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. 2016 Feb;32(2):228–235. doi: 10.1016/j.nut.2015.08.014

Birth weight, intrauterine growth restriction and nutritional status in childhood in relation to grip strength in adults: from the 1982 Pelotas (Brazil) birth cohort

Renata Moraes Bielemann a,b,, Denise Petrucci Gigante a,b, Bernardo Lessa Horta a
PMCID: PMC4732988  PMID: 26678603

Abstract

Objective

The aim of this study was to evaluate the association among birth weight, intrauterine growth, and nutritional status in childhood with grip strength in young adults from the 1982 Pelotas (Brazil) birth cohort.

Methods

In 1982, the hospital live births of Pelotas were followed. In 2012, grip strength was evaluated using a hand dynamometer and the best of the six measurements was used. Birth weight was analyzed as z-score for gestational age according to Williams (1982) curve. Weight-for-age, weight-for-length/height, and length/height-for-age at 2 and 4 y were analyzed in z-scores according to 2006 World Health Organization Child Growth Standards. Lean mass at 30 y was included as possible mediator using the g-computation formula.

Results

In 2012, 3701 (68.1%) individuals were interviewed and 3470 were included in the present analyses. An increase of 1 z-score in birth weight was associated with an increase of 1.5 kg in grip strength in males (95% confidence interval, 1.1–1.9). Positive effect of birth weight on grip strength was found in females. Grip strength was greater in individuals who were born with appropriate size for gestational age and positively associated with weight- and length/height-for-age z-score at 2 and 4 y of age. A positive association between birth weight and grip strength was only partially mediated by adult lean mass (50% and 33% of total effect in males and females), whereas direct effect of weight at 2 y was found only in males.

Conclusions

It is suggested that good nutrition in prenatal and early postnatal life has a positive influence on adult muscle strength. The results from birth weight were suggestive of fetal programming on grip strength measurement.

Keywords: Cohort studies, Hand strength, Nutritional status, Birth weight

Highlights

  • Newborns from southern Brazil were followed for 30 y.

  • Birth weight and nutritional status in childhood were prospectively measured.

  • Grip strength was positively related to birth weight and early nutritional status.

  • Coefficients of the association between birth weight and grip strength were higher in males.

  • Birth weight was associated with adult grip strength independent of current lean mass.

Introduction

Grip strength has been associated with several outcomes. In the clinical environment, low hand-grip strength is associated with postoperative complications, hospital length of stay, and short-term survival, whereas in epidemiological studies, grip strength is inversely related to all-cause mortality, disability, and risk for fracture but is positively related to functional status and bone mass [1].

While it has long been known that lifestyle conditions affect physical capacity as well as health status, the fetal origins of adult disease hypothesis, also known as the Barker hypothesis, provides additional insights based on a biological programming theory in which conditions in the womb determine susceptibility to diseases in later life [2]. Thus, considerable attention has been devoted to within-lifetime adaptation of the organism, termed phenotypic plasticity [3], which supports that experience in earlier life may predict adult health status. In particular, growth patterns in fetal life, infancy, and childhood have been associated with the components of the metabolic syndrome (hypertension, type 2 diabetes, and cardiovascular disease), implicating early nutrition as the underlying mechanism [4], [5], [6], [7], [8].

Evidence suggests that birth weight may be related to muscle strength in adulthood. Results from a meta-analysis observed a pooled effect of 0.86 kg (95% confidence interval [CI], 0.58–1.15) increase in muscle strength (mainly evaluated by grip strength) per additional kg of birth weight, which is maintained across the life span [9]. On the other hand, the effect of nutritional status in infancy and childhood has been scarcely evaluated, with studies suggesting that poor early growth is related to low muscle strength in children, adults, and the elderly [10], [11], [12]. Possible mechanisms involved in this long-term adaptation may include the number and type of muscle fibers [13], [14], [15], in addition to processes regulated by satellite cells [16].

Most of the studies on the long-term consequences of birth weight on muscular strength come from high-income countries [9]. However, investigations regarding this subject are important from low- and middle-income countries (LMICs) because there is uncertainty about the biological pathways that link low birth weight and stunting in childhood to later disease outcomes, as well as a possible difference in body composition at a given birth weight between high- and low-income countries [17]. Thus, establishing whether nutritional status during developmental periods is associated to outcomes related to adult noncommunicable diseases in LMICs in the same importance as in high-income countries is necessary [17].

Additionally, previous studies have not, to our knowledge, explored the mediating effect of the amount of lean mass in the relationship between early nutritional exposures and grip strength, especially regarding the use of adequate statistical tools. Recognizing these relationships may increase understanding of the underlying mechanisms that may explain the biological plausibility of this association. Moreover, the existing relationship between nutrition in infancy and childhood and later grip strength is not well established in the literature and this study may help in the construction of the body of evidence of studies analyzing the long-term consequences of early nutrition.

This study was aimed at assessing the role of birth weight, intrauterine growth restriction, and nutritional status in childhood on grip strength in young adults from the 1982 Pelotas (Brazil) birth cohort.

Materials and methods

Participants

In 1982, all maternity hospitals in the city were visited daily and the 5914 live births whose families lived in the urban area of the city were examined and their mothers interviewed. These individuals have been followed often throughout the years [8].

The study was approved by the Ethics Committee of the Medicine School of the Federal University of Pelotas. Written informed consent was obtained during the 2012–2013 follow-up before the interviews and physical evaluations.

Infancy and childhood follow-ups

Maternity hospital staff used pediatric scales (Filizolla, Brazil; precision 10 g) to record birth weight. The scales were calibrated weekly. Gestational age was obtained by asking mothers the date of their last menstrual period. Term birth was defined as gestational age ≥37 wk. Information on prepregnancy weight was referred by the mother and was confirmed on the antenatal care register card. The research team measured maternal height soon after the women were admitted to the maternity hospital in 1982.

In 1984, a census was carried out in the urban area of the city in search of the cohort members; 4934 children were identified, which added to the 227 deaths representing a follow-up rate of 87.2%. Mean age at follow-up was 19.4 mo. In 1986, approximately 84.2% of the cohort children were located. In these visits, children were weighed using a portable spring scale with an accuracy of ±100 g (CMS Weighing Equipment, London, UK) and had their supine length (1984) or standing height (1986) measured using boards manufactured locally according to international specifications (AHRTAG, London, UK).

