Long-term studies on blood pressure

We have recently reviewed the evidence from RCT on the antihypertensive effects of milk proteins and peptides⁽ Reference Fekete, Givens and Lovegrove ^{13 )}. For that review we systematically searched and reviewed the literature until December 2012. There was an imbalance in the literature as more RCT were conducted using mainly one type of casein-derived peptides, called lactotripeptides (LTP). We, therefore conducted an updated meta-analysis on the impact of LTP on BP⁽ Reference Fekete, Givens and Lovegrove ^{14 )}, which included all available and relevant RCT and detailed subgroup and regression analyses, which were somewhat limited in previous meta-analyses in this area⁽ Reference Xu, Qin and Wang ^{15 –} Reference Qin, Xu and Dong ^{18 )}. We found a small, but significant reduction in both SBP (−2·95 mmHg (95 % CI −4·17, −1·73; P < 0·001)) and DBP (−1·51 mmHg (95 % CI −2·21, −0·80; P < 0·001)) after 4 weeks of LTP supplementation in pre- and hypertensive populations. Since there was a statistically significant heterogeneity of treatment effects across studies, sub-group analyses were performed. These analyses suggested differences in countries where RCT were conducted: Japanese studies reported significantly greater BP-lowering effect of LTP (−5·54 mmHg for SBP; and −3·01 mmHg for DBP), compared with European studies (−1·36 mmHg for SBP; and −0·83 mmHg for DBP; P = 0·002 for SBP and <0·001 for DBP). This was confirmed in a recent meta-analysis which focused on Asian RCT only. However, it only assessed SBP and the authors reported a very similar reduction of −5·63 mmHg in SBP compared to our −5.54 mmHg⁽ Reference Chanson-Rolle, Aubin and Braesco ^{19 )}. There may be several explanations for this observation. Firstly Japanese diets contains less milk and dairy products than European diets, therefore consumption of milk proteins may have a greater overall impact when compared with populations that consume these proteins more regularly and in higher quantities^{( 20 )}. Furthermore, there are reported ethnic differences in the response to drug administration, BP lowering in particular⁽ Reference Johnson ^{21 )} which could impact on the response to these bioactive proteins. Finally differences in response may also have resulted from different spatial conformations (cis/trans) of LTP used in the studies, due to production processes⁽ Reference Siltari, Viitanen and Kukkurainen ^{22 )}. Intriguingly, we also found a small-study effect, and when all bias was considered it shifted the treatment effect towards a less significant SBP and non-significant DBP reduction in response to LTP supplementation. We concluded that with potential bias considered, LTP consumption may still be effective in lowering BP in mildly hypertensive or hypertensive groups⁽ Reference Fekete, Givens and Lovegrove ^{14 )}.

During our systematic literature search⁽ Reference Fekete, Givens and Lovegrove ^{13 )} we found that there were very few studies investigating the BP-lowering effects of other casein-derived peptides in human subjects⁽ Reference Ashar ^{23 –} Reference Sugai ^{27 )}. Furthermore these studies were limited, used different types of peptides and were often uncontrolled with poor methodological and study design. Due to these inconsistencies in the study design, it was impossible to compare these data and no firm conclusion could be drawn on the antihypertensive effects of casein-derived peptides. Similarly, we found a limited number of RCT conducted using intact whey or whey-derived peptides assessing their antihypertensive effects in human subjects ⁽ Reference Kawase, Hashimoto and Hosoda ^{28 –} Reference Pal and Ellis ^{33 )}. These trials seem to be of higher quality than studies on casein-derived peptides; however, the findings of these studies were also inconsistent⁽ Reference Fekete, Givens and Lovegrove ^{13 )}.

