | 2501 patients with a history of ischemic heart disease or stroke, mean age: 60.9 years | Folic acid, vitamin B6, vitamin B12 | Median: 4.7 years | No significant effect on risk of major cardiovascular events |
Huo et al., 2015 [55] | RCT | 20,702 patients with hypertension, without a history of stroke or myocardial infarction aged 45–75 years | Enalapril, folic acid | Median: 4.5 years | 21% reduction in first stroke and 20% reduction in composite cardiovascular events |
Lee et al., 2005 [66] | RCT | 39,876 healthy women aged ≥ 45 years | Vitamin E | Mean: 10.1 years | No effect on MI, stroke; 24% reduction in cardiovascular death |
Lonn et al., 2005 [67] | RCT | 9541 patients with vascular disease or diabetes | Vitamin E | Median: 7.0 years | 13% increase in heart failure |
Wang et al., 2019 [68] | Mendelian randomization study | 7781 participants | Vitamin E | No data | Genetically determined higher blood levels of vitamin E increases the risk of CAD and MI, increases the concentration of LDL cholesterol and triglycerides, decreases HDL cholesterol concentration |
Schwingshackl et al., 2017 [63] | Meta-analysis, 49 RCTs | 287,304 participants | Vitamins and minerals | 1.0–11.2 years | 12% reduction in cardiovascular mortality with vitamin E supplementation; no beneficial effect from other vitamin/mineral supplementation |
Kim et al., 2018 [56] | Meta-analysis, 18 clinical trials and prospective cohort studies | 2,019,862 participants | Multivitamins and minerals | 5.0–19.1 years | No effect on cardiovascular mortality, CHD mortality, stroke mortality, stroke incidence |
Li et al., 2018 [48] | Meta-analysis, 12 RCTs | 23,207 patients aged 21.9–64.7 years | Multivitamins and minerals | 1.0–86.4 months | No effect on risk of hypertension; significant reduction of systolic BP in subjects with hypertension |
Khan et al., 2019 [57] | An umbrella review: 9 systematic review, 4 RCTs, 105 meta-analyses | 992,129 participants | Multivitamins and antioxidants | No data | No effect on cardiovascular diseases outcomes |
Loffredo et al., 2015 [70] | Meta-analysis, 16 RCTs | Up to 39,876 patients aged > 50 years | Antioxidants | 0.5–9.4 years | 18% reduction in MI with vitamin E supplementation |
Vivekananthan et al., 2003 [69] | Meta-analysis, 32 RCTs | 81,788 patients | Vitamin E, beta- carotene | 1.4–12.0 years | No effect from supplementation of vitamin E on cardiovascular mortality, cerebrovascular events; significant increase in cardiovascular death with beta-carotene supplementation |
Poorolajal et al., 2017 [49] | Meta-analysis, 23 RCTs | 1213 patients with hypertension, mean age: 19–75 years | Potassium | 4–52 weeks | Significant reduction of systolic and diastolic BP |
Filippini et al., 2020 [50] | Meta-analysis, 32 RCTs | 1764 patients mainly with hypertension aged 18–79 years | Potassium | 4–15 weeks | Significant reduction of systolic and diastolic BP |
Authors | Study Design | Participants | Type of Dietary Supplements | Duration of the Study | Results |
---|---|---|---|---|---|
Omenn et al., 1996 [77] | RCT | 18,314 smokers | Beta-carotene and vitamin A | Mean: 4 years | 28% increase in lung cancer incidence |
Albanes et al., 1996 [78] | RCT | 29,133 smokers aged 50–69 years | Beta-carotene, vitamin E | Median: 6.1 years | 16% increase in lung cancer incidence with beta-carotene supplementation; no effect on lung cancer incidence with vitamin E supplementation. |
Lee et al., 2005 [66] | RCT | 39,876 healthy women aged ≥ 45 years | Vitamin E | Mean: 10.1 years | No effect on cancer incidence |
Gaziano et al., 2009 [74] | RCT | 14,641 men aged ≥ 50 years | Vitamin E, vitamin C | Mean: 8.0 years | No effect on cancer incidence |
Klein et al., 2011 [75] | RCT | 34,887 men aged ≥50 years | Vitamin E, selenium | 7.0–12.0 years | 17% increase in prostate cancer incidence with vitamin E supplementation; no effect on prostate cancer incidence with selenium supplementation |
Park et al., 2011 [51] | Cohort study | 182,099 patients aged 45–75 years | Multivitamins | Mean: 11 years | No effect on cancer incidence |
Ambrosone et al., 2019 [96] | Prospective study | 1134 patients with breast cancer | Antioxidants, multivitamins vitamin B12, iron, | 6 months | 41% increased risk of recurrence with antioxidant supplementation both before and during chemotherapy; no effect of multivitamins on survival outcomes; 2-fold decrease in the probability of disease-free survival for vitamin B12 supplementation both before and during chemotherapy; 79% higher risk of recurrence with iron supplementation both before and during chemotherapy |
Narita et al., 2018 [80] | Prospective study | 79,705 participants | Retinol, vitamin C, vitamin E, alfa- carotene, and beta-carotene | Mean: 5 years | 26% increase in lung cancer incidence in men with higher dietary retinol intake; no associations with lung cancer incidence for vitamin C, vitamin E, alfa-carotene and beta-carotene intake |
Van Gorkom et al., 2019 [93] | A systematic review, 19 trials | No data | Vitamin C | 1 week–12 months | No positive effect of vitamin C supplementation on cancer patients |
Pais et al., 2013 [82] | Meta-analysis, 20 RCTs | 268,590 participants | Antioxidants | No data | No effect on colorectal cancer incidence with antioxidant supplementation |
Park et al., 2017 [76] | Meta-analysis, 14 RCTs | 147,383 participants | Antioxidants | 1.0–13.0 years | No effect on bladder cancer incidence with antioxidant supplementation |
Cortés-Jofré et al., 2020 [81] | Meta-analysis, 12 RCTs | 733–212,314 participants 35–84 years | Antioxidants | 2.0–12.0 years | No beneficial effect on lung cancer incidence for combination of vitamins A, C, E + selenium + zinc supplementation; 84% increase in lung cancer incidence in women with vitamin C supplementation; 10% increase in lung cancer incidence in smokers and people with history of asbestos exposure with vitamin A supplementation |
Bjelakovic et al., 2014 [88] | Meta-analysis, 18 RCTs | 50,623 participants | Vitamin D | Mean: 6 years | No effect on cancer incidence; 12% reduction in cancer death. |
Goulao et al., 2018 [86] | Meta-analysis, 30 RCTs | 18,808 participants | Vitamin D | Median: 1,0–6.2 years | No effect on cancer incidence and mortality |
Keum et al., 2019 [87] | Meta-analysis, 5–10 RCTs | 6537 cases | Vitamin D | 3–10 years | No effect on cancer incidence; 13% reduction in cancer death |
Authors | Study Design | Participants(n) | Type of Dietary Supplements | Duration of the Study | Results |
---|---|---|---|---|---|
Onakpoya et al., 2013 [109] | Meta-analysis, 20 RCTs | 1038 | Chromium | 8–26 weeks | 0.5 kg more weight loss as compared with placebo |
Tsang et al., 2019 [110] | Meta-analysis, 21 trials | 1316 | Chromium | ≤12 weeks | 0.75 kg more weight loss as compared with placebo |
Moraru et al., 2018 [112] | Meta-analysis, 14 RCTs | 1101 | Chitosan | 4–52 weeks | 1.01 kg more weight loss as compared with placebo |
Huang et al., 2020 [114] | Meta-analysis, 15 RCTs | 1130 | Chitosan | ≥12 weeks | 0.89 kg more weight loss, 0.39 kg/m2 more BMI loss, and 0.69% more body fat loss as compared with placebo |
Baladia et al., 2014 [115] | Meta-analysis, 5 RCTs | 260 | Green tea, green tea extract | 12 weeks | No effect on body weight |
Lin et al., 2020 [116] | Meta-analysis, 22 RCTs | 2357 | Green tea extract | 4–14 weeks | 1.78 kg more weight loss and 0.65 kg/m2 more BMI loss as compared with placebo |
Onakpoya et al., 2011 [119] | Meta-analysis, 12 RCTs | 706 | hydroxycitric acid from Garcinia cambogia | 2–12 weeks | 0.88 kg more weight loss as compared with placebo |
Golzarand et al., 2020 [120] | Meta-analysis, 8 RCTs | 530 | Garcinia cambogia | 8–12 weeks | 1.34 kg more weight loss, 0.99 kg/m2 more BMI loss, and 0.42% more body fat loss, 4.16 cm more loss of waist circumference as compared with placebo |
Stohs 2017 [122] | Review 30 trials | 600 | Citrus aurantium extract | No data | No proven effect on body weight |
This entry is adapted from the peer-reviewed paper 10.3390/ijerph18178897