Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-28T20:46:40.709Z Has data issue: false hasContentIssue false

Lactotripeptides and antihypertensive effects: a critical review

Published online by Cambridge University Press:  05 December 2008

Esther Boelsma*
Affiliation:
TNO Quality of Life, Business Unit Biosciences, PO Box 360, 3700AJ, Zeist, The Netherlands
Joris Kloek
Affiliation:
DSM Food Specialties, Department of Nutrition and Health, PO Box 1, 2600MA, Delft, The Netherlands
*
*Corresponding author: Dr E. Boelsma, fax +31 30 694 49 28, email esther.boelsma@tno.nl
Rights & Permissions [Opens in a new window]

Abstract

Hypertension or high blood pressure is a significant health problem worldwide. Typically, lifestyle changes, including adopting a healthy diet, are recommended for people with an elevated blood pressure. Lactotripeptides are bioactive milk peptides with potential antihypertensive properties in man. These peptides, as part of a food product or as nutraceutical, may contribute to the prevention and treatment of hypertension. This paper reviews the current evidence of the blood pressure control properties of lactotripeptides in man. Blood pressure-lowering effects of lactotripeptides are typically measured after 4–6 weeks of treatment. However, in some cases, a blood pressure response has been observed after 1–2 weeks. Maximum blood pressure reductions approximate 13 mmHg (systolic blood pressure) and 8 mmHg (diastolic blood pressure) after active treatment compared with placebo, and are likely reached after 8–12 weeks of treatment. Effective dosages of lactotripeptides range from 3·07 to 52·5 mg/d. Evidence indicates that lactotripeptides are only effective at elevated blood pressure; no further lowering of normal blood pressure has been observed. Concomitant intake of antihypertensive medication does not seem to influence the potency of lactotripeptides to lower blood pressure. Similarly, ethnicity has not been found to influence the extent of lactotripeptide-induced blood pressure lowering. Based on the currently available data, lactotripeptides appear to be safe and effective. Thus, they can be part of a healthy diet and lifestyle to prevent or reduce high blood pressure.

Type
Review Article
Copyright
Copyright © The Authors 2008

CVD and its related complications affect a significant proportion of the world's population(Reference Lawes, Vander Hoorn and Rodgers1). The risk of developing CVD is directly related to blood pressure (BP) level. Prolonged reductions of diastolic blood pressure (DBP) of 5, 7·5 and 10 mmHg were respectively associated with at least 34, 46 and 56 % less stroke and at least 21, 29 and 37 % less CHD(Reference Collins, Peto and MacMahon2Reference Collins and MacMahon4). In a large meta-analysis by the Prospective Studies Collaboration(5), it was estimated that a 10 mmHg lower usual systolic blood pressure (SBP) or 5 mmHg lower usual DBP would, in the long term, be associated with about 40 % lower risk of stroke death and about 30 % lower risk of death from IHD or other vascular causes. Extending these observations to small reductions in DBP of about 2 mmHg would result in a 14 % reduction in the risk of stroke, and 6 % reduction in the risk of CHD(Reference Cook, Cohen and Hebert6). Also SBP lower by 2 mmHg is associated with lower IHD and CVD death rates by 4–5 %(Reference Stamler7). The results suggested that for the large majority of individuals, whether hypertensive or normotensive, a lower BP should eventually confer a lower risk of CVD.

Adoption of a healthy lifestyle is important for the prevention of high BP and is an indispensable part of the management of hypertension. The application of specific foods or food components in the prevention and/or treatment of disease are of particular relevance in the management of CVD(Reference Houston8Reference Rudkowska and Jones10). High BP, or hypertension, is a controllable risk factor in the development of a range of cardiovascular conditions. Therefore, any food component that has the ability to reduce BP is a potential candidate component in the prevention/treatment of CVD.

Milk proteins contain angiotensin-converting enzyme (ACE) inhibitory peptides encrypted within their primary structures(Reference Murray and FitzGerald11). These peptides can be released by enzymatic hydrolysis either during gastrointestinal digestion or during food processing. The sequences of the individual milk proteins displaying ACE inhibitory activity in vitro are reviewed elsewhere(Reference FitzGerald and Meisel12). The best characterized peptides found in fermented milk are peptides with the amino acid sequence isoleucine–proline–proline (IPP; ic50 = 5 μmol/l), and valine–proline–proline (VPP; ic50 = 9 μmol/l). About twenty human studies have been published linking the consumption of products containing lactotripeptides (here defined as IPP and VPP) with significant reductions in both SBP and DBP.

Consumption of products enriched with lactotripeptides has risen slowly since their introduction into the Japanese market in 1997. BP-lowering products containing lactotripeptides are currently on the market in the USA, Spain, UK, Finland, Switzerland, Italy, South Korea, Japan, Iceland and Portugal. Standard use of such products provides on average 5 mg/d lactotripeptides.

This review outlines the current evidence of the BP control properties of lactotripeptides in man. The relation between these milk-derived peptides and BP was discussed previously(Reference FitzGerald, Murray and Walsh13Reference Jauhiainen and Korpela15). However, not all of the reviews have expressed BP-lowering effects relative to placebo treatment. Furthermore, a number of interesting questions have remained unanswered. This review article aims at clarifying issues such as the duration of intake required to obtain a BP effect, the maximum BP effect, effective dosages of lactotripeptides, the relation between height of baseline BP and attainable effect, and the influence of antihypertensive medication and race. Aspects of bioavailability, safety and proposed mechanisms of action will be addressed as well.

