The Effects of Cow-Milk Protein Supplementation in Elderly Population: Systematic Review and Narrative Synthesis
Abstract
:1. Introduction
- average protein intake for older people should range from 1.0 to 1.2 g/kg of body weight per day (while in young adults, the recommended intake is about 0.7–0.8 g/kg/day) [12];
- it must be taken into account that the feeding-associated anabolic threshold for dietary protein is higher in the elderly than in younger subjects, with the amount of protein required to reach it from a variety of foods being in the order of 25–30 g of protein per meal;
- dietary recommendations for protein intake in the elderly should consider, beyond quantity, also quality, protein source and timing of intake;
- best protein sources are rich in leucine;
- oral supplementation should be considered when dietary protein intake does not reach recommended goals [11].
2. Materials and Methods
2.1. Literature Search Strategy
2.2. Study Selection
3. Results
3.1. Muscle Related Endpoints among Healthy Subjects (40 Studies)
- co-ingestion of carbohydrates and fats with 21 g of leucine enriched WP did not affect the improvement of MPS rates, among 45 nonsarcopenic older men [45];
- a high WP-leucine- and vitamin D-enriched supplement (21 g protein in 150 Kcal/serving, 10 servings per week) was effective in preserving muscle mass during intentional weight reduction in association with regular physical activity, among 80 obese older adults [46];
- leucine-enriched WP (21 g) and vitamin D (800 IU) daily supplementation before breakfast enhanced post prandial MPS (acute effect) and muscle mass (long term effect) in 24 healthy elderly men in a ‘proof of principle’ trial [47];
- a multi-ingredient supplementation consisting of 30 g WP, 2.5 g creatine, 500 IU vitamin D, 400 mg calcium and 1500 mg n-3 PUFA was tested with and without exercise versus placebo and was effective in increasing both muscle strength and mass among 49 older men [48];
- co-ingestion of milk fat (26.7 g) did not affect the raise in plasma amino-acids and MPS after the ingestion of 20 g of casein, among 24 healthy older males [49].
3.2. Muscle Related Endpoints among Patients (14 Studies)
- during a six-month resistance training (RT) intervention among 80 mobility-limited older adults, 40 g of daily WP supplementation did not add benefit to exercise in improving lean mass, muscle strength and physical function [66];
- a leucine-enriched WP supplement with vitamin D (20 g + 800 IU, twice a day for 13 weeks) was tested versus an iso-caloric dietary supplement, and was superior to placebo in improving muscle mass and lower-extremity function among a large cohort of 380 sarcopenic older adults, even in patients who were unable to exercise [67];
- the association of physical activity with a daily supplementation consisting of WP (22 g), essential amino acids (10.9 g including 4 g of leucine) and vitamin D (100 IU) was more effective than physical activity plus placebo in increasing fat free mass and muscle strength, in improving quality of life and in decreasing inflammation index in 130 sarcopenic elderly people [68];
- the combination of regular resistance muscle training with a nutrition therapy based on an oral supplement offered twice daily (containing 20 g WP, 9 g carbohydrates, 3 g fat, 800 IU vitamin D, and a mixture of vitamins, minerals, and fibers per serving) was superior to exercise alone in improving muscle mass and strength, in 34 elderly patients at high risk of sarcopenia [69];
- the combination of RE with different isocaloric shakes containing 12 g of milk protein or 12 g of soy proteins versus placebo (rice milk, considered as non-protein control) had a positive effect on muscle mass, independently from the type of protein source (milk or soy), among 26 sarcopenic men. The same intervention study among 26 overweight sarcopenic men resulted in a decrease in fat mass only in the dairy supplemented group [70,71].
