Wampole Vitamin Syrup by JAMP Pharma Corporation

EFFECTIVE

• Anemia of chronic disease. Oral and intravenous iron in combination with erythropoiesis-stimulating agents (ESAs) are effective for treating anemia of chronic disease. Details: Iron supplementation with ESAs is effective for treating anemia associated with chronic kidney disease (CKD) or chemotherapy. During therapy with ESAs, iron levels should be monitored and supplementation provided as needed to ensure that the response is not limited by lack of iron for erythropoiesis (1087,1091,20110,20111,110192). Research shows that intravenous iron appears to be more effective than oral supplements for this purpose (20112,20113). In patients with CKD, intravenous iron at total doses from 2232 mg over 6 months to 1020 mg over one week increases hemoglobin levels more than oral doses of 4-6 mg/kg daily or 325 mg daily for up to 6 months (20112). Some research has evaluated the effect of intravenous or oral iron in patients not treated with ESAs. In patients with cancer or CKD, oral iron supplements have been shown to improve iron status (110184,110192). However, overall benefits of iron alone remain unclear in treated or untreated patients with cancer and more research is needed to rule out an increase in mortality and to determine any effect on blood transfusion requirements (110192). Preliminary clinical research shows that children aged 6 months to 10 years with HIV and anemia who take elemental iron 3 mg/kg daily along with a multivitamin for 3 months have a 41% lower chance of having persistent anemia at 3 months when compared with multivitamins alone (95432).
• Iron deficiency anemia. Oral and intravenous iron are effective for treating or preventing iron deficiency anemia. The benefits of iron supplementation in people with iron deficiency without anemia are unclear. Details: Oral iron supplements, mainly as ferrous sulfate, are effective for treating and preventing iron deficiency anemia in adults, children, and infants (1089,7135,17495,17496,17497,103806,20114,20115,91183,96621)(104680,104681,112601). Other forms are also effective, including sodium iron ethylenediaminetetra-acetate (NaFeEDTA), iron(III)-hydroxide polymaltose complex (IPC), iron protein succinylate, iron bisglycinate, and lactoferrin with iron (20117,20118,110189). Treatment with iron supplements should increase hemoglobin levels by 1 gram/dL every 2-3 weeks. However, even after hemoglobin has normalized, it may take up to 4 months for iron stores to be replenished (17497). Historically, treatment of iron deficiency anemia with oral iron supplements has typically consisted of a daily dosing regimen, often taken in divided doses to reduce adverse effects. In more recent years, however, intermittent iron supplementation (1-3 doses/week) has become preferred for some patients, particularly those with mild anemia, due to better absorption and a possible reduction in side effects compared to daily dosing. One small clinical study shows that taking ferrous sulfate 60 mg on alternate days in single doses improves iron absorption when compared to once daily dosing (96630). Another small clinical study in females with iron-deficiency anemia shows that fractional iron absorption is 40% to 50% higher with alternate-day dosing compared with daily dosing. Furthermore, total iron absorption was shown to be similar for alternate day dosing of elemental iron 200 mg compared with daily dosing of 100 mg, but the incidence of gastrointestinal adverse effects may be lower for the alternate day dosing regimen (101514). A meta-analysis of 25 clinical trials, including 10,996 menstruating females with or without pre-existing iron deficiency and/or anemia, shows that intermittent iron reduces the risk of anemia and increases hemoglobin and serum ferritin when compared with placebo or no intervention. This meta-analysis did not identify differences in the risk of anemia, hemoglobin, or serum ferritin between intermittent and daily iron supplementation. However, it did show that females receiving intermittent dosing had a 59% reduction in the risk for adverse effects. The validity of these findings is limited by significant heterogeneity in the enrolled populations and selected dosing strategies, including frequency of intermittent dosing, total weekly dose, and duration of follow-up. In addition, the subgroup analyses performed by baseline anemia, hemoglobin, and serum ferritin, as well as duration of follow-up, showed differing overall conclusions when comparing intermittent and daily iron supplementation. While intermittent dosing appears to be beneficial when compared with daily dosing for some patients with iron deficiency anemia, intermittent dosing may be less effective than daily iron supplementation in some patients (103806). For patients with severe anemia, twice daily dosing may be preferred to alternate day dosing due to faster response. A small clinical study in patients with iron deficiency anemia shows that taking ferrous sulfate 200 mg twice daily is more effective at increasing hemoglobin levels by 3 weeks when compared with ferrous sulfate 400 mg taken on alternate days in single doses (102864). Intermittent iron supplementation has also been investigated in children. A meta-analysis of clinical research in children and adolescents with or without pre-existing iron deficiency and/or anemia shows that taking iron supplements 1-2 times weekly is similarly effective as 3-7 times weekly for decreasing iron deficiency and iron deficiency anemia. However, ferritin and hemoglobin levels increased to a greater extent with 3-7 times weekly supplementation (112601). Blood transfusion may be required for some patients with severe iron deficiency anemia who have symptoms such as dyspnea and fatigue (17497). Intravenous iron should be considered in patients who cannot tolerate oral iron or in patients with chronic bleeding or intestinal malabsorption (17497). Guidelines from the British Society of Gastroenterology recommend treatment with iron while awaiting investigations to rule out gastrointestinal issues in adults in the absence of an alternative explanation. The guidelines recommend ferrous sulfate, fumarate, or gluconate as one tablet daily. If adverse effects occur, intake can be reduced to once every other day, or alternative oral or parenteral sources of iron can be used. Parenteral sources should be used if oral sources are contraindicated or ineffective. Treatment should be monitored and continued after hemoglobin levels are normalized (110193). Iron supplementation may also be beneficial in patients with iron deficiency without anemia, which can cause fatigue and reduced well-being, although guidelines are lacking. A meta-analysis of randomized controlled trials in adults with iron deficiency but not anemia shows that supplemental iron improves iron stores and hemoglobin levels. In addition, iron moderately reduces self-reported fatigue, but not physical capacity, when compared with placebo. Oral ferrous sulfate was used in most studies included in the analysis; however, intravenous or intramuscular iron were also used (104684).
• Pregnancy-related iron deficiency. Oral iron is effective for preventing pregnancy-related iron deficiency. Details: Clinical research shows that taking iron orally at an average daily dose of 20-225 mg of elemental iron increases maternal hemoglobin levels by up to 1 gram/dL when compared with placebo and reduces the risk of maternal anemia by 62% to 100% (20122,20123,20124,110180,110188). Some clinicians may recommend alternating days of iron administration to reduce gastrointestinal adverse effects. A pooled analysis shows that taking iron supplements on alternating days during pregnancy maintains adequate iron intake and reduces gastrointestinal adverse effects when compared with taking iron daily (96625). Various forms of oral iron seem to be equally effective for raising hemoglobin levels (110185,110188). However, in patients with anemia during pregnancy, a meta-analysis of clinical research shows that intravenous iron sucrose and ferric carboxymaltose were more effective than oral ferrous sulfate for improving hemoglobin levels (110185).

POSSIBLY EFFECTIVE

• Breath-holding attacks. Oral iron seems to be effective for reducing the frequency of breath-holding attacks in children with iron deficiency. Details: The incidence of breath-holding attacks is increased in children with iron deficiency or iron deficiency anemia. Most research shows that oral supplementation with ferrous sulfate 3-6 mg/kg daily for 4-16 weeks reduces the frequency of breath-holding attacks in children aged 1-72 months (20128,104682,104683). The best evidence comes from a meta-analysis of one randomized controlled trial and 11 observational single arm studies (104682). In this analysis, approximately 84% of children experienced at least a 50% decreased frequency of breath-holding attacks (104682). Some preliminary clinical research also shows that administering intramuscular iron reduces the frequency of breath-holding attacks and increases remission in children with iron deficiency anemia (20128).
• Cognitive function. Oral iron seems to be effective for improving cognitive function in children and adolescents with iron deficiency. Details: Taking iron orally seems to improve cognitive function in iron-deficient children and adolescents (20121,112600). For example, ferrous sulfate 650 mg twice daily for 8 weeks improved verbal learning and memory in non-anemic iron-deficient adolescent females (1095). Ferrous sulfate 50 mg twice weekly for 16 weeks appeared to improve attention measures in adolescent females with possible anemia (91186). Iron also appears to reverse developmental and learning deficits caused by iron-deficiency in anemic infants (1104). Some clinical research is focused on children and adolescents from low- and middle-income countries. In children aged 5-19 years with or without iron-deficiency anemia, a meta-analysis of clinical research shows that iron supplementation for 3-8 months dose-dependently improves measured intelligence by a modest amount. However, there was no effect on other measures of cognition, including attention or memory (110181). Another meta-analysis of clinical research in school age children shows that taking iron for 2-12 months modestly improves intelligence, attention, and memory, but not educational achievement, when compared with placebo or no intervention. However, sub-analyses show that any benefits are limited to children with anemia (112600).
• Heart failure. Intravenous iron seems to be effective for improving recovery in patients with heart failure and iron deficiency. It is unclear if oral iron is effective. Details: Iron deficiency is common in patients with heart failure (17499,112597,112598,112599). Individual clinical trials and meta-analyses of clinical research in patients with heart failure show that administering intravenous iron, as ferric carboxymaltose, iron dextran, iron isomaltoside, or iron sucrose, for at least 12 weeks modestly improves quality of life, increases exercise capacity, and reduces hospitalizations when compared with placebo or standard care. However, there was no effect on all-cause mortality or cardiovascular mortality (17498,91179,110176,110187,112597,112598,112599). Some individual clinical trials have used intravenous ferric carboxymaltose 200 mg or iron sucrose 200 mg in patients with mild or moderate heart failure and iron deficiency (17498,91179). Guidelines from the British Society of Gastroenterology suggest that treatment with parenteral iron improves symptoms and quality of life in patients with functional iron deficiency related to CHF (110193). Limited research has investigated the effect of oral iron in this population. A small meta-analysis of clinical research shows with low certainty that taking iron orally has beneficial effects on serum ferritin and left ventricular ejection fraction (110178). Most research shows that taking oral iron does not improve hemoglobin levels, quality of life, or exercise capacity when compared with placebo (100970,110178). However, one small clinical trial shows that taking oral iron modestly improves iron status and overall symptoms and increases the 6-minute walking distance by about 46 meters, compared with a reduction of only 14 meters in those taking placebo (110183). Some doses used in individual clinical studies have included iron polysaccharide 150 mg twice daily for 16 weeks and ferrous sulfate 200 mg three times daily for 12 weeks (100970,110183).
• Restless legs syndrome (RLS). Oral and intravenous iron seem to be beneficial for RLS. The American Academy of Neurology recommends a combination of oral ferrous sulfate and vitamin C or intravenous ferric carboxymaltose for patients with RLS. Details: RLS is commonly associated with iron deficiency anemia. Some clinical research shows that taking iron in the form of ferrous sulfate 325 mg twice daily for 12 weeks reduces RLS symptoms comparably to pramipexole. Symptoms such as leg discomfort, need to move, and sleep disturbances improved considerably in about half of the patients taking either treatment (91181). Additional clinical research shows that taking ferrous sulfate 325 mg twice daily along with vitamin C 100 mg twice daily for 12 weeks reduces symptoms of RLS when compared with vitamin C alone in patients with RLS and low-normal serum ferritin levels (94189). Based on these results, clinical practice guidelines by the American Academy of Neurology report that taking this combination of oral ferrous sulfate and vitamin C is likely to improve symptoms in patients with RLS and low-normal serum ferritin (93587). Intravenous iron may also reduce symptoms of RLS. Clinical practice guidelines by the American Academy of Neurology report that two doses of intravenous ferric carboxymaltose 500 mg given 5 days apart are likely to improve symptoms and quality of life within 28 days in patients with moderate to severe RLS, regardless of serum ferritin levels. Intravenous iron sucrose has also been evaluated in patients with RLS, but there is currently insufficient available evidence to support or refute the use of this form of iron for treating RLS (93587).