Since our review, published in 2013, three new studies which assessed the effects of milk proteins on BP as primary outcome were published. Petyaev et al. ⁽ Reference Petyaev, Dovgalevsky and Klochkov ^{34 )} examined the impacts of whey protein embedded in a protective lycopene matrix, a new proprietary formulation, the so-called whey protein lycosome, in a pilot study. Authors hypothesised that this formulation would protect whey protein from gastrointestinal degradation which would increase the bioavailability of the protein, and thus reduce the need for a high dose. They administered 70 mg whey protein along with 7 mg lycopene in the form of a capsule (WPL) and compared this with whey protein (70 mg) and lycopene (7 mg) separately (taken once daily for a month). A significant decrease in BP (−7 mmHg in SBP and −4 mmHg in DBP, P < 0·05) in the WPL group was reported compared with baseline only and no effect relative to the whey and lycopene given separately. Due to the nature of this pilot study, there was no information on blinding, the sample size was small (ten/treatment group) and due to the limited statistical analysis further investigation is needed to evaluate the potential antihypertensive effect of WPL. Another RCT was conducted in overweight and obese adolescents (aged 12–15 years), who were asked to consume 1 litre/d of either water, skimmed milk, whey or casein (milk-based treatment drink contained 35 g/l protein) for 12 weeks⁽ Reference Arnberg, Larnkjaer and Michaelsen ^{35 )}. A decrease in brachial and central aortic DBP compared with baseline and control group (consuming water) was observed, whereas whey protein appeared to increase brachial and central aortic SBP, and central DBP. The authors acknowledged several limitations of the study, including difficulties in recruitment, changes in the research protocol after study commencement and not controlling for the extra energy intake that 1 litre/d treatment drinks provided, which led to an increase in weight in those in the treatment groups compared with a loss in the control group which consumed water. Therefore, due to these limitations it was difficult to draw firm conclusions from these data. A study of Figueroa et al. ⁽ Reference Figueroa, Wong and Kinsey ^{36 )} examined the effects of both whey and casein on BP and vascular function combined with exercise training in obese, hypertensive women. In their 4-week trial, participants were assigned to consume 30 g casein, whey or 34 g maltodextrin (control) and perform resistance and endurance exercises 3 d/week under a qualified instructor's supervision. They reported significant reduction in both brachial and aortic SBP in both whey and casein groups compared with the control, although this was not observed for DBP. The exercise training did not have additional effects on BP or arterial function, owing the beneficial effect on the cardiovascular system to the milk proteins (Table 1).

Table 1. Impacts of milk proteins on blood pressure

↑, Increase; ↓, decrease; BP, blood pressure; bBP, brachial blood pressure; cBP, central blood pressure; DBP, diastolic blood pressure; SBP, systolic blood pressure.

In summary, emerging evidence suggest that milk protein consumption for at least 4 weeks may result in small BP lowering; however, further well-controlled studies involving 24-h ambulatory BP monitor should be performed for confirmation.

Short-term studies on blood pressure

According to a typical Western eating pattern, people spend up to 18 h/d in a postprandial state consuming three or more meals daily. Furthermore elevated postprandial lipeamia, glycaemia and inflammation have been linked with increased risk for chronic disease development, including diabetes and CVD⁽ Reference Alipour, Elte and van Zaanen ^{37 –} Reference Lopez-Miranda, Williams and Lairon ^{39 )}. Therefore dietary strategies that attenuate the postprandial metabolic disturbance are urgently required.

To date only two studies have evaluated the acute (short-term) effects of milk proteins on BP. Pal and Ellis compared 45 g whey protein isolate, 45 g Na-caseinate with 45 g glucose in conjunction with a breakfast in normotensive overweight and obese women⁽ Reference Pal and Ellis ^{32 )}, but found no effect of treatment. A more recent study compared the postprandial effects of several dietary proteins (milk protein, pea protein and egg-white) and carbohydrate-rich meals on BP-related responses⁽ Reference Teunissen-Beekman, Dopheide and Geleijnse ^{40 )}. Although the authors failed to specify the specific type of milk protein isolate used, its BP-lowering effect was not significantly different to pea protein, although both milk and pea protein were significantly lower than egg-white (P ≤ 0·01; Table 1). The lack of evidence on the acute BP effects of milk proteins warrants further research.

