Hostname: page-component-78c5997874-v9fdk Total loading time: 0 Render date: 2024-11-04T19:50:21.734Z Has data issue: false hasContentIssue false
  • English
  • Français

Associations of protein intake, sources and distribution on muscle strength in community-dwelling older adults living in Auckland, New Zealand

Published online by Cambridge University Press:  23 August 2023

Anne N. Hiol Open the ORCID record for Anne N. Hiol [Opens in a new window] ,
Pamela R. von Hurst ,
Cathryn A. Conlon  and
Kathryn L. Beck Open the ORCID record for Kathryn L. Beck [Opens in a new window]
Anne N. Hiol
Affiliation:
School of Sport, Exercise and Nutrition, Massey University, North Shore City 0632, New Zealand
Pamela R. von Hurst
Affiliation:
School of Sport, Exercise and Nutrition, Massey University, North Shore City 0632, New Zealand
Cathryn A. Conlon
Affiliation:
School of Sport, Exercise and Nutrition, Massey University, North Shore City 0632, New Zealand
Kathryn L. Beck*
Affiliation:
School of Sport, Exercise and Nutrition, Massey University, North Shore City 0632, New Zealand
*
*Corresponding author: Kathryn Beck, Email [email protected]

Abstract

Protein intake, sources and distribution impact on muscle protein synthesis and muscle mass in older adults. However, it is less clear whether dietary protein influences muscle strength. Data were obtained from the Researching Eating Activity and Cognitive Health (REACH) study, a cross-sectional study aimed at investigating dietary patterns, cognitive function and metabolic syndrome in older adults aged 65–74 years. Dietary intake was assessed using a 4-d food record and muscle strength using a handgrip strength dynamometer. After adjusting for confounders, in female older adults (n 212), total protein intake (β = 0⋅22, P < 0⋅01); protein from dairy and eggs (β = 0⋅21, P = 0⋅03) and plant food sources (β = 0⋅60, P < 0⋅01); and frequently consuming at least 0⋅4 g/kg BW per meal (β = 0⋅08, P < 0⋅01) were associated with higher BMI-adjusted muscle strength. However, protein from meat and fish intake and the coefficient of variance of protein intake were not related to BMI-muscle strength in female older adults. No statistically significant associations were observed in male participants (n = 113). There may be sex differences when investigating associations between protein intake and muscle strength in older adults. Further research is needed to investigate these sex differences.

Keywords

Muscle strengthOlder adultsProtein distributionProtein intakeProtein sources
Type
Research Article
Information
Journal of Nutritional Science , Volume 12 , 2023 , e94
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Introduction

Proteins are the most abundant component of skeletal muscle mass. Approximately 40 % of the body weight of a healthy adult weighing 70 kg is skeletal muscle mass, which is composed of about 20 % muscle protein(Reference Frontera and Ochala1). With aging, the muscle's ability to stimulate protein synthesis is reduced, leading to a decline in muscle mass in older adults(Reference Colley, Garriguet and Janssen2Reference Volpi, Sheffield-Moore and Rasmussen4). The loss of muscle mass is suggested to be a key contributor to the decrease in muscle strength observed with age, and low muscle strength is recognised as the single largest intrinsic risk factor for falls(Reference Frontera, Hughes and Fielding5,Reference Newman, Kupelian and Visser6) .

The cause of muscle protein synthesis (MPS) impairment with aging is unknown, but it is assumed to be affected by impairments in several physiological processes(Reference Burd, Gorissen and Van Loon7Reference Boirie, Gachon and Beaufrère12). It was initially thought that a reduced rate of amino acid absorption into the bloodstream and/or digestibility in the stomach and the small intestine may limit the availability of amino acids for MPS(Reference Volpi, Mittendorfer and Wolf11,Reference Boirie, Gachon and Beaufrère12) . Further research suggested that a decline in amino acid transporters, which mediate the transfer of amino acids into and out of cells, may decrease amino acids that are delivered to the muscle and their subsequent uptake by the muscle(Reference Dickinson, Drummond and Coben8Reference Timmerman, Lee and Dreyer10). Amino acid transfer and availability are both regulated by the quality and quantity of protein consumed per meal and per day.