3.3. Bones (12 Studies)
3.4. Cardiovascular Diseases (Eight Studies)
3.5. Protein Intake and Metabolism (Seven Studies)
3.6. Inflammation Markers (Seven Studies)
3.7. Chronic Obstructive Pulmonary Disease (Four Studies)
3.8. Neurocognitive Function (Four Studies)
3.9. Response to Vaccines (Two Studies)
3.10. Miscellanea (5 Studies)
4. Discussion
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Author, Year | Number Participants, Gender | Age (Mean or Range) | Type of Study: Intervention Arms | Main Endpoints | Results |
---|---|---|---|---|---|
Paddon-Jones, 2006 [30] | 14, 7 ♀/7 ♂ | 68 | RCT: 15 g WP vs. 15 g EAA | Muscle FSR for 3.5 h after ingestion | Both supplementations stimulated FSR, with greater increase in EAA arm |
Katsanos, 2008 [31] | 15, 6 ♀/9 ♂ | 60–85 | RCT: 15 g WP vs. 6.72 g WP’s EAA vs. 7.57 WP’s Non-EAA | blood phenylalanine, insulin, glucose concentration, muscle biopsy | WP improves MP accrual through mechanisms beyond its EAA content |
Koopman, 2009 [32] | 10, ♂ (cross over) | 64 | Case-control study: 35 g intact casein vs. 35 g hydrolyzed casein | blood phenylalanine concentration, muscle biopsy (FSR) | Hydrolysate accelerates protein digestion and absorption, increase AA availability and FSR |
Pennings, 2011 [33] | 48, ♂ | 74 | RCT: 20 g WP vs. 20 g casein vs. 20 g casein hydrolysate | Postprandial Muscle FSR | MP accretion more effective in WP arm |
Burd, 2012 [34] | 14, ♂ | 71 | RCT: 20 g micellar casein vs. 20 g WP | Rate of MPS at rest and after exercise | Greater rates of MPS in WP arm |
Groen, 2012 [35] | 16, ♂ | 74 | RCT: intra-gastric administration during sleep of 400 mL of water with vs. without 40 g casein | BPB, MPS | Casein administration during sleep improves BPB and stimulates MPS |
Pennings, 2012 [36] | 33, ♂ | 73 | RCT: 10 g vs. 20 g vs. 35 g WP | AA absorption, BPB, MPA | 35 g WP reaches best values in all endpoints |
Wall, 2013 [37] | 24, ♂ | 74 | RCT: 20 g casein vs. 20 g casein + 2.5 g leucine | MPA | Leucine co-ingestion improves MPA |
Luiking, 2014 [38] | 19, 10 ♀/9 ♂ | 69 | RCT: 20 g WP vs. 6 g milk protein, both arms after unilateral resistance exercise | MPS | Higher MPS with WP, without further enhance with exercise |
Churchward-Venne, 2015 [39] | 32, ♂ | 71 | Parallel group study: 25 g casein in milk matrix vs. 25 g casein in water | Post-prandial MPS | Milk matrix delays casein digestion and absorption without affecting MPS |
Borack, 2016 [40] | 20, ♂ | 55–75 | RCT: 30 g WP isolate vs. 30 g soy-dairy protein blend (25% soy, 25% WP and 50% casein); both arms after resistance exercise | Blood and muscle AA concentration; FSR | No differences in endpoints among arms |
Gorissen, 2016 [41] | 60, ♂ | 71 | RCT: 35 g WhP vs. 35 g WhPH, vs. 35 g micellar casein vs. 35 g WP vs. 35 g WPH vs. 60 g WhP | Post-prandial AA concentration and MPS | Greater AA concentration after WP, greater MPS after micellar casein |
Walrand, 2016 [42] | 31, ♂ | 72 | RCT: 10-day period of AP or HP diet followed by ingestion of 15 g or 30 g casein vs. 15 g or 30 g of soluble milk proteins | FSR | Greater increase in FSR after ingestion of soluble milk proteins only in the AP group |
Kouw, 2017 [43] | 48, ♂ | 72 | RCT: before sleep administration of 40 g casein vs. 20 g casein vs. 20 g casein + 1.5 g leucine vs. placebo | MPS | Ingestion of 40 g casein increases MPS better than other arms |
