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Sesame fractions and lipid profiles: a systematic review and meta-analysis of controlled trials

Published online by Cambridge University Press:  13 January 2016

Saman Khalesi
Affiliation:
Population and Social Health Research Program, School of Medicine, Menzies Health Institute Queensland, Griffith University, Gold Coast, QLD 4222, Australia
Ernesta Paukste
Affiliation:
Population and Social Health Research Program, School of Medicine, Menzies Health Institute Queensland, Griffith University, Gold Coast, QLD 4222, Australia
Elham Nikbakht
Affiliation:
Molecular Basis of Disease Program, School of Medical Science, Menzies Health Institute Queensland, Griffith University, Gold Coast, QLD 4222, Australia
Hossein Khosravi-Boroujeni*
Affiliation:
Population and Social Health Research Program, School of Medicine, Menzies Health Institute Queensland, Griffith University, Gold Coast, QLD 4222, Australia
*
*Corresponding author: H. Khosravi-Boroujeni, email hossein.khosraviboroujeni@griffithuni.edu.au
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Abstract

Increased plasma lipid profiles are among the most important risk factors of CHD and stroke. Sesame contains considerable amounts of vitamin E, MUFA, fibre and lignans, which are thought to be associated with its plasma lipid-lowering properties. This study aimed to systematically review the evidence and identify the effects of sesame consumption on blood lipid profiles using a meta-analysis of controlled trials. PubMed, CINAHL and Cochrane Library databases were searched (from 1960 to May 2015). A total of ten controlled trials were identified based on the eligibility criteria. Both the Cochrane Collaboration tool and the Rosendal scale were used to assess the risk of bias of the included studies. The meta-analysis results showed that consumption of sesame did not significantly change the concentrations of total blood cholesterol (−0·32 mmol/l; 95 % CI −0·75, 0·11; P=0·14, I2=96 %), LDL-cholesterol (−0·15 mmol/l; 95 % CI −0·50, 0·19; P=0·39, I2=96 %) or HDL-cholesterol (0·01 mmol/l; 95 % CI −0·00, 0·02; P=0·16, I2=0 %). However, a significant reduction was observed in serum TAG levels (−0·24 mmol/l; 95 % CI −0·32, −0·15; P<0·001, I2=84 %) after consumption of sesame. It was concluded that sesame consumption can significantly reduce blood TAG levels but there is insufficient evidence to support its hypocholesterolaemic effects. Further studies are required to determine the potential effect of sesame consumption on lipid profiles and cardiovascular risk factors.

Type
Full Papers
Copyright
Copyright © The Authors 2016 

CHD is one of the major causes of death worldwide( Reference Gaziano 1 ). Increased plasma cholesterol levels and LDL-cholesterol concentrations are among the most important risk factors of CHD and stroke( Reference Imamura, Doi and Arima 2 ). Oxidation of LDL-cholesterol triggers the generation of a series of oxidative reactions, promoting the initiation of atherosclerosis( Reference Matsuura, Hughes and Khamashta 3 ). The literature indicates that antioxidants and oils rich in PUFA and MUFA, such as sesame oil, have cardiovascular protective characteristics( Reference Young and Woodside 4 ). Antioxidants (such as vitamin E) are known to protect LDL-cholesterol against oxidative modification( Reference Stocker and Keaney 5 , Reference Niki 6 ). In addition, the consumption of PUFA- and MUFA-rich oils may help decrease the fractions of circulating lipid levels, as well as the risk of CHD( Reference Mozaffarian, Micha and Wallace 7 , Reference Kris-Etherton 8 ).