The quality of protein in various foods is determined by their essential amino acid composition, total amount of each amino acid and relative ease of digestion in the stomach and small intestine, as well as absorption. High-quality animal proteins (e.g., meat, fish, dairy and eggs) have a greater ability to enhance MPS and increase muscle mass than plant-based proteins (e.g., soya, pea and wheat)(Reference Gorissen, Horstman and Franssen13Reference Yang, Churchward-Venne and Burd16). Isanejad et al. reported higher total and animal (but not plant) protein intakes were associated with greater muscle strength in women aged 65–71 years(Reference Isanejad, Mursu and Sirola17). These findings were subsequently confirmed in women and men by McLean et al. (Reference McLean, Mangano and Hannan18). However, these studies did not consider whether the source of animal protein, i.e., meat, fish, dairy or eggs, makes any difference. In terms of protein quality properties, not all animal-based protein sources are the same. Leucine, for instance, makes up 10⋅9 % of all essential amino acids in milk proteins, compared to 8⋅8 % in beef proteins; and compared to beef/fish, egg proteins have the highest value for protein digestibility(Reference van Vliet, Burd and van Loon15,Reference Smith and Gray19,Reference Schaafsma20) . A highly digestible protein source offers a higher proportion of absorbed amino acids, whereas a higher leucine content indicates that less protein from a given source is necessary to maximise MPS rates(Reference Lynch21,Reference Garlick22) . As a result, the association between muscle strength and animal proteins may depend on the type of animal protein being consumed.

In older adults, a protein intake of 0⋅4 g/kg body weight (BW) per meal has been found to provide a pool of available amino acids that stimulate muscle protein maximally(Reference Moore and Soeters23,Reference Paddon-Jones and Rasmussen24) . Therefore, it is hypothesised that eating three meals per day, with a regular protein intake of 0⋅4 g/kg BW per meal, could increase MPS throughout the day, potentially increasing and preserving muscle strength in older adults. In a randomised controlled trial, Mamerow et al. demonstrated that, in healthy adults aged 25–55 years, MPS was approximately 25 % higher in those with an even distribution of daily protein intake (0⋅4 g/kg BW per meal) compared with those who had a skewed meal distribution but the same amount of daily protein (1⋅2 g/kg BW per day)(Reference Mamerow, Mettler and English25). The distribution of protein is a relatively new concept. In previous studies, distribution is estimated as the coefficient of variance (CV) of the protein intake or the number of meals exceeding 0⋅4 g/kg BW. There are conflicting findings regarding the influence of protein distribution on muscle strength, which could be impeded by different distribution calculations.

The aim of this study was to examine protein intake, sources and different estimates of protein distribution throughout the day and associations with muscle strength, in community-living older adults in Auckland, New Zealand (NZ).

Materials and methods

Study design

Data for this study were obtained from Researching Eating, Activity and Cognitive Health (REACH) study; the methodology has been described elsewhere(Reference Mumme, von Hurst and Conlon26). In brief, REACH participants were adults aged between 65 and 74 years, proficient in English, and living independently (i.e., not in residential care) in Auckland, NZ. Ineligibility criteria included a diagnosis of dementia or any condition which may impair cognitive function (e.g., previous head injury, stroke), taking medication which may influence cognitive function, colour blindness (due to cognitive testing requirements) or experiencing any other event in the last 2 years which may have had a substantial impact on dietary intake or cognition.

The research protocol was approved by the Massey University Human Ethics Committee: Southern A, Application 17/69 and all participants provided written informed consent.

Data collection

Age, sex, polypharmacy and smoking data were collected using a health and demographic written questionnaire. Physical activity was assessed through the International Physical Activity Questionnaire – short form(Reference Craig, Marshall and Sjöström27). A physical activity score was calculated using the metabolic equivalent of a task (MET-min) where 1 min of walking, moderate or vigorous activity equates to 3⋅3, 4⋅0 or 8⋅0 METs, respectively(Reference Craig, Marshall and Sjöström27). Polypharmacy was defined as five or more daily medications, and smoking was described as both current and previous smoking(Reference Masnoon, Shakib and Kalisch-Ellett28).

Weight (in cm, to the nearest 0⋅1 cm) was measured using a stadiometer (SECA). BW (in kg, to the nearest 0⋅1 kg) was assessed using floor scales (Wedderburn). Body mass index (BMI) was calculated as weight in kilograms divided by height in metres squared.

Muscle strength was assessed using an adjustable handgrip strength dynamometer (JAMAR HAND). The handgrip dynamometer measures the maximum kilograms of force per trial, where three trials were undertaken for each of the right and left hands with a 15–20 s break between trials(Reference Roberts, Denison and Martin29,Reference Mathiowetz, Kashman and Volland30) . The mean of three trials for each hand was noted and the highest value of the two means was considered the final value. Because the Foundation for the National Institutes of Health (FNIH) showed that BMI-standardised handgrip strength is more strongly associated with falls and related injuries than absolute handgrip strength, we used handgrip strength adjusted for BMI(Reference Tang, Hwang and Liu31). Low muscle strength was defined as BMI-handgrip strength <1⋅00 m2 in men and <0⋅56 m2 in women(Reference Cawthon, Peters and Shardell32).

Dietary intake data were collected using a 4-d food record. Participants were asked to write down everything they ate and drank for four consecutive days, including at least one weekend day. They were advised to describe the amount of food consumed using household measurements. The dietary data collection method has been described in detail elsewhere(Reference Hiol, von Hurst and Conlon33).

