Lowering blood homocysteine with folic acid based supplements: meta-analysis of randomised trialsBMJ 1998; 316 doi: https://doi.org/10.1136/bmj.316.7135.894 (Published 21 March 1998) Cite this as: BMJ 1998;316:894
- Homocysteine Lowering Trialists' Collaboration ()
- Correspondence to: Dr Robert Clarke, Homocysteine Lowering Trialists' Collaboration, Clinical Trial Service Unit, Radcliffe Infirmary, Oxford OX2 6HE
- Accepted 27 November 1997
Objective: To determine the size of reduction in homocysteine concentrations produced by dietary supplementation with folic acid and with vitamins B-12 or B-6.
Design: Meta-analysis of randomised controlled trials that assessed the effects of folic acid based supplements on blood homocysteine concentrations. Multivariate regression analysis was used to determine the effects on homocysteine concentrations of different doses of folic acid and of the addition of vitamin B-12 or B-6.
Subjects: Individual data on 1114 people included in 12 trials.
Findings: The proportional and absolute reductions in blood homocysteine produced by folic acid supplements were greater at higher pretreatment blood homocysteine concentrations (P<0.001) and at lower pretreatment blood folate concentrations (P<0.001). After standardisation to pretreatment blood concentrations of homocysteine of 12 μmol/l and of folate of 12 nmol/l (approximate average concentrations for Western populations), dietary folic acid reduced blood homocysteine concentrations by 25% (95% confidence interval 23% to 28%; P<0.001), with similar effects in the range of 0.5-5 mg folic acid daily. Vitamin B-12 (mean 0.5 mg daily) produced an additional 7% (3% to 10%) reduction in blood homocysteine. Vitamin B-6 (mean 16.5 mg daily) did not have a significant additional effect.
Conclusions: Typically in Western populations, daily supplementation with both 0.5-5 mg folic acid and about 0.5 mg vitamin B-12 would be expected to reduce blood homocysteine concentrations by about a quarter to a third (for example, from about 12 μmol/l to 8-9 μmol/l). Large scale randomised trials of such regimens in high risk populations are now needed to determine whether lowering blood homocysteine concentrations reduces the risk of vascular disease.
Higher blood homocysteine concentrations seem to be associated with higher risks of occlusive vascular disease and with lower blood concentrations of folate and vitamins B-12 and B-6
Proportional and absolute reductions in blood homocysteine concentrations with folic acid supplements are greater at higher pretreatment blood homocysteine concentrations and at lower pretreatment blood folate concentrations
In typical Western populations, supplementation with both 0.5-5 mg daily folic acid and about 0.5 mg daily vitamin B-12 should reduce blood homocysteine concentrations by about a quarter to a third
Large scale randomised trials of such regimens in people at high risk are now needed to determine whether lowering blood homocysteine concentrations reduces the risk of vascular disease
Epidemiological studies have consistently reported that patients with occlusive vascular disease have higher blood homocysteine concentrations than control subjects, and that these differences precede the onset of disease and are independent of other risk factors.1-5 A meta-analysis of the observational studies of blood homocysteine and vascular disease indicated that a prolonged lowering of homocysteine concentration by 1 μmol/l was associated with about a 10% reduction in risk throughout the range 10-15 μmol/l.1 Blood concentrations of homocysteine are inversely related to blood concentrations of folate, vitamin B-12, and, to a lesser extent, vitamin B-6.6 Dietary supplements of these vitamins are used to reduce homocysteine concentrations in subjects with homozygous homocystinuria, who have particularly high blood concentrations of homocysteine.7 Several randomised controlled trials of the effects of folic acid based supplements on homocysteine concentrations have been conducted. Our study aimed, by a meta-analysis of data from individual participants in these trials, to determine more reliably the size of the reduction in blood homocysteine achieved with different doses of folic acid and with the addition of vitamin B-12 and vitamin B-6. This should help in the design of randomised trials of the effects of lowering homocysteine concentrations on vascular disease.
We aimed to identify all published and unpublished randomised trials that had assessed the effects on blood homocysteine concentrations of folic acid supplements, with or without the addition of vitamins B-12 or B-6. Studies were not eligible if they did not include an untreated control group, assessed treatment after methionine loading, or treated patients for less than 3 weeks.8-15 Eligible studies were identified by Medline searches (using search terms and widely used variants for folic acid, vitamin B-12, vitamin B-6, and homocysteine, and including the non-English language literature), scanning reference lists, and personal contact with relevant investigators. The 14 trials we identified that fulfilled the eligibility criteria16-24 included two completed trials (involving 50 and 144 subjects; V Howard, I Brouwer, personal communications) from which data are not available for collaborative analyses until their publication. The 12 available trials included 1114 subjects. Ten of these trials had a parallel group design16-24 and two had a crossover design21 (for which, to avoid any carryover effects, we used only data from the first period). The allocated treatment was blinded in all trials except two that had untreated controls. 16 23
For each subject entered in these trials, we sought details of age, sex, smoking habits, history of vascular disease or hypertension, and vitamin use before randomisation, and of their randomly allocated treatment regimen (daily dose of folic acid, vitamin B-12 or vitamin B-6, and scheduled duration) and blood concentrations of homocysteine, folate, vitamin B-12, and vitamin B-6 before treatment and at the end of the scheduled treatment period.