In all clinical trials performed in (mildly) hypertensive subjects, by the time of the last visit, SBP had fallen significantly from baseline in the groups that ingested the product containing lactotripeptides, but also in the placebo groups often a trend was seen towards a decreasing BP(Reference Seppo, Kerojoki and Suomalainen16, Reference Seppo, Jauhiainen and Poussa17). The consequence is that a significant decrease of BP compared with baseline does not mean that there is a significant difference between the test product and placebo. Generally, the nutritional composition of the placebo and test products was similar, with the difference that the active ingredient was not present in the placebo products. In most clinical trials, the test products consisted of sour milk prepared by fermenting skim milk using Lactobacillus helveticus and/or Saccharomyces cerevisiae. As a placebo mostly artificially acidified milk was used. In three other trials, test products consisted of casein hydrolysate, generated using Aspergillus oryzae protease, added to a carrier (vegetable and fruit juice(Reference Sano, Ohki and Higuchi18, Reference Sano, Ohki and Higuchi19) and tablets(Reference Mizuno, Matsuura and Gotou20)). For the corresponding placebo products the same carrier was used without the casein hydrolysate. Therefore, a comparison between test product and placebo would be more appropriate for evaluation of a true treatment effect. Similarly, Itakura et al. (Reference Itakura, Ikemoto and Terada21) observed only a trend towards greater lowering of SBP in the test product group compared with the placebo group throughout the treatment period, whereas absolute changes of SBP were already significantly different from baseline after 2 weeks of treatment with the test product. In other trials, similar effects were found throughout the treatment period(Reference Kajimoto, Aihara, Hirata, Takahashi and Nakamura22Reference Hirata, Nakamura and Yada24). Even in the absence of any treatment, BP may decrease, as was observed after a 4-week run-in period in a study by Seppo et al. (Reference Seppo, Kerojoki and Suomalainen16). These findings stress the power of a so-called placebo effect. Alternatively, they may be indicative of a regression-to-the-mean effect following selection of study subjects with an elevated BP. To control for these phenomena, in the present review, BP-lowering effects are expressed against placebo rather than starting BP. In the present paper, BP changes will only be reviewed if they were compared to placebo; not if only a comparison with baseline BP was made in the original articles.

What is the time–effect relation of blood pressure lowering by lactotripeptides?

Trials in hypertensive subjects, in which BP measurements were taken at relatively early time-points, demonstrated significantly lower SBP values (8–10 mmHg) and DBP values (6–7 mmHg) after 1–2 weeks of active treatment compared with placebo treatment(Reference Kajimoto, Aihara, Hirata, Takahashi and Nakamura22Reference Aihara, Kajimoto and Hirata25). Aihara et al. (Reference Aihara, Kajimoto and Hirata25) reported a trend for a BP-lowering effect even after 1 d of treatment with the peptides compared with placebo, but it took another week for the effects to reach significance.

Most clinical trials have assessed BP-lowering effects at multiple points over time. Generally, maximum duration of treatment was 8 weeks. From these data, it becomes apparent that the largest part of the total BP reduction takes place in the first 1–2 weeks of treatment. Thereafter, a further gradual lowering is seen, but to a lesser extent than in the first period(Reference Kajimoto, Kurosaki and Mizutani23Reference Aihara, Kajimoto and Hirata25). For example, Aihara et al. (Reference Aihara, Kajimoto and Hirata25) have observed such patterns. In that study, lactotripeptides induced a gradual lowering of SBP compared to control treatment by 7·8, 10·5, 10·6 and 11·2 mmHg after 1, 2, 3 and 4 weeks of active treatment, respectively. Kajimoto et al. (Reference Kajimoto, Kurosaki and Mizutani23) demonstrated a comparable profile; SBP decreased by 7·6 mmHg after a 1-week intake of lactotripeptides compared with placebo and gradually thereafter to 13 mmHg after 8 weeks. In this respect even more clear were BP results reported by Hirata et al. (Reference Hirata, Nakamura and Yada24) showing a BP lowering by 10 mmHg already after 2 weeks and by 12·1 mmHg after 6 more weeks of treatment compared with placebo. In general, changes in DBP were smaller and curves of BP effects in time were more flat compared with changes in SBP.

A few interventions evaluated BP-lowering effects after treatment periods that lasted longer than the generally applied 8 weeks. Sano et al. (Reference Sano, Ohki and Higuchi18) demonstrated a decrease of SBP by 3·3 mmHg after 8 weeks of intake of 3·1 mg/d lactotripeptides compared with placebo and a slightly further decrease by 4·4 and 4·1 mmHg after 10 and 12 weeks, respectively, in subjects with high-normal BP and subjects with hypertension. DBP was 2·8 mmHg lower compared with placebo after 8 weeks of treatment, and remained nearly constant at 10 and 12 weeks. The study with the longest treatment period in hypertensive subjects that was published lasted 5 months(Reference Seppo, Jauhiainen and Poussa17). An overall treatment effect over 5 months was observed yielding a significant mean difference of − 6·7 mmHg SBP and a trend of − 3·6 mmHg DBP between the test product and placebo group. BP effects did not become larger with a prolonged treatment time.

After termination of treatment, BP gradually returned to baseline values within 2–4 weeks(Reference Seppo, Kerojoki and Suomalainen16, Reference Itakura, Ikemoto and Terada21, Reference Kajimoto, Kurosaki and Mizutani23, Reference Kajimoto, Nakamura and Yada26, Reference Nakamura, Kajimoto and Kaneko27). In the study by Hirata et al. (Reference Hirata, Nakamura and Yada24) even at 2 weeks after completion of intake, a significantly lower SBP (by 8·4 mmHg) was still observed in the subjects that had received the test product compared with those that received placebo. This difference, however, was smaller than at 8 weeks of intake (SBP was 12·1 mmHg lower than placebo) and disappeared at 4 weeks after completion of intake. Subjects with high-normal BP or mild hypertension, treated for 12 weeks with 3·07 mg lactotripeptides, demonstrated still a significantly lower SBP at 2 weeks (by 2·4 mmHg) and 4 weeks (by 2·5 mmHg) after completion of intake as compared with the placebo group(Reference Sano, Ohki and Higuchi18). Several antihypertensive drugs are known to cause a rapid and abnormal elevation of BP, so-called rebound, after treatment stops, but from the data mentioned earlier, no such effects become apparent after intake of lactotripeptides.

In conclusion, first significant effects of lactotripeptides on BP in hypertensive subjects are observed after 1–2 weeks of treatment with dosages as low as 3·8 mg/d. Maximum BP-lowering effects of lactotripeptides approximate 13 mmHg SBP and 8 mmHg DBP active treatment v. placebo, and are likely reached after 8–12 weeks of treatment. Lactotripeptides exert a gradual effect on BP lowering after start of intake and return of BP after end of treatment as well.