The weights in childhood were transformed to z-scores of weight, as well as the length/height at the 1984 and 1986 follow-ups, for age and sex using the 2006 World Health Organization growth standards [18]. Weight-for-length/height for sex was also transformed to z-score according to the same growth standard. Birth weight was transformed to z-score according to gestational age, using the reference population developed previously. Small-for-gestational-age was defined as a birth weight below the 10th percentile for gestational age and sex of the Williams' curve [19].

Follow-up at 30 y

From June 2012 to February 2013, the cohort members were invited to visit the Epidemiologic Research Center, and 3701 individuals (follow-up rate: 68.1%, considering 325 known deaths) were examined and interviewed. Standing height was measured to the nearest 1 mm with barefooted participants using a wooden stadiometer. Weight was assessed using a BodPod® scale with a precision of 0.01 kg. Body mass index (BMI) was calculated as weight in kg divided by the square of height in m.

Grip strength was obtained using the Jamar hand dynamometer (Lafayette Instrument Company, Lafayette, IN, USA). The assessment occurred with the participants in the sitting position in a chair with legs, back support, and fixed arms, with their shoulders adducted, their elbows flexed 90°, and their forearms in neutral, as recommended by the American Society of Hand therapists [20], and has high intratest and intertest reliability [21]. The hands in the device were positioned so that the thumbs were around one side of the handle and the four fingers were around the other side. Interviewees were able to hold the device comfortably in their hands and the position of the handle was altered if necessary. Participants were encouraged to squeeze as long and as tightly as possible or until the needle stopped. Three readings in total for each side were taken, alternately. The highest of the six grip strength measurements was considered in the statistical analysis. Exclusion criteria were pregnancy; tendinitis, current injuries or deterioration of mobility due to previous injury or accident in at least one of the arms or hands; fracture in the upper limbs in the previous 6 mo; wheelchair use; mental disorders; and degenerative diseases (e.g., fibromyalgia).

In 2012, lean mass was measured using the method of dual-energy x-ray absorptiometry (DXA; Lunar Prodigy Advance - GE®, Germany). Due to disparities between the sums of bone, fat, and lean mass measured by DXA and body weight measured by the previously described scale, the lean mass obtained by DXA was corrected according to body weight. Physical activity during commuting and leisure-time was measured in min/wk using the commuting section of the International Physical Activity Questionnaire and also a list of activities with frequency and duration of each activity, respectively.

Statistical analyses

The analyses were performed using Stata 12 software (StataCorp, College Station, TX, USA). All analyses were stratified by sex and statistical interaction in the association between the exposures and grip strength according to sex was formally tested. The association between exposures and grip strength was evaluated using linear regression models. Wald test was used to test the significance and P = 0.05 was used to assign statistical significance. Maternal smoking during pregnancy, family income at birth, maternal prepregnancy BMI, maternal schooling, and skin color (evaluated by self-report in 2004–2005 and imputed maternal skin color for missing information) were considered possible confounders and the relationship of these variables with outcome was showed. Birth weight was used in the models that included nutritional status at the 1984 and 1986 follow-ups. Nutritional status at age 2 was included in the models using nutritional variables at the 1986 follow-up. A mediation analysis, using lean mass as a mediator, was carried out using the g-computation formula [22]. The formula is used to estimate the causal effect of time-varying exposures (early nutrition) on an outcome in the presence of later confounders (post-confounders) that are themselves affected by the exposures. It addresses the problem of estimating direct and indirect effects when the causal effect of the exposures on an outcome is mediated by intermediate variables (lean mass), and in particular when confounders (post-confounders) of the mediator–outcome relationships are themselves affected by the exposures. Thus, g-computation formula works with base confounders—variables that affect both main exposures and outcome—and post-confounders—variables not previously included in the model that are affected by exposures and related to the mediating variable. In this analysis, family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, skin color, birth weight, and nutritional status at age 2 were considered base confounders. Height and physical activity during commuting and leisure-time were considered post-confounders.

Results

In the 2012–2013 visit, grip strength was measured in 3470 participants from the cohort (93.8% of the 3701 individuals interviewed). Percentage of data from males and females was similar. Characteristics of individuals with grip strength measurements are shown in Table 1. The prevalence of low birth weight was 6% and 9% for males and females, respectively (average birth weight for males was 3245.2 g, and for females, 3126.6 g). Most of the participants were white, from A/B economic level (highest), and had mothers with ≤8 y of study who did not smoke during pregnancy. More than half of the individuals were overweight and grip strength was higher in males (mean = 50.2 kg; SD = 8.2 kg) than in females (mean = 29.7 kg; SD = 5.4 kg).

Table 1.

Characteristics of participants from the 1982 Pelotas (Brazil) birth cohort included in the analysis

Subjects' characteristics Males
 Females
N % N %
Maternal schooling (y)
 0–4 551 31.9 557 32.1
 5–8 755 43.6 736 42.4
 9–11 191 11.1 188 10.8
 ≥12 231 13.4 256 14.7
Maternal smoking during pregnancy
 Yes 597 34.5 608 35
 No 1133 65.5 1131 65
Birth weight (g)
 <2500 109 6.3 158 9.1
 ≥2500 1621 93.7 1581 90.9
Skin color
 White 1341 75 1476 77.1
 Non-white 446 25 438 22.9
Economic status at 30 y (ABEP)
 A/B (richest) 960 68.0 933 63.7
 C 408 28.9 464 31.7
 D/E (poorest) 44 3.1 67 4.6
Nutritional status at 30 y (BMI)
 Underweight (<18.5 kg/m2) 27 1.6 104 5.6
 Normal (18.5–24.9 kg/m2) 625 35.6 809 43.7
 Overweight (25–29.9 kg/m2) 714 40.7 515 27.8
 Obese (>30 kg/m2) 388 22.1 425 22.9
Physical activity ≥150 min/wk
 Yes 1034 59.6 944 50.5
 No 701 40.4 927 49.5
Grip strength (kg) [mean (SD)] 1730 50.2 (8.2) 1739 29.7 (5.4)
Lean mass (kg) [mean (SD)] 1596 56.7 (6.6) 1721 38.6 (5.3)
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ABEP, Associação Brasileira de Empresas de Pesquisa; BMI, body mass index

Criterion based on possession of certain consumer goods, head of the household's schooling, and presence of a maid.