POSSIBLY INEFFECTIVE

• Athletic performance. Oral iron does not seem to improve athletic performance. Details: A meta-analysis of clinical research in adults of childbearing age shows that iron supplementation improves some exercise performance measures, such as maximal oxygen uptake capacity, but not others, such as time until exhaustion and energy consumption, when compared with control (91184). Another meta-analysis of clinical research in patients with iron deficiency without anemia shows that iron supplementation improves subjective measures of fatigue, but does not improve exercise time to exhaustion or other measures of physical capacity (104684). A small clinical study in healthy children shows that taking iron supplements or consuming food providing iron 30-200 mg daily for 1-2 months improves running performance when compared with placebo. This was demonstrated by reductions of heart rate of 6.6 to 8 beats per minute during the running exercise. One preliminary study included in this analysis also showed that iron supplementation improved treadmill endurance time (20140).
• Child growth. Oral iron does not seem to be beneficial for child growth. Details: Meta-analyses of mainly preliminary clinical research show that oral iron supplementation, at doses averaging 2-80 mg or 1-10 mg/kg elemental iron daily for up to 52 weeks, does not increase growth rate in children (20131,20132,20133,95434).
• Preterm labor. Oral iron does not seem to prevent preterm labor and may actually increase the risk in malaria-endemic regions. Details: A meta-analysis of results from five clinical studies shows that maternal intake of iron as ferrous sulfate 20-60 mg daily for 14-26 weeks starting in the second trimester of pregnancy does not affect the length of gestation or increase birthweight of the infant (95434). In females from a malaria-endemic area who have never been pregnant before, another clinical study shows that taking ferrous gluconate 60 mg and folic acid 2.8 mg weekly, starting before conception and continuing to the first antenatal visit, may more than double the risk of preterm birth, defined as a delivery under 37 weeks gestation, when compared with folic acid alone (100969). Some research suggests that the adverse outcome in this latter study may be explained by a rise in hepcidin levels in pregnant patients with malaria. Hepcidin is a hormone that regulates iron absorption and distribution, and malaria can upregulate hepcidin. High levels of hepcidin can decrease iron absorption, stimulate inflammatory processes, and cause progesterone withdrawal, leading to preterm labor (102863).

INSUFFICIENT RELIABLE EVIDENCE to RATE

• ACE inhibitor-induced cough. It is unclear if oral iron is beneficial in patients with this condition. Details: A small clinical trial shows that taking ferrous sulfate 256 mg daily reduces or eliminates cough induced by ACE inhibitors such as captopril (Capoten), enalapril (Vasotec), lisinopril (Prinivil, Zestril), and others, when compared with placebo (7307).
• Androgenic alopecia. Oral iron has only been evaluated in combination with other ingredients, its effect when used alone is unclear. Details: A moderate-sized clinical study in adults with androgenic alopecia or telogen effluvium shows that taking one tablet daily of a specific product (GFM Oral, Cantabria Labs), providing an unknown dose of iron in combination with selenium, taurine, cysteine, methionine, and hydrolyzed collagen, along with conventional therapy, consisting primarily of finasteride or minoxidil, for 12 weeks improves hair loss when compared with conventional therapy alone (111636). It is unclear if this effect is due to iron, other ingredients, or the combination.
• Attention deficit-hyperactivity disorder (ADHD). It is unclear if oral iron is beneficial in children with ADHD. Details: Three small clinical studies in children with ADHD and iron deficiency shows that taking oral iron improves some measures of ADHD after 1-3 months of treatment when compared with baseline or placebo. These studies used ferrous sulfate 5 mg/kg daily, ferrous sulfate 80 mg daily, ferrous fumarate 200 mg daily for children weighing up to 30 kg, or ferrous fumarate 400 mg daily for children weighing more than 30 kg (1093,16013,110191).
• Child development. It is unclear if oral iron is beneficial for improving development in non-anemic children. Details: Some observational research has found that iron deficiency in infancy is associated with poor verbal performance and social skills in childhood (102862). It is unknown whether iron supplementation can ameliorate these developmental issues. In non-anemic infants and children, preliminary clinical research shows that iron does not improve cognitive performance; the evidence for the benefits of iron on psychomotor development is conflicting (20129,20130,91315,96616,96626).
• Esophageal cancer. It is unclear if oral iron is beneficial for esophageal cancer prevention. Details: Population research has found that taking iron supplements is associated with a 32% lower risk of esophageal adenocarcinoma when compared to never taking iron supplements. However, use of iron supplements is not associated with a lower risk of esophageal squamous cell carcinoma (95435).
• Fatigue. It is unclear if oral iron is beneficial in patients with fatigue due to iron deficiency without anemia. Details: A meta-analysis of mainly preliminary clinical research in adults with iron deficiency without anemia shows that iron reduces self-reported fatigue moderately more than placebo (104684). A specific ferrous sulfate supplement (Tardyferon; Pierre Fabre Médicament) providing 80 mg of elemental iron daily for 4-12 weeks was used in two studies included in this analysis (11406,91188).
• Inflammatory bowel disease (IBD). In patients with active IBD, intravenous iron may be more beneficial than oral iron due to impaired absorption. However, it may also increase the risk of infection in these patients. Details: Since the absorption of oral iron may be impaired in patients with active symptoms of IBD, guidelines from the British Society of Gastroenterology suggest that treatment with parenteral iron may be needed in patients with IBD who have moderate to severe iron-deficiency anemia (110193). However, a meta-analysis of clinical research in this population shows that administering IV iron, usually as iron sucrose or ferric carboxymaltose, increases the risk of infection by 73% when compared with oral iron or no iron (110186).
• Postoperative recovery. It is unclear if intravenous iron is beneficial for recovery following cardiac surgery. Details: A meta-analysis of low- to moderate-quality clinical research in patients with preoperative iron-deficiency anemia shows that treatment with intravenous iron before cardiac surgery does not improve the rate of transfusions or the length of stay in the intensive care unit or hospital when compared with control groups, including placebo, oral iron, or no treatment. Also, a meta-analysis of clinical research shows that intravenous iron does not reduce postoperative mortality rates (110182).
• Postpartum depression. Although there has been interest in using iron for postpartum depression, there is insufficient reliable information about the clinical effects of iron for this condition.
• Prematurity. Enteral iron seems to be beneficial for some measures of development in preterm infants. Details: A meta-analysis of clinical research in preterm or low birthweight infants fed human milk shows that enteral iron supplementation increases linear growth and reduces the risk of anemia when compared with control groups receiving no iron supplementation. However, there was no effect on serum ferritin, weight, head circumference, cognitive development, risk of infection, or risk of necrotising enterocolitis (110177). Additional clinical research in infants born at 24-28 weeks' gestation shows that a higher average enteral iron dose by 60 days of age is positively associated with cognitive performance at 2 years of corrected age. However, this association was not present for iron doses received at 90 days of age (110190). More evidence is needed to rate iron for these uses.

(Read more about IRON)

LIKELY EFFECTIVE

• Dyslipidemia. Niacin prescription products, in doses of 500 mg or greater, are FDA-approved for primary hyperlipidemia and mixed dyslipidemia. Niacin dietary supplements are generally available in lower doses and have not been shown to improve lipid levels. Details: Prescription niacin is not routinely recommended as second-line therapy for patients who primarily need to decrease low-density lipoprotein (LDL) cholesterol. This is due to results from clinical trials showing no effect on cardiovascular related events or mortality (93346,93354,96208,96211,97308,97477,97336). However, niacin might be considered for patients with mixed hyperlipidemia or patients who need to increase high-density lipoprotein (HDL) cholesterol and lower triglycerides. Niacin might also be effective for isolated hypoalphalipoproteinemia (4817). The most pronounced increases in HDL and decreases in triglycerides occur at 1-1.5 grams daily, and the greatest LDL reduction occurs at 2-3 grams daily. Niacin reduces LDL cholesterol by up to 25%, compared with up to a 55% reduction with statins. High-dose niacin can also decrease triglycerides by 20% to 50%, increase HDL by 13% to 35%, decrease apolipoprotein B levels by 2% to 20%, and decrease lipoprotein(a) levels by 23% (4818,4886,4887,4888,4889,4890,12033,25567,93347,96213). The effects of higher dose extended-release niacin on LDL cholesterol and triglycerides appear to be greater in females than males (25565). Experts recommend maximizing statins first because they have the best evidence for improving cardiovascular outcomes (97477,97336,97337). However, if patients cannot reach their LDL goal with a statin alone or if they cannot tolerate a statin, niacin might be combined with other cholesterol-lowering drugs when diet and single-drug therapy are not adequately effective (8545,25566,93351,94191,97337). Adding low-dose niacin, 50 mg daily, to statin therapy has no additional benefit on lipid levels (8546). Population research in adults without dyslipidemia has also found that higher dietary intake of niacin for 3-10 years is associated with a 29% lower risk of developing dyslipidemia when compared with low dietary niacin intake (110493).
• Pellagra. Oral niacin is FDA-approved for the prevention and treatment of pellagra. Details: Population research has found that low consumption of niacin is associated with an increased risk of developing pellagra (25903). Taking niacin 500-1000 mg daily can resolve symptoms of pellagra within a week of treatment initiation (25904). However, niacinamide is sometimes preferred for this indication because it lacks the vasodilating effects of niacin (15,6243).

POSSIBLY EFFECTIVE

• HIV/AIDS-related dyslipidemia. Oral niacin seems to improve lipid levels in patients with dyslipidemia due to HIV/AIDs. Details: Small clinical trials in HIV patients with dyslipidemia associated with antiretroviral therapy shows that taking extended-release niacin (Niaspan, Abbott Laboratories) titrated up to 2 grams daily for 14-48 weeks improves total cholesterol, high-density lipoprotein (HDL) cholesterol, and triglyceride levels when compared to baseline (25570,25902). Other preliminary clinical research in this population shows that taking extended-release niacin (Niaspan, Abbott Laboratories) titrated to 2 grams daily for up to 2 years improves HDL cholesterol levels, but not total cholesterol or triglyceride levels, when compared with no treatment (25569).
• Metabolic syndrome. Oral niacin seems to improve lipid levels in patients with metabolic syndrome. Details: Clinical research shows that taking niacin (Niaspan, Abbott Laboratories) 2 grams daily orally for 16 weeks reduces triglyceride levels by 39 mg/dL and increases high-density lipoprotein (HDL) cholesterol by 5 mg/dL when compared to baseline in patients with metabolic syndrome. These improvements are significant when compared with placebo and are further increased when niacin is taken along with prescription omega-3 ethyl esters (Lovaza, GlaxoSmithKline Pharmaceuticals) 4 grams daily orally (93353). However, niacin does not seem to improve postprandial glucose levels in patients with metabolic syndrome (97333).

INEFFECTIVE

• Cardiovascular disease (CVD). Oral niacin does not seem to reduce cardiovascular-related events in patients with or without CVD. Details: Overall, niacin is not recommended for primary or secondary prevention of CVD. Most clinical trials and meta-analyses conducted prior to 2011 showed a reduction in cardiovascular-related events, cardiovascular-related mortality, and all-cause mortality in patients taking niacin alone or in combination with a statin or clofibrate for primary or secondary prevention of CVD (4847,7388,25095,25911,25912,93349). However, recent meta-analyses of these studies and additional moderate-to-high quality research conducted in over 39,000 patients show no effect of niacin on cardiovascular-related events, cardiovascular-related mortality, or overall mortality (93346,93354,96208,96211,97308). Additionally, one meta-analysis shows that patients taking niacin are twice as likely to report side effects when compared with placebo (96211).