Data handling

Food record data were entered by trained nutritionists into FoodWorks 10, which is based on the New Zealand Food Composition database(34,Reference Sivakumaran, Huffman and Gilmore35) . Energy and macronutrient intake was generated as kilojoules and grams of intake per day, respectively. Relative protein intake was calculated by dividing the amount of protein (g) consumed by BW (kg).

Meals were categorised into ‘breakfast’, the ‘mid-day meal’ and the ‘evening meal’ based on the time of day at which protein was consumed. Protein in g and g/kg BW was calculated at breakfast, the mid-day meal and the evening meal. The consumption of 0⋅4 g/kg BW of protein at each meal was reported. Protein distribution was calculated for each participant as a:

  • – CV ( = standard deviation of protein intake of the three meals (g)/total protein intake for the three meals (g)). A CV of zero indicates that protein is distributed evenly throughout the day. The smaller the CV, the more even the distribution and,

  • – The frequency of consuming ≥0⋅4 g/kg BW of protein across the day's meal. This was calculated by adding the number of meals at which individuals consumed ≥0⋅4 g/kg BW of protein. The value for the frequency of protein consumption variable ranged from 1 to 3 (breakfast, the mid-day and the evening meal). A higher number represented a more even distribution.

All foods from the food records were allocated into one of 27 food groups based on the main sources of protein intake reported in the 2008/09 New Zealand Adult Nutrition Survey(36). The food groups were further classified under meat and fish; dairy and egg products; and plants according to the main type of protein they contained. Protein intake from meat and fish; dairy and egg products; and plants were calculated in g/kg BW.

Statistical analysis

All continuous variables were tested for normality with the Shapiro–Wilk test. Participant characteristics were displayed as median and interquartile range (IQR) for non-parametric continuous variables and as counts with percentages for categorical variables. Differences between groups were tested using the Mann–Whitney U test for non-normally distributed continuous data or the χ 2 test for categorical variables. Multiple regression analysis was performed separately in females and males to examine associations between BMI-muscle strength (dependent variable) and:

  • – Relative protein intake g/kg BW per day. The confounding variables were energy intake (kJ), physical activity level (MET-min/week), age (years), polypharmacy status (yes or no) and smoking status (yes or no).

  • – Protein from meat and fish (g/kg BW); dairy and egg products (g/kg BW); and plants (g/kg BW). These models accounted for the effects of energy intake (kJ), physical activity level (MET-min/week), age (years), polypharmacy status (yes or no) and smoking status (yes or no). For these models, protein intakes from meat and fish; dairy and egg products; and plants were included in the same regression model to adjust for one another.

  • – Different estimates of protein distribution throughout the day (CV and frequency consuming of meals containing ≥0⋅4 g/kg BW of protein per day). The models were controlled for total protein intake (g), energy intake (kJ), physical activity level (MET-min/week), age (years), polypharmacy status (yes or no) and smoking status (yes or no).

All statistical analyses were performed using IBM SPSS Statistics for Windows, version 27.0 (IBM SPSS, Armonk, NY, USA). All the probability values were two-tailed and were considered significant if a P-value was <0⋅05.

Results

A total of 371 individuals participated in the REACH study. We excluded individuals who did not provide or had incomplete variables such as food records (n 44), handgrip strength (n 1) and physical activity (n 1). The final data set included 325 older adults (113 males and 212 females). Table 1 presents descriptive statistics according to sex for the study population. There were no significant differences between males and females in physical activity (P = 0⋅88), polypharmacy (P = 0⋅31) or smoking status (P = 0⋅93). Females were younger (P < 0⋅01) and had a lower height (P < 0⋅01), weight (P < 0⋅01), BMI (P = 0⋅02) and BMI-muscle strength (P < 0⋅01) compared with males. Males had a higher prevalence of low BMI-muscle strength (4⋅4 %) than females (3⋅8 %).

Table 1. Participants’ characteristics

aCategorical values are expressed as frequency (percentage). Differences between groups were tested using the Mann–Whitney U test for non-normally distributed continuous data or the χ 2 test for categorical variables. Sex difference at **P < 0⋅01, *P < 0⋅05.

bContinuous values are expressed as median (25th, 75th percentile).

Table 2 shows the median protein intake, distribution and sources for both females and males. Females consumed significantly less energy (P < 0⋅01), carbohydrate (P < 0⋅01), fat (P < 0⋅01) and absolute protein (P < 0⋅01) than males. Females had a similar relative protein intake per day (1⋅1 (0⋅9, 1⋅3) g/kg BW) to males (1⋅2 (0⋅9, 1⋅4) g/kg BW) (P = 0⋅38).