Table 1 presents a summary of all human trials on antihypertensive effects of lactotripeptides. In the table, sex, age and BMI are included since there is a strong association of age and BMI and elevated BP(Reference Brown, Higgins and Donato28, Reference Burke, Bertoni and Shea29). Concerning sex, the incidence of hypertension is markedly higher in men than in age-matched, premenopausal women. After menopause, this relationship no longer exists, and the incidence is comparable in women and men(Reference Reckelhoff30). A large number of the individuals with high BP are either overweight and/or elderly. However, sex, age and BMI were not analysed separately for associations with BP.

Table 1 Overview of human trials on antihypertensive effects of lactotripeptides

A. oryzae, Aspergillus oryzae; ACE, angiotensin-converting enzyme; BP, blood pressure; d-bld, double blind; DBP, diastolic blood pressure; F, female; IPP, isoleucine–proline–proline; L. helv. Lactobacillus helveticus; LTP, lactotripeptides; M, male; NR, not reported; p-c, placebo controlled; R, randomized; S. cerv., Saccharomyces cerevisiae; SBP, systolic blood pressure; Sig., significant; VPP, valine–proline–proline.

* Degree of hypertension of subjects (SBP/DBP): optimal < 120/80 mmHg; normal < 130/85 mmHg, high-normal 130–139/85–89 mmHg; mild 140–159/90–99 mmHg; moderate 160–179/100–109 mmHg, severe >179/109 mmHg.

Results reported as changes in SBP and DBP after each month of treatment for all subjects (intention-to-treat analysis), and as mean changes over the total intervention period among subjects who had BP measurements for each month (per protocol analysis); BMI was not reported, only body weight (in kg).

Results reported separately for subjects with mild hypertension and subjects with high-normal blood pressure and for both groups combined.

§ Results reported separately for subjects with mild hypertension, subjects with high-normal blood pressure, subjects with normal blood pressure, and for all groups combined.

Results reported separately for subjects with mild to moderate hypertension and subjects with normal blood pressure; BMI was not reported, only body weight (in kg).

Results reported separately for subjects with mild hypertension and subjects with high-normal blood pressure.

** Results of 24 h ambulatory (amb.) BP measurements and office (off.) BP measurements were reported.

†† First part of the study was carried out in parallel design and second part of the study was carried out in crossover design.

‡‡ Subjects with BP values ranging from optimal to moderate hypertension were included, but the majority had high-normal BP or mild hypertension and no relevant differences were reported among groups. Results of office (off.) BP and home BP were reported.

What is the lowest and highest effective dosage tested in human trials?

The lowest dosage of lactotripeptides that was proven effective in man was 3·07 mg/d in subjects with high-normal BP or mild hypertension. Daily intake of sour milk with this amount of peptides resulted in a maximal significant lowering of SBP by 4·4 mmHg and DBP by 2·8 mmHg after 10 weeks of intake as compared with placebo drink(Reference Sano, Ohki and Higuchi18).

The highest effective dosage of lactotripeptides was evaluated in a safety study, and consisted of 52·5 mg/d(Reference Jauhiainen, Vapaatalo and Poussa31). After 10 weeks of active treatment, mean SBP in subjects with hypertension decreased by 4·1 mmHg and DBP by 1·8 mmHg. The next highest dose of lactotripeptides that was tested amounted to 13·0 mg/d(Reference Aihara, Kajimoto and Hirata25). After 4 weeks of active treatment, SBP in subjects with mild hypertension decreased by 11·2 mmHg compared to placebo, and DBP tended to decrease by 6·5 mmHg. It is intriguing that the study applying the lower dose produced the biggest BP decrease. A regional difference may account for this apparent discrepancy, as will be discussed later.

Mizuno et al. (Reference Mizuno, Matsuura and Gotou20) were the first, and so far the only research group, to study dose-dependent effects of lactotripeptides on the extent of BP lowering in subjects with high-normal BP and mild hypertension. In hypertensives, intake of 1·8, 2·5 and 3·6 mg lactotripeptides during 6 weeks resulted in greater decreases of SBP in the test group compared with placebo; by 6·5, 7·9 and 12·2 mmHg, respectively. No differences in DBP in the test group compared with the placebo group were observed during the treatment period. In subjects with high-normal BP, intake of lactotripeptides did not affect BP.

In conclusion, effective dosages of lactotripeptides range from 3·07 to 52·5 mg/d. A dose–effect relationship was found in the one study that specifically addressed this relation, but from a comparison of studies using different doses, no clear dose–effect relation can be established.

Why are lactotripeptides only effective in subjects with higher blood pressure?

In all clinical trials, the current BP classification recommended by the WHO(32) was used. With respect to effectiveness of the lactotripeptides in different BP categories, clinical trials have been carried out in subjects with (mild) hypertension, either or not using antihypertensive medication, in subjects with high-normal BP and subjects with normal BP.

It appears that lactotripeptides are effective in reducing BP provided that starting BP is at least high-normal. Sano et al. (Reference Sano, Ohki and Higuchi19) who performed a trial including three BP categories illustrated this: mild hypertensive, high-normal BP and normal BP. Daily consumption of 600 ml juice containing in total 9·21 mg lactotripeptides during 4 weeks induced a significant decrease of both SBP (by 7·7 mmHg) and DBP (by 6·4 mmHg) in the mild hypertensive group as compared to the placebo drink. In the high-normal group, SBP and DBP showed a tendency to decrease by 3·6 and 1·8 mmHg, respectively, whereas in the normal BP group no changes were found. Also in another trial, Sano et al. (Reference Sano, Ohki and Higuchi18) compared BP of subjects with high-normal BP and subjects with mild hypertension after intake of 3·07 mg lactotripeptides during 12 weeks. Relative to placebo, the test product decreased SBP by approximately 6 mmHg in mild hypertensives and approximately 3 mmHg in subjects with high-normal BP. Comparable results were reported by Aihara et al. (Reference Aihara, Kajimoto and Hirata25). At the end of a 4-week treatment, in the subjects with mild hypertension, SBP decreased by 11·2 mmHg and DBP tended to decrease by 6·5 mmHg compared with placebo. In subjects with high-normal BP, SBP decreased by 3·2 mmHg and DBP by 5·0 mmHg compared with placebo. These trials demonstrated the positive relation between height of starting BP and effectiveness of the peptides.