INSUFFICIENT RELIABLE EVIDENCE to RATE

• Alzheimer disease. It is unclear if oral niacin is beneficial for reducing Alzheimer disease risk. Details: Observational research has found that consuming higher amounts of niacin (17-45 mg daily) from food and supplements is associated with a slower cognitive decline and a lower risk of developing Alzheimer disease when compared with people who consume less niacin (14 mg daily) (12077). It is not known if the risk of Alzheimer disease is reduced by taking a stand-alone niacin supplement.
• Atherosclerosis. It is unclear if oral niacin prevents atherosclerosis progression. Details: Preliminary clinical studies show that taking niacin orally, in combination with colestipol for up to 2 years, might modestly reduce progression of atherosclerosis as measured by coronary lesions and carotid arterial intima-media thickness in high-risk males with existing coronary atherosclerosis (25906,25909,25910). However, niacin does not seem to be better than statins. One clinical study in adults with atherosclerosis and peripheral arterial disease shows that taking extended-release niacin 1500 mg, simvastatin 40 mg, and ezetimibe 10 mg daily for 2 years does not reduce atherosclerosis of the superficial femoral artery when compared with simvastatin alone (96208). Niacin has also not been shown to prevent cardiovascular events or mortality (93346,93354,96208,96211,97308).
• Athletic performance. It is unclear if oral niacin improves athletic performance. Details: Preliminary clinical research in untrained adult males shows that taking niacin 1000 mg orally once before a cycling test does not improve power, respiratory exchange ratio, or time to exhaustion when compared with placebo. In addition, these measures were significantly worse when compared with taking caffeine 5 mg/kg orally as a single dose (107942). Clinical research in untrained males also shows that taking a supplement containing niacin 40 mg, caffeine 400 mg, capsicum extract 66.7 mg, and black pepper extract 10 mg prior to exercising does not improve strength, time to exhaustion, or maximal oxygen consumption when compared with placebo (37873).
• Attention deficit-hyperactivity disorder (ADHD). Although there is interest in using oral niacin for ADHD, there is insufficient reliable information about the clinical effects of niacin for this condition.
• Cancer. It is unclear if dietary niacin is beneficial for cancer. Details: Population research in adults with cancer has found that high dietary niacin intake is associated with 49% and 27% lower risk of cancer-related mortality and all-cause mortality when compared with low dietary niacin intake. The same study also found that taking niacin supplements is associated with a lower risk of cancer-related mortality, but not all-cause mortality when compared with not taking niacin supplements (110496).
• Cataracts. It is unclear if oral niacin is beneficial for preventing cataracts. Details: Population research has found that high dietary intake of niacin is associated with a reduced risk of nuclear cataracts (6378). However, there is no reliable evidence that niacin supplements reduce the risk of cataracts.
• Cholera. It is unclear if oral niacin is beneficial for cholera. Details: One small clinical study in adults with severe cholera shows that taking 1-2 grams niacin orally reduces fluid loss in the stool by 31% to 47% in the first 16 hours when compared with control. The 2 gram dose seemed to result in a greater reduction in fluid loss than the 1 gram dose (4868).
• Erectile dysfunction (ED). It is unclear if oral niacin is beneficial in patients with ED and dyslipidemia. Details: Clinical research in patients with erectile dysfunction and dyslipidemia shows that taking extended-release niacin (Niaspan, Abbott Laboratories) titrated to 1.5 grams nightly for a total of 12 weeks significantly improves penetration frequency and the maintenance of an erection after penetration when compared to baseline (25913). The validity of this finding is limited by the lack of a comparator group.
• Glaucoma. It is unclear if oral niacin is beneficial for preventing or treating glaucoma. Details: Population research has found that higher dietary intake of niacin is associated with a lower odds of having glaucoma. However, this association was not consistently present when adjusting for confounders. The effects of niacin supplementation on glaucoma have not been evaluated (107942).
• Hyperphosphatemia. It is unclear if oral niacin is beneficial for preventing high levels of phosphorus in the blood. Details: Preliminary clinical research in patients on maintenance dialysis who are no longer using phosphate binders shows that taking niacin 375-750 mg daily for 8 weeks reduces serum phosphorus levels by 2.1 mg/dL, increases calcium levels by 0.4 mg/dL, and decreases serum alkaline phosphatase when compared with baseline (25914). However, clinical research in hemodialysis patients with inadequate phosphate control despite using standard phosphate-binding therapy shows that taking niacin at the maximum tolerated dose, up to 1000 mg daily, for 12 weeks, does not decrease serum phosphate levels when compared with placebo (93341). It is possible that this latter study was too small to observe between-group differences in changes in serum phosphate levels.
• Hypertension. It is unclear if dietary niacin is beneficial for preventing hypertension. Details: Observational research in Chinese adults found a J-shaped association between dietary niacin intake and development of hypertension, with the lowest risk occurring in those with a daily dietary niacin intake of 14.3-16.7 mg (104934).
• Meniere disease. Although there is interest in using oral niacin for Meniere disease, there is insufficient reliable information about the clinical effects of niacin for this condition.
• Migraine headache. It is unclear if dietary niacin is beneficial for preventing migraine headaches. Details: Population research in adults has found that high dietary intake of niacin is associated with a 28% lower likelihood of having migraine headaches when compared with low dietary intake of niacin (110495). However, the effect of niacin supplementation on migraines has not been studied.
• Motion sickness. Although there is interest in using oral niacin for motion sickness, there is insufficient reliable information about the clinical effects of niacin for this purpose.
• Parkinson disease. It is unclear if oral niacin is beneficial for improving Parkinson disease symptoms. Details: Low-quality clinical research in adults with Parkinson disease shows that taking slow-release niacin 250 mg orally daily for 12 months improves Parkinson disease motor scores and fatigue scores by 17% and 26%, respectively, when compared with baseline (107944). However, higher quality clinical research shows that taking niacin 250 mg orally daily for 6 months does not improve Parkinson disease motor scores when compared with placebo (107943).
• Retinal vein occlusion. It is unclear if oral niacin is beneficial for improving retinal vein occlusion symptoms. Details: A small case series in patients with chronic retinal vein occlusion shows that taking niacin titrated to 500 mg three times daily for 1 year is associated with reduced central macular thickness and improved visual acuity in over 50% of patients when compared with a control group. The addition of prednisolone eye drops does not alter the outcomes of those taking niacin (96212). The validity of this finding is limited due to the retrospective nature of this study.
• Sickle cell disease. It is unclear if oral niacin is beneficial for improving lipid levels in patients with sickle cell disease. Details: A small clinical study in patients with sickle cell disease shows that taking extended-release niacin titrated to 1.5 grams daily for 12 weeks does not improve vascular function or increase high-density lipoprotein (HDL) or apolipoprotein A-I cholesterol levels when compared with placebo (96209).
• Schizophrenia. Although there is interest in using oral niacin for schizophrenia, there is insufficient reliable information about the clinical effects of niacin for this condition.
• Vertigo. Although there is interest in using oral niacin for vertigo, there is insufficient reliable information about the clinical effects of niacin for this condition. More evidence is needed to rate niacin for these uses.

(Read more about NIACIN)

EFFECTIVE

• Ariboflavinosis. Oral riboflavin can treat and prevent low riboflavin levels.

POSSIBLY EFFECTIVE

• Hyperhomocysteinemia. Oral riboflavin reduces homocysteine levels in individuals with the MTHFR 677 TT genotype. It does not seem to provide benefit in individuals with other genotypes. Details: Population research has found that poor riboflavin status is associated with high homocysteine levels in individuals with the 677 TT genotype for the MTHFR enzyme (71386,71403,71409). Taking riboflavin 1.6 mg daily for 12 weeks reduces homocysteine levels by 22% to 40% in individuals with the 677 TT genotype of MTHFR when compared with pretreatment. However, riboflavin supplementation does not seem to reduce homocysteine levels in individuals with the 677 CC or CT genotypes (71443).
• Migraine headache. Oral riboflavin modestly reduces migraine attack frequency and severity in adults. The benefits of oral riboflavin in children are unclear. Details: A meta-analysis of 5 small clinical trials in adults with migraine shows that taking riboflavin 100-400 mg daily, alone or in combination with other natural ingredients, for three months modestly reduces migraine duration, frequency, and pain scores when compared with control (105480). These findings are limited by significant heterogeneity. Most clinical studies compared riboflavin 400 mg daily with placebo, no treatment, or an active control (1396,1397,1398,12387,105480). Limited evidence also suggests that taking riboflavin 400 mg daily might be no different for migraine prevention than certain conventional treatments such as bisoprolol 10 mg, metoprolol 200 mg, propranolol 80 mg, or valproate 500 mg (1396,105480). These findings are limited due to small study size and a lack of power to detect a difference between groups. Limited research has also evaluated riboflavin in children. A network meta-analysis of 3 small clinical trials in children with migraine shows that taking oral riboflavin 100-200 mg daily for 4-12 months does not significantly reduce incidence of migraine when compared with placebo. However, there was a non-significant trend towards reduced migraine frequency. Furthermore, conventional treatments such as propranolol, pregabalin, valproate, and topiramate were not shown to be significantly better than riboflavin for migraine prevention (105484). These findings are limited by small population sizes and insufficient power to detect differences between groups. Although riboflavin 100-200 mg has been used in prospective clinical studies, small observational studies have found some benefit in children taking riboflavin doses as low as 10-40 mg daily and as high as 400 mg daily for 3-4 months (105481,105485). Riboflavin has also been studied in combination with other ingredients, with research suggesting potential benefit. Specifically, riboflavin 400 mg has been combined with magnesium 600 mg and coenzyme Q10 150 mg daily (Dolovent; Linpharma Inc.) (92101), and also with magnesium 300 mg and feverfew 100 mg daily (12389).