Table 2. Median protein intake, distribution and sources

aContinuous values are expressed as median (25th, 75th percentile).

bCategorical values are expressed as frequency (percentage). Sex difference at **P < 0⋅01, *P < 0⋅05.

The evening meal provided the highest median protein intake (g/kg BW) at 0⋅5 (0⋅3, 0⋅7), followed by the mid-day meal at 0⋅3 (0⋅2, 0⋅4), and breakfast at 0⋅3 (0⋅2, 0⋅3). Protein distribution was uneven throughout the day as indicated by a median CV for protein distribution of 0⋅5 (0⋅3, 0⋅6) for both males and females. When comparing individual meals to the 0⋅4 g/kg threshold, 5 % of females and 5 % of males met the threshold for all three meals. Males and females had a median protein intake (g/kg BW) of 0⋅4 (0⋅3, 0⋅6) from plant sources, 0⋅4 (0⋅3, 0⋅5) from meat and fish sources, and 0⋅3 (0⋅2, 0⋅4) from dairy and egg sources.

Table 3 shows the association of relative protein intake, sources and distribution on BMI-muscle strength in females. Relative protein intake was positively associated with BMI-muscle strength (β = 0⋅22, P < 0⋅01). Protein from dairy and egg products (β = 0⋅21, P = 0⋅03), as well as plant proteins (β = 0⋅60, P < 0⋅01), but not with proteins from meat and fish (β = 0⋅04, P = 0⋅55) was positively associated with BMI-muscle strength. The CV was not significantly associated with BMI-muscle strength (β = −0⋅05, P = 0⋅47), whereas meal frequency of 0⋅4 g/kg BW was significantly associated with BMI-muscle strength (β = 0⋅08, P < 0⋅01).

Table 3. Association between protein intake and muscle strength in females

CV, coefficient of variance of protein intake (g) at breakfast, mid-day meal and evening meal.

Significant at **P < 0⋅01, *P < 0⋅05.

Table 4 shows there was no relationship between total protein intake (β = 0⋅11, P = 0⋅23), proteins from meat and fish (β = 0⋅06, P = 0⋅65), from dairy and egg products (β = 0⋅00, P = 0⋅99) or plant proteins (β = 0⋅32, P = 0⋅10) and BMI-muscle strength in males. No association was observed CV of protein across main meals (β = −0⋅21, P = 0⋅12) and number of meals containing at least 0⋅4 g of protein/kg BW (β = −0⋅05, P = 0⋅35) and BMI-muscle strength in males.

Table 4. Association between protein intake and muscle strength in males

CV, coefficient of variance of protein intake (g) at breakfast, mid-day meal and evening meal. Significant at **P < 0⋅01, *P < 0⋅05.

Discussion

In this cross-sectional study, we investigated the relationship between protein intake, sources and distribution and BMI-muscle strength in females and males older adults living in Auckland, NZ. In females, the findings indicate that BMI-muscle strength was associated with relative protein intake. This relationship was independent of total energy intake, age, physical activity, smoking and polypharmacy status. We also demonstrated an association of protein intake from dairy, eggs and plant sources; but not with protein from meat and fish intake and BMI-muscle strength. We found the CV of protein intake was not related to BMI-muscle strength. However, we demonstrated that a greater frequency of protein consumption of 0⋅4 g/kg BW per meal was associated with BMI-muscle strength. In male older adults, there were no associations between protein intake, sources or distribution and BMI-muscle strength.

Associations of protein intake, sources and distribution on BMI-muscle strength in females

We provide evidence that relative protein intake is positively associated with BMI-muscle strength in females older adults aged between 65 and 74 years. Our findings are consistent with previous cross-sectional studies indicating an association between relative protein intake and muscle strength adjusted by BW or BMI in older adults(Reference Celis-Morales, Petermann and Steell37Reference Isanejad, Mursu and Sirola39). In contrast, other studies found that there was no association between relative protein intake and muscle strength(Reference Ten Haaf, van Dongen and Nuijten40Reference Mishra, Goldman and Sahyoun42). One explanation for their lack of associations could be related to not adjusting muscle strength for BW or BMI.

Muscle strength-adjusted BMI or BMI-muscle strength has been proposed as the ideal marker for muscle strength because it minimises the confounding effect of BW(Reference Kim, Jeon and Jeong43Reference Keevil, Luben and Dalzell46). Furthermore, low BMI-muscle strength represents not only low muscle strength but also obesity, both of which are closely related to impairment of MPS in response to ingested protein(Reference Kim, Jeon and Jeong43Reference Murton, Marimuthu and Mallinson49). In this regard, we used BMI-muscle strength and demonstrated a relationship between relative dietary protein and muscle strength in females older adults.