Table 2 shows the average and prevalence of each exposure according to potential confounding variables, stratified by sex. The occurrence of the term birth was not related to any possible confounder. Family income at birth, maternal schooling, and maternal prepregnancy BMI were positively associated to birth weight z-score and nutritional status at 2 and 4 y in both males and females. Maternal smoking during pregnancy was associated with lower birth weight (P < 0.001), lower weight at age 2, and lower length for age z-score at 2 and 4 y in both sexes.

Table 2.

Description of main exposures according to socioeconomic and maternal characteristics of the 1982 Pelotas birth cohort

Subjects' characteristics n Birth weight z-score
 Gestational age (≥37 wk)
 Weight for age z score at 2 y
 Weight for length z-score at 2 y
 Length for age z-score at 2 y
 Weight for age z-score at 4 y
 Weight for height z-score at 4 y
 Height for age z-score at 4 y
P value
Mean (SD)		 P value
N (%)		 P value
Mean (SD)		 P value
Mean (SD)		 P value
Mean (SD)		 P value
Mean (SD)		 P value
Mean (SD)		 P value
Mean (SD)
Males
 Family income at birth (minimum wages) <0.001 0.10 <0.001 <0.001 <0.001 <0.001 <0.001 <0.001
 ≤1 666 −0.51 (1.02) 387 (83.4) −0.79 (1.16) −0.06 (1.03) −1.29 (1.18) −0.40 (1.04) 0.52 (0.96) −1.29 (1.18)
 1.1–3 1463 −0.29 (1.01) 1001 (86.8) −0.36 (1.12) 0.13 (1.03) −0.79 (1.06) −0.04 (1.02) 0.56 (1.02) −0.70 (1.06)
 3.1–6 544 −0.13 (1.05) 406 (86.4) −0.04 (1.09) 0.26 (1.02) −0.37 (1.06) 0.24 (1.04) 0.66 (1.08) −0.35 (0.98)
 >6 351 −0.01 (1.02) 281 (89.5) 0.31 (1.11) 0.48 (0.99) −0.05 (1.02) 0.66 (1.18) 0.93 (1.20) 0.05 (0.96)
 Maternal schooling (y) <0.001 0.080 <0.001 <0.001 <0.001 <0.001 <0.001 <0.001
 0–4 1008 −0.36 (1.08) 630 (86.5) −0.64 (1.18) 0.01 (1.05) −1.11 (1.19) −0.28 (1.06) 0.51 (1.00) −1.06 (1.19)
 5–8 1288 −0.31 (1.02) 879 (84.7) −0.35 (1.11) 0.12 (1.02) −0.75 (1.07) −0.02 (1.01) 0.59 (1.02) −0.71 (1.04)
 9–11 330 −0.07 (0.98) 250 (89.9) 0.11 (1.07) 0.39 (0.97) −0.28 (0.94) 0.37 (1.07) 0.70 (1.13) −0.18 (0.93)
 ≥12 406 0.06 (0.98) 319 (88.4) 0.28 (1.08) 0.45 (1.00) −0.06 (0.99) 0.59 (1.13) 0.85 (1.17) 0.03 (0.97)
 Maternal smoking during pregnancy <0.001 0.08 <0.001 0.71 <0.001 0.01 0.14 <0.001
 No 1946 −0.15 (1.01) 1381 (87.3) −0.23 (1.16) 0.17 (1.04) −0.60 (1.12) 0.06 (1.06) 0.59 (1.01) −0.58 (1.11)
 Yes 1091 −0.49 (1.03) 699 (84.7) −0.43 (1.18) 0.15 (1.02) −0.94 (1.15) −0.05 (1.14) 0.65 (1.12) −0.83 (1.15)
 Maternal prepregnancy BMI (kg/m2) <0.001 0.34 <0.001 <0.001 <0.001 <0.001 <0.001 <0.001
 First quartile (≤20.1) 645 −0.48 (0.91) 432 (84.4) −0.53 (1.09) −0.06 (0.99) −0.83 (1.08) −0.27 (0.95) 0.26 (0.93) −0.77 (1.02)
 Second quartile (20.2–21.9) 650 −0.34 (0.97) 467 (87.0) −0.32 (1.13) 0.12 (1.00) −0.69 (1.19) 0.00 (1.04) 0.56 (0.96) −0.64 (1.13)
 Third quartile (22–24.6) 652 −0.24 (1.01) 467 (86.0) −0.18 (1.14) 0.27 (1.02) −0.65 (1.09) 0.18 (1.12) 0.76 (1.12) −0.57 (1.11)
 Fourth quartile (≥24.7) 619 0.03 (1.15) 440 (88.2) −0.05 (1.18) 0.35 (1.05) −0.53 (1.10) 0.26 (1.09) 0.82 (1.04) −0.49 (1.12)
Females
 Family income at birth (minimum wages) <0.001 0.50 <0.001 <0.001 <0.001 <0.001 <0.001 <0.001
 ≤1 622 −0.53 (1.07) 358 (86.3) −0.72 (1.13) −0.02 (1.05) −1.21 (1.14) −0.48 (0.99) 0.33 (0.88) −1.20 (1.12)
 1.1–3 1325 −0.23 (1.03) 903 (86.3) −0.29 (1.11) 0.17 (1.04) −0.69 (1.07) −0.10 (0.96) 0.47 (0.94) −0.71 (1.02)
 3.1–6 547 −0.21 (1.05) 420 (89.0) −0.11 (1.19) 0.41 (1.11) −0.31 (1.07) 0.35 (1.09) 0.75 (1.10) −0.28 (1.08)
 >6 366 0.07 (0.99) 280 (86.7) 0.30 (1.12) 0.46 (1.02) −0.06 (1.12) 0.37 (0.97) 0.67 (0.96) −0.14 (0.96)
 Maternal schooling (y) <0.001 0.791 <0.001 <0.001 <0.001 <0.001 <0.001 <0.001
 0–4 952 −0.33 (1.04) 561 (87.7) −0.62 (1.15) 0.01 (1.04) −1.07 (1.13) −0.36 (1.02) 0.40 (0.94) −1.08 (1.10)
 5–8 1166 −0.28 (1.09) 818 (86.3) −0.22 (1.10) 0.22 (1.04) −0.64 (1.08) −0.04 (0.95) 0.51 (0.89) −0.66 (1.01)
 9–11 324 −0.12 (1.01) 246 (88.2) 0.14 (1.22) 0.39 (1.13) −0.26 (1.14) 0.31 (1.08) 0.64 (1.11) −0.21 (1.00)
 ≥12 432 −0.09 (0.98) 345 (86.7) 0.31 (1.10) 0.47 (1.04) −0.04 (0.99) 0.42 (1.02) 0.73 (1.10) −0.12 (1.01)
 Maternal smoking during pregnancy (y) <0.001 0.47 <0.001 0.16 <0.001 <0.001 0.85 <0.001
 No 1864 −0.10 (1.05) 1296 (86.6) −0.15 (1.19) 0.23 (1.07) −0.54 (1.16) 0.04 (1.06) 0.54 (1.00) −0.56 (1.10)
 Yes 1012 −0.53 (0.99) 674 (87.7) −0.37 (1.14) 0.17 (1.04) −0.83 (1.09) −0.15 (0.98) 0.50 (0.91) −0.84 (1.06)
 Maternal prepregnancy BMI (kg/m2) <0.001 0.66 <0.001 <0.001 <0.001 <0.001 <0.001 0.003
 First quartile (≤20.1) 595 −0.50 (0.97) 418 (86.5) −0.51 (1.04) −0.08 (0.94) −0.76 (1.09) −0.28 (0.92) 0.23 (0.86) −0.76 (1.00)
 Second quartile (20.2–21.9) 610 −0.35 (0.95) 424 (85.8) −0.16 (1.13) 0.27 (1.07) −0.58 (1.12) −0.02 (0.98) 0.49 (0.88) −0.59 (1.09)
 Third quartile (22–24.6) 588 −0.19 (1.01) 441 (88.4) −0.07 (1.18) 0.35 (1.06) −0.54 (1.14) 0.06 (1.04) 0.57 (0.94) −0.56 (1.11)
 Fourth quartile (≥24.7) 616 0.12 (1.13) 446 (87.5) 0.04 (1.24) 0.41 (1.15) −0.44 (1.05) 0.26 (1.11) 0.82 (1.07) −0.51 (1.09)
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BMI, body mass index