Long-term studies on vascular function

Our previous review also evaluated the health effects of milk proteins and/or their peptides on vascular function⁽ Reference Fekete, Givens and Lovegrove ^{13 )}. In brief, we identified nine chronic RCT⁽ Reference Pal and Ellis ^{33 ,} Reference Hirota, Ohki and Kawagishi ^{46 –} Reference Nakamura, Mizutani and Ohki ^{53 )}, of which eight used LTP⁽ Reference Hirota, Ohki and Kawagishi ^{46 –} Reference Turpeinen, Ehlers and Kivimaki ^{54 )} and one trial used intact casein and whey⁽ Reference Pal and Ellis ^{33 )}. These studies were diverse in several aspects of methodologies such as design, length and dose of treatment, subject characteristics and measures of vascular function, and most importantly type of milk proteins used. Due to this heterogeneity, it is not possible to draw firm conclusions on the relative effects of milk proteins on the vascular function.

We have identified three further RCT: Petyaev et al. ⁽ Reference Petyaev, Dovgalevsky and Klochkov ^{34 )} examined the impacts of WPL not only on BP, but also on vascular reactivity, using FMD. They reported statistically significant improvements in FMD in the WPL group only (+2·6 %, P < 0·05) compared with baseline. Arnberg et al. also evaluated the effects of intact whey, casein and semi-skimmed milk on arterial stiffness using pulse wave velocity, however, failed to show any changes in vascular function⁽ Reference Arnberg, Larnkjaer and Michaelsen ^{35 )}. Figueroa et al. ⁽ Reference Figueroa, Wong and Kinsey ^{36 )} reported favourable changes in augmentation index (a measure of arterial stiffness) and brachial-pulse wave velocity in both whey and casein groups combined with exercise, compared with the control group. It is of note that the randomisation may not have been adequate as the baseline values for both BP and arterial stiffness were different in the treatment groups, which may have confounded the study (Table 2).

Table 2. Impacts of milk proteins on vascular function

FMD, flow-mediated dilation, ↑, increase; ↔, no effect.

Short-term studies on vascular function

Only four RCT were conducted to evaluate the effects of milk proteins on vascular function in a postprandial setting⁽ Reference Pal and Ellis ^{32 ,} Reference Turpeinen, Ehlers and Kivimaki ^{54 –} Reference Ballard, Bruno and Seip ^{56 )}. Pal and Ellis failed to show any acute effects of whey and casein ingestion with a meal in normotensive obese postmenopausal women on arterial stiffness measured by pulse wave analysis⁽ Reference Pal and Ellis ^{32 )}. Likewise, Turpeinen et al. ⁽ Reference Turpeinen, Ehlers and Kivimaki ^{54 )} also did not observe any statistically significant change in arterial stiffness measured by pulse wave velocity after acute ingestion of 25 mg LTP with 2 g plant sterol ester mixed in a milk drink in mildly hypertensive subjects. However, Ballard et al. reported significant improvements in arterial reactivity assessed by FMD (+4·3 %) at 120 min after ingestion compared with placebo corresponding time point (P < 0·05) in mildly hypertensive, overweight individuals after whey hydrolysate (5 g NOP-47) ingestion with water⁽ Reference Ballard, Kupchak and Volk ^{55 )}. Mariotti et al. failed to report any significant effects of casein, whey or α-lactalbumin enriched whey protein on digital volume pulse (a measure of arterial stiffness)⁽ Reference Mariotti, Valette and Lopez ^{57 )} (Table 2).

Intriguingly, BP-lowering effects of milk proteins were not associated with changes in vascular function in the reviewed RCT⁽ Reference Fekete, Givens and Lovegrove ^{13 )} which is confirmed by emerging evidence on the relationship between BP and arterial stiffness. This suggests that the interaction between BP and arterial stiffness may be bi-directional⁽ Reference Franklin ^{58 ,} Reference Dernellis and Panaretou ^{59 )} via complex interactions between different pathways such as inflammatory⁽ Reference Sesso, Buring and Rifai ^{60 ,} Reference Tsai, Lin and Lin ^{61 )}, hormonal (e.g. leptin and insulin)⁽ Reference Tsai, Lin and Lin ^{61 –} Reference Singhal, Farooqi and Cole ^{63 )} and disturbances in endothelial-derived mediators⁽ Reference Franklin ^{58 )}. Therefore it is important to determine the effects of milk proteins on other mediators of CVD risk that may indirectly affect BP.