INSUFFICIENT RELIABLE EVIDENCE to RATE

• Acne. Although there is interest in using oral riboflavin for acne, there is insufficient reliable information about the clinical effects of riboflavin for this purpose.
• Alzheimer disease. Although there is interest in using oral riboflavin for Alzheimer disease, there is insufficient reliable information about the clinical effects of riboflavin for this condition.
• Cardiovascular disease (CVD). It is unclear if oral riboflavin can prevent mortality due to CVD. Details: Epidemiological research has found that dietary and supplemental riboflavin intake in the highest quartile, around 3.4 mg daily, is associated with a 47% lower risk of CVD mortality when compared with riboflavin intake in the lowest quartile, around 1 mg/day. The reduction in CVD mortality with riboflavin was enhanced by higher folate intake (110727). The validity of this finding is limited by the fact that dietary riboflavin intake was based on 2-day dietary recall.
• Carpal tunnel syndrome. Although there is interest in using oral riboflavin for carpal tunnel syndrome, there is insufficient reliable information about the clinical effects of riboflavin for this purpose.
• Cataracts. It is unclear if oral riboflavin is beneficial in patients with cataracts. Details: Observational research has found that high dietary intake of riboflavin is associated with a reduced risk of nuclear cataracts and age-related lens opacification (6378,14301). Furthermore, a clinical study in Chinese patients with nutrient deficiencies shows that taking a combination of riboflavin 3 mg plus niacin 40 mg daily also seems to reduce the risk of developing nuclear cataracts when compared with no supplementation (4885). It is unclear if the benefit is due to riboflavin, niacin, or the combination.
• Cervical cancer. It is unclear if oral riboflavin helps to prevent cervical cancer. Details: Epidemiological evidence has found that increased riboflavin intake from dietary and supplement sources, along with other B vitamins, is associated with a reduced risk of precancerous cervical lesions (11074).
• Colorectal cancer. It is unclear if oral riboflavin reduces colorectal cancer risk. Details: Epidemiological evidence in a Chinese population has found that increased dietary intake of riboflavin is associated with a reduced risk of developing colorectal cancer (105482).
• Diabetic neuropathy. Intravenous and oral riboflavin have only been evaluated in combination with other ingredients; riboflavin's effect when used alone is unclear. Details: Clinical research in patients with type 2 diabetes shows that intravenous administration of a specific combination product containing succinic acid, inosine, nicotinamide, and riboflavin (Cytoflavin, Polysan) daily for 10 days followed by an oral formulation of the same product, taken daily for 76 days, reduces symptoms of diabetic neuropathy including paresthesia, numbness, and burning when compared with placebo (110503). It is unclear if these findings are due to riboflavin, other ingredients, or the combination.
• Esophageal cancer. It is unclear if oral riboflavin reduces esophageal cancer risk. Details: Population research in Iranian patients has found that low riboflavin status is associated with a two-fold increase in the risk of esophageal cancer (71439). However, not all evidence agrees. Preliminary clinical studies in Chinese individuals with esophageal dysplasia shows that taking riboflavin, alone or in combination with calcium or niacin, for 3-5 years does not seem to reduce the risk of esophageal cancer in patients when compared with baseline or control (4679,63576,71488). Taking riboflavin 200 mg weekly, in combination with retinol 15 mg and zinc 50 mg, also does not seem to be beneficial in this patient population (71501). It is unclear if these findings are generalizable to geographic locations other than China and Iran.
• Gastric cancer. It is unclear if oral riboflavin reduces colorectal cancer risk. Details: Low quality clinical research in a Chinese population shows that taking riboflavin in combination with niacin does not appear to reduce the risk of gastric cancer when compared with control (4679).
• Hypertension. There is limited evidence on the oral use of riboflavin for reducing blood pressure in patients with the MTHFR 677 TT genotype. Details: A 677 C to T polymorphism on the MTHFR gene has been associated with hypertension. In patients with a confirmed MTHFR 677 TT genotype and premature cardiovascular disease, preliminary clinical research suggests that taking riboflavin 1.6 mg daily for 16 weeks reduces systolic blood pressure (SBP) by 9 mmHg and diastolic blood pressure (DBP) by 6 mmHg when compared with placebo . This decrease in blood pressure is larger than that reported in other trials, which may be due to the fact that only patients with the 677 TT genotype were included. These patients seem to respond to riboflavin therapy more so than patients with 677 CC or 677 CT genotype (92102). Additional clinical research in patients with the 677 TT genotype but without cardiovascular disease shows that taking riboflavin 1.6 mg daily for 16 weeks reduces SBP by 5.6 mmHg but does not reduce DBP (92103). There is also interest in using dietary riboflavin for reducing the onset of hypertension. Some epidemiological evidence in a Chinese population has found that increased dietary intake of riboflavin is associated with a reduced risk of developing hypertension (105483).
• Liver cancer. Oral riboflavin has only been evaluated in combination with niacin; its effect when used alone is unclear. Details: Preliminary clinical research in Chinese individuals older than 55 years shows that taking riboflavin in combination with niacin does not seem to prevent liver cancer mortality when compared with control. However, there was a reduced risk of liver cancer mortality in people aged less than 55 years when compared with control (63470).
• Lung cancer. Oral riboflavin has only been evaluated in combination with niacin; its effect when used alone is unclear. Details: Preliminary clinical research in Chinese individuals shows that taking riboflavin in combination with niacin does not appear to reduce the risk of lung cancer when compared with control (34539).
• Malaria. Oral riboflavin has only been evaluated in combination with other ingredients; its effect when used alone is unclear. Details: Preliminary clinical research in children ages 5-14 years living in Gambia and at high risk for malaria exposure suggests that taking riboflavin, in combination with iron, thiamine, and vitamin C, for 3 months does not reduce the frequency or severity of malaria infections when compared with placebo (56730).
• Malnutrition. There is limited evidence on the oral use of riboflavin with other ingredients in children at risk for kwashiorkor. Details: A clinical study in Malawian children at risk for kwashiorkor, a severe form of malnutrition, suggests that taking riboflavin, vitamin E, selenium, and N-acetyl cysteine at a dose of three times the recommended dietary allowance does not prevent kwashiorkor, reduce edema, increase physical growth, or reduce infection when compared with placebo (71433).
• Mitochondrial myopathies. Although there is interest in using oral riboflavin for mitochondrial myopathies, there is insufficient reliable information about the clinical effects of riboflavin for this condition.
• Multiple sclerosis (MS). It is unclear if oral riboflavin slows the progression of MS-related disability. Details: A small clinical study in patients with relapsing-remitting MS or secondary progressive MS who are undergoing treatment with disease-modifying therapies suggests that taking oral riboflavin 10 mg daily for six months is no more effective for improving disability than placebo (91752). The validity of this finding is limited by the small study sample size.
• Oral leukoplakia. It is unclear if oral riboflavin prevents or slows progression of oral leukoplakia. Details: Population research in people living in Uzbekistan has found that low blood levels of riboflavin are associated with an increased prevalence of oral leukoplakia (71502). However, clinical evidence in patients with a high occurrence of oral and esophageal cancer who are living in Uzbekistan suggests that taking riboflavin 80 mg weekly for 20 months does not improve the prevalence or progression of oral leukoplakia when compared to baseline (71565). The validity of this finding is limited by the lack of a placebo group and unusual once weekly dosing. Furthermore, it is unclear if these results are generalizable to other geographic locations.
• Pre-eclampsia. Although there is interest in using oral riboflavin for pre-eclampsia, there is insufficient reliable information about the clinical effects of riboflavin for this purpose.
• Pregnancy-related iron deficiency. It is unclear if oral riboflavin is beneficial in patients with iron deficiency due to pregnancy. Details: Preliminary clinical research in pregnant patients in China suggests that adding riboflavin 1 mg daily to supplemental iron and folic acid does not improve iron status when compared with taking iron and folic acid alone (71480).
• Sickle cell disease. It is unclear if oral riboflavin is beneficial in patients with sickle cell disease. Details: One small clinical study in patients with sickle cell disease suggests that taking riboflavin 5 mg twice daily for 8 weeks increases serum iron and transferrin saturation when compared to baseline; however, riboflavin does not seem to improve serum ferritin or circulating hemoglobin levels (71566).
• Stroke. Oral riboflavin has only been evaluated in combination with niacin; its effect when used alone is unclear. Details: Preliminary clinical research in Chinese individuals with poor nutritional status who are at risk for stroke suggests that taking riboflavin 5.2 mg daily in combination with niacin 40 mg daily does not reduce the risk of stroke-related mortality (2673). More evidence is needed to rate riboflavin for these uses.

(Read more about RIBOFLAVIN)

EFFECTIVE

• Thiamine deficiency. Oral thiamine prevents and treats thiamine deficiency syndromes. Details: Thiamine deficiency is treated with oral thiamine 5-30 mg daily as a single dose or in divided daily doses for one month. For severe deficiency, thiamine up to 300 mg daily can be used (15).Thiamine deficiency can occur in people with malabsorption conditions such as alcohol use disorder, cirrhosis, and gastrointestinal diseases; in those with inadequate intake due to anorexia, nausea, and vomiting; and in those with increased requirements, including pregnancy, increased carbohydrate intake, increased physical activity, hyperthyroidism, infection, and liver disease. However, deficiency is rare with these conditions (15). The elderly might also be at increased risk for subclinical thiamine deficiency (11076).
• Wernicke-Korsakoff syndrome (WKS). Parenteral thiamine is effective for treating symptoms of WKS. Details: Parenteral administration of thiamine 5-200 mg daily for 2 days decreases the risk of developing WKS and decreases symptoms of WKS in acute alcohol withdrawal. Between 30% and 80% of alcoholics are suspected to have thiamine deficiency (11075). An optimal dose for treating WKS has not been established; however, early research suggests that a 200 mg intramuscular dose may be more effective than lower doses (11075). In contrast, a moderate-sized clinical trial in adults with a history of heavy alcohol use who were asymptomatic or symptomatic for WKS shows that there is no benefit to administering high doses (300 mg 3 times daily) compared with medium (100 mg 3 times daily) or low (100 mg daily) doses of parenteral thiamine on cognitive or neurological functioning (111690). The study may have been inadequately powered to detect a difference between groups.

POSSIBLY EFFECTIVE

• Dysmenorrhea. Oral thiamine might reduce pain in some patients with dysmenorrhea. Details: A clinical study in adolescent Iranian females with dysmenorrhea shows that taking thiamine 100 mg alone or along with fish oil 500 mg daily for 2 months moderately reduces pain intensity and duration when compared with placebo (89341). Another preliminary clinical study in Indian females 12-21 years of age with moderate to severe primary dysmenorrhea shows that taking thiamine 100 mg daily for 90 days eliminates pain in 87% of participants when compared to baseline (77820). The validity of this finding is limited by the lack of a placebo group. Furthermore, available research was conducted in India and Iran, so it is unclear if these findings are generalizable to other geographic locations.

POSSIBLY INEFFECTIVE

• Coronary artery bypass graft (CABG) surgery. Intravenous thiamine does not seem to improve outcomes after CABG surgery. Details: A small clinical study in adults undergoing CABG surgery with cardiopulmonary bypass shows that giving intravenous thiamine 200 mg immediately prior to surgery and immediately after surgery does not improve clinical outcomes or lactate levels when compared with placebo (97010). Larger doses of thiamine also don't seem to be beneficial. Another small clinical study in patients receiving CABG with cardiopulmonary bypass shows that giving thiamine 600 mg intravenously on the day of surgery, and 400 mg daily for three postoperative days, does not improve postoperative outcomes when compared with placebo (103000).
• Heart failure. Most research suggests that oral or intravenous thiamine does not improve outcomes in patients with heart failure. Details: Observational research suggests that having heart failure is associated with 2.5-fold increased odds of having thiamine deficiency, possibly because of diuretic use, intestinal malabsorption, and metabolism changes. However, it is unclear if thiamine supplementation is beneficial. A meta-analysis of 2 small clinical trials in adults with systolic heart failure and unclear thiamine status shows that thiamine 200-300 mg given orally or by IV for 7-28 days improves left ventricular ejection fraction (LVEF) by 3% when compared with control (97012). However, other meta-analyses and clinical studies in adults with heart failure with or without thiamine deficiency show that taking intravenous, intramuscular, or oral thiamine 100-500 mg daily does not improve LVEF fraction, left ventricular end-diastolic volume, dyspnea, mortality, hospitalization, or exercise tolerance when compared with placebo or control (103002,111682,111686,111688).
• Mosquito repellent. Oral thiamine does not seem to repel mosquitos. Details: Clinical research in healthy volunteers shows that taking thiamine does not improve mosquito repellency when compared with taking vitamin C as a control (18016).
• Sepsis. Intravenous or oral thiamine, alone or in combination with vitamin C and hydrocortisone, does not seem to reduce mortality or prevent organ failure in sepsis or septic shock. Details: Multiple meta-analyses of small clinical studies in patients with septic shock show that intravenous or oral thiamine 100-500 mg 2-3 times daily for 3-7 days is no better than placebo for improving mortality, end-organ damage, number of ventilator-free days, and duration of intensive care unit (ICU) stay (105443,107717,107727,111689). One meta-analysis suggests that administration of thiamine alone increases the risk of mortality in these patients (111689). Subgroup analyses including only higher quality studies also fail to show a benefit of thiamine (107717). Another recent small clinical trial in patients with septic shock shows that receiving the same dose of intravenous thiamine does not increase vasopressor-free days when compared with placebo (105441). Intravenous thiamine 200 mg every 12 hours has also been evaluated in combination with intravenous vitamin C 1.5-2 grams and hydrocortisone 50-200 mg every 6-12 hours for 4-10 days (HAT therapy). While some retrospective research found HAT therapy to be beneficial (100315,102980,111689), high-quality, prospective clinical research has shown no benefit (105447,109956,111689). Meta-analyses in patients with sepsis and septic shock shows that receiving HAT therapy does not improve mortality, kidney injury, number of ventilator-free days, or ICU length of stay when compared with control (102129,104027,104028,104032,102998,105447,109956,111642,111689). Additionally, the meta-analyses suggest that HAT therapy does not reverse shock or improve sequential organ failure assessment (SOFA) scores (109556,111642). However, one meta-analysis found that HAT therapy shortened the duration of vasopressor use when compared with placebo (111642). Long-term follow up from a study in patients with sepsis-induced respiratory and/or cardiovascular dysfunction shows that receiving HAT therapy does not improve cognitive, psychological, or functional status after 6 months and, for immediate memory scores and development of posttraumatic stress disorder, HAT therapy was less beneficial when compared with placebo (111299).