According William's curve.

Kruskal Wallis' test.

In males, maternal prepregnancy BMI was positively associated with adult grip strength (P = 0.005). Females whose mothers achieved ≥12 y of schooling had lower adult grip strength than their counterparts. Non-white females had ∼2 kg more strength than white females (P < 0.001; Table 3).

Table 3.

Grip strength at age 30 y according to socioeconomic and maternal characteristics

Subjects' characteristics Males
 Females
n Mean (SD) P value n Mean (SD) P value
Family income at birth (minimum wages) 0.28 0.06
 ≤1 345 49.4 (8) 332 29.7 (5.5)
 1.1–3 842 50.4 (8.4) 867 30 (5.3)
 3.1–6 343 50.2 (7.7) 334 29.7 (5.6)
 >6 194 50.2 (8.2) 198 28.8 (5.3)
Maternal schooling (y) 0.24 0.01
 0–4 551 50.4 (8.1) 557 30.1 (5.5)
 5–8 755 49.8 (8.3) 736 29.9 (5.3)
 9–11 191 51 (8.4) 188 29.6 (5.1)
 ≥12 231 50.1 (7.8) 256 28.8 (5.8)
Maternal smoking during pregnancy 0.29 0.75
 No 1133 50.0 (8) 1131 29.7 (5.5)
 Yes 597 50.4 (8.5) 608 29.8 (5.4)
Maternal prepregnancy BMI (kg/m2) 0.005 0.65
 First quartile (≤20.1) 360 49.5 (8.4) 359 29.4 (5)
 Second quartile (20.2–21.9) 384 49.1 (7.8) 368 30 (5.2)
 Third quartile (22–24.6) 381 50.9 (8.5) 360 29.5 (5.5)
 Fourth quartile (≥24.7) 368 50.8 (7.9) 390 30 (5.8)
Skin color 0.19 <0.001
 White 1296 50 (8.2) 1337 29.3 (5.2)
 Non-white 433 50.6 (8.2) 401 31.1 (5.6)
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BMI, body mass index

Table 4 shows that grip strength was not associated with gestational age in males. Males whose birth weight was appropriate for gestational age had on average 2.7 kg higher strength than males who were born small for gestational age. Men whose birth weight was >1.1 z-score had 8.5 kg (95% CI, 5.9–11.7) higher grip strength than males with birth weight <−2 z-score. Additionally, positive association was observed among males whose birth weight was between −2 and −1.1 z-score. Grip strength was also positively associated with all nutritional status variables at 2 y. Males with weight- and length-for-age and weight-for-length >1.1 z-score at 2 y had higher grip strength than males whose these nutritional status variables were <−2 z-score. Weight- and height-for-age z-score at 4 y were positively related to males' grip strength in young adulthood.

Table 4.