Hamarsland, 2019 [44] | 21, 8 ♀/13 ♂ | 74 | RCT: 20 g WP vs. 20 g native WP vs. milk (ingested after 2 h of resistance training) | Serum leucine concentration; FSR | Greater increase in serum leucine in native WP arm, but no difference with WP in FSR (only superior to milk) |
Author, Year | Number Participants, Gender | Age (Mean or Range) | Duration | Intervention Arms | Main Endpoints | Results |
---|---|---|---|---|---|---|
Dideriksen 2011 [52] | 24, 9 ♀/15 ♂ | 68 | acute supplementation | RE + WP (0.45 g/kg) vs. RE + caseinate (0.45 g/kg) | MPS | Increase in MPS, no difference between arms |
Yang 2012 [53] | 37 ♂ | 71 | acute supplementation | WP 0 g, 10 g, 20 g or 40 g vs. WP same doses + RE | MPS | RE increases MPS at all WP doses with greater extent with 40 g WP |
Arnarson 2013 [54] | 161, 94 ♀/67 ♂ | 65–91 | 12 weeks | RE + WP (20 g) vs. RE + isocaloric CHO | Lean body mass, strength, physical function | Increase in all endpoints, no difference between arms |
Gryson 2014 [55] | 48, ♂ | 61 | 16 weeks (sedentary) | MET + total milk proteins (10 g) vs. MET + soluble milk proteins rich in leucine (10 g) | Muscle mass and strength, time to task failure, index of muscle fatigue | Better results in all endpoints with soluble milk proteins + after MET |
Karelis 2015 [56] | 99, 76 ♀/23 ♂ | 65–88 | 135 days | 20 g of cysteine enrich-WP vs. 20 g casein (both arms in combination with RT) | Body composition (DXA), muscle strength | Muscle strength increases in both arms, additional increasing WP arm |
Weisgarber 2015 [57] | 12, ♀ | 57 | 10 weeks | RE (high volume) + WP (40 g) vs. RE + placebo | Lean tissue mass, muscle thickness, muscle strength | Increase in muscle thickness and strength, but no difference between arms |
Thomson 2016 [58] | 179, 99 ♀/80 ♂ | 62 | 12 weeks | RE + high dairy protein (1.2 g/kg) vs. RE +high soy protein (1.2 g/kg) vs. RE + usual protein intake (<1.2 g/kg) | Muscle strength, body composition, physical function, quality of life | Increase in lean mass, physical function and mental health in all arms, increase in strength attenuated in soy arm |
Mori 2018 [59] | 81, ♀ | 65–80 | 24 weeks | RE + WP (22.3 g/day) vs. RE alone vs. WP alone | Muscle mass, physical function | Higher improvement in all endpoints in RE + WP arm |
Sugihara 2018 [60] | 31, ♀ | 67 | 12 weeks | RE + WP (35 g) vs. RE + placebo | Muscle strength, hypertrophy, muscle quality | Higher increase in muscle strength and hypertrophy in RE + WP |
Author, Year | Number Participants, Gender | Age Mean and/or Range | Duration | Intervention Arms | Main Endpoints | Results |
---|---|---|---|---|---|---|
Khalil 2002 [83] | 17, ♂ | 65–84 | 3 months | Daily supplementation of 40 g SP vs. 40 g MP | Bone specific ALP activity, urinary deoxypyridinoline excretion | No endpoint difference among arms |
Holm 2008 [84] | 29, ♀ Postmenopausal | 55 | 24 weeks | 10 g WP + 31 g CHO + 1 g fat + 5 mcg vitamin D + 250 mg calcium vs. 6 g CHO + 12 mg calcium; both arms with ST | BMD with DXA, Osteocalcin, CTx | Increase in BMD and osteocalcin in WP multi-ingredient arm |
Adolphi 2009 [85] | 85, ♀ postmenopausal | 59 (48–67) | 2 weeks | Bedtime consumption of 175 mL Fm vs. 175 mL Fm + 510 mg Calcium vs. Fm+ 510 mg calcium + 0.175 g CPP + 1.75 g ITF | Nocturnal bone resorption markers | Fm reduced bone resorption independently of further supplementation |