In none of the trials with normotensives were statistically significant BP changes found(Reference Itakura, Ikemoto and Terada21, Reference Kajimoto, Nakamura and Yada26). Even at the highest dosage of lactotripeptides used in normotensives, which included a total of 29·2 mg/d during a period of 7 d, no BP-lowering effects by lactotripeptides were observed(Reference Yasuda, Aihara and Komazaki33).

Thus, efficacy of lactrotripeptides could only be demonstrated in subjects with (slightly) elevated BP. This is in line with findings in BP-lowering studies using pharmaceutical interventions. In such settings, BP decreases are also larger at higher starting BP values, although a small residual BP-lowering effect is still observed even at normotensive starting values(Reference Law, Wald and Morris34). The fact that this latter finding is not true for lactotripeptides may be due to their lower potency compared to BP-lowering medication. A further explanation for the more pronounced effects of lactotripeptides on BP in subjects with elevated BP may be that if subjects have been screened for a higher-than-normal BP, regression to the mean may occur after screening, giving a BP decrease that is independent of the intervention (but that would not be corrected for if no placebo comparison is made). This artifact is likely more pronounced with higher starting values. Indeed, in a number of trials a decrease of BP was observed from screening to baseline(Reference Seppo, Jauhiainen and Poussa17, Reference Yasuda, Aihara and Komazaki33, Reference Mizushima, Ohshige and Watanabe35). In a trial by Seppo et al. (Reference Seppo, Kerojoki and Suomalainen16), a marked BP decrease of mildly hypertensive subjects was observed during the 4-week run-in period, which was explained by training the subjects to BP measurements.

Thus, lactotripeptides only seem to be active at elevated BP and not at normal BP values. Evidence indicates that effectiveness is positively associated with BP level, which is in line with existing data for BP-lowering medication(Reference Law, Wald and Morris34).

Are lactotripeptides effective in subjects on antihypertensive medication?

The use of lactotripeptides on top of antihypertensive medication was described in two papers(Reference Seppo, Jauhiainen and Poussa17, Reference Hata, Yamamoto and Ohni36). As described by Hata et al. (Reference Hata, Yamamoto and Ohni36), lactotripeptides can have antihypertensive effects even in addition to the effects of antihypertensive medication. Although numbers were very small for statistics, in stratified analyses by the kind of antihypertensive medication used, the decrease in SBP and DBP in the test group tended to be greater than in the placebo group for all types of medication (mainly calcium antagonists, β-blockers and ACE inhibitors). These findings demonstrate the potency of lactotripeptides to lower BP in addition to medication. Also Seppo et al. (Reference Seppo, Jauhiainen and Poussa17) reported that the use of antihypertensive medication did not significantly influence the BP responses to lactotripeptides, although no data were given.

Are blood pressure effects of lactotripeptides different in Japanese subjects versus Caucasian subjects?

Hypertension is a complex multifactor disorder that is thought to result from an interaction between environmental factors and genetic background. Subject characteristics such as age and race/ethnicity can affect BP, including the BP response to specific antihypertensive medication. Indeed, public health studies have observed that the prevalence of hypertension is different in different racial groups. Worldwide, a particularly high prevalence of hypertension was reported in Latin America and the Caribbean, and a number of Asian countries had the lowest prevalence, with the exception of Japan(Reference Kearney, Whelton and Reynolds37).

Most of the BP studies with lactotripeptides have been done in Japanese subjects, and several studies have been done in Finnish subjects(Reference Seppo, Kerojoki and Suomalainen16, Reference Seppo, Jauhiainen and Poussa17, Reference Jauhiainen, Vapaatalo and Poussa31, Reference Tuomilehto, Lindstrom and Hyyrynen38). In general, the effects described in Japanese studies on lactotripeptides are larger than those reported in Finnish studies. However, it is unlikely that genetic differences can account for these differential effects. Comparative studies on antihypertensive medication in different races/ethnic groups have demonstrated that pharmacokinetic parameters and haemodynamic effects are essentially the same in Chinese and Japanese subjects compared with Caucasian subjects(Reference Anderson, Critchley and Tomlinson39Reference Vaidyanathan, Jermany and Yeh41).

Thus, despite genetic differences related to hypertension between different ethnic groups, there is no reason to consider Japanese subjects different from Caucasian subjects with respect to BP effects of lactotripeptides. However, a number of other background factors are different between Japanese and Caucasian subjects that may account for variation in BP responses to lactotripeptides, especially dietary factors such as dairy intake(42).

What is the mechanism of action?

Inhibition of ACE is generally believed to be the underlying working mechanism of lactotripeptides(Reference Jauhiainen and Korpela15). ACE is an enzyme that plays a crucial role in the renin angiotensin system, which regulates BP and fluid and electrolyte balance. The ACE inhibitory activity of lactotripeptides has mainly been determined in vitro (Reference Nakamura, Yamamoto and Sakai43). One of the few studies that support their in vivo action demonstrated the presence of IPP and VPP as well as a decreased ACE activity in the aorta after a single oral administration to spontaneously hypertensive rats(Reference Masuda, Nakamura and Takano44). Sipola et al. (Reference Sipola, Finckenberg and Korpela45) demonstrated ACE inhibition by measuring an increased plasma renin activity in spontaneously hypertensive rats after oral intake of IPP and VPP. Changes in angiotensin I and angiotensin II have been reported, but the result was not significant(Reference Mizushima, Ohshige and Watanabe35). However, ACE inhibitors not only decrease the production of angiotensin II but also decrease the degradation of the vasodilator bradykinin(Reference FitzGerald, Murray and Walsh13). Thus, BP-lowering activity of lactotripeptides may therefore also result from inhibition of bradykinin degradation and/or subsequent increases of vasodilating PG or endothelium-derived relaxing factor(s).