Birth weight and growth at 2 y in relation to grip strength in males

Subjects' characteristics n Grip strength (kg)
Crude
 Adjusted
β [95% CI] P value β [95% CI] P value
Intrauterine growth retardation (<10th percentile) <0.001 <0.001
 Yes 204 Reference Reference
 No 1207 2.4 [1.2–3.6] 2.7 [1.4–4.0]
Gestational age (≥37 wk) 0.64 0.99
 Yes 1240 0.31 [−1.0 to 1.62] 0.0 [−1.4 to 1.4]
 No 171 Reference Reference
Birth weight z-score (according to William's curve) <0.001 <0.001
 <−2 55 Reference Reference
 −2 to −1.1 255 3.6 [1.3–6] 3.6 [1.1–6.1]
 −1 to 0 510 4.6 [2.3–6.8] 5 [2.7–7.4]
 0.1–1 440 5.2 [3–7.5] 5.6 [3.2–8]
 >1.1 151 7.9 [5.4–10.4] 8.5 [5.9–11.2]
Weight-for-age z-score at 2 y <0.001 <0.001
 <−2 79 Reference Reference
 −2 to −1.1 325 4.1 [2.1–6] 3.1 [0.5–5.7]
 −1 to 0 560 5.8 [3.9–7.7] 5.6 [3.1–8.2]
 0.1–1 402 8.2 [6.3–10.1] 7.5 [4.9–10.0]
 >1.1 213 9.1 [7–11.1] 8.9 [6.1–11.7]
Weight-for-length z-score at 2 y <0.001 <0.001
 <−2 17 Reference Reference
 −2 to −1.1 166 4.9 [0.8–8.9] 5.4 [0–10.8]
 −1 to 0 517 6.5 [2.6–10.5] 6.5 [1.3–11.8]
 0.1–1 570 8.1 [4.2–12] 7.8 [2.5–13.1]
 >1.1 309 9.8 [5.9–13.8] 9.6 [4.3–15]
Length-for-age z-score at 2 y <0.001 <0.001
 <−2 175 Reference Reference
 −2 to −1.1 411 2.7 [1.3–4.1] 2.8 [1–4.6]
 −1 to 0 586 4.3 [2.9–5.6] 4.5 [2.7–6.2]
 0.1–1 302 5.8 [4.3–7.3] 5.8 [3.9–7.8]
 >1.1 105 7.4 [5.4–9.3] 7.4 [4.9–9.8]
Weight-for-age z-score at 4 y <0.001 0.03
 <−2 25 Reference Reference
 −2 to −1.1 190 1.4 [−1.9 to 4.6] −0.6 [−4.7 to 3.5]
 −1 to 0 558 4 [0.8–7.1] 1.1 [−3 to 5.1]
 0.1–1 528 6.8 [3.6–9.9] 2.6 [−1.7 to 6.9]
 >1.1 254 7.7 [4.5–11] 2.2 [−2.4 to 6.8]
Weight-for-height z-score at 4 y <0.001 0.55
 <−1.1 82 −2.3 [−4.2 to −0.4] −1.3 [−3.5 to 1]
 −1 to 0 323 Reference Reference
 0.1−1 641 1 [−0.1 to 2.1] −0.5 [−1.7 to 0.7]
 >1.1 507 2 [0.9–3.2] −0.8 [−2.3 to 0.6]
Height-for-age z-score at 4 y <0.001 0.006
 <−2 158 Reference Reference
 −2 to −1.1 383 3 [1.6–4.5] 3.3 [1.3–5.3]
 −1 to 0 575 4.4 [3–5.8] 3.9 [1.7–6]
 0.1–1 324 6.7 [5.2–8.2] 4.7 [2.2–7.3]
 >1.1 113 7.5 [5.6–9.4] 5.5 [2.3–8.8]
Open in a new tab

BMI, body mass index; CI, confidence interval

Adjusted for family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, and skin color.

Adjusted for family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, skin color, and birth weight.

Adjusted for family income at birth, maternal schooling, maternal smoking at pregnancy, maternal prepregnancy BMI, skin color, birth weight, and nutritional status at 2 y.

Table 5 shows that among females, birth weight was positively associated with adult grip strength (P < 0.001). Those females whose birth weight was appropriate for the gestational age had 1.2 kg higher strength than females who were born small for the gestational age. Regarding association between grip strength and nutritional status at 2 y, females whose weight-for-age was >1.1 z-scores had 2 kg (95% CI, 0.1–3.8) higher grip strength than females whose weight-for-age was more than 2 SD below the mean of the reference population. Weight-for-length z-score at 2 y was not associated with grip strength, whereas females with length-for-age >1.1 had higher grip strength than females with length-for-age <−2 z-scores. Similar to males, weight- and height-for-age z-score at 4 y were positively associated with adult grip strength in females. However, grip strength was positively associated with weight-for-length at 4 y (P = 0.019), since females with weight-for-height above p50 of the reference population had higher grip strength than females below the p50.

Table 5.

Birth weight and growth at 2 y in relation to grip strength in females

Subjects' characteristics n Grip strength (kg)
Crude
 Adjusted
β [95% CI] P value β [95% CI] P value
Intrauterine growth retardation (<10th percentile) 0.02 0.008
 Yes 192 Reference Reference
 No 1195 1.01 [0.2–1.8] 1.2 [0.3–2.1]
Gestational age (≥37 wk) 0.41 0.74
 Yes 1205 −0.4 [−1.2 to 0.5] −0.15 [−1 to 0.7]
 No 183 Reference Reference
Birth weight z-score (according to William's curve) 0.003 <0.001
 <−2 53 Reference Reference
 −2 to −1.1 250 −0.2 [−1.8 to 1.42] −0.4 [−2.1 to 1.2]
 −1 to 0 522 0.3 [−1.3 to 1.8] 0.3 [−1.2 to 1.9]
 0.1–1 403 0.6 [−0.9 to 2.2] 0.9 [−0.7 to 2.5]
 >1.1 159 2 [0.3–3.6] 2.1 [0.4–3.9]
Weight-for-age z-score at age 2 y <0.001 0.001
 <−2 77 Reference Reference
 −2 to −1.1 321 0.1 [−1.2 to 1.4] −0.3 [−2 to 1.4]
 −1 to 0 588 1.1 [−0.1 to 2.4] 1.0 [−0.6 to 2.7]
 0.1–1 394 1.5 [0.2–2.9] 1.3 [−0.4 to 3]
 >1.1 220 2.1 [0.7–3.5] 2 [0.1–3.8]
Weight-for-length z-score at age 2 y 0.07 0.39
 <−2 15 Reference Reference
 −2 to −1.1 172 −2.7 [−5.5 to 0.2] −2.2 [−5.6 to 1.2]
 −1 to 0 542 −2.4 [−5.1 to 0.4] −1.7 [−5 to 1.6]
 0.1–1 533 −1.8 [−4.6 to 1.0] −1.4 [−4.7 to 1.9]
 >1.1 337 −1.7 [−4.5 to 1.1] −1.2 [−4.5 to 2.1]
Length-for-age z-score at age 2 y <0.001 <0.001
 <−2 174 Reference Reference
 −2 to −1.1 402 0.2 [−0.8 to 1.1] −0.4 [−1.5 to 0.8]
 −1 to 0 584 1.2 [0.3–2.1] 0.7 [−0.5 to 1.8]
 0.1–1 345 2.3 [1.3–3.3] 1.9 [0.7–3.1]
 >1.1 96 2.6 [1.3–3.9] 2.6 [1–4.3]
Weight-for-age z-score at age 4 y <0.001 <0.001
 <−2 35 Reference Reference
 −2 to −1.1 213 0.4 [−1.5 to 2.3] 1.0 [−1.5 to 3.6]
 −1 to 0 577 1.5 [−0.3 to 3.3] 2.7 [0.2–5.3]
 0.1–1 505 2.3 [0.5–4.2] 3.7 [1–6.4]
 >1.1 224 3.2 [1.3–5.1] 5.2 [2.3–8.1]
Weight-for-height z-score at age 4 y 0.003 0.019
 <−1.1 62 0.0 [−1.4 to 1.4] 0.0 [−1.6 to 1.6]
 −1 to 0 422 Reference Reference
 0.1–1 647 0.7 [0.1–1.4] 0.9 [0.1–1.6]
 >1.1 422 1.4 [0.6–2.1] 1.5 [0.6–2.5]
Height-for-age z-score at age 4 y <0.001 0.008
 <−2 166 Reference Reference
 −2 to −1.1 419 1.3 [0.3–2.3] 1.9 [0.6–3.1]
 −1 to 0 554 1.7 [0.8–2.7] 1.5 [0.2–2.9]
 0.1–1 316 2.8 [1.8–3.8] 2.5 [0.9–4.2]
 >1.1 99 3.6 [2.3–4.9] 3.2 [1–5.3]
Open in a new tab

BMI, body mass index; CI, confidence interval

Adjusted for family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, skin color.