INSUFFICIENT RELIABLE EVIDENCE to RATE

• Acute kidney injury (AKI). It is unclear if oral or intravenous thiamine is beneficial for treating or preventing AKI. Details: Observational research in adults admitted to the intensive care unit (ICU) with AKI has found that treatment with thiamine (dose unspecified) within the first 48 hours of admission is associated with 39% lower odds of in-hospital mortality and 28% higher odds of kidney function recovery when compared with patients that did not receive thiamine. Receiving thiamine was also associated with a 0.5-day reduction in ICU length of stay (107719).
• Anxiety. Although there is interest in using oral thiamine for anxiety, there is insufficient reliable information about the clinical effects of thiamine for this purpose.
• Cardiac arrest. It is unclear if intravenous thiamine reduces the risk of death after resuscitation from cardiac arrest. Details: A small clinical study in adults resuscitated from cardiac arrest shows that receiving intravenous thiamine 100 mg every 8 hours for 7 days does not reduce 28-day mortality when compare with a normal saline placebo (105442).
• Cardiovascular disease (CVD). It is unclear if oral thiamine is beneficial for treating or preventing CVD. Details: Population research in Korea has found that insufficient dietary thiamine intake (daily intake of less than 1.22 mg in males or 1.03 mg in females) is associated with a 16% increased odds of developing angina or myocardial infarction when compared with sufficient dietary thiamine. However, the effects of thiamine supplementation on CVD have not been studied (107725).
• Cataracts. Small studies suggest that increased dietary thiamine might help prevent cataracts. Details: Observational research has found that a high dietary intake of thiamine 10 mg daily is associated with 40% lower odds of nuclear cataracts (6378). Other population research has found that higher dietary intake of thiamine is associated with a modestly reduced risk of age-related lens opacification (14301).
• Cervical cancer. It is unclear if oral thiamine reduces the risk of developing cervical cancer. Details: Epidemiological research has found that increasing intake of thiamine from dietary and supplemental sources, along with folic acid, riboflavin, and vitamin B12, is associated with a lower odds of precancerous cervical lesions (11074).
• Child development. It is unclear if supplementing breastfeeding females with oral thiamine improves infant neurocognitive development. Details: Preliminary clinical research shows that supplementing breastfeeding females with oral thiamine, 1.2-10 mg daily for 22 weeks, starting at 2 weeks postpartum, does not improve most cognitive or neurodevelopmental scores in the child when compared with placebo. However, one subgroup analysis suggests that thiamine supplementation may improve language scores (107726).
• Cognitive function. Oral thiamine has only been studied in combination with other ingredients; its effect when used alone is unclear. Details: A moderate-sized clinical study in healthy, middle-aged adults shows that taking a combination product containing thiamine hydrochloride 50 mg, other group B vitamins, bacopa, and ginkgo daily for 12 weeks does not improve measures of memory, attention, cognition, mood, or stress reactivity when compared with placebo. Subgroup analysis shows a possible benefit of the combination supplementation on measures of attention in those with an optimal diet at baseline (111334). It is unclear if these findings are due to thiamine, other ingredients, or the combination.
• Coronavirus disease 2019 (COVID-19). It is unclear if intravenous or oral thiamine improves clinical outcomes in patients hospitalized with COVID-19. Details: A small observational study of adults admitted to the intensive care unit with COVID-19 has found that treatment with intravenous or oral thiamine 100 mg daily for an average of 7 days is associated with a 63% reduction in the odds of death within 30 days when compared with control. However, there was no associated reduction in duration of hospitalization or mechanical ventilation (107721). In addition, a small observational study of adults with encephalopathy that were mechanically ventilated secondary to COVID-19 has found that taking thiamine 500 mg three times daily orally for 5 days improves neurological manifestations, including ophthalmoparesis and ataxia, when compared with baseline. The validity of this study is limited by the lack of a comparator group (107722).
• Critical illness (trauma). It is unclear if oral or intravenous thiamine is beneficial in patients with critical illness. Details: A meta-analysis of critically ill patients shows that treatment with oral or intravenous thiamine 100-600 mg daily for up to 7 days does not affect the need for mechanical ventilation, duration of hospital stay, or mortality when compared with control (107727).
• Delirium. It is unclear if oral or intravenous thiamine helps to prevent or treat delirium. Details: In critically ill patients, a meta-analysis of clinical research shows that treatment with oral or intravenous thiamine 100-600 mg daily for up to 7 days reduces the odds of developing delirium by 42% when compared with control (107727). However, some observational research in adults with septic shock has found that receiving intravenous thiamine 400 mg daily with vitamin C 6 grams daily, both in divided doses, is not associated with reduced delirium when compared with control (103001). In non-critically ill, hospitalized adults with altered mental status, retrospective, observational research has also found that administration of oral or intravenous thiamine is not associated with improved cognitive function or reduced in-hospital mortality when compared with control (107723). Preliminary clinical research in adults undergoing an allogeneic hematopoietic stem cell transplant also shows that administering thiamine 200 mg three times a day intravenously for 7 days does not prevent delirium or shorten duration of delirium when compared with placebo (107718).
• Dementia. It is unclear if oral thiamine is beneficial for the prevention of dementia. Details: Observational research in patients with alcohol use disorder has found that taking thiamine is associated with a 24% to 46% lower risk of developing dementia when compared with not taking thiamine (102999).
• Depression. It is unclear if oral thiamine is beneficial in patients with depression. Details: Meta-analyses of population research in adults has found that high dietary consumption of thiamine is associated with a 10% to 31% lower risk of having depression when compared with low dietary consumption of thiamine. However, this research did not evaluate the effects of thiamine supplementation on depression (107133,107725). One small clinical study in adults with major depressive disorder shows that taking thiamine 300 mg daily in conjunction with fluoxetine 20 mg daily leads to greater improvements in depressive symptoms at 6 weeks when compared to fluoxetine with placebo. This benefit was no longer present at 12 weeks. This suggests that thiamine may accelerate improvement in symptoms during initiation of fluoxetine therapy (97013).
• Diabetes. It is unclear if oral thiamine is beneficial for type 2 diabetes or gestational diabetes. Details: A meta-analysis of 6 clinical studies in adults with type 2 diabetes shows that taking thiamine 100-300 mg or its derivative benfotiamine 120-900 mg daily for 1-3 months does not reduce glycated hemoglobin (HbA1c), fasting blood glucose, or postprandial blood glucose when compared with placebo (111681). A large, prospective cohort study in adults without type 2 diabetes suggests that the risk of new-onset diabetes is minimized in adults consuming thiamine 0.75-1.10 mg daily from the diet, while lower and higher thiamine intake levels are associated with an increased risk of new-onset diabetes (111685). Thiamine has also been studied for preventing gestational diabetes. A large, prospective cohort study in pregnant adults suggests that higher supplementation with thiamine during the first and second trimesters is associated with a lower risk of gestational diabetes when compared with lower levels of total thiamine intake. However, this effect was not found for dietary intake of thiamine, only supplementation. Additionally, the participants were mostly Han Chinese adults, limiting the generalizability of the findings to other populations (111680).
• Diabetic nephropathy. It is unclear if oral thiamine is beneficial for diabetic nephropathy. Details: A small clinical study in patients with early-stage diabetic nephropathy and microalbuminuria shows that taking thiamine 100 mg three times daily for 3 months decreases urinary albumin excretion, but does not affect glomerular filtration rate (GFR), when compared with placebo (16556).
• Diabetic neuropathy. Although there is interest in using oral thiamine for diabetic neuropathy, there is insufficient reliable information about the clinical effects of thiamine for this condition.
• Dry eye. Oral thiamine has only been evaluated in combination with other ingredients; its effect when used alone is unclear. Details: A small clinical study in patients with dry eye suggests that adding unspecified doses of thiamine and mecobalamin to treatment with daily artificial tears and corticosteroid drops might slightly improve overall symptoms when compared with only artificial tears and corticosteroid drops for 1 month. There were no differences between groups at 2 months (105444). This finding is limited due to incomplete reporting and a lack of adjustment for multiple hypothesis testing.
• Dyslipidemia. It is unclear if oral thiamine is beneficial for treating or preventing dyslipidemia. Details: A meta-analysis of 3 clinical studies in adults with type 2 diabetes shows that taking thiamine 100-300 mg or its derivative benfotiamine 120-900 mg daily for 1-3 months does not improve low-density lipoprotein (LDL) cholesterol, high-density lipoprotein (HDL) cholesterol, or triglycerides when compared with placebo (111681). Observational research in Korea suggests that insufficient dietary thiamine intake (daily intake of less than 1.22 mg in males or 1.03 mg in females) is associated with 10% higher odds of developing dyslipidemia when compared with sufficient dietary thiamine intake. However, the effects of thiamine supplementation on dyslipidemia have not been studied (107725).
• Emergence delirium. It is unclear if intravenous thiamine helps to prevent emergence delirium in patients after surgery. Details: One clinical study in adults in the intensive care unit (ICU) after gastrointestinal surgery shows that receiving intravenous thiamine 200 mg daily for 3 days is associated with up to 84% lower odds of emergence delirium on the first two days, but not on the third day, when compared with a normal saline control (105440).
• Fatigue. It is unclear if oral thiamine is beneficial in patients with fatigue. Details: A small clinical crossover study in patients with chronic fatigue and inflammatory bowel disease (IBD) shows that taking thiamine 600-1800 mg daily for 20 days reduces fatigue scores when compared with placebo (105438). Taking oral thiamine 300 mg daily for an additional 12 weeks did not seem to affect fatigue scores when compared with placebo. However, an observational follow-up study found that those who self-continued thiamine for an additional 24 weeks after the study ended reported lower fatigue scores when compared with those who did not self-continue thiamine (107720).
• Glaucoma. Although there is interest in using oral thiamine for glaucoma, there is insufficient reliable information about the clinical effects of thiamine for this condition.
• Herpes zoster (shingles). It is unclear if subcutaneous thiamine is beneficial in patients with shingles. Details: A small clinical trial shows that receiving subcutaneous thiamine 100 mg injections six times weekly for 4 weeks reduces itching by at least 30% in 67% of patients with herpes zoster. However, thiamine does not appear to significantly reduce pain in most patients (90396).
• Hypertension. It is unclear if oral thiamine is beneficial in treating or preventing hypertension. Details: Population research in Korea has found that insufficient dietary thiamine intake (daily intake of less than 1.22 mg in males or 1.03 mg in females) is associated with a 5% increased odds of developing hypertension when compared with sufficient dietary thiamine. However, the effects of thiamine supplementation on hypertension have not been studied (107725).
• Impaired glucose tolerance (prediabetes). It is unclear if oral thiamine is beneficial in patients with prediabetes. Details: A very small clinical trial in patients with prediabetes shows that taking thiamine 100 mg by mouth three times daily for 6 weeks modestly decreases 2-hour postprandial plasma glucose levels when compared to baseline and decreases fasting blood glucose levels when compared with placebo (91168).
• Kidney failure. Oral thiamine has only been evaluated in combination with other ingredients; its effect when used alone is unclear. Details: Preliminary, low-quality, clinical research in adults with kidney failure undergoing regular hemodialysis shows that taking oral thiamine 90 mg daily with folic acid 30 mg daily for 96 weeks reduces overall mortality by 67% and improves cognitive scores by 31% when compared with no intervention (107724). It is unclear if this effect is due to thiamine, folic acid, or the combination.
• Migraine headache. It is unclear if dietary thiamine is beneficial for the prevention or treatment of migraine headache. Details: A large, retrospective, cross-sectional study suggests that higher dietary intake of thiamine is associated with lower odds of severe headache or migraine, especially in females (111684). The validity of these effects is limited by the subjective outcome measures and retrospective study design.
• Pneumonia. It is unclear if thiamine is beneficial for patients with pneumonia. Details: A large retrospective cohort study in adults hospitalized with pneumonia and active alcohol use disorder suggests that parenteral administration of thiamine is associated with reduced 14-day mortality and more frequent discharges home, but not a shorter length of stay or fewer ICU transfers, when compared with no thiamine use. Furthermore, parenteral thiamine doses above 200 mg do not appear to improve mortality but may be associated with longer length of stay and less frequent discharges home when compared with low oral doses of thiamine or parenteral thiamine at doses under 200 mg (111679). The validity of these effects is limited by the retrospective study design.
• Ventilator-associated pneumonia (VAP). It is unclear if oral or parenteral thiamine is beneficial for patients with VAP. Details: A retrospective study in adults with VAP in the intensive care unit (ICU) suggests that supplementation with intravenous or oral thiamine may be associated with reduced ICU and in-hospital mortality (111683). The validity of these effects is limited by the retrospective study design. More evidence is needed to rate thiamine for these uses.