In multiple regression analysis, examining associations between protein sources and BMI-muscle strength, dairy and egg proteins (but not meat and fish) were found to be positively associated with BMI-muscle strength. Because the amount of protein consumed from both animal food group sources was comparable, these findings suggest that the protein quality properties of dairy and eggs, which have a higher leucine content and higher value for protein digestibility than meat and fish proteins, may explain the association found in this study. In contrast to previous research(Reference Isanejad, Mursu and Sirola17,Reference McLean, Mangano and Hannan18) , an association of protein from plant sources on BMI-muscle strength was observed. The differences in findings could be attributed to differences in the amount of plant protein consumed. Participants in this cohort consumed a similar amount of protein from both animal and plant-based sources, whereas in other studies, the range of plant-based protein sources was much smaller.

When calculating the distribution of protein using the CV calculation, we found no association between the CV and BMI-muscle strength in females and male older adults. This result aligns with the literature(Reference Ten Haaf, van Dongen and Nuijten40,Reference Bollwein, Diekmann and Kaiser50Reference Kim, Schutzler and Schrader52) and suggests that the CV might give information about the distribution of protein, but it does not provide information about the amount of protein consumed. Murphy et al. also demonstrated that MPS responses were not different in older adults subjected to uneven or even distribution(Reference Murphy, Churchward-Venne and Mitchell53). Given this, the consumption of meals containing less than 0⋅4 g/kg BW, required for maximal MPS in older adults may help to explain this finding. We demonstrated a positive association between the frequency of meals of ≥0⋅4 g/kg BW and BMI-muscle strength in female older adults. Two recent studies also investigated associations between muscle strength and consuming at least 0⋅4 g/kg BW in older adults(Reference Gingrich, Spiegel and Kob51,Reference Johnson, Kotarsky and Mahoney54) . While both studies did not adjust muscle strength for BMI, Johnson et al. did account for BMI in their multiple regression analyses and found an association between absolute muscle strength and consuming at least 0⋅4 g/kg BW in females older adults(Reference Johnson, Kotarsky and Mahoney54). Gingrich et al., on the other hand, found no relationship between the number of meals providing 0⋅4 g/kg BW and muscle strength(Reference Gingrich, Spiegel and Kob51). However, BMI and sex differences were not considered in their analysis. These findings confirm that the conflicting findings on the influence of protein distribution on muscle strength are impeded by different protein distribution calculations. In the wider literature, it is necessary to reach an agreement on an appropriate protein distribution calculation.

Associations of protein intake, sources and evenness distribution on BMI-muscle strength in males

There was no association of protein intake, sources or distribution on BMI-muscle strength in older male adults. Males have a greater anabolic response to protein intake with greater muscle strength than females. Consequently, males may require more protein in order to develop greater muscle strength than do females. In this population male protein intake was comparable to females, which may explain the association between muscle strength and relative protein intake in females but not males.

One of the main strengths of this study was the use of BMI-muscle strength, which has been shown to be more strongly associated with composite adverse outcomes such as falls compared with absolute muscle strength(Reference Tang, Hwang and Liu31). An additional strength was the use of food records, which is considered the gold standard of dietary assessment methods due to their accuracy in estimating actual dietary intakes(Reference Gibson55). Relative protein intake was used to account for differences in BW, and particularly weight differences between sexes in older adults(Reference Moore56). In addition, several variables related to protein intake (quantity, sources and distribution) were addressed concurrently in this study. Finally, adjustments were made for age, total energy intake, physical activity, polypharmacy and smoking status, all of which are important potential confounders in the relationship between muscle strength and dietary intake. Total protein intake was adjusted for when considering the distribution of protein consumed throughout the day. The study's limitations include its cross-sectional design, which limited its ability to detect causality; thus, only associations can be discussed.

Conclusions

In this study, we demonstrated that females older adults who consumed a high relative protein intake and frequently consumed higher amounts of protein at each meal had increased BMI-muscle strength. Protein from dairy and eggs, as well as plant sources, was associated with BMI-muscle strength, but not protein from meat and fish. In male older adults, however, there was no association of protein intake, sources or distribution between BMI-muscle strength. These results indicate that there may be sex differences when investigating associations between dietary protein quantity, sources and distribution and muscle strength. Future research should investigate the factors that contribute to the sex differences in this relationship.

Acknowledgments

We thank the REACH team, including Owen Mugridge and Cassie Slade for managing recruitment and data collection; Cherise Pendergrast, Kimberley Brown, Karen Mumme, Harriet Guy, Angela Yu and Nicola Gillies for assistance with data collection and data entry.

Funding was provided by a Health Research Council of New Zealand Emerging Researcher Grant 17/566 – Beck: Optimising cognitive function: the role of dietary and lifestyle patterns. The funders have no role in the design of the study; collection, analysis and interpretation of the data; writing manuscripts or publishing results.