Adjusted for family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, skin color, and birth weight.

Adjusted for family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, skin color, and birth weight and nutritional status at 2 y.

We observed an interaction between sex and most of the independent variables included in the analyses, the P-values for the variables weight-for-age z-score at 2 and 4 y, weight-for-length at 2 y, length- and height-for-age at 2 and 4 y were <0.001.

To test the mediation of lean mass, we also stratified the mediation analyses (Table 6). Results from weight-for-age and weight-for-height at 4 y in males and weight-for-length z-scores at 2 y in females were not showed in Table 6 because there was no total effect of these exposures on grip strength. All exposures showed a positive effect in grip strength at 30 y of age mediated by lean mass. Around 50% and 33% of total effect of birth weight on grip strength was explained by the mediator in males and females. Thus, the direct effect of birth weight was greater than the effect mediated by lean mass in females. No other variable had direct effect on adult grip strength in females. However, weight-for-age and weight-for-length z-scores at 2 y had a positive direct effect on grip strength in males. The percentage of effect on grip strength mediated by lean mass was 59% and 57% when considered weight-for-age and weight-for-length z-scores at 2 y, respectively.

Table 6.

Total, direct, and indirect effects of infancy and childhood exposures on adult grip strength

Nutritional characteristics Total association
 Direct association
 Indirect association
β [95% CI] P value β [95% CI] P value β [95% CI] P value
Males
 Intrauterine growth retardation (<10th percentile) 2.57 [1.32–3.81] <0.001 0.92 [−0.25 to 2.10] 0.13 1.65 [0.95–2.34] <0.001
 Birth weight z score (according to William's curve) 1.48 [0.99–1.96] <0.001 0.72 [0.21–1.23] 0.006 0.76 [0.41–1.10] <0.001
 Weight-for-age z-score at age 2 y 1.97 [1.44–2.51] <0.001 0.80 [0.23–1.38] 0.006 1.17 [0.79–1.55] <0.001
 Weight-for-length z-score at age 2 y 1.4 [0.9–2] <0.001 0.6 [0–1.2] 0.04 0.8 [0.5–1.2] <0.001
 Length-for-age z-score at age 2 y 1.67 [1.15–2.18] <0.001 0.36 [−0.21 to 0.92] 0.21 1.31 [0.92–1.70] <0.001
 Height-for-age z-score at age 4 y 0.96 [0.20–1.73] 0.01 0.10 [−0.68 to 0.88] 0.80 0.86 [0.44–1.29] <0.001
Females
 Intrauterine growth retardation (<10th percentile) 0.99 [0.12–1.86] 0.03 0.54 [−0.26 to 1.34] 0.18 0.45 [0.13–0.77] 0.006
 Birth weight z-score (according to William's curve) 0.58 [0.26–0.90] <0.001 0.39 [0.07–0.71] 0.02 0.19 [0.03–0.36] 0.02
 Weight-for-age z-score at age 2 y 0.60 [0.28–0.92] <0.001 0.06 [−0.28 to 0.41] 0.72 0.54 [0.33–0.75] <0.001
 Length-for-age z-score at age 2 y 0.83 [0.50–1.16] <0.001 0.18 [−0.18 to 0.54] 0.33 0.66 [0.44–0.87] <0.001
 Weight-for-age z-score at age 4 y 1.27 [0.74–1.81] <0.001 0.49 [−0.06 to 1.04] 0.08 0.78 [0.51–1.05] <0.001
 Weight-for-height z-score at age 4 y 0.5 [0.1–0.9] 0.03 0.1 [−0.4 to 0.5] 0.82 0.4 [0.2–0.6] <0.001
 Height-for-age z-score at age 4 y 0.58 [0.10–1.06] 0.02 0.19 [−0.30 to 0.68] 0.44 0.39 [0.17–0.60] 0.001
Open in a new tab

BMI, body mass index; CI, confidence interval

Variables included in the analysis as base confounders were family income at birth, maternal schooling, maternal smoking during pregnancy, maternal prepregnancy BMI, skin color, birth weight, and nutritional status at 2 y. Variables included in the analysis as post-confounders were height and physical activity during commuting and leisure-time. Mediator was lean mass.

Discussion

Results of the present study demonstrated an important relationship between intrauterine growth and nutritional status at 2 and 4 y and grip strength in young adults belonging to the 1982 Pelotas birth cohort. Gestational age, however, was not associated with grip strength. The effect of most exposures was mainly mediated by lean mass in adulthood. However, birth weight according to the gestational age and weight-for-age z-score at 2 y in males had part of its effect not mediated by lean mass.

The main limitation of this study was the lack of data on birth length making it impossible to compare effects of birth weight and length. The present study, however, had the advantage of being population based and including several measurements at different ages. The high follow-up rate of the 1982 Pelotas birth cohort is another strength as it reduces the susceptibility to selection bias. Additionally, both exposures and outcomes were prospective and objectively measured.

A recent systematic review and meta-analysis found strong and consistent evidence for a positive association between birth weight and muscle strength in men and women across the life course [9]. Concerning evidence from LMICs, a study carried out in the Philippines showed a positive association between birth weight and adult grip strength only in males [23]. Birth weight was related to higher grip strength in Indian children, as well as conditional height and BMI from birth to 24 mo [10]. In Guatemala, intrauterine growth retardation was inversely related to grip strength in adolescence or in young adulthood [24].