(Read more about THIAMINE)

LIKELY SAFE ...when used orally and appropriately. For people age 14 and older with adequate iron stores, iron supplements are safe when used in doses below the tolerable upper intake level (UL) of 45 mg per day of elemental iron. The UL is not meant to apply to those who receive iron under medical supervision (7135,96621). To treat iron deficiency, most people can safely take up to 300 mg elemental iron per day (15). ...when used intravenously and appropriately. Ferric carboxymaltose 200 mg and iron sucrose 200 mg have been given intravenously for up to 10 doses with no reported serious adverse effects (91179). A meta-analysis of clinical studies of hemodialysis patients shows that administering high-dose intravenous (IV) iron does not increase the risk of hospitalization, infection, cardiovascular events, or death when compared with low-dose IV iron, oral iron, or no iron treatment (102861). A more recent meta-analysis of clinical studies of all patient populations shows that administering IV iron does not increase the risk of hospital length of stay or mortality, although the risk of infection is increased by 16% when compared with oral iron or no iron (110186). Despite these findings, there are rare reports of hypophosphatemia and/or osteomalacia (112603,112608,112609,112610).

LIKELY UNSAFE ...when used orally in excessive doses. Doses of 30 mg/kg are associated with acute toxicity. Long-term use of high doses of iron can cause hemosiderosis and multiple organ damage. The estimated lethal dose of iron is 180-300 mg/kg; however, doses as low as 60 mg/kg have also been lethal (15).

CHILDREN: LIKELY SAFE
when used orally and appropriately (7135,91183,112601).

CHILDREN: LIKELY UNSAFE
when used orally in excessive amounts. Tell patients who are not iron-deficient not to use doses above the tolerable upper intake level (UL) of 40 mg per day of elemental iron for infants and children. Higher doses frequently cause gastrointestinal side effects such as constipation and nausea (7135,20097). Iron is the most common cause of pediatric poisoning deaths. Doses as low as 60 mg/kg can be fatal (15).

PREGNANCY AND LACTATION: LIKELY SAFE
when used orally and appropriately. Iron is safe during pregnancy and breast-feeding in patients with adequate iron stores when used in doses below the tolerable upper intake level (UL) of 45 mg daily of elemental iron (7135,96625,110180).

PREGNANCY AND LACTATION: LIKELY UNSAFE
when used orally in high doses. Tell patients who are not iron deficient to avoid exceeding the tolerable upper intake level (UL) of 45 mg daily of elemental iron. Higher doses frequently cause gastrointestinal side effects such as nausea and vomiting (7135) and might increase the risk of preterm labor (100969). High hemoglobin concentrations at the time of delivery are associated with adverse pregnancy outcomes (7135,20109).

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LIKELY SAFE ...when niacin is taken in food or as a supplement in amounts below the tolerable upper intake level (UL) of 30 mg daily for adults 18 years of age and 35 mg daily for adults 19 years and older (6243). ...when prescription products are used orally and appropriately in doses of up to 2 grams daily (12033). CHILDREN:

LIKELY SAFE ...when used orally in amounts that do not exceed the tolerable upper intake level (UL). The ULs of niacin for children are: 1-3 years of age, 10 mg daily; 4-8 years of age, 15 mg daily; 9-13 years of age, 20 mg daily; 14-18 years of age, 30 mg daily (6243).

PREGNANCY AND LACTATION: LIKELY SAFE
when used orally in amounts that do not exceed the tolerable upper intake level (UL). The UL of niacin during pregnancy and lactation is 30 mg daily for 14-18 years of age and 35 mg daily for 19 years and older (6243). There is insufficient reliable information available about the safety of larger oral doses of niacin during pregnancy or lactation; avoid using.

(Read more about NIACIN)

LIKELY SAFE ...when used orally and appropriately. Riboflavin 400 mg daily has been taken for up to 3 months, and 10 mg daily has been taken safely for up to 6 months (4912,91752,105480). A tolerable upper intake level (UL) has not been established (3094,91752,94089).

CHILDREN: LIKELY SAFE
when used orally and appropriately in dietary amounts. A tolerable upper intake level (UL) has not been established (3094,94089). ...when used orally in higher doses for up to 1 year. Doses of 100-200 mg daily have been used safely for 4-12 months in children ages 9-13 years (71483,105484).

PREGNANCY AND LACTATION: LIKELY SAFE
when used orally and appropriately in dietary amounts. A tolerable upper intake level (UL) has not been established (3094,94089).

(Read more about RIBOFLAVIN)

LIKELY SAFE ...when used orally and appropriately. A tolerable upper intake level (UL) has not been established for thiamine, and doses up to 50 mg daily have been used without adverse effects (15,6243). ...when used intravenously or intramuscularly and appropriately. Injectable thiamine is an FDA-approved prescription product (15,105445).

CHILDREN: LIKELY SAFE
when used orally and appropriately in dietary amounts. A tolerable upper intake level (UL) has not been established for healthy individuals (6243).

PREGNANCY AND LACTATION: LIKELY SAFE
when used orally in dietary amounts of 1. 4 mg daily. A tolerable upper intake level (UL) has not been established for healthy individuals (3094,6243).

(Read more about THIAMINE)

BISPHOSPHONATES Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = D Iron reduces the absorption of bisphosphonates.  Details Advise patients that doses of bisphosphonates should be separated by at least two hours from doses of all other medications, including supplements such as iron. Divalent cations, including iron, can decrease absorption of bisphosphonates by forming insoluble complexes in the gastrointestinal tract (15).

CHLORAMPHENICOL Interaction Rating = Minor Be watchful with this combination. Severity = Moderate •  Occurrence = Unlikely •  Level of Evidence = D Theoretically, taking chloramphenicol with iron might reduce the response to iron therapy in iron deficiency anemia.  Details Chloramphenicol interferes with erythrocyte maturation (15,3046). However, since chloramphenicol isn't usually taken for prolonged periods, this isn't likely to be clinically significant.

DOLUTEGRAVIR (Tivicay) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = B Iron might decrease dolutegravir levels by reducing its absorption.  Details Advise patients to take dolutegravir at least 2 hours before or 6 hours after taking iron. Pharmacokinetic research shows that iron can decrease the absorption of dolutegravir from the gastrointestinal tract through chelation (93578). When taken under fasting conditions, a single dose of ferrous fumarate 324 mg orally along with dolutegravir 50 mg reduces overall exposure to dolutegravir by 54% (94190).

INTEGRASE INHIBITORS Interaction Rating = Moderate Be cautious with this combination. Severity = High •  Occurrence = Possible •  Level of Evidence = D Theoretically, taking iron along with integrase inhibitors might decrease the levels and clinical effects of these drugs.  Details Iron is a divalent cation. There is concern that iron may decrease the absorption of integrase inhibitors from the gastrointestinal tract through chelation (93578). One pharmacokinetic study shows that iron can decrease blood levels of the specific integrase inhibitor dolutegravir through chelation (94190). Also, other pharmacokinetic research shows that other divalent cations such as calcium can decrease the absorption and levels of some integrase inhibitors through chelation (93578,93579).

LEVODOPA Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = B Iron might decrease levodopa levels by reducing its absorption.  Details Advise patients to separate doses of levodopa and iron as much as possible. There is some evidence in healthy people that iron forms chelates with levodopa, reducing the amount of levodopa absorbed by around 50% (9567). The clinical significance of this hasn't been determined.

LEVOTHYROXINE (Synthroid, others) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = B Iron might decrease levothyroxine levels by reducing its absorption.  Details Advise patients to separate levothyroxine and iron doses by at least 2 hours. Iron can decrease the absorption and efficacy of levothyroxine by forming insoluble complexes in the gastrointestinal tract (9568).

METHYLDOPA (Aldomet) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = B Iron might decrease methyldopa levels by reducing its absorption.  Details Advise patients to separate methyldopa and iron doses by at least 2 hours. Iron can decrease the absorption of methyldopa from the gastrointestinal tract through chelation, resulting in increases in blood pressure (7900,20151).

MYCOPHENOLATE MOFETIL (CellCept) Interaction Rating = Moderate Be cautious with this combination. Severity = High •  Occurrence = Unlikely •  Level of Evidence = D Theoretically, iron might decrease mycophenolate mofetil levels by reducing its absorption.  Details Advise patients to take iron 4-6 hours before, or 2 hours after, mycophenolate mofetil. It has been suggested that a decrease of absorption is possible, probably by forming nonabsorbable chelates. However, mycophenolate pharmacokinetics are not affected by iron supplementation in available clinical research (3046,20152,20153,20154,20155).

PENICILLAMINE (Cuprimine, Depen) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = D Iron might decrease penicillamine levels by reducing its absorption.  Details Advise patients to separate penicillamine and iron doses by at least 2 hours. Oral iron supplements can reduce absorption of penicillamine by 30% to 70%, probably due to chelate formation. In people with Wilson's disease, this interaction has led to reduced efficacy of penicillamine (3046,3072,20156).

QUINOLONE ANTIBIOTICS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = D Iron might decrease levels of quinolone antibiotics by reducing their absorption.  Details Advise patients to separate quinolone antibiotics and iron doses by at least 2 hours. Iron decreases the absorption of quinolones due to formation of insoluble complexes in the gastrointestinal tract (15,3072).

TETRACYCLINE ANTIBIOTICS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = D Iron might decrease levels of tetracycline antibiotics by reducing their absorption.  Details Advise patients to take iron at least 2 hours before or 4 hours after tetracycline antibiotics. Concomitant use can decrease absorption of tetracycline antibiotics from the gastrointestinal tract by 50% to 90% (15).