Long-term studies on glycaemic control

To the best of our knowledge, only three studies have investigated the chronic supplementation of milk proteins, rather than milk or dairy products, on glycaemic control. Pal et al. examined the effects of whey and casein (2 × 27 g/d for 12 weeks) in overweight and obese subjects⁽ Reference Pal, Ellis and Dhaliwal ^{96 )}. Most subjects had borderline impaired glucose tolerance at baseline, but at the end of the intervention a reduced fasting insulin concentration was observed in the whey protein group compared with the control group (glucose), although no change in fasting glucose was reported. In another study, a whey fermentation product (malleable protein matrix) decreased fasting plasma glucose concentration after 3 months supplementation compared with the control group, which was more pronounced in individuals with impaired fasting glucose at baseline⁽ Reference Gouni-Berthold, Schulte and Krone ^{108 )}. An acute-in-chronic study also reported a decrease in postprandial glucose response in whey group, which remained unchanged after the 4-week supplementation period⁽ Reference Ma, Jesudason and Stevens ^{102 )} (Table 3).

Short-term studies on lipids

Postprandial triacylglycerolaemia has been associated with markers of early atherosclerosis such as endothelial dysfunction and carotid media thickness⁽ Reference Teno, Uto and Nagashima ^{109 ,} Reference Vigna, Delli Gatti and Fellin ^{110 )} and is strongly influenced by the composition of a meal, including the quality and quantity of fat⁽ Reference Thomsen, Storm and Holst ^{111 ,} Reference Thomsen, Rasmussen and Lousen ^{112 )} and carbohydrate⁽ Reference Cohen and Schall ^{113 ,} Reference Lairon, Play and Jourdheuil-Rahmani ^{114 )}. In theory due to the insulinogenic effects of milk proteins, their consumption would be predicted to attenuate postprandial lipaemia, as insulin has an inhibitory effect on hormone-sensitive lipase and hepatic release of free fatty acid and stimulatory effect on lipoprotein lipase which hydrolyses TAG for metabolism or storage. However, evidence from postprandial RCT is limited. Postprandial investigations reported decrease in TAG after both whey and casein ingestion in combination with a fat-rich meal in obese⁽ Reference Holmer-Jensen, Mortensen and Astrup ^{98 )} and individuals with type 2 diabetes mellitus ⁽ Reference Mortensen, Hartvigsen and Brader ^{103 ,} Reference Brader, Holm and Mortensen ^{115 )}, but showed no effect on TAG after acute consumption of whey protein⁽ Reference Holmer-Jensen, Hartvigsen and Mortensen ^{99 ,} Reference Mortensen, Holmer-Jensen and Hartvigsen ^{104 )}. Free fatty acid also decreased after whey and casein ingestion in obese⁽ Reference Holmer-Jensen, Hartvigsen and Mortensen ^{99 )} and type 2 diabetes mellitus patients⁽ Reference Mortensen, Holmer-Jensen and Hartvigsen ^{104 )}. It is of note that parameters of lipid metabolism such as LDL and HDL and total cholesterol remain stable acutely⁽ Reference Olefsky, Crapo and Reaven ^{116 ,} Reference Roche, Zampelas and Knapper ^{117 )}.

Recently an acute study reported that casein with a high-fat, high-energy meal, compared with whey protein and α-lactalbumin-enriched whey protein, significantly reduced postprandial TAG and had a marked effect of chylomicron kinetics⁽ Reference Mariotti, Valette and Lopez ^{57 )}. This could be due to the different physicochemical makeup of casein and whey protein, as casein forms a gel in the stomach influencing the rate of absorption and gastric emptying (Table 4).

Table 4. Impacts of milk proteins on lipid metabolism

↑, Increase; ↓, decrease; ↔, no effect; CH, casein hydrolysate; D, day; FFA, free fatty acids; HC; hydrolysed casein; HDL-c, HDL cholesterol; LDL-c, LDL cholesterol; MS; metabolic syndrome; T2D, type-2 diebetes; TC, total cholesterol; Whey MPM, whey malleable protein matrix; WP, whey protein; WPH, whey protein hydrolysate;WPI, whey protein isolate.