K.L.B., P.R.v.H. and C.A.C. conceptualized the whole article; A.N.H., K.L.B., P.R.v.H. and C.A.C. developed the methodology; A.N.H. conducted a formal analysis; A.N.H., K.L.B., P.R.v.H. and C.A.C. rendered support in investigation; A.N.H. wrote the original draft; K.L.B., P.R.v.H. and C.A.C. wrote the review and edited the article; K.L.B., P.R.v.H. and C.A.C. supervised the work; K.L.B., P.R.v.H. and C.A.C. administered the project; K.L.B., P.R.v.H. and C.A.C. conducted funding acquisition. All authors have read and agreed to the published version of the manuscript.

Conflicts of interest

The authors declare no conflict of interest. The funders have no role in the design of the study; in the collection, analyses or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

References

Frontera, WR & Ochala, J (2015) Skeletal muscle: a brief review of structure and function. Calcif Tissue Int 96, 183195.CrossRefGoogle ScholarPubMed
Colley, RC, Garriguet, D, Janssen, I, et al. (2011) Physical activity of Canadian adults: accelerometer results from the 2007 to 2009 Canadian health measures survey. Health Rep 22, 714.Google ScholarPubMed
Fujita, S, Rasmussen, BB, Cadenas, JG, et al. (2007) Aerobic exercise overcomes the age-related insulin resistance of muscle protein metabolism by improving endothelial function and Akt/mammalian target of rapamycin signaling. Diabetes 56, 16151622.CrossRefGoogle ScholarPubMed
Volpi, E, Sheffield-Moore, M, Rasmussen, BB, et al. (2001) Basal muscle amino acid kinetics and protein synthesis in healthy young and older men. JAMA 286, 12061212.CrossRefGoogle Scholar
Frontera, WR, Hughes, VA, Fielding, RA, et al. (2000) Aging of skeletal muscle: a 12-yr longitudinal study. J Appl Physiol 88, 13211326.CrossRefGoogle ScholarPubMed
Newman, AB, Kupelian, V, Visser, M, et al. (2003) Sarcopenia: alternative definitions and associations with lower extremity function. J Am Geriatr Soc 51, 16021609.CrossRefGoogle ScholarPubMed
Burd, NA, Gorissen, SH & Van Loon, LJ (2013) Anabolic resistance of muscle protein synthesis with aging. Exerc Sport Sci Rev 41, 169173.CrossRefGoogle ScholarPubMed
Dickinson, JM, Drummond, MJ, Coben, JR, et al. (2013) Aging differentially affects human skeletal muscle amino acid transporter expression when essential amino acids are ingested after exercise. Clin Nutr 32, 273280.CrossRefGoogle ScholarPubMed
Rasmussen, BB, Fujita, S, Wolfe, RR, et al. (2006) Insulin resistance of muscle protein metabolism in aging. FASEB J 20, 768769.CrossRefGoogle ScholarPubMed
Timmerman, KL, Lee, JL, Dreyer, HC, et al. (2010) Insulin stimulates human skeletal muscle protein synthesis via an indirect mechanism involving endothelial-dependent vasodilation and mammalian target of rapamycin complex 1 signaling. J Clin Endocrinol Metab 95, 38483857.CrossRefGoogle ScholarPubMed
Volpi, E, Mittendorfer, B, Wolf, SE, et al. (1999) Oral amino acids stimulate muscle protein anabolism in the elderly despite higher first-pass splanchnic extraction. Am J Physiol Endocrinol Metab 277, E513E520.CrossRefGoogle ScholarPubMed
Boirie, Y, Gachon, P & Beaufrère, B (1997) Splanchnic and whole-body leucine kinetics in young and elderly men. Am J Clin Nutr 65, 489495.CrossRefGoogle Scholar
Gorissen, SH, Horstman, AM, Franssen, R, et al. (2016) Ingestion of wheat protein increases in vivo muscle protein synthesis rates in healthy older men in a randomized trial. J Nutr 146, 16511659.CrossRefGoogle ScholarPubMed
Scherz, H, Senser, F, Souci, SW, et al. (2000) Food Composition and Nutrition Tables. Boca Raton, FL: CRC Press/Medpharm.Google Scholar
van Vliet, S, Burd, NA & van Loon, LJC (2015) The skeletal muscle anabolic response to plant- versus animal-based protein consumption. J Nutr 145, 19811991.CrossRefGoogle ScholarPubMed
Yang, Y, Churchward-Venne, TA, Burd, NA, et al. (2012) Myofibrillar protein synthesis following ingestion of soy protein isolate at rest and after resistance exercise in elderly men. Nutr Metab 9, 57.CrossRefGoogle ScholarPubMed
Isanejad, M, Mursu, J, Sirola, J, et al. (2015) Association of protein intake with the change of lean mass among elderly women: the osteoporosis risk factor and prevention – fracture prevention study (OSTPRE-FPS). J Nutr Sci 4, e41.CrossRefGoogle ScholarPubMed
McLean, RR, Mangano, KM, Hannan, MT, et al. (2016) Dietary protein intake is protective against loss of grip strength among older adults in the Framingham Offspring Cohort. J Gerontol A Biol Sci Med Sci 71, 356361.CrossRefGoogle ScholarPubMed
Smith, A & Gray, J (2016) Considering the benefits of egg consumption for older people at risk of sarcopenia. Br J Community Nurs 21, 305309.CrossRefGoogle ScholarPubMed
Schaafsma, G (2000) The protein digestibility–corrected amino acid score. J Nutr 130, 1865S1867S.CrossRefGoogle ScholarPubMed
Lynch, CJ (2001) Role of leucine in the regulation of mTOR by amino acids: Revelations from structure-activity studies. J Nutr 131, 861s865s.CrossRefGoogle ScholarPubMed
Garlick, PJ (2005) The role of leucine in the regulation of protein metabolism. J Nutr 135, 1553s1556s.CrossRefGoogle ScholarPubMed
Moore, DR & Soeters, PB (2015) The biological value of protein. Nestle Nutr Inst Workshop Ser 82, 3951.CrossRefGoogle ScholarPubMed
Paddon-Jones, D & Rasmussen, BB (2009) Dietary protein recommendations and the prevention of sarcopenia. Curr Opin Clin Nutr Metab Care 12, 8690.CrossRefGoogle ScholarPubMed
Mamerow, MM, Mettler, JA, English, KL, et al. (2014) Dietary protein distribution positively influences 24-h muscle protein synthesis in healthy adults. J Nutr 144, 876880.CrossRefGoogle ScholarPubMed
Mumme, KD, von Hurst, PR, Conlon, CA, et al. (2019) Study protocol: associations between dietary patterns, cognitive function and metabolic syndrome in older adults – a cross-sectional study. BMC Public Health 19, 535.CrossRefGoogle ScholarPubMed
Craig, CL, Marshall, AL, Sjöström, M, et al. (2003) International physical activity questionnaire: 12-country reliability and validity. Med Sci Sports Exerc 35, 13811395.CrossRefGoogle ScholarPubMed
Masnoon, N, Shakib, S, Kalisch-Ellett, L, et al. (2017) What is polypharmacy? A systematic review of definitions. BMC Geriatr 17, 110.CrossRefGoogle ScholarPubMed
Roberts, HC, Denison, HJ, Martin, HJ, et al. (2011) A review of the measurement of grip strength in clinical and epidemiological studies: towards a standardised approach. Age Ageing 40, 423429.CrossRefGoogle ScholarPubMed
Mathiowetz, V, Kashman, N, Volland, G, et al. (1985) Grip and pinch strength: normative data for adults. Arch Phys Med Rehabil 66, 6974.Google ScholarPubMed
Tang, TC, Hwang, AC, Liu, LK, et al. (2018) FNIH-defined sarcopenia predicts adverse outcomes among community-dwelling older people in Taiwan: results from I-Lan longitudinal aging study. J Gerontol A Biol Sci Med Sci 73, 828834.CrossRefGoogle ScholarPubMed
Cawthon, PM, Peters, KW, Shardell, MD, et al. (2014) Cutpoints for low appendicular lean mass that identify older adults with clinically significant weakness. J Gerontol A Biol Sci Med Sci 69, 567575.CrossRefGoogle ScholarPubMed
Hiol, AN, von Hurst, PR, Conlon, CA, et al. (2023, in press) Protein intake, distribution, and sources in community-dwelling older adults living in Auckland, New Zealand. J Nutr Health Aging.CrossRefGoogle Scholar
Xyris Pty Ltd (2019) FoodWorks 10 Premium, 10.0 edn, Brisbane, QLD, Australia: Xyris Pty Ltd.Google Scholar
Sivakumaran, S, Huffman, L & Gilmore, Z (2017) New Zealand FOODfiles 2016 manual. New Zealand Institute for Plant and Food Research Limited and Ministry of Health.Google Scholar
University of Otago and Ministry of Health (2011) A Focus on Nutrition: Key Findings of the 2008/09 New Zealand Adult Nutrition Survey. Wellington: Ministry of Health.Google Scholar
Celis-Morales, CA, Petermann, F, Steell, L, et al. (2018) Associations of dietary protein intake with fat-free mass and grip strength: a cross-sectional study in 146,816 UK biobank participants. Am J Epidemiol 187, 24052414.CrossRefGoogle ScholarPubMed
Fanelli Kuczmarski, M, Pohlig, RT, Stave Shupe, E, et al. (2018) Dietary protein intake and overall diet quality are associated with handgrip strength in African American and white adults. J Nutr Health Aging 22, 700709.CrossRefGoogle ScholarPubMed
Isanejad, M, Mursu, J, Sirola, J, et al. (2016) Dietary protein intake is associated with better physical function and muscle strength among elderly women. Br J Nutr 115, 12811291.CrossRefGoogle ScholarPubMed
Ten Haaf, DSM, van Dongen, EJI, Nuijten, MAH, et al. (2018) Protein intake and distribution in relation to physical functioning and quality of life in community-dwelling elderly people: acknowledging the role of physical activity. Nutrients 10, 506.CrossRefGoogle ScholarPubMed
Granic, A, Mendonça, N, Sayer, AA, et al. (2018) Low protein intake, muscle strength and physical performance in the very old: the Newcastle 85+ study. Clin Nutr 37, 22602270.CrossRefGoogle ScholarPubMed
Mishra, S, Goldman, JD, Sahyoun, NR, et al. (2018) Association between dietary protein intake and grip strength among adults aged 51 years and over: what we eat in America, national health and nutrition examination survey 2011–2014. PLoS One 13, e0191368.CrossRefGoogle ScholarPubMed
Kim, CR, Jeon, YJ & Jeong, T (2019) Risk factors associated with low handgrip strength in the older Korean population. PLoS One 14, e0214612.CrossRefGoogle ScholarPubMed
Kim, S, Leng, XI & Kritchevsky, SB (2017) Body composition and physical function in older adults with various comorbidities. Innov Aging 1, igx008.CrossRefGoogle ScholarPubMed
Villareal, DT, Banks, M, Siener, C, et al. (2004) Physical frailty and body composition in obese elderly men and women. Obes Res 12, 913920.CrossRefGoogle ScholarPubMed
Keevil, VL, Luben, R, Dalzell, N, et al. (2015) Cross-sectional associations between different measures of obesity and muscle strength in men and women in a British cohort study. J Nutr Health Aging 19, 311.CrossRefGoogle Scholar
Beals, JW, Skinner, SK, McKenna, CF, et al. (2018) Altered anabolic signalling and reduced stimulation of myofibrillar protein synthesis after feeding and resistance exercise in people with obesity. J Physiol 596, 51195133.CrossRefGoogle ScholarPubMed
Guillet, C, Delcourt, I, Rance, M, et al. (2009) Changes in basal and insulin and amino acid response of whole body and skeletal muscle proteins in obese men. J Clin Endocrinol Metab 94, 30443050.CrossRefGoogle ScholarPubMed
Murton, AJ, Marimuthu, K, Mallinson, JE, et al. (2015) Obesity appears to be associated with altered muscle protein synthetic and breakdown responses to increased nutrient delivery in older men, but not reduced muscle mass or contractile function. Diabetes 64, 31603171.CrossRefGoogle ScholarPubMed
Bollwein, J, Diekmann, R, Kaiser, MJ, et al. (2013) Distribution but not amount of protein intake is associated with frailty: a cross-sectional investigation in the region of Nürnberg. Nutr J 12, 109.CrossRefGoogle Scholar
Gingrich, A, Spiegel, A, Kob, R, et al. (2017) Amount, distribution, and quality of protein intake are not associated with muscle mass, strength, and power in healthy older adults without functional limitations-an enable study. Nutrients 9, 1358.CrossRefGoogle Scholar
Kim, IY, Schutzler, S, Schrader, AM, et al. (2018) Protein intake distribution pattern does not affect anabolic response, lean body mass, muscle strength or function over 8 weeks in older adults: a randomized-controlled trial. Clin Nutr 37, 488493.CrossRefGoogle ScholarPubMed
Murphy, CH, Churchward-Venne, TA, Mitchell, CJ, et al. (2015) Hypoenergetic diet-induced reductions in myofibrillar protein synthesis are restored with resistance training and balanced daily protein ingestion in older men. Am J Physiol Endocrinol Metab 308, E734E743.CrossRefGoogle ScholarPubMed
Johnson, NR, Kotarsky, CJ, Mahoney, SJ, et al. (2022) Evenness of dietary protein intake is positively associated with lean mass and strength in healthy women. Nutr Metab Insights 15, 11786388221101829.CrossRefGoogle ScholarPubMed
Gibson, RS (2005) Principles of Nutritional Assessment, New York: Oxford University Press.Google Scholar
Moore, DR (2019) Maximizing post-exercise anabolism: the case for relative protein intakes. Front Nutr 6, 147.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Participants’ characteristics

Figure 1

Table 2. Median protein intake, distribution and sources

Figure 2

Table 3. Association between protein intake and muscle strength in females

Figure 3

Table 4. Association between protein intake and muscle strength in males