Moreover, lactotripeptides may exert antihypertensive effects through other mechanisms, such as opioid-like activities(Reference Nurminen, Sipola and Kaarto46), inhibition of the release of the vasoactive substances such as the vasoconstrictor endothelin-1, eicosanoids and nitric oxide(Reference Maes, Van Camp and Vermeirssen47). However, involvement of ACE inhibition in these pathways cannot be excluded.

Lactotripeptides have additionally been shown to exert beneficial effects other than lowering systemic BP, such as improvement of vascular endothelial function in subjects with mild hypertension(Reference Hirota, Ohki and Kawagishi48). Since there was no change in systemic BP, the authors suggest that the improvement of the vascular endothelial function attributable to VPP and IPP is independent of haemodynamic changes.

Lactotripeptides may exert BP-lowering effects either via ACE inhibition or via non-ACE-dependent pathways, but only limited in vivo evidence is currently available for the physiological basis of their antihypertensive action.

Are lactotripeptides bioavailable?

To exert physiological effects after oral ingestion, it is of crucial importance that lactotripeptides remain active during gastrointestinal digestion and absorption and reach the cardiovascular system. Proline- and hydroxyproline-containing peptides are relatively resistant to degradation by digestive enzymes. Furthermore, tripeptides containing the C-terminal proline–proline are reported to be resistant to proline-specific peptidases(Reference FitzGerald and Meisel12). Peptides consisting of two or three amino acids can be absorbed intact from the intestinal lumen into the blood circulation via different mechanisms for intestinal transport(Reference Vermeirssen, Van Camp and Verstraete49). The presence of IPP (but not VPP) was recently demonstrated in measurable amounts in the circulation of volunteers that consumed a drink enriched in IPP and VPP(Reference Foltz, Meynen and Bianco50).

Are differences in composition of the test products important for the blood pressure effect?

In all clinical trials discussed here, the study products contained both IPP and VPP administered either as a fermented milk drink or as tablets. In vitro studies indicate that IPP (ic50 = 5 μmol/l) has a higher ACE inhibitory potency than VPP (ic50 = 9 μmol/l)(Reference Murray and FitzGerald11), and may thus be more effective. Moreover, data from a study that assessed the bioavailability of IPP and VPP suggest that IPP may have a better bioavailability than VPP(Reference Foltz, Meynen and Bianco50). In most products more VPP is present than IPP giving a ratio of approximately 1·1–1·8 VPP:IPP. Only the products used by Sano et al. (Reference Sano, Ohki and Higuchi18, Reference Sano, Ohki and Higuchi19) and Jauhiainen et al. (Reference Jauhiainen, Vapaatalo and Poussa31) contained slightly less VPP than IPP, giving ratios of 0·8 and 0·9 VPP:IPP, respectively. Recently, a study compared the effects on BP of different lactotripeptide sources, namely a fermented and an enzymatically hydrolysed dairy drink, a dairy drink in which equal amounts of IPP and VPP but no other tripeptides were added, and a dairy drink without further additions (placebo)(Reference Engberink, Schouten and Kok51). Since no results on BP were observed in any of the conditions, it is difficult to draw conclusions on the importance of the source of the tripeptides. It appears, however, that beneficial BP effects do not require both lactotripeptides to be present in the product, because a recently conducted study on a product containing IPP but no VPP showed significant BP-lowering effects in Caucasian stage I hypertensive subjects (E Boelsma and J Kloek, unpublished results).

All products tested in human studies so far contain a number of minerals with known effects on BP, such as calcium, potassium, magnesium and phosphorus. Concerning calcium and magnesium, meta-analyses of randomized, controlled trials yielded an inverse association between intake of these minerals and BP in hypertensive and non-hypertensive subjects(Reference Allender, Cutler and Follmann52Reference van Mierlo, Arends and Streppel55). A negative correlation of potassium with BP has been demonstrated as well(Reference Linas56, Reference Whelton, He and Cutler57). In a recent study, significant inverse relationships of dietary phosphorus intake with BP were found(Reference Elliott, Kesteloot and Appel58). Although the dosages of the minerals in the sour milk/tablets were much lower than those that were effective in lowering BP in intervention trials, and placebo treatments were controlled for mineral content, it is possible that the minerals present may have induced synergistic effects to reduce BP. Only in the studies by Seppo et al. (Reference Seppo, Kerojoki and Suomalainen16, Reference Seppo, Jauhiainen and Poussa17) and Jauhiainen et al. (Reference Jauhiainen, Vapaatalo and Poussa31) did the placebo products contain 1·5–3·5 times more minerals compared with the sour milk drinks.

Is administration of lactotripeptides safe?

In general, lactotripeptides are considered safe since milk proteins are an essential part of the daily human diet. After ingestion, proteins are hydrolysed in the gastrointestinal tract by proteolytic enzymes derived from the pancreas resulting in the release of dipeptides, tripeptides and free amino acids(Reference Grimble59). In addition, the FDA list mentioning specific substances affirmed as ‘generally recognized as safe’ includes casein peptones(60). Recently, a battery of in vitro and in vivo toxicity tests were performed with lactotripeptide-containing products, casein hydrolysate, fermented milk and lactotripeptides(Reference Bernard, Nakamura and Bando61, Reference Dent, O'Hagan and Braun62). Results from the in vitro toxicity studies showed that the lactotripeptide-containing products did not exert mutagenic or genotoxic properties. Results from the in vitro toxicity studies, including sub-chronic studies in rats and developmental and reproductive toxicity studies in rats and rabbits, showed that the lactotripeptide-containing products did not induce any treatment-related adverse effects, even in the highest doses tested. Therefore, in the sub-chronic toxicity test in rats exposed to the casein hydrolysate product, the ‘no observable adverse effect level’ (NOAEL) resulted in >1000 mg casein hydrolysate/kg body weight per d (corresponding to 3 mg IPP +3 mg VPP/kg body weight per d), and for the lactotripeptide product it resulted in >4000 mg lactotripeptides/kg body weight per d (corresponding to 11·2 mg IPP +10·4 mg VPP/kg body weight per d). Fertility, reproductive performance, embryo toxicity and F1 generation (first offspring) studies in rats were performed and showed a NOAEL of >2000 mg fermented milk/kg body weight per d (corresponding to 3 mg IPP +3 mg VPP/kg body weight per d). In the embryo-fetal (pre-natal) developmental study in rabbits exposed to the lactoripeptide-containing product, the NOAEL was set for the highest dose tested, 1000 mg lactotripeptide product/kg body weight per d (corresponding to 2·8 mg IPP +2·6 mg VPP/kg body weight per d). Finally, in a number of human trials, clinical, biochemical and haematological parameters as well as urinalysis, medical examinations and questionnaires were included covering most parameters related to known adverse events of ACE inhibitory drugs. Even doses of lactotripeptides up to 52·5 mg/d did not cause adverse effects and neither did they affect serum clinical chemistry, substantiating the safety of consumption of lactotripeptides(Reference Sano, Ohki and Higuchi19, Reference Aihara, Kajimoto and Hirata25, Reference Jauhiainen, Vapaatalo and Poussa31, Reference Yasuda, Aihara and Komazaki33, Reference Kajimoto, Aihara and Hirata63).