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ALCOHOL (Ethanol) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = D Concomitant use of alcohol and niacin might increase the risk of flushing and hepatotoxicity.  Details Alcohol can exacerbate the flushing and pruritus associated with niacin (4458,11689). Large doses of niacin might also exacerbate liver dysfunction associated with chronic alcohol use. A case report describes delirium and lactic acidosis in a patient taking niacin 3 grams daily who ingested 1 liter of wine (14510). Advise patients to avoid large amounts of alcohol while taking niacin.

ALLOPURINOL (Zyloprim) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = C Theoretically, niacin might antagonize the therapeutic effects of uricosurics such as allopurinol.  Details Large doses of niacin can reduce urinary excretion of uric acid, potentially resulting in hyperuricemia (4860,4863,12033). Doses of uricosurics such as allopurinol might need to be increased to maintain control of gout in patients who start taking niacin (4458). People who have frequent attacks of gout despite uricosuric therapy should avoid niacin (4863).

ANTICOAGULANT/ANTIPLATELET DRUGS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = D Theoretically, niacin may have additive effects when used with anticoagulant or antiplatelet drugs.  Details Several cases of clotting factor synthesis deficiency and coagulopathy have been reported in patients taking sustained-release niacin (25915). Also, thrombocytopenia has been reported in patients treated with niacin or niacin plus lovastatin (25916).

ANTIDIABETES DRUGS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = B Niacin can increase blood glucose levels and may diminish the effects of antidiabetes drugs.  Details Niacin impairs glucose tolerance in a dose-dependent manner, probably by causing or aggravating insulin resistance and increasing hepatic production of glucose (4860,4863,11692,11693). In diabetes patients, niacin 4.5 grams daily for 5 weeks can increase plasma glucose by an average of 16% and glycated hemoglobin (HbA1c) by 21% (4860). However, lower doses of 1.5 grams daily or less appear to have minimal effects on blood glucose (12033). In some patients, glucose levels increase when niacin is started, but then return to baseline when a stable dose is reached (12033,93344). Up to 35% of patients with diabetes may need adjustments in hypoglycemic therapy when niacin is added (4458,4860,4863,11689,12033).

ANTIHYPERTENSIVE DRUGS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = B Theoretically, niacin may increase the risk of hypotension when used with antihypertensive drugs.  Details The vasodilating effects of niacin can cause hypotension (4863,12033,93341). Furthermore, some clinical evidence suggests that a one-hour infusion of niacin can reduce systolic, diastolic, and mean blood pressure in hypertensive patients. This effect is not observed in normotensive patients (25917).

ASPIRIN Interaction Rating = Minor Be watchful with this combination. Severity = Insignificant •  Occurrence = Likely •  Level of Evidence = B Large doses of aspirin might alter the clearance of niacin.  Details Aspirin is often used with niacin to reduce niacin-induced flushing (4458,11689). Doses of 80-975 mg aspirin have been used, but 325 mg appears to be optimal (4458,4852,4853,11689). Aspirin also seems to reduce the clearance of niacin by competing for glycine conjugation. Taking aspirin 1 gram seems to reduce niacin clearance by 45% (14524). This is probably a dose-related effect and not clinically significant with the more common aspirin dose of 325 mg (11689,14524).

BILE ACID SEQUESTRANTS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = D Bile acid sequestrants can bind niacin and decrease absorption. Separate administration by 4-6 hours to avoid an interaction.  Details In vitro studies show that colestipol (Colestid) binds about 98% of available niacin and cholestyramine (Questran) binds 10% to 30% (14511).

GEMFIBROZIL (Lopid) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = D Theoretically, concomitant use of niacin and gemfibrozil might increase the risk of myopathy in some patients.  Details A case of myopathy from concomitant use of niacin and gemfibrozil has been reported (25920). Niacin alone has also been associated with cases of myopathy (26100,26111). Using gemfibrozil with niacin might further increase the risk of developing myopathy.

HEPATOTOXIC DRUGS Interaction Rating = Moderate Be cautious with this combination. Severity = High •  Occurrence = Possible •  Level of Evidence = D Theoretically, concomitant use of niacin and hepatotoxic drugs might increase the risk of hepatotoxicity.  Details Niacin has been associated with cases of liver toxicity, especially when used in pharmacologic doses (4863,11689,11691,25929,25930,25931). Sustained-release niacin preparations appear to be associated with a higher risk of hepatotoxicity than immediate-release niacin (11691,25930,25931,93342).

HMG-CoA REDUCTASE INHIBITORS ("Statins") Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = D Theoretically, concomitant use of niacin and statins might increase the risk of myopathy and rhabdomyolysis in some patients.  Details Some case reports have raised concerns that niacin might increase the risk of myopathy and rhabdomyolysis when combined with statins (14508,25918). However, a significantly increased risk of myopathy has not been demonstrated in clinical trials, including those using an FDA-approved combination of lovastatin and niacin (Advicor) (7388,11689,12033,14509).

PROBENECID (Benemid) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = C Theoretically, niacin might antagonize the therapeutic effects of uricosurics such as probenecid.  Details Large doses of niacin reduce urinary excretion of uric acid, potentially causing hyperuricemia (4863,12033). Doses of uricosurics such as probenecid might need to be increased to maintain control of gout in patients who start taking niacin (4458). People who have frequent attacks of gout despite uricosuric therapy should avoid niacin (4863).

SULFINPYRAZONE (Anturane) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = C Theoretically, niacin might antagonize the therapeutic effects of uricosurics such as sulfinpyrazone.  Details Large doses of niacin reduce urinary excretion of uric acid, potentially causing hyperuricemia (4863,12033). Doses of uricosurics such as sulfinpyrazone might need to be increased to maintain control of gout in patients who start taking niacin (4458). People who have frequent attacks of gout despite uricosuric therapy should avoid niacin (4863).

THYROID HORMONE Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Probable •  Level of Evidence = D Theoretically, niacin might antagonize the therapeutic effects of thyroid hormones.  Details Clinical research and case reports suggests that taking niacin can reduce serum levels of thyroxine-binding globulin by up to 25% and moderately reduce levels of thyroxine (T4) (25916,25925,25926,25928). Patients taking thyroid hormone for hypothyroidism might need dose adjustments when using niacin.

TRANSDERMAL NICOTINE (Nicoderm) Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = D Theoretically, concomitant use of niacin and transdermal nicotine might increase the risk of flushing and dizziness.  Details Niacin and nicotine can both cause flushing and dizziness (496,96211).

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TETRACYCLINE ANTIBIOTICS Interaction Rating = Moderate Be cautious with this combination. Severity = Moderate •  Occurrence = Possible •  Level of Evidence = D Theoretically, taking riboflavin with tetracycline antibiotics may decrease the potency of these antibiotics.  Details In vitro research suggests that riboflavin may inhibit the potency of tetracycline antibiotics (23372). It is not clear if this effect is clinically significant, as this interaction has not been reported in humans.

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TRIMETHOPRIM (Proloprim) Interaction Rating = Minor Be watchful with this combination. Severity = Insignificant •  Occurrence = Probable •  Level of Evidence = B Trimethoprim might increase blood levels of thiamine.  Details In vitro, animal, and clinical research suggest that trimethoprim inhibits intestinal thiamine transporter ThTR-2, hepatic transporter OCT1, and renal transporters OCT2, MATE1, and MATE2, resulting in paradoxically increased thiamine plasma concentrations (111678).

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General ...Orally or intravenously, iron is generally well tolerated when used appropriately.
Most Common Adverse Effects:
Orally: Abdominal pain, constipation, diarrhea, gastrointestinal irritation, nausea, and vomiting.
Serious Adverse Effects (Rare):
Orally: Case reports have raised concerns about oral or gastric ulcerations.
Intravenously: Case reports have raised concerns about hypophosphatemia and osteomalacia.

Cardiovascular ...There is debate regarding the association between coronary heart disease (CHD) or myocardial infarction (MI) and high iron intake or high body iron stores. Some observational studies have reported that high body iron stores are associated with increased risk of MI and CHD (1492,9542,9544,9545,15175). Some observational studies reported that only high heme iron intake from dietary sources such as red meat are associated with increased risk of MI and CHD (1492,9546,15174,15205,15206,91180). However, the majority of research has found no association between serum iron levels and cardiovascular disease (1097,1099,9543,9547,9548,9549,9550,56469,56683).
There is one case of Kounis syndrome, also referred to as allergic angina or allergic myocardial infarction, in a 39-year-old female patient without previous coronary artery disease given intravenous ferric carboxymaltose. The patient experienced anaphylactic symptoms, including headache, abdominal pain, and breathing difficulties, 3 minutes after starting the infusion. She was further diagnosed with non-ST-elevation myocardial infarction (112607).

Dermatologic ...Cutaneous hemosiderosis, or skin staining, has been reported following intravenous iron infusion in various case reports. Most of these cases are due to extravasation following iron infusion (112605,112611). In one case, extravasation has occurred following iron derisomaltose infusion in a 41-year-old female with chronic kidney disease (112605). Rarely, diffuse cutaneous hermosiderosis has occurred. In one case, a 31-year-old female with excessive sweating developed cutaneous hemosiderosis in the armpits following an intravenous iron polymaltose infusion (112611).

Endocrine ...Population research in females shows that higher ferritin levels are associated with an approximately 1. 5-fold higher odds of developing gestational diabetes. Increased dietary intake of heme-iron, but not non-heme iron, is also associated with an increased risk for gestational diabetes. The effects of iron supplementation could not be determined from the evaluated research (96618). However, in a sub-analysis of a large clinical trial in pregnant adults, daily supplementation with iron 100 mg from 14 weeks gestation until delivery did not affect the frequency or severity of glucose intolerance or gestational weight gain (96619).

Gastrointestinal ...Orally, iron can cause dry mouth, gastrointestinal irritation, heartburn, abdominal pain, constipation, diarrhea, nausea, or vomiting (96621,102864,104680,104684,110179,110185,110188,110189,110192). These adverse effects are uncommon at doses below the tolerable upper intake level (UL) of 45 mg per day of elemental iron in adults with normal iron stores (7135). Higher doses can be taken safely in adults with iron deficiency, but gastrointestinal side effects may occur (1095,20118,20119,56698,102864). Taking iron supplements with food seems to reduce gastrointestinal side effects (7135). However, food can also significantly reduce iron absorption. Iron should be taken on an empty stomach, unless it cannot be tolerated.
There are several formulations of iron products such as ferrous sulfate, ferrous gluconate, ferrous fumarate, and others. Manufacturers of some formulations, such as polysaccharide-iron complex products (Niferex-150, etc), claim to be better tolerated than other formulations; however, there is no reliable evidence to support this claim. Gastrointestinal tolerability relates mostly to the elemental iron dose rather than the formulation (17500).
Enteric-coated or controlled-release iron formulations might reduce nausea for some patients, however, these products also have lower absorption rates (17500).
Liquid oral preparations can blacken and stain teeth (20118).
Iron can also cause oral ulcerations and ulcerations of the gastric mucosa (56684,91182,96622,110179). In one case report, an 87-year-old female with Alzheimer disease experienced a mucosal ulceration, possibly due to holding a crushed ferrous sulfate 80 mg tablet in the mouth for too long prior to swallowing (91182). The ulceration was resolved after discontinuing iron supplementation. In another case report, a 76-year old male suffered gastric mucosal injury after taking a ferrous sulfate tablet daily for 4 years (56684). In a third case report, a 14-year-old female developed gastritis involving symptoms of upper digestive hemorrhage, nausea, melena, and stomach pain. The hemorrhage was attributed to supplementation with ferrous sulfate 2 hours after meals for the prior 2 weeks (96622). In one case report, a 43-year old female developed atrophic gastritis with non-bleeding ulcerations five days after starting oral ferrous sulfate 325 mg twice daily (110179).
Intravenously, iron can cause gastrointestinal symptoms sch as nausea (104684,110192).

Immunologic ...Although there is some clinical research associating iron supplementation with an increased rate of malaria infection (56796,95432), the strongest evidence to date does not support this association, at least for areas where antimalarial treatment is available (95433,96623). In an analysis of 14 trials, iron supplementation was not associated with an increased risk of malaria (96623). In a sub-analysis of 7 preliminary clinical studies, the effect of iron supplementation was dependent upon the access to services for antimalarial treatment. In areas where anemia is common and services are available, iron supplementation is associated with a 9% reduced risk of clinical malaria. In an area where services are unavailable, iron supplementation was associated with a 16% increased risk in malaria incidence (96623). The difference in these findings is likely associated with the use of malaria prevention methods.
A meta-analysis of clinical studies of all patient populations shows that administering IV iron, usually iron sucrose and ferric carboxymaltose, increases the risk of infection by 16% when compared with oral iron or no iron. However, sub-analyses suggest this increased risk is limited to patients with inflammatory bowel disease (IBD) (110186).
Intravenously, iron has rarely resulted in allergic reactions, including anaphylactoid reactions (110185,110192,112606,112607). There is one case of Kounis syndrome, also referred to as allergic angina or allergic myocardial infarction, in a 39-year-old female patient without previous coronary artery disease given intravenous ferric carboxymaltose. The patient experienced anaphylactic symptoms, including headache, abdominal pain, and breathing difficulties, 3 minutes after starting the infusion. She was further diagnosed with non-ST-elevation myocardial infarction (112607).

Musculoskeletal ...Intravenously, iron rarely results in osteomalacia related to hypophosphatemia (112609). At least 2 cases exist of hypophosphatemic osteomalacia. In one case, a 70-year-old male with a genetic hemorrhagic disorder infused with ferric carboxymaltose developed lower limb pain with hypophosphatemia and diffuse bone demineralization in the feet (112609). In a second case, a 61-year-old male developed femoral neck insufficiency fractures following repeated ferric carboxymaltose transfusions for anemia related to vascular malformation in the bowel (112603). Severe hypophosphatemia requiring intravenous phosphate in the absence of osteomalacia has also occurred following intravenous ferric carboxymaltose (112608,112610).

Oncologic ...There is a debate regarding the association between high levels of iron stores and cancer. Data are conflicting and inconclusive (1098,1099,1100,1102). Epidemiological studies suggest that increased body iron stores may increase the risk of cancer or general mortality (56703).
Occupational exposure to iron may be carcinogenic (56691). Oral exposure to iron may also be carcinogenic. Pooled analyses of population studies suggest that increasing the intake of heme iron increases the risk of colorectal cancer. For example, increasing heme iron intake by 1 mg/day is associated with an 11% increase in risk (56699,91185).

Other ...Intravenously, sodium ferric gluconate complex (SFGC) caused drug intolerance reactions in 0. 4% of hemodialysis patients including 2 patients with pruritus and one patient each with anaphylactoid reaction, hypotension, chills, back pain, dyspnea/chest pain, facial flushing, rash and cutaneous symptoms of porphyria (56527).

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General ...Orally, niacin is well tolerated in the amounts found in foods. It is also generally well tolerated in prescription doses when monitored by a healthcare provider.
Most Common Adverse Effects:
Orally: Flushing, gastrointestinal complaints (abdominal pain, constipation, diarrhea, heartburn, nausea, vomiting), and elevated liver enzymes.
Serious Adverse Effects (Rare):
Orally: Hepatotoxicity, myopathy, thrombocytopenia, and vision changes.

Cardiovascular ...Orally, flushing is a common dose-related adverse reaction to niacin. A large meta-analysis of clinical studies shows that up to 70% of patients may experience flushing (96211). Although flushing can occur with doses of niacin as low as 30 mg daily, it is more common with the larger doses used for treatment of dyslipidemia. The flushing reaction is due to prostaglandin-induced blood vessel dilation and can also include symptoms of burning, tingling, urticaria, erythema, pain, and itching of the face, arms, and chest. There may also be increased intracranial blood flow and headache (4889,26089,93341,104933). Onset is highly variable and ranges from within 30 minutes to as long as 6 weeks after the initial dose (6243). Flushing can be minimized via various strategies, including taking doses with meals, slow dose titration, using extended release formulations, pretreating with non-steroidal anti-inflammatory drugs, taking regular-release niacin with meals, or taking the sustained-release product at bedtime (4852,4853,4854,4857,4858,25922,26073,26084). Flushing often diminishes with continued use but can recur when niacin is restarted after missed doses (4863,6243,26081). The vasodilating effects of niacin can also cause hypotension, dizziness, tachycardia, arrhythmias, syncope, and vasovagal attacks, especially in patients who are already taking antihypertensive drugs (4863,12033,93341,110494).
High doses of niacin can raise homocysteine levels. A 17% increase has been reported with 1 gram daily and a 55% increased has been reported with 3 grams daily. Elevated homocysteine levels are an independent risk factor for cardiovascular disease (490); however, the clinical significance of this effect is unknown. A large-scale study (AIM-HIGH) found that patients receiving extended-release niacin (Niaspan) 1500-2000 mg daily with a statin had an over two-fold increased risk of ischemic stroke (1.6%) when compared with those receiving only simvastatin (0.7%). However, when the risk was adjusted for confounding factors, niacin was not found to be associated with increased stroke risk (17627,93354). A meta-analysis of three clinical trials conducted in approximately 29,000 patients showed a higher risk of mortality in patients taking niacin in addition to a statin when compared with a statin alone. However, with a p-value of 0.05 and confidence interval including 1, the validity of this finding remains unclear (97308).

Endocrine ...Orally, niacin can impair glucose tolerance in a dose-dependent manner. Dosages of 3-4 grams daily appear to increase blood glucose in patients with or without diabetes, while dosages of 1.5 grams daily or less have minimal effects (12033). Niacin is thought to impair glucose tolerance by increasing insulin resistance or increasing hepatic output of glucose (4863,11692,11693). In patients with diabetes, niacin 4.5 grams daily for 5 weeks has been associated with an average 16% increase in plasma glucose and 21% increase in glycated hemoglobin (HbA1C) (4860). Up to 35% of patients with diabetes may need to increase the dose or number of hypoglycemic agents when niacin is started (4458,4860,4863,11689,12033). Occasionally, severe hyperglycemia requiring hospitalization can occur (11693). In patients with impaired fasting glucose levels, niacin may also increase fasting blood glucose, and adding colesevelam might attenuate this effect (93343).
Although patients without diabetes seem to only experience small and clinically insignificant increases in glucose (4458), niacin might increase their risk of developing diabetes. A meta-analysis of clinical research involving over 26,000 patients shows that using niacin over 5 years is associated with increased prevalence of new onset type 2 diabetes at a rate of 1 additional case of diabetes for every 43 patients treated with niacin (96207). This finding is limited because the individual trials were not designed to assess diabetes risk and the analysis could not be adjusted for confounding factors like obesity. One small clinical study shows that taking extended-release niacin with ezetimibe/simvastatin does not increase the risk of a new diagnosis of diabetes or need for antidiabetic medication when compared with ezetimibe/simvastatin alone after 16 months (93344). This may indicate that the increased risk of developing diabetes is associated with niacin use for more than 16 months.
Niacin therapy has also been linked with hypothyroidism and its associated alterations in thyroid hormone and binding globulin tests (such as decreased total serum thyroxine, increased triiodothyronine, decreased thyroxine-binding globulin levels, and increased triiodothyronine uptake) (25916,25925,25926,25928).

Gastrointestinal ...Orally, large doses of niacin can cause gastrointestinal disturbances including nausea, vomiting, bloating, heartburn, abdominal pain, anorexia, diarrhea, constipation, and activation of peptic ulcers (4458,4863,12033,26083,93341,96211). These effects may be reduced by taking the drug with meals or antacid, and usually disappear within two weeks of continued therapy (4851,26094). Gastrointestinal effects may be more common with time-release preparations of niacin (11691).

Hematologic ...Orally, sustained-release niacin has been associated with cases of reversible coagulopathy, mild eosinophilia, and decreased platelet counts (4818,25915,26097,93340). Also, there have been reports of patients who developed leukopenia while taking niacin for the treatment of hypercholesterolemia (25916).

Hepatic ...Orally, niacin is associated with elevated liver function tests and jaundice, especially with doses of 3 grams/day or more, and when doses are rapidly increased (4458,4863,6243). The risk of hepatotoxicity appears to be higher with slow-release and extended-release products (4855,4856,4863,6243,11691,12026,12033,93342). Niacin should be discontinued if liver function tests rise to three times the upper limit of normal (4863). There are rare cases of severe hepatotoxicity with fulminant hepatitis and encephalopathy due to niacin (4863,6243,11691). Also, there is at least one case of niacin-induced coagulopathy resulting from liver injury without liver enzyme changes (93340).

Musculoskeletal ...Orally, niacin has been associated with elevated creatine kinase levels (4818,4888). Also, several cases of niacin-induced myopathy have been reported (26100,26111). Concomitant administration of niacin and HMG-CoA reductase inhibitors may increase the risk of myopathy and rhabdomyolysis (14508,25918,26111); patients should be monitored closely.

Neurologic/CNS ...Orally, high-dose niacin has been associated with cases of neuropsychiatric adverse events such as extreme pain and psychosis. Two 65-year-old males taking niacin orally for 5 months for the treatment of dyslipidemias developed severe dental and gingival pain. The pain was relieved by the discontinuation of niacin. The pain was thought to be due to inflammation and pain referral to the teeth (4862). In one case report, a 52-year-old male with no history of psychiatric illness who initially complained of hot flushes when taking niacin 500 mg daily, presented with an acute psychotic episode involving mania after niacin was increased to 1000 mg daily (93350).

Ocular/Otic ...Orally, chronic use of large amounts of niacin has been associated with dry eyes, toxic amblyopia, blurred vision, eyelid swelling, eyelid discoloration, loss of eyebrows and eyelashes, proptosis, keratitis, macular edema, and cystic maculopathy, which appear to be dose-dependent and reversible (4863,6243,26112).

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General ...Orally, riboflavin is generally well tolerated.
Most Common Adverse Effects:
Orally: Dose-related nausea and urine discoloration.

Gastrointestinal ...Orally, riboflavin has been associated with rare diarrhea and dose-related nausea (1398,71483). In one clinical study, one subject out of 28 reported having diarrhea two weeks after starting riboflavin 400 mg daily (1398).

Genitourinary ...Orally, high doses of riboflavin can cause bright yellow urine. Furthermore, in one clinical study, one subject out of 28 reported polyuria two weeks after starting riboflavin 400 mg daily (1398,3094).

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General ...Orally and parenterally, thiamine is generally well tolerated.
Serious Adverse Effects (Rare):
Parenterally: Hypersensitivity reactions including angioedema and anaphylaxis.

Immunologic ...Orally, thiamine might rarely cause dermatitis and other allergic reactions. Parenterally, thiamine can cause anaphylactoid and hypersensitivity reactions, but this is also rare (<0.1%). Reported symptoms and events include feelings of warmth, tingling, pruritus, urticaria, tightness of the throat, cyanosis, respiratory distress, gastrointestinal bleeding, pulmonary edema, angioedema, hypotension, and death (15,35585,105445).
In one case report, a 46-year-old female presented with systemic allergic dermatitis after applying a specific product (Inzitan, containing lidocaine, dexamethasone, cyanocobalamin and thiamine) topically by iontophoresis; the allergic reaction was attributed to thiamine (91170).

(Read more about THIAMINE)