The proportional reductions in blood homocysteine in the treated groups compared with the control groups were determined by extending an analysis of covariance25 that estimated the differences in post-treatment, log transformed homocysteine values after adjustment for baseline values of homocysteine. The simple model was extended to allow the extent of this adjustment to vary between studies and to take account of factors such as folic acid dose, concomitant vitamin B-12 or vitamin B-6, age, sex, and duration of treatment. More complex models that allowed the effect of folic acid supplementation to differ in individual studies were used to investigate sources of heterogeneity.
Characteristics of individual trials
Among the 1114 subjects in the trials, the mean age was 52 years (range of trial means 23 to 75 years) and the mean duration of treatment was 6 weeks (range 3 to 12 weeks) (table 1). The median pretreatment blood concentration of homocysteine was 11.8 μmol/l and of folate was 11.6 nmol/l, but there were substantial differences between the trials. All of the trials compared folic acid alone versus control or folic acid plus vitamin B-6 or B-12, or both, versus control, although two trials 17 18 also involved within-trial comparisons of folic acid alone versus combination therapy (table 2). A correlation coefficient of 0.87 for homocysteine in pretreatment blood samples collected from 664 of these patients on two separate occasions shows that there was relatively little variation within subjects and that the homocysteine measurements were reliable. Compliance with the study protocols was good, with blood homocysteine measurements at the end of study treatment available from 98% of those randomised.
Exploration of heterogeneity between the results of different trials
The effect of folic acid on blood homocysteine concentrations seemed to differ among the trials. This heterogeneity of the homocysteine lowering effect was not explained by differences in age, sex, or duration of treatment (although the longest duration studied was only 12 weeks). The proportional and absolute reductions in blood homocysteine concentrations seemed, however, to be influenced by the pretreatment blood concentrations of homocysteine and folate, but not of vitamin B-12. Even after adjustment for differences in the folic acid regimen, the homocysteine lowering effect of folic acid ranged from a proportional reduction of 16% (11% to 20%) among subjects in the bottom fifth of pretreatment blood homocysteine concentrations to a 39% (36% to 43%) reduction among those in the top fifth (fig 1; P for trend <0.001). Conversely, the blood homocysteine lowering effect of folic acid was greater at lower pretreatment blood concentrations of folate (P for trend <0.001). These associations of the homocysteine lowering effect with pretreatment concentrations of blood homocysteine and blood folate remained significant (P<0.001) when both pretreatment measurements were included simultaneously in the model. The model provided no strong evidence that the variation in the homocysteine lowering effect with baseline homocysteine depended on baseline folate or vice versa. Figure 2 shows that the proportional reductions in blood homocysteine concentrations achieved by folic acid supplementation according to pretreatment blood levels of homocysteine and folate under this assumption. (Exclusion of the two trials 18 19 in subjects with very high pretreatment blood homocysteine concentrations did not materially alter these findings, and nor did inclusion of the two small completed but unpublished trials not yet formally available for these collaborative analyses: data not shown.)
Effects of different folic acid doses on blood homocysteine
After pretreatment blood concentrations of homocysteine and folate were adjusted for, there was no longer much evidence of heterogeneity between the separate blood homocysteine lowering effects in the different trials of daily folic acid doses of <1 mg (mean dose 0.5 mg; P value for heterogeneity=0.15), of 1-3 mg (mean dose 1.2 mg; P=0.05), or of >3 mg folic acid (mean dose 5.7 mg; P=0.69). Nor was there any evidence of differences between the blood homocysteine lowering effects of these different folic acid doses. For individuals with pretreatment blood concentrations of homocysteine of 12 μmol/l and of folate of 12 nmol/l (approximate average concentrations for Western populations), folic acid doses of <1 mg, 1-3 mg, and >3 mg daily were each associated with reductions in blood homocysteine of about one quarter (fig 3).
Effects of adding vitamin B-12 or vitamin B-6 to folic acid
The addition of vitamin B-12 (0.02-1 mg daily; mean 0.5 mg) to folic acid further reduced blood homocysteine concentrations by about 7% (3% to 10%). Hence, among people with pretreatment blood concentrations of homocysteine of 12 μmol/l and of folate of 12 nmol/l, adding vitamin B-12 to folic acid changed the reduction in homocysteine from 25% (23% to 28%) to 31% (27% to 35%). Adding vitamin B-6 (2-50 mg daily; mean 16.5 mg) to folic acid did not lower blood homocysteine any further.
Among the vitamins studied in these trials, folic acid had the dominant blood homocysteine lowering effect, and this effect was greater among subjects with higher blood homocysteine concentrations or lower blood folate concentrations before treatment. After standardisation for differences in pretreatment blood homocysteine and folate concentrations, the effect of folic acid was similar for daily doses ranging from 0.5 to 5 mg daily, and vitamin B-12 produced a small additional effect. Supplementation with vitamin B-6 did not seem to have any material effect on blood homocysteine concentrations, but these trials did not assess effects on blood homocysteine after methionine loading, which may be determined to a greater extent by the transulphuration pathway in which vitamin B-6 is a cofactor.8
Our results suggest that a daily dose of at least 0.5 mg of folic acid, along with a similar amount of vitamin B-12, would produce a proportional reduction in blood homocysteine of about a quarter to a third. The addition of about 1 mg daily of oral vitamin B-12 to folic acid would also be expected to avoid the theoretical risk of neuropathy due to unopposed folic acid therapy in patients deficient in vitamin B-12, even those with intrinsic factor deficiency or malabsorption states.26-28 Studies in the United States and Britain indicate that the average concentration of blood homocysteine in a typical Western population is about 12 μmol/l, 4 6 and so a reduction of about a quarter to a third would correspond to an absolute reduction of about 3-4 μmol/l. A previous meta-analysis of the observational studies suggests that a prolonged lower blood homocysteine concentration of 3-4 μmol/l would correspond to 30-40% less vascular disease.1 Consequently, even if as much as half of the epidemiologically predicted benefit is achieved within a few years of lowering blood homocysteine (as seems to be the case with cholesterol lowering29-31), trials of folic acid supplements may well need to be large, and to include people at high risk, to be able to detect the sort of reductions—15% to 20%—in cardiovascular risk that might realistically be anticipated.
Supplementation with folic acid is a cheap and effective method of lowering blood homocysteine concentrations. If large scale trials in high risk populations do show reliably that blood homocysteine reductions with such supplements can be sustained over time and that this strategy reduces the risk of vascular events (and is safe), this could have important public health implications. Higher dose supplements could be used in people at high risk, and population mean concentrations of blood homocysteine could be reduced by fortifying flour with folic acid. 1 32 Introducing fortified flour for the prevention of neural tube defects before trials of folic acid on vascular disease are conducted could, however, complicate the overall assessment of any benefits—or risks—of lowering homocysteine concentrations in this way.
The following investigators were members of the Homocysteine Lowering Trialists' Collaboration. Abbreviated trial names are listed alphabetically, along with the institutions and names of the principal investigators. Brattström (University of Lund: L Brattström, F Landgren, B Israelsson, A Lindgren, B Hultberg, A Andersson); Cuskelly (University of Ulster: G Cuskelly, H McNulty, SS Strain; Trinity College, Dublin: J McPartlin, DG Weir, JM Scott); den Heijer (Leyenburg Hospital, the Hague, and University of Nijmegen: M den Heijer, IA Brouwer, HJ Blom, GMJ Bos, A Spaans, FR Rosendaal, CMG Thomas, HL Haak, PW Wijermans, WBJ Gerrits); Naurath (University of Leuven and Witten-Herdecke: HJ Naurath, E Joosten, R Riezler, SP Stabler, RH Allen, J Lindenbaum); Pietrzik (University of Bonn: K Pietrzik, R Prinz-Langenohl, J Dierkes); Saltzman (USDA-HNRC at Tufts University: E Saltzman, JB Mason, P Jacques, J Selhub, D Salem, E Schaefer, IH Rosenberg); Ubbink (University of Pretoria: J Ubbink, A van der Mere, WJH Vermack, R Delport, PJ Becker, HC Potgieter); Woodside (Queen's University of Belfast: JV Woodside, JWG Yarnell, D McMaster, IS Young, EE McCrum, SS Patterson, KF Gey, AE Evans).
Secretariat: Clinical Trial Service Unit, University of Oxford (R Clarke, P Appleby, P Harding, P Sherliker, R Collins) and Medical Statistics Unit, London School of Hygiene and Tropical Medicine (C Frost, V Leroy).
Writing committee and guarantors: R Clarke, C Frost, V Leroy, R Collins.
This paper is dedicated to the late Dr John Lindenbaum.
Funding: British Heart Foundation and Medical Research Council.
Conflict of interest: None.