General conclusion

In the present review, a number of issues on BP-lowering effects of lactotripeptides in man were clarified and current knowledge was updated. Available data demonstrate that lactotripeptides need to be taken for at least 1–2 weeks before BP effects become apparent. Within the first 2 weeks the largest effect is achieved followed by a gradual BP lowering until a maximum effect after about 8–12 weeks of treatment. Largest BP-lowering effects approximate 13 mmHg SBP and 8 mmHg DBP active treatment v. placebo. Effective dosages range between 3·07 and 52·5 mg/d, but the existence of a relationship between dose and effect is not yet clear.

Given the facts that lactotripeptides are safe and exert relevant and stable BP-lowering effects within relatively short time periods, they are good candidates to be included in healthy lifestyle changes to prevent or reduce high blood pressure.

Acknowledgements

Y. Ponstein is gratefully acknowledged for her contribution to the safety paragraph of this paper. The authors' responsibilities were as follows: E. B. reviewed the literature; E. B. and J. K. wrote the manuscript; J. K. approved the final version. The authors did not have a conflict of interest. E. B. is a project manager of clinical trials and consultant at the Business Unit Biosciences, TNO Quality of Life, Zeist, The Netherlands. J. K. is a senior scientist at the Department of Nutrition and Health, DSM Food Specialties, The Netherlands.