Chevallley 2010 [86] | 45, ♀ (recent hip fracture) | 81 | 1 week | Daily supplementation of 20 g casein vs. 15 g WP vs. 5 g EAA | Elevation of circulating IGF-1 | Increase in IGF-1 in casein arm supplementation |
Zhu 2011 [87] | 219, ♀ | 70–80 | 2 years | Daily supplementation of a drink with 30 g WP vs. placebo | BMD with DXA and QCT. IGF-1 level, urinary calcium excretion | Increase in IGF-1 at year 1 and 2 in WP arm, but no effect on bone mass or strength |
Kerstetter 2015 [88] | 208, 178 ♀/30 ♂ | 70 | 18 months | Supplementation of 45 g WP vs. isocaloric placebo | BMD with DXA, fat free mass | No difference in BMD, better preservation of fat free mass in WP arm |
Author, Year | Study Type | Intervention | Main Endpoints | Results | Brief Comment |
---|---|---|---|---|---|
Numan 2007 [138] | Pilot study | Anti-Clostridium difficile WP concentrate | Prevention of relapse of Clostridium difficile infection | 10% relapse rate in comparison to 20–25% relapse rate in a control contemporary cohort | Waiting for confirmation in RCT |
Coker 2012 [139] | RCT during caloric restriction | Meal replacement with WP and EAA vs. a standard meal replacement | Weight loss preserving lean tissue (muscle mass) | WP + EAA was effective in weight reduction promoting preferential reduction of adipose tissue | Small sample size (12 subjects) |
Ooi 2015 [140] | RCT | 30 g WP supplementation vs. a high CHO energy match supplementation | Weight reduction and reduction of hepatic steatosis in women | No difference in weight reduction or hepatic steatosis | WP supplementation may reduce hepatic steatosis despite weight gain |
Dhillon 2017 [141] | RCT crossover design | WP isolate (50 g) vs. soy protein isolate (50 g) | Bioavailability of folates and Vitamin B12 in elderly with subclinical deficiencies | WP isolate was superior to soy in improving active B12 and folate status | - |
Song 2018 [142] | Blind sensory analysis | Rye bread and cream cheese enriched with:
| Consumer acceptance | Better acceptance of WP hydrolysate in bread and of WP isolate in cheese | Developing protein enriched food may increase protein intake in elderly but innovation in protein enriched appealing food is challenging |
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Zanini, B.; Simonetto, A.; Zubani, M.; Castellano, M.; Gilioli, G. The Effects of Cow-Milk Protein Supplementation in Elderly Population: Systematic Review and Narrative Synthesis. Nutrients 2020, 12, 2548. https://doi.org/10.3390/nu12092548
Zanini B, Simonetto A, Zubani M, Castellano M, Gilioli G. The Effects of Cow-Milk Protein Supplementation in Elderly Population: Systematic Review and Narrative Synthesis. Nutrients. 2020; 12(9):2548. https://doi.org/10.3390/nu12092548
Chicago/Turabian StyleZanini, Barbara, Anna Simonetto, Matilde Zubani, Maurizio Castellano, and Gianni Gilioli. 2020. "The Effects of Cow-Milk Protein Supplementation in Elderly Population: Systematic Review and Narrative Synthesis" Nutrients 12, no. 9: 2548. https://doi.org/10.3390/nu12092548
APA StyleZanini, B., Simonetto, A., Zubani, M., Castellano, M., & Gilioli, G. (2020). The Effects of Cow-Milk Protein Supplementation in Elderly Population: Systematic Review and Narrative Synthesis. Nutrients, 12(9), 2548. https://doi.org/10.3390/nu12092548