The regression coefficients of the present study showed higher strength of association and more pronounced dose–response relationship in males. Other studies also found differences between sex in the relationship between early growth variables and later grip strength so that some associations were not statistically significant in females [11], [23], [25]. These disparities may be due to the different influence of sex hormones, such as testosterone [26], [27], which has anabolic effects on muscle and function [28], including strength in males [29]. It has been reported that among males, birth weight or weight gain in childhood are positively related to testosterone levels in adulthood [23], [30].

The association between birth weight and later grip strength can be explained by influences of birth size on growth and development of muscle fibers [31]. Although the concept that there is a fixed number of muscle fibers determined by birth, with subsequent growth only achieved by increasing fiber size, is probably outdated [31], results from the Hertfordshire Cohort Study found that muscle fiber score (fibers kg/mm2) from biopsy of the vastus lateralis was significantly lower in individuals with decreased birth weight in elderly males [32]. This finding lends support to the hypothesis that the number of muscle fibers is determined up to the birth, and subsequent growth is achieved by increasing size rather than the number of fibers [13].

The results indicated that both prenatal and postnatal period might play an important role on adult grip strength. A study in the United Kingdom found that grip strength in the elderly was positively associated with weight at 1 y [12]. On the other hand, a study carried out with participants from The Medical Research Council National Survey of Health and Development did not find association between weight and height at 2 y and adult grip strength, after adjustment for birth weight [33].

The theory of phenotypic plasticity explains lifetime adaptation of the organism due to early nutrition. In the case of muscle strength, the satellite cells, formed during myogenesis, play an essential role in the processes of postnatal muscle growth, muscle regeneration, and muscle hypertrophy across the life course. In animal models, the postnatal growth, a process that is normally regulated by satellite cells, is related to a phenotype marked by reduction in skeletal muscle mass and fiber caliber [16], which may help to explain the association found between nutritional status at 2 y and grip strength on later life. Additionally, hypertrophy is responsible for postnatal muscle growth, whereas hyperplasia occurs during prenatal period [15]. The hypertrophy helps to compensate for any deficit in fiber number, but it is suggested that muscle containing fewer fibers have larger type I fibers but not type II fibers [14]. This is important because the type II muscle fiber cross-sectional area seems to be associated with higher muscle strength [34].

In addition to the type of fiber, the amount of lean mass was important to mediate the association between early nutrition and later grip strength in our population. Several studies in diverse populations have supported the hypothesis that poor fetal growth, as measured by low birth weight, results in a smaller proportion of lean mass later in life [35], [36]. This increased susceptibility to lower values of lean mass and other negative outcomes (e.g., type 2 diabetes, hypertension, etc.) results from adaptations made by the fetus in an environment limited in its supply of nutrients, termed the thrifty phenotype hypothesis, which primarily reflects adaptation in growth of lean mass and competing organs [37].

The results pointed to no effect of gestational age on grip strength in adulthood, whereas birth weight according to gestational age, a proxy of intrauterine growth, was positively related to grip strength. It suggests that intrauterine growth is more important than duration of the gestation. Thus, more attention should be focused on the intrauterine environment, especially from 6 to 18 wk, when the primary muscle fibers are formed and after the formation of secondary fibers [38].

Conclusions

The results of this study suggested that good nutrition in prenatal and early postnatal life positively influences adult muscle strength, evaluated in this study as grip strength. The results reinforce that the first 1000 d (conception to the first year of life) is a critical period for human growth and development. The findings indicate that the relationship between early determinants and adult grip strength may be mediated not only by muscle mass but by other causes not yet elucidated. The association with intrauterine growth emphasizes the importance of early environment and nutrition on later life. This is relevant because muscle strength is a marker of muscle function, which is related to loss of functional capacity, sarcopenia, and unfavorable cardiometabolic conditions in later life.

Footnotes

RMB conceptualized the study, was responsible for the data collection of grip strength, conducted the statistical analysis, and wrote the manuscript. BLH coordinated the last follow-up with participants from the cohort, conducted the statistical analysis, and wrote the manuscript. DPG coordinated the last follow-up with participants from the cohort and wrote the manuscript. This article is based on data from the study Pelotas birth cohort, 1982 conducted by Postgraduate Program in Epidemiology at Universidade Federal de Pelotas. The 1982 birth cohort study was supported by the Wellcome Trust (grant number: 086974/Z/08/Z) Initiative entitled Major Awards for Latin America on Health Consequences of Population Change. Previous phases of the study were supported by the International Development Research Center, The World Health Organization (grant number: C6/370/17A), Overseas Development Administration, European Union, National Support Program for Centers of Excellence (PRONEX), the Brazilian National Research Council (CNPq) and Brazilian Ministry of Health.