References

1Lawes, CM, Vander Hoorn, S & Rodgers, A (2008) International Society of Hypertension. Global burden of blood-pressure-related disease, 2001. Lancet 371, 15131518.CrossRefGoogle ScholarPubMed
2Collins, R, Peto, R, MacMahon, S, et al. (1990) Blood pressure, stroke, and coronary heart disease. Part 2, Short-term reductions in blood pressure: overview of randomised drug trials in their epidemiological context. Lancet 335, 827838.CrossRefGoogle ScholarPubMed
3MacMahon, S, Peto, R, Cutler, J, et al. (1990) Blood pressure, stroke, and coronary heart disease. Part 1, Prolonged differences in blood pressure: prospective observational studies corrected for the regression dilution bias. Lancet 335, 765774.CrossRefGoogle ScholarPubMed
4Collins, R & MacMahon, S (1994) Blood pressure, antihypertensive drug treatment and the risks of stroke and of coronary heart disease. Br Med Bull 50, 272298.CrossRefGoogle ScholarPubMed
5Prospective Studies Collaboration (2002) Age-specific relevance of usual blood pressure to vascular mortality: a meta-analysis of individual data for one million adults in 61 prospective studies. Lancet 360, 19031913.CrossRefGoogle Scholar
6Cook, NR, Cohen, J, Hebert, PR, et al. (1995) Implications of small reductions in diastolic blood pressure for primary prevention. Arch Intern Med 155, 701709.CrossRefGoogle ScholarPubMed
7Stamler, J (1997) The INTERSALT Study: background, methods, findings, and implications. Am J Clin Nutr 65, 626S642S.CrossRefGoogle Scholar
8Houston, MC (2007) Treatment of hypertension with nutraceuticals, vitamins, antioxidants and minerals. Expert Rev Cardiovasc Ther 5, 681691.CrossRefGoogle ScholarPubMed
9Thomas, GN, Cheung, BM, Ho, SY, et al. (2007) Overview of dietary influences on atherosclerotic vascular disease: epidemiology and prevention. Cardiovasc Hematol Disord Drug Targets 7, 8797.CrossRefGoogle ScholarPubMed
10Rudkowska, I & Jones, PJ (2007) Functional foods for the prevention and treatment of cardiovascular diseases: cholesterol and beyond. Expert Rev Cardiovasc Ther 5, 477490.CrossRefGoogle ScholarPubMed
11Murray, BA & FitzGerald, RJ (2007) Angiotensin converting enzyme inhibitory peptides derived from food proteins: biochemistry, bioactivity and production. Curr Pharm Des 13, 773791.CrossRefGoogle ScholarPubMed
12FitzGerald, RJ & Meisel, H (2000) Milk protein-derived peptide inhibitors of angiotensin-I-converting enzyme. Br J Nutr 84, Suppl. 1, S33S37.CrossRefGoogle ScholarPubMed
13FitzGerald, RJ, Murray, BA & Walsh, DJ (2004) Hypotensive peptides from milk proteins. J Nutr 134, 980S988S.CrossRefGoogle ScholarPubMed
14Lopez-Fandino, R, Otte, J & van Camp, J (2006) Physiological, chemical and technological aspects of milk-protein-derived peptides with antihypertensive and ACE-inhibitory activity. Int Dairy J 16, 12771293.CrossRefGoogle Scholar
15Jauhiainen, T & Korpela, R (2007) Milk peptides and blood pressure. J Nutr 137, 825S829S.CrossRefGoogle ScholarPubMed
16Seppo, L, Kerojoki, O, Suomalainen, T, et al. (2002) The effect of a Lactobacillus helveticus LBK-16H fermented milk on hypertension – a pilot study on humans. Milchwissenschaft 57, 124127.Google Scholar
17Seppo, L, Jauhiainen, T, Poussa, T, et al. (2003) A fermented milk high in bioactive peptides has a blood pressure-lowering effect in hypertensive subjects. Am J Clin Nutr 77, 326330.CrossRefGoogle Scholar
18Sano, J, Ohki, K, Higuchi, T, et al. (2005) Effect of casein hydrolysate, prepared with protease derived from Aspergillus oryzae, on subjects with high-normal blood pressure or mild hypertension. J Med Food 8, 423430.CrossRefGoogle ScholarPubMed
19Sano, J, Ohki, K, Higuchi, T, et al. (2005) Safety evaluation of excessive intake of drink containing ‘lactotripeptides (VPP, IPP)’ in subjects with normal blood pressure to mild hypertension. J Nutr Food 7, 1730.Google Scholar
20Mizuno, S, Matsuura, K, Gotou, T, et al. (2005) Antihypertensive effect of casein hydrolysate in a placebo-controlled study in subjects with high-normal blood pressure and mild hypertension. Br J Nutr 94, 8491.CrossRefGoogle Scholar
21Itakura, H, Ikemoto, S, Terada, S, et al. (2001) The effect of sour milk on blood pressure in untreated hypertensive and normotensive subjects. J Jap Soc Clin Nutr 23, 2631.Google Scholar
22Kajimoto, O, Aihara, K, Hirata, H, Takahashi, R & Nakamura, Y (2001) Hypotensive effects of the tablets containing ‘lactotripeptides (VPP, IPP)’. J Nutr Food 4, 5161.Google Scholar
23Kajimoto, O, Kurosaki, T, Mizutani, J, et al. (2002) Antihypertensive effects of liquid yogurts containing ‘lactotripeptides (VPP, IPP)’ in mild hypertensive subjects. J Nutr Food 5, 5566.Google Scholar
24Hirata, H, Nakamura, Y, Yada, H, et al. (2002) Clinical effects of new sour milk drink on mild or moderate hypertensive subjects. J New Rem Clin 51, 6169.Google Scholar
25Aihara, K, Kajimoto, O, Hirata, H, et al. (2005) Effect of powdered fermented milk with Lactobacillus helveticus on subjects with high-normal blood pressure or mild hypertension. J Am Coll Nutr 24, 257265.CrossRefGoogle ScholarPubMed
26Kajimoto, O, Nakamura, Y, Yada, H, et al. (2001) Hypotensive effects of sour milk in subjects with mild or moderate hypertension. J Jpn Soc Nutr Food Sci 54, 347354.CrossRefGoogle Scholar
27Nakamura, Y, Kajimoto, O, Kaneko, K, et al. (2004) Effects of the liquid yogurts containing ‘lactotripeptide (VPP, IPP)’ on high-normal blood pressure. J Nutr Food 7, 123137.Google Scholar
28Brown, CD, Higgins, M, Donato, KA, et al. (2000) Body mass index and the prevalence of hypertension and dyslipidemia. Obes Res 8, 605619.CrossRefGoogle ScholarPubMed
29Burke, GL, Bertoni, AG, Shea, S, et al. (2008) The impact of obesity on cardiovascular disease risk factors and subclinical vascular disease: the Multi-Ethnic Study of Atherosclerosis. Arch Intern Med 12, 928935.CrossRefGoogle Scholar
30Reckelhoff, JF (2001) Gender differences in the regulation of blood pressure. Hypertension 37, 11991208.CrossRefGoogle ScholarPubMed
31Jauhiainen, T, Vapaatalo, H, Poussa, T, et al. (2005) Lactobacillus helveticus fermented milk lowers blood pressure in hypertensive subjects in 24-h ambulatory blood pressure measurement. Am J Hypertens 18, 16001605.CrossRefGoogle ScholarPubMed
32World Health Organization, International Society of Hypertension Writing Group (2003) 2003 World Health Organization (WHO)/International Society of Hypertension (ISH) statement on management of hypertension. J Hypertens 21, 19831992.CrossRefGoogle Scholar