Long-term studies on lipids

To date, five chronic RCT, which examined the lipid-lowering effects of milk proteins, have been identified. Three month supplementation of whey (2 × 25 g/d) and casein (2 × 25 g/d) during an ad libitum weight regain diet after substantial diet-induced weight loss in healthy obese subjects resulted in no change in plasma lipids⁽ Reference Claessens, van Baak and Monsheimer ^{118 )}. However, whey protein isolate (2 × 27 g/d) significantly reduced fasting TAG, total cholesterol and LDL-cholesterol after 3 months in overweight, obese individuals⁽ Reference Pal, Ellis and Dhaliwal ^{96 )}. Another 3-month supplementation study with malleable protein matrix (15 g/d protein in two daily servings of 150 g yoghurt) reduced fasting TAG, which was more pronounced in subjects with elevated baseline TAG⁽ Reference Gouni-Berthold, Schulte and Krone ^{108 )}. In a 6-week study casein (35 g/d) also reduced total cholesterol in hypercholesterolaemic subjects⁽ Reference Weisse, Brandsch and Zernsdorf ^{119 )}. Petyaev et al. reported a decrease in LDL-cholesterol, TAG and total cholesterol in their pilot study⁽ Reference Petyaev, Dovgalevsky and Klochkov ^{34 )} (Table 4). The limited evidence suggests that milk proteins have a beneficial impact on fasted lipids; however further studies are required. Although its possible mechanism of action is not clear, insulin may play a role. In vitro studies suggest that milk proteins and BCAA inhibit expression of genes involved in intestinal fatty acid and cholesterol absorption and synthesis⁽ Reference Chen and Reimer ^{120 )}. Whey has been shown to induce urinary excretion of tricarboxylic acid cycle compounds such as citric acid and succinic acid in rats, which are substrates for lipogenesis, suggesting an increased catabolic state (e.g. lipolysis) and reduced lipid accretion compared with casein⁽ Reference Lillefosse, Clausen and Yde ^{121 )}. This could be a possible mechanism of lipid reduction. Similarly, in another metabolic study conducted in human subjects, cheese (casein) appeared to induce lowering of urinary citrate⁽ Reference Zheng, Yde and Clausen ^{122 )}, which suggests that cheese consumption affects the tricarboxylic acid cycle. Additionally, microbiota-related metabolite, hippuric acid was significantly higher in the cheese group, than in the milk, implying a stimulation of gut bacteria activity. The enhanced bacterial activity also resulted in higher SCFA⁽ Reference Zheng, Yde and Clausen ^{122 )}, which have been proposed as key regulatory metabolites in lipid metabolism⁽ Reference Tremaroli and Backhed ^{123 )}. This effect may be due to the cheese matrix rather than the casein per se. An in vivo study proposed another potential mechanism of action through decreased lipid infiltration into the liver in rats with non-alcoholic fatty liver⁽ Reference Hamad, Taha and Abou Dawood ^{124 )}. Another possible putative mechanism is increased fat oxidation. Lorenzen et al. ⁽ Reference Lorenzen, Frederiksen and Hoppe ^{125 )} demonstrated an increased lipid oxidation after acute casein consumption compared with whey. They speculated that it may be due to lower insulin secretion after casein consumption relative to whey since insulin down-regulates lipid oxidation. However, insulin was not measured in the study and this mechanism could not be confirmed. The same research group examined the effects of dairy Ca on lipid metabolism in conjunction with a low- and high-fat diet for 10 d⁽ Reference Lorenzen and Astrup ^{126 )}. They found that dairy Ca attenuated the increase in total and LDL-cholesterol, without affecting the rise in HDL-cholesterol. This observed phenomenon may be due to the formation of insoluble Ca-fatty acid soaps and/or the production of hydrophobe aggregation with bile and with other fatty acids⁽ Reference Lorenzen and Astrup ^{126 –} Reference Govers, Termont and Van Aken ^{128 )}.

Long-term studies on inflammation and oxidative stress

A recent meta-analysis evaluated the effects of chronic consumption of whey protein and hydrolysate on C-reactive protein (CRP), a systemic inflammatory marker⁽ Reference Zhou, Xu and Rao ^{133 )}. Nine RCT were included which showed a small, non-significant reduction in CRP 0·42 mg/l (95 % CI −0·96, 0·13). Sub-group analyses suggested that >20 g/d may be more effective, and the elevated baseline CRP level (≥3 mg/l) could be more responsive to whey or whey peptides consumption⁽ Reference Zhou, Xu and Rao ^{133 )}. Similarly, Arnberg et al. ⁽ Reference Arnberg, Larnkjaer and Michaelsen ^{35 )} reported no change in CRP in adolescence after whey, casein or skimmed milk consumption for 12 weeks.

IL-6, IL-8 and TNF-α are also recognised inflammatory markers, which induce CRP. Pal and Ellis failed to observe significant changes in these inflammatory markers (2 × 27 g whey or casein or glucose for 12 weeks) in overweight individuals⁽ Reference Pal and Ellis ^{33 )}. However, Sugawara et al. ⁽ Reference Sugawara, Takahashi and Kashiwagura ^{134 )} reported decreased level of IL-6, IL-8 and TNF-α in patients with chronic obstructive pulmonary disease after whey intervention compared with the control group. Likewise, IL-6 and TNF-α were decreased after lactoferrin consumption for 6 months in postmenopausal women⁽ Reference Bharadwaj, Naidu and Betageri ^{135 )}. Similarly Hirota et al. ⁽ Reference Hirota, Ohki and Kawagishi ^{46 )} reported decreased levels of TNF-α in mildly hypertensive subjects fed with the casein-derived LTP (Table 5).

Table 5. Impacts of milk proteins on inflammation and oxidative stress

↑, Increase; ↓, decrease; ↔, no effect; BW, body weight; CCL5, CC chemokine ligand-5; CH, casein hydrolysate; COPD, chronic obstructive pulmonary disease; CRP, C-reactive protein; IPP, isoleucine–proline–proline; MCP-1, monocyte chemotactic protein-1; VPP, valine–proline–proine; Whey MPM, whey malleable protein matrix; WP, whey protein; WPH, whey protein hydrolysate;WPI, whey protein isolate.

Short-term studies on inflammation and oxidative stress

Pal and Ellis also reported no change in IL-6, IL-8 and TNF-α in a postprandial study investigating whey and casein⁽ Reference Pal and Ellis ^{32 )}. Likewise, a whey-derived peptide, NOP-47, also failed to change the level of serum cytokines (TNF-α, IK-6, IL-8, monocyte chemoattractant protein-1, vascular endothelial growth factor, soluble E-selectin, soluble vascular cell adhesion molecule-1) and chemokines⁽ Reference Ballard, Bruno and Seip ^{56 )}. However, consumption of a cake containing whey protein after exhaustive cycling in nine subjects reported reduced levels of CRP and IL-6 by 46 and 50 %, respectively⁽ Reference Kerasioti, Stagos and Jamurtas ^{136 )}. Holmer-Jensen et al. assessed the postprandial effects of whey protein, casein, gluten and cod on low-grade inflammatory markers (monocyte chemotactic protein-1, CC chemokine ligand-5/RANTES (Regulated on activation, normal T cell expressed and secreted)) in conjunction with a high fat meal⁽ Reference Holmer-Jensen, Karhu and Mortensen ^{137 )}. They reported that all meals increased CC chemokine ligand/RANTES; however, the smallest increase was observed after the whey protein meal. Monocyte chemotactic protein-1 was initially suppressed after all meals, and the meal containing whey protein induced the smallest overall postprandial suppression⁽ Reference Holmer-Jensen, Karhu and Mortensen ^{137 )} (Table 5).

The mechanism of action of milk proteins on oxidative stress and inflammation are unclear but Ca may supresses the pro-inflammatory and reactive oxygen species production in vitro ⁽ Reference Sun and Zemel ^{138 )}. Interestingly, the milk protein-derived inhibitors of the angiotensin-I-converting enzyme may also be involved in the anti-inflammatory process⁽ Reference Kalupahana and Moustaid-Moussa ^{139 )}.