For thousands of years, sesame has been used as an important ingredient in cooking worldwide, especially in Asian countries. However, only recently it has attracted research attention for its medicinal properties and physiological effects( Reference Namiki 9 ). Sesame oil contains considerable amounts of vitamin E (40 mg/100 g oil), PUFA (43 % of oil) and MUFA (40 % of oil)( Reference Sankar, Rao and Sambandam 10 ). The seeds also contain sesame lignans including sesamin, episesamin and sesamolin, which are effective antioxidants( Reference Matsumura 11 , Reference Kita, Matsumura and Morimoto 12 ) (mean amount of lignans in sesame oil is 11·51 mg/g( Reference Wu 13 ) and 5·81 mg/g in sesame seeds( Reference Moazzami and Kamal-Eldin 14 )). High amounts of α-tocopherol and lignans in sesame oil underlie its capacity as a naturally stable edible oil with strong radical-scavenging properties( Reference Nakai, Harada and Nakahara 15 ). Further, high linoleic acid and dietary fibre contents of sesame seed may be responsible for its plasma cholesterol-lowering properties( Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 16 ). Studies conducted on the biological activities of sesamin have shown its effects on the following: the inhibition of lipid metabolism; intestinal cholesterol absorption; desaturation in PUFA biosynthesis; and the inhibition of the activity of acyl-CoA reductase( Reference Hirose, Inoue and Nishihara 17 ). Several animal studies have also confirmed that the intake of sesame seeds or sesamin has cholesterol-lowering effects( Reference Sirato-Yasumoto, Katsuta and Okuyama 18 , Reference Ashakumary, Rouyer and Takahashi 19 ). The literature also reports that sesame lignans improve lipid profiles, lipid peroxidation, serum lipoprotein metabolism, increase apoA and decrease atherogenic apoB( Reference Ashakumary, Rouyer and Takahashi 19 Reference Farajzadeh Sheikh, Zahdei Asl and Asgarisabzkoohi 22 ). However, in human studies, the evidence of the effects of sesame or sesame oil on lipid profiles and cardiovascular risk factors is inconsistent( Reference Sankar, Rao and Sambandam 10 , Reference Wu, Hodgson and Puddey 23 Reference Chen, Tsai and Chang 25 ). Therefore, this systematic review and meta-analysis of randomised clinical trials was conducted to summarise the available evidence and to increase statistical ability in order to detect the effect of sesame consumption on lipid profiles in humans.

Methods

Literature search

Two researchers searched online databases including PubMed (MEDLINE), CINAHL and Cochrane Library (Central) to identify potentially relevant studies that evaluated the effects of sesame on lipid profile, dating from 1960 to May 2015. The following terms (including MeSH terms) and their combinations were used to search for publications: sesame, sesamin, sesamum, lipid, cholesterol, chol, triglyceride, TG, lipoprotein, LDL, LDL-C, HDL and HDL-C. Two researchers independently screened the titles, abstracts and full texts of the identified articles and made decisions regarding inclusion or exclusion of the articles. A third researcher was involved in the decision-making process in case of disagreement. Selection of studies was based on pre-determined inclusion and exclusion criteria. Studies were included if they (1) were randomised or non-randomised controlled trials, (2) included adults (≥18 years of age) in their intervention, (3) used sesame seed or its extract (such as oil and powder) and (4) had accessible full-text articles in English. Studies using sesame (or its extracts) in combination with other dietary components (e.g. mixture of sesame oil and fish oil) were included if the other component could be controlled. Studies were excluded if the duration of sesame consumption was <2 weeks or the dose of sesame (or its extracts) consumption was not reported.

In screening the literature and presenting results, the ‘Preferred reporting items for systematic reviews and meta-analysis: the PRISMA statement’ was followed( Reference Moher, Liberati and Tetzlaff 26 ). A summary of the review and the reasons for excluding studies are presented in the PRISMA flow chart (see Fig. 1). This systematic review is registered at the International Prospective Register for Systematic Review with the registration number CRD42014013244.

Fig. 1 Preferred reporting items for systematic reviews and meta-analysis flow chart.

Quality assessment and data extraction

The Cochrane Collaboration tool and the Rosendal scale( Reference van Rosendal, Osborne and Fassett 27 ) were used to assess risk of bias and the methodology quality of the included studies. Studies that scored 60 % or more, based on the Rosendal scale, were classified as excellent methodological quality studies( Reference van Rosendal, Osborne and Fassett 27 ). A Rosendal score of <50 % was chosen as the cut-off point for the exclusion of studies. Studies were also excluded if they were ranked as high risk of bias based on the Cochrane quality assessment tool. To extract relevant data from the included studies, the ‘Checklist of items to consider in data collection’ from the Cochrane Handbook for Systematic Review of Interventions ( Reference Higgins and Green 28 ) was followed. In the process of data collection, the following information was extracted from each study: study design, location, characteristics of the participants, intervention/control characteristics (supplementation, duration and dose), baseline and final measures, body weight changes, dietary measures and side-effects.

Data synthesis and analysis

RevMan software (Cochrane Review Manager version 5.2) was used to perform meta-analysis of the data. The mean difference of changes between the intervention groups and control groups was defined as the effect of nutrition intervention. Statistical analysis was performed following the Cochrane Handbook for Systematic Review of Interventions ( Reference Higgins and Green 28 ) guidelines. A correlation coefficient (r) of 0·5 was chosen to impute the standard deviation of change for all interventions( Reference Higgins and Green 28 ). Considering differences in the design of included studies, the DerSimonian & Laird( Reference DerSimonian and Laird 29 ) random effect model was selected to perform the meta-analysis. The I 2 index was evaluated to assess heterogeneity. Low, moderate and high heterogeneity were defined as I 2 index equal to 25, 50 and 75 %, respectively( Reference Higgins and Green 28 ). Statistically significant difference was defined as an effect with a P value of <0·05.

Sensitivity and subgroup analysis

A one-by-one sensitivity analysis was performed to assess the effect of individual studies on the overall meta-analysis results. The robustness of the meta-analysis was assessed using alternative correlation coefficients (r 0·2 and 0·8), and then by comparing the results with the imputed correlation coefficient chosen for the meta-analysis (r 0·5). Subgroup analysis of interventions with sesame consumption for ≥8 weeks was compared with those with intervention duration of <8 weeks. Sources of sesame (whole or ground v. oil) were chosen for another subgroup analysis. The influence of the intervention design was assessed by comparing the difference in the meta-analysis results of the parallel against cross-over design trials. Finally, the influence of body weight on meta-analysis results was assessed by comparing the subgroup of studies with participants with mean baseline BMI of ≥30 kg/m2 against those with BMI <30 kg/m2.

Results

Overview of the studies and their quality

A total of ten trials (908 participants) that examined the effect of sesame consumption on blood lipid profiles were included in the systematic review and meta-analysis. Of these, three studies( Reference Sankar, Rao and Sambandam 10 , Reference Sankar, Rao and Sambandam 24 Reference Sankar, Sambandam and Rao 30 ) had the lowest Rosendal score of 50 % (online Supplemental Table S1). The highest Rosendal score of 93 % was calculated for the studies conducted by Wu et al. ( Reference Wu, Hodgson and Puddey 31 ) and Helli et al. ( Reference Helli, Mowla and Mohammadshahi 32 ). Four of the studies had a cross-over design( Reference Sankar, Rao and Sambandam 10 , Reference Wu, Hodgson and Puddey 31 Reference Wu, Kang and Wang 33 ), and the rest of the studies used a parallel design. Three studies reported using a double-blind design( Reference Wu, Hodgson and Puddey 31 , Reference Helli, Mowla and Mohammadshahi 32 Reference Mirmiran, Bahadoran and Golzarand 34 ), and one study reported using a single-blind design( Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 ). The remaining studies did not mention blinding of the participants or the investigators.

Characteristics of participants and studies

Table 1 presents the characteristics of the included trials. Changes in total cholesterol, TAG, LDL-cholesterol and HDL-cholesterol were reported in all studies. The ten trials included different types of participants: two included hypertensives( Reference Sankar, Rao and Sambandam 10 , Reference Sankar, Sambandam and Rao 30 ); one diabetics( Reference Mirmiran, Bahadoran and Golzarand 34 ); one hypertensives and diabetics( Reference Sankar, Rao and Sambandam 10 ); one hyperlipidaemia patients( Reference Alipoor, Haghighian and Sadat 36 ); one haemodialysis participants( Reference Khajehdehi 37 ); one rheumatoid arthritis patients( Reference Helli, Mowla and Mohammadshahi 32 ); and one overweight and obese individuals( Reference Wu, Hodgson and Puddey 31 ). Among all included trials, three studies included only female participants( Reference Helli, Mowla and Mohammadshahi 32 , Reference Wu, Kang and Wang 33 , Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 ). Five studies used sesame oil for the intervention( Reference Sankar, Rao and Sambandam 10 , Reference Sankar, Rao and Sambandam 24 , Reference Sankar, Sambandam and Rao 30 , Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 , Reference Khajehdehi 37 ), and the remaining trials used the seed or ground powdered sesame or its extracts( Reference Wu, Hodgson and Puddey 31 Reference Mirmiran, Bahadoran and Golzarand 34 , Reference Alipoor, Haghighian and Sadat 36 ). Three studies reported a significant reduction in body weight after consuming sesame( Reference Sankar, Rao and Sambandam 10 , Reference Sankar, Rao and Sambandam 24 Reference Helli, Mowla and Mohammadshahi 32 ), and one study reported a significant increase in body weight in the intervention group( Reference Wu, Kang and Wang 33 ). The remainder of the studies did not report significant changes in body weight in any of the groups.

Table 1 Characteristics of studies evaluating the effect of sesame on blood lipid profile (Mean values and standard deviations; mean of changes and standard deviations of change)

M, male; F, female; R, randomised; C, controlled; TC, total cholesterol; PC, placebo control; CO, cross-over; DB, double-blind; RA, rheumatoid arthritis; P, parallel; SB, single blind; DM, diabetes mellitus; HTN, hypertension; PM, post-menopausal; OW, overweight; OB, obesity.* No information on sex distribution was provided in the trial.

The majority of trials did not report measuring dietary intake of the participants, with only four studies( Reference Wu, Hodgson and Puddey 31 , Reference Helli, Mowla and Mohammadshahi 32 Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 Reference Miyawaki, Aono and Toyoda-Ono 38 ) using a 3-d food record method to measure dietary intake before and after intervention in order to determine any potential dietary changes. No significant differences were reported between control and intervention groups at baseline in any of these studies. Lemcke-Norojärvi et al. ( Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 ) reported a significantly lower intake of PUFA as the difference between the oil consumed between control and intervention groups. Mirmiran et al. ( Reference Mirmiran, Bahadoran and Golzarand 34 ) also reported that the sesame group had a higher intake of total fat as a result of intervention. Three studies reported that participants received advice to maintain their usual diet( Reference Helli, Mowla and Mohammadshahi 32 , Reference Wu, Kang and Wang 33 Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 ) or to avoid adding foods to their diet that contain sesame during the intervention( Reference Mirmiran, Bahadoran and Golzarand 34 ).

Information on supplement protocol

Three of the trials reported using capsules as the vehicle for sesame supplementation( Reference Helli, Mowla and Mohammadshahi 32 , Reference Wu, Kang and Wang 33 Reference Khajehdehi 37 ). One used breakfast bars( Reference Wu, Hodgson and Puddey 31 ) and the remaining studies used sesame oil replacement of all oils consumed or a mixture of ground sesame in a variety of foods. A wide variation in daily dose of sesame consumption was observed between the studies. Daily sesame oil consumption varied from using capsules of 3·5 g oil( Reference Khajehdehi 37 ) to 35 g of sesame oil replacing the common oil used by participants daily( Reference Sankar, Rao and Sambandam 10 , Reference Sankar, Rao and Sambandam 24 Reference Sankar, Sambandam and Rao 30 ). Overall sesame (ground, powdered or whole seed) consumption varied from 25( Reference Wu, Hodgson and Puddey 31 ) to 50 g/d( Reference Wu, Kang and Wang 33 ). Study duration varied from 4( Reference Lemcke-Norojärvi, Kamal-Eldin and Appelqvist 35 ) to 10 weeks( Reference Wu, Kang and Wang 33 ). None of the studies reported any significant side-effects.

Meta-analysis results

The forest plots of the meta-analysis effect of sesame consumption on blood lipid profile are presented in Figs. 25. Consumption of sesame did not significantly reduce total blood cholesterol levels (−0·32 mmol/l; 95 % CI −0·75, 0·11; P=0·14, I 2=96 %) (Fig. 2). However, a significant meta-analysis effect of sesame consumption was observed for the mean difference in TAG levels (−0·24 mmol/l; 95 % CI −0·32, −0·15; P<0·001, I 2=84 %) (Fig. 3). The meta-analysis for the effect of sesame consumption on the mean difference of LDL-cholesterol was not significant (−0·15 mmol/l; 95 % CI −0·50, 0·19; P=0·39, I 2=96 %) (Fig. 4). No significant change in the mean difference of HDL-cholesterol after consumption of sesame was observed (0·01 mmol/l; 95 % CI −0·00, 0·02; P=0·16, I 2=0 %) (Fig. 5).

Fig. 2 Forest plot and risk of bias of the effect of sesame consumption on blood total cholesterol levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Fig. 3 Forest plot and risk of bias of the effect of sesame consumption on blood TAG levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Fig. 4 Forest plot and risk of bias of the effect of sesame consumption on blood LDL-cholesterol levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Fig. 5 Forest plot and risk of bias of the effect of sesame consumption on blood HDL-cholesterol levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Sensitivity and subgroup analysis

The one-by-one sensitivity analysis did not show a significant effect of individual studies on the overall meta-analysis of the effect of sesame consumption on lipid profiles. Sensitivity analysis of alternative correlation coefficients (r 0·2 and 0·8) showed agreement between the direction of the effect with the chosen correlation coefficient. These results showed the robustness of the meta-analysis results using the chosen correlation coefficient of 0·5.

Subgroup analyses of the effect of sesame consumption on total cholesterol did not identify any study characteristics that could have moderated the results of the meta-analyses (Table 2). The duration of intervention, source of sesame (seed or oil) or baseline BMI of participants had no significant influence on the subgroup analysis results. Subgroup analysis of the design of the studies (parallel or cross-over) also did not significantly affect the mean difference of total cholesterol. Further, the test of the difference between subgroups did not reveal any significant results (Table 2).

Table 2 Results of subgroup analyses of included randomised-controlled trials in the meta-analysis of sesame consumption and blood lipid profileFootnote * (Mean differences and 95 % CI; heterogeneity (I 2))

* Removing two studies by Sankar et al.( Reference Sankar, Rao and Sambandam 10 , 24) without the complete cross-over design changed the subgroup analysis to non-significant effect. A P value <0·05 is considered significant

A number of study characteristics seem to influence the effect of sesame consumption on blood TAG levels. Subgroup analysis by duration of intervention showed significant reduction in TAG levels in both durations ≥8 and <8 weeks. The reduction observed in the subgroup of interventions with duration of <8 weeks (n=4) was slightly more pronounced compared with duration of ≥8 weeks (n=4) (−0·26 v. −0·16 mmol/l). Nevertheless, the test for subgroup differences was not significant (I 2 =7 %, P=0·30) (Table 2). Subgroup analysis of the effect of the source of sesame showed a significant reduction in TAG levels when sesame was consumed as oil (n=5) (−0·27 mmol/l; 95 % CI −0·36, −0·17; P<0·001). No meaningful effect of sesame consumption on TAG levels was observed in the subgroup of sesame as whole or ground seed (n=5). Although the test for subgroup differences of source of sesame did not reach statistical significance, a trend was observed (I 2 =71 %, P=0·06) (Table 2). The baseline BMI of participants had an influence on TAG level changes following sesame consumption. The subgroup of baseline BMI <30 kg/m2 (n=7) had a significant reduction in TAG levels (−0·25 mmol/l; 95 % CI −0·35, −0·15; Ρ<0·001). However, no significant effect was observed in the subgroup of studies with BMI ≥30 kg/m2 (n=7). The test for subgroup analysis showed no significant difference between baseline BMI subgroups (I 2=0 %, P=0·40). Both parallel and cross-over design subgroups showed significant reduction in TAG levels. The reduction was more pronounced in the subgroup of cross-over design compared with parallel design studies (−0·23 v. −0·16 mmol/l). No significant difference was observed between the study design subgroups (Table 2).

The subgroup analyses of the effect of duration of intervention on LDL-cholesterol did not result in significant differences (Table 2). The source of sesame consumption (oil or seed) also did not have any significant influence on LDL-cholesterol changes. Similar results were observed for the effect of the design of the studies. However, baseline BMI of participants had a more pronounced effect on the subgroup meta-analysis of the effect of sesame consumption on LDL-cholesterol. A 0.32 reduction in LDL-cholesterol was observed in the subgroup of studies with baseline BMI ≥30 kg/m2, but the reduction did not reach statistical significance (Table 2).

None of the characteristics of the studies was found to have a significant influence on the subgroup analysis of the effect of sesame consumption on blood HDL-cholesterol (Table 2). It appears that the different duration of sesame consumption, the source of sesame or the design of studies do not have any moderating influence on the meta-analysis of the effect of sesame on HDL-cholesterol. Similar results were observed with regard to the different baseline BMI of participants (Table 2).

Discussion

To our knowledge, the present meta-analysis is the first quantitative review of controlled trials on the effect of sesame consumption on serum lipid profiles. The present meta-analysis showed that sesame consumption significantly reduced TAG concentrations but not total cholesterol, HDL-cholesterol or LDL-cholesterol concentrations. Although a neutral effect of sesame consumption on total cholesterol, HDL-cholesterol and LDL-cholesterol was observed, the significant TAG reduction reported by the meta-analysis of this study may have pivotal clinical and public health implications.

Although the association between increased total cholesterol and LDL-cholesterol and reduced HDL-cholesterol and the risk of CVD is well studied, elevated TAG levels have been recently considered as a single important risk factor of CVD( Reference Nordestgaard and Varbo 39 ). The management of dyslipidaemia (characterised by elevated levels of total cholesterol, LDL-cholesterol and TAG and reduced levels of HDL-cholesterol) involves a variety of approaches such as pharmacotherapy and lifestyle modification that can be adapted to control the lipid levels. However, many patients treated with anti-dyslipidaemic drugs do not achieve satisfactory results and still remain at high risk for CVD( Reference Catapano, Farnier and Foody 40 ). For instance, statins, which are the most commonly used lipid-lowering drugs, at maximum dosage can reduce LDL-cholesterol only by 50–55 %( Reference Banach 41 ). However, such dosages are often not well tolerated, and 10–15 % of patients report statin intolerance( Reference Banach, Rizzo and Toth 42 ). Considering the limitation of the anti-dyslipidaemic drugs, there is a great deal of interest in nutraceuticals that may possibly complement the pharmaceutical treatments. Food and dietary supplementation and nutraceuticals may affect lipids through complicated mechanisms that affect the absorption and metabolism of lipids( Reference Banach 41 ).

Sesame, as one of these potential dietary factors, contains several lignans such as sesamolin, sesaminol and sesamin, which can be absorbed by the intestines, and through the portal vein they reach the liver where they metabolise into catechol derivatives( Reference Tsuruoka, Kidokoro and Matsumoto 43 ). The catechol metabolites from sesamin have a strong antioxidative activity on the liver( Reference Nakai, Harada and Nakahara 44 ), and they can affect the metabolism and production of lipids( Reference Hirose, Inoue and Nishihara 17 Reference Ashakumary, Rouyer and Takahashi 19 ). Its potential cholesterol-lowering effects may be due to the inhibition of the 3-hydroxy-3-methylglutaryl-coenzyme A reductase activity, which is the enzyme involved in the synthesis of cholesterol( Reference Hirose, Inoue and Nishihara 17 ). In addition, TAG-lowering properties of sesame can be partially explained by its high MUFA contents (40 % in sesame oil)( Reference Sankar, Rao and Sambandam 10 ). The American Heart Association has reported that high dietary MUFA intake is likely to decrease blood TAG concentrations( Reference Kris-Etherton 8 ). Evidence from the meta-analysis shows that a short-term intervention with a MUFA-rich diet can reduce the serum levels of TAG and HDL-cholesterol( Reference Schwingshackl and Hoffmann 45 ). In addition, the high content of fibre, vitamin E and PUFA in sesame seeds, as well as the antioxidant activity of its lignans, can affect TAG generation and metabolism( Reference Sankar, Rao and Sambandam 10 ). It has been described that PUFA consumption reduces the risk of CVD by decreasing serum TAG levels and by modestly increasing serum HDL-cholesterol concentrations( Reference Harris, Mozaffarian and Rimm 46 ). Furthermore, the biological effectiveness of nutrients, such as antioxidant activity, can be enhanced by their interaction with other components in the diet( Reference Zhu, Huang and Chen 47 ). Sesame lignans in combination with α-tocopherol (precursor of vitamin E) were more effective on lipid peroxidation than as a single compound( Reference Hemalatha and Rao 48 ). The literature also reports that certain lignans in sesame seeds and oil can elevate plasma and tissue levels of vitamin E precursors (α- and γ-tocopherol)( Reference Kamal-Eldin, Frank and Razdan 49 , Reference Yamashita, Iizuka and Imai 50 ). Dietary sesame lignans may also influence the gene expressions of various lipid metabolism enzymes involved in lipogenesis and β-oxidation and also influence the expressions of proteins involved in transportation of fatty acids( Reference Tsuruoka, Kidokoro and Matsumoto 43 ).

This meta-analysis found that sesame consumption significantly decreased TAG levels. The results of subgroup analyses showed that the source of sesame intake moderates the effects of sesame intake on TAG levels. Consuming sesame as oil (but not as whole or ground seeds) has significant reducing effects on TAG levels. A more pronounced effect of sesame on TAG levels was also observed in the subgroup with BMI <30 kg/m2. There is no logical explanation for the observed findings. However, the difference observed in the subgroup of BMI can be due to the lower number of trials included in the subgroup of BMI ≥30 kg/m2. Further interventions with a focus on higher BMI need to confirm the effect of sesame observed in this study. Subgroup analyses for duration and design of intervention did not affect the results. A neutral effect of sesame consumption on total cholesterol, LDL-cholesterol and HDL-cholesterol was observed in the present meta-analysis. Subgroup analysis of the effect of sesame intake on cholesterol or lipoprotein levels did not moderate the outcome. These findings are generally in line with the majority of individual studies selected for this review. Only one study showed a significant change in cholesterol levels( Reference Sankar, Rao and Sambandam 10 ) and others failed to find such a relationship.

In vitro studies showed that sesaminol inhibits peroxidation of LDL-cholesterol( Reference Kang, Katsuzaki and Osawa 51 , Reference Kang, Naito and Sakai 52 ), and therefore sesame consumption may have a protective role in atherogenesis( Reference Steinbrecher, Parthasarathy and Leake 53 ). Animal studies have also reported that sesamin decreases the synthesis of fatty acids in the liver, down-regulates transcriptional factors( Reference Ide, Ashakumary and Takahashi 54 ), increases the activity of β-oxidation-associated enzymes and decreases hepatic arachidonic acid and EPA concentrations( Reference Umeda-Sawada, Ogawa and Nakamura 55 ). The suggested mechanisms for the effect of sesame on human lipid profiles are not entirely similar to those of animal studies. For instance, peroxisome proliferation that corresponds to increased peroxisomal fatty acid β-oxidation activity can be activated in rodents but not in humans( Reference Desvergne and Wahli 56 ). In addition, the dose of sesame consumption can have an influence on the effect of sesame on lipid profiles. There is a dose-dependent association between gene expression of hepatic beta-oxidation enzymes and sesamin intake( Reference Ashakumary, Rouyer and Takahashi 19 ). Therefore, higher amounts of sesame intake may have different results on cholesterol levels in humans. However, the dose-dependency effect analysis was not applicable in this meta-analysis because of the differences between the sesame sources (oil, lignans) and difficulties in accurate dose conversions.

The present meta-analysis has a number of limitations that need to be considered. First, a small number of controlled trials was included in this review. The characteristics of included studies varied widely in terms of health status, sex and age of participants, study duration and sources and the dosage of sesame. In addition, a significant heterogeneity was detected between the studies in the meta-analysis. Sensitivity analyses attempted to highlight the influence of study characteristics on the heterogeneity and overall meta-analysis results. However, the wide variation in the characteristics of included studies limited the subgroup analysis. The limited number of studies also raised the heterogeneity of analyses. Furthermore, the majority of trials did not control for dietary changes of participants during the intervention, which may have influenced the accuracy of the results. Moreover, one study with low quality assessment scores was excluded from the quantitative synthesis, which could have skewed the meta-analysis results( Reference Sankar, Ali and Sambandam 57 ). Finally, only studies published in English language were included in this study. This may have resulted in the exclusion of quality studies that were published in other languages. Nevertheless, this study systematically reviewed the effects of sesame on lipid profiles and increased the power of conclusion by using meta-analysis of controlled trials.

Conclusion

Consumption of sesame can significantly reduce blood TAG levels. Despite not having adequate evidence to support the hypocholesterolaemic effects of sesame, the question of whether a higher dosage or longer duration of sesame consumption would have such effects remains unanswered. Therefore, there is a need for further investigation of sesame consumption as a complementary dietary constituent to determine its potential effects on improving lipid profiles and, in turn, reducing the risk of CVD.

Acknowledgements

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

S. K. and H. K.-B. designed the study; S. K., H. K.-B., E. P. and E. N. conducted the research; E. P. and E. N. conducted the quality assessment of studies. S. K. analysed the data, S. K. and H. K.-B. drafted the manuscript; S. K., H. K.-B., E. P and E. N. finalised the paper. All the authors read and approved the final version of the manuscript.

The authors declare that they have no conflicts of interests regarding the publication of this article.

Supplementary Material

For supplementary material/s referred to in this article, please visit http://dx.doi.org/doi:10.1017/S0007114515005012

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Figure 0

Fig. 1 Preferred reporting items for systematic reviews and meta-analysis flow chart.

Figure 1

Table 1 Characteristics of studies evaluating the effect of sesame on blood lipid profile (Mean values and standard deviations; mean of changes and standard deviations of change)

Figure 2

Fig. 2 Forest plot and risk of bias of the effect of sesame consumption on blood total cholesterol levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Figure 3

Fig. 3 Forest plot and risk of bias of the effect of sesame consumption on blood TAG levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Figure 4

Fig. 4 Forest plot and risk of bias of the effect of sesame consumption on blood LDL-cholesterol levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Figure 5

Fig. 5 Forest plot and risk of bias of the effect of sesame consumption on blood HDL-cholesterol levels. A random effect model was used to analyse the effectiveness of intervention. Effect of each trial was presented as weight (%) as well as mean difference and 95 % CI. Risk of bias legend: (A) random sequence generation (selection bias); (B) allocation concealment (selection bias); (C) blinding of participants and personnel (performance bias); (D) blinding of outcome assessment (detection bias); (E) incomplete outcome data (attrition bias); (F) selective reporting (reporting bias); (G) other bias.

Figure 6

Table 2 Results of subgroup analyses of included randomised-controlled trials in the meta-analysis of sesame consumption and blood lipid profile* (Mean differences and 95 % CI; heterogeneity (I2))

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