33Yasuda, K, Aihara, K, Komazaki, K, et al. (2001) Effect of large high intake of tablets containing ‘lactotripeptides (VPP, IPP)’ on blood pressure, pulse rate and clinical parameters in healthy volunteers. J Nutr Food 4, 6372.Google Scholar
34Law, MR, Wald, NJ, Morris, JK, et al. (2003) Value of low dose combination treatment with blood pressure lowering drugs: analysis of 354 randomised trials. Br Med J 326, 14271431.CrossRefGoogle ScholarPubMed
35Mizushima, S, Ohshige, K, Watanabe, J, et al. (2004) Randomized controlled trial of sour milk on blood pressure in borderline hypertensive men. Am J Hypertens 17, 701706.CrossRefGoogle ScholarPubMed
36Hata, Y, Yamamoto, M, Ohni, M, et al. (1996) A placebo-controlled study of the effect of sour milk on blood pressure in hypertensive subjects. Am J Clin Nutr 64, 767771.CrossRefGoogle ScholarPubMed
37Kearney, PM, Whelton, M, Reynolds, K, et al. (2005) Global burden of hypertension: analysis of worldwide data. Lancet 365, 217223.CrossRefGoogle ScholarPubMed
38Tuomilehto, J, Lindstrom, J, Hyyrynen, J, et al. (2004) Effect of ingesting sour milk fermented using Lactobacillus helveticus bacteria producing tripeptides on blood pressure in subjects with mild hypertension. J Hum Hypertens 18, 795802.CrossRefGoogle ScholarPubMed
39Anderson, PJ, Critchley, JA, Tomlinson, B, et al. (1995) Comparison of the pharmacokinetics and pharmacodynamics of oral doses of perindopril in normotensive Chinese and Caucasian volunteers. Br J Clin Pharmacol 39, 361368.Google ScholarPubMed
40Anderson, PJ, Critchley, JA & Tomlinson, B (1996) A comparison of the pharmacokinetics and pharmacodynamics of cilazapril between Chinese and Caucasian healthy, normotensive volunteers. Eur J Clin Pharmacol 50, 5762.CrossRefGoogle ScholarPubMed
41Vaidyanathan, S, Jermany, J, Yeh, C, et al. (2006) Aliskiren, a novel orally effective renin inhibitor, exhibits similar pharmacokinetics and pharmacodynamics in Japanese and Caucasian subjects. Br J Clin Pharmacol 62, 690698.CrossRefGoogle ScholarPubMed
42Japanese Ministry of Health, Labour and Welfare (2004) The National Nutrition Survey in Japan, 2002. Tokyo: Ministry of Health, Labour and Welfare.Google Scholar
43Nakamura, Y, Yamamoto, N, Sakai, K, et al. (1995) Purification and characterization of angiotensin I-converting enzyme inhibitors from sour milk. J Dairy Sci 78, 777783.CrossRefGoogle ScholarPubMed
44Masuda, O, Nakamura, Y & Takano, T (1996) Antihypertensive peptides are present in aorta after oral administration of sour milk containing these peptides to spontaneously hypertensive rats. J Nutr 126, 30633068.CrossRefGoogle ScholarPubMed
45Sipola, M, Finckenberg, P, Korpela, R, et al. (2002) Effect of long-term intake of milk products on blood pressure in hypertensive rats. J Dairy Res 69, 103111.CrossRefGoogle ScholarPubMed
46Nurminen, M, Sipola, M, Kaarto, H, et al. (2000) α-Lactorphin lowers blood pressure via radiotelemetry in normotensive and spontaneously hypertensive rats. Life Sci 66, 15351543.CrossRefGoogle Scholar
47Maes, W, Van Camp, J, Vermeirssen, V, et al. (2004) Influence of the lactokinin Ala-Leu-Pro-Met-His-Ile-Arg (ALPMHIR) on the release of endothelin-1 by endothelial cells. Regul Pept 118, 105109.CrossRefGoogle ScholarPubMed
48Hirota, T, Ohki, K, Kawagishi, R, et al. (2007) Casein hydrolysate containing the antihypertensive tripeptides Val-Pro-Pro and Ile-Pro-Pro improves vascular endothelial function independent of blood pressure-lowering effects: contribution of the inhibitory action of angiotensin-converting enzyme. Hypertens Res 30, 489496.CrossRefGoogle ScholarPubMed
49Vermeirssen, V, Van Camp, J & Verstraete, W (2004) Bioavailability of angiotensin I converting enzyme inhibitory peptides. Br J Nutr 92, 357366.CrossRefGoogle ScholarPubMed
50Foltz, M, Meynen, EE, Bianco, V, et al. (2007) Angiotensin converting enzyme inhibitory peptides from a lactotripeptide-enriched milk beverage are absorbed intact into the circulation. J Nutr 137, 953958.CrossRefGoogle ScholarPubMed
51Engberink, MF, Schouten, EG, Kok, FJ, et al. (2008) Lactotripeptides show no effect on human blood pressure: results from a double-blind randomized controlled trial. Hypertension 51, 399405.CrossRefGoogle ScholarPubMed
52Allender, PS, Cutler, JA, Follmann, D, et al. (1996) Dietary calcium and blood pressure: a meta-analysis of randomized controlled trials. Ann Intern Med 124, 825831.CrossRefGoogle Scholar
53Griffith, LE, Guyatt, GH, Cook, RJ, et al. (1999) The influence of dietary and nondietary calcium supplementation on blood pressure: an updated meta-analysis of randomized controlled trials. Am J Hypertens 12, 8492.CrossRefGoogle Scholar
54Jee, SH, Miller, ER III, Guallar, E, et al. (2002) The effect of magnesium supplementation on blood pressure: a meta-analysis of randomized clinical trials. Am J Hypertens 15, 691696.CrossRefGoogle ScholarPubMed
55van Mierlo, LA, Arends, LR, Streppel, MT, et al. (2006) Blood pressure response to calcium supplementation: a meta-analysis of randomized controlled trials. J Hum Hypertens 20, 571580.CrossRefGoogle ScholarPubMed
56Linas, SL (1991) The role of potassium in the pathogenesis and treatment of hypertension. Kidney Int 39, 771786.CrossRefGoogle ScholarPubMed
57Whelton, PK, He, J, Cutler, JA, et al. (1997) Effects of oral potassium on blood pressure. Meta-analysis of randomized controlled clinical trials. JAMA 277, 16241632.Google ScholarPubMed
58Elliott, P, Kesteloot, H, Appel, LJ, et al. (2008) INTERMAP Cooperative Research Group. Dietary phosphorus and blood pressure: international study of macro- and micro-nutrients and blood pressure. Hypertension 51, 669675.CrossRefGoogle Scholar
59Grimble, GK (1994) The significance of peptides in clinical nutrition. Annu Rev Nutr 14, 419447.CrossRefGoogle ScholarPubMed
60FDA (1998) List of substances that added directly to human food that are affirmed as GRAS.http://www.cfsan.fda.gov/~rdb/opa-gras.html.Google Scholar
61Bernard, BK, Nakamura, Y, Bando, I, et al. (2005) Studies of the toxicological potential of tripeptides (l-valyl-l-prolyl-l-proline and l-isoleucyl-l-prolyI-l-proline): II. Introduction. Int J Toxicol 24, Suppl. 4, 511.CrossRefGoogle ScholarPubMed
62Dent, MP, O'Hagan, S, Braun, WH, et al. (2007) A 90-day subchronic toxicity study and reproductive toxicity studies on ACE-inhibition of lactotripeptide. Food Chem Toxicol 45, 14681477.CrossRefGoogle Scholar
63Kajimoto, O, Aihara, K, Hirata, H, et al. (2001) Safety evaluation of excessive intake of the tablet containing ‘Lactotripeptides (VPP, IPP)’ on healthy volunteers. J Nutr Food 4, 3746.Google Scholar
Figure 0

Table 1 Overview of human trials on antihypertensive effects of lactotripeptides