References

  • 1.Norman K., Stobaus N., Gonzalez M.C., Schulzke J.D., Pirlich M. Hand grip strength: outcome predictor and marker of nutritional status. Clin Nutr. 2011;30:135–142. doi: 10.1016/j.clnu.2010.09.010. [DOI] [PubMed] [Google Scholar]
  • 2.Barker D.J.P. Churchill Livingstone; Edinburgh: 1998. Mothers, babies and health in later life. [Google Scholar]
  • 3.Wells J.C. Environmental quality, developmental plasticity and the thrifty phenotype: a review of evolutionary models. Evol Bioinform Online. 2007;3:109–120. [PMC free article] [PubMed] [Google Scholar]
  • 4.Barker D.J. The fetal origins of type 2 diabetes mellitus. Ann Intern Med. 1999;130:322–324. doi: 10.7326/0003-4819-130-4-199902160-00019. [DOI] [PubMed] [Google Scholar]
  • 5.Barker D.J., Hales C.N., Fall C.H., Osmond C., Phipps K., Clark P.M. Type 2 (non-insulin-dependent) diabetes mellitus, hypertension and hyperlipidaemia (syndrome X: relation to reduced fetal growth. Diabetologia. 1993;36:62–67. doi: 10.1007/BF00399095. [DOI] [PubMed] [Google Scholar]
  • 6.Barker D.J., Osmond C. Infant mortality, childhood nutrition, and ischaemic heart disease in England and Wales. Lancet. 1986;1:1077–1081. doi: 10.1016/s0140-6736(86)91340-1. [DOI] [PubMed] [Google Scholar]
  • 7.Barker D.J., Winter P.D., Osmond C., Margetts B., Simmonds S.J. Weight in infancy and death from ischaemic heart disease. Lancet. 1989;2:577–580. doi: 10.1016/s0140-6736(89)90710-1. [DOI] [PubMed] [Google Scholar]
  • 8.Victora C.G., Barros F.C. Cohort profile: the 1982 Pelotas (Brazil) birth cohort study. Int J Epidemiol. 2006;35:237–242. doi: 10.1093/ije/dyi290. [DOI] [PubMed] [Google Scholar]
  • 9.Dodds R., Denison H.J., Ntani G., Cooper R., Cooper C., Sayer A.A. Birth weight and muscle strength: a systematic review and meta-analysis. J Nutr Health Aging. 2012;16:609–615. doi: 10.1007/s12603-012-0053-9. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 10.Barr J.G., Veena S.R., Kiran K.N., Wills A.K., Winder N.R., Kehoe S. The relationship of birthweight, muscle size at birth and postnatal growth to grip strength in 9 year-old Indian children: findings from the Mysore Parthenon study: birthweight and grip strength at 9. J Dev Orig Health Dis. 2010;1:329–337. doi: 10.1017/S2040174410000309. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 11.Kuh D., Hardy R., Butterworth S., Okell L., Wadsworth M., Cooper C. Developmental origins of midlife grip strength: findings from a birth cohort study. J Gerontol A Biol Sci Med Sci. 2006;61:702–706. doi: 10.1093/gerona/61.7.702. [DOI] [PubMed] [Google Scholar]
  • 12.Sayer A.A., Syddall H.E., Gilbody H.J., Dennison E.M., Cooper C. Does sarcopenia originate in early life? Findings from the Hertfordshire cohort study. J Gerontol A Biol Sci Med Sci. 2004;59:M930–M934. doi: 10.1093/gerona/59.9.m930. [DOI] [PubMed] [Google Scholar]
  • 13.Grounds M.D., White J.D., Rosenthal N., Bogoyevitch M.A. The role of stem cells in skeletal and cardiac muscle repair. J Histochem Cytochem. 2002;50:589–610. doi: 10.1177/002215540205000501. [DOI] [PubMed] [Google Scholar]
  • 14.Lexell J., Taylor C.C., Sjostrom M. What is the cause of the ageing atrophy? Total number, size and proportion of different fiber types studied in whole vastus lateralis muscle from 15- to 83-year-old men. J Neurol Sci. 1988;84:275–294. doi: 10.1016/0022-510x(88)90132-3. [DOI] [PubMed] [Google Scholar]
  • 15.Maltin C.A., Delday M.I., Sinclair K.D., Steven J., Sneddon A.A. Impact of manipulations of myogenesis in utero on the performance of adult skeletal muscle. Reproduction. 2001;122:359–374. doi: 10.1530/rep.0.1220359. [DOI] [PubMed] [Google Scholar]
  • 16.Bailey P., Holowacz T., Lassar A.B. The origin of skeletal muscle stem cells in the embryo and the adult. Curr Opin Cell Biol. 2001;13:679–689. doi: 10.1016/s0955-0674(00)00271-4. [DOI] [PubMed] [Google Scholar]
  • 17.Batty G.D., Alves J.G., Correia J., Lawlor D.A. Examining life-course influences on chronic disease: the importance of birth cohort studies from low- and middle- income countries. An overview. Braz J Med Biol Res. 2007;40:1277–1286. doi: 10.1590/s0100-879x2007000900015. [DOI] [PubMed] [Google Scholar]
  • 18.WHO WHO child growth standards based on length/height, weight and age. Acta Paediatr Suppl. 2006;450:76–85. doi: 10.1111/j.1651-2227.2006.tb02378.x. [DOI] [PubMed] [Google Scholar]
  • 19.Williams R.L., Creasy R.K., Cunningham G.C., Hawes W.E., Norris F.D., Tashiro M. Fetal growth and perinatal viability in California. Obstet Gynecol. 1982;59:624–632. [PubMed] [Google Scholar]
  • 20.Fess E.E., Moran C. American Society of Hand Therapists Monograph; Indianapolis: 1981. Clinical assessment recommendations. [Google Scholar]
  • 21.Mathiowetz V., Weber K., Volland G., Kashman N. Reliability and validity of grip and pinch strength evaluations. J Hand Surg Am. 1984;9:222–226. doi: 10.1016/s0363-5023(84)80146-x. [DOI] [PubMed] [Google Scholar]
  • 22.Daniel R.M., De Stavola B.L., Cousens S.N. gformula: estimating causal effects in the presence of time-varying confounding or mediation using the g-computation formula. STATA J. 2011;11:479–517. [Google Scholar]
  • 23.Kuzawa C.W., McDade T.W., Adair L.S., Lee N. Rapid weight gain after birth predicts life history and reproductive strategy in Filipino males. Proc Natl Acad Sci U S A. 2010;107:16800–16805. doi: 10.1073/pnas.1006008107. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 24.Martorell R., Ramakrishnan U., Schroeder D.G., Melgar P., Neufeld L. Intrauterine growth retardation, body size, body composition and physical performance in adolescence. Eur J Clin Nutr. 1998;52(Suppl 1):S43–S52. discussion S-3. [PubMed] [Google Scholar]
  • 25.Robinson S.M., Simmonds S.J., Jameson K.A., Syddall H.E., Dennison E.M., Cooper C. Muscle strength in older community-dwelling men is related to type of milk feeding in infancy. J Gerontol A Biol Sci Med Sci. 2012;67:990–996. doi: 10.1093/gerona/gls061. [DOI] [PubMed] [Google Scholar]
  • 26.Auyeung T.W., Lee J.S., Kwok T., Leung J., Ohlsson C., Vandenput L. Testosterone but not estradiol level is positively related to muscle strength and physical performance independent of muscle mass: a cross-sectional study in 1489 older men. Eur J Endocrinol. 2011;164:811–817. doi: 10.1530/EJE-10-0952. [DOI] [PubMed] [Google Scholar]
  • 27.Schaap L.A., Pluijm S.M., Smit J.H., van Schoor N.M., Visser M., Gooren L.J. The association of sex hormone levels with poor mobility, low muscle strength and incidence of falls among older men and women. Clin Endocrinol (Oxf) 2005;63:152–160. doi: 10.1111/j.1365-2265.2005.02315.x. [DOI] [PubMed] [Google Scholar]
  • 28.Bhasin S., Woodhouse L., Casaburi R., Singh A.B., Bhasin D., Berman N. Testosterone dose–response relationships in healthy young men. Am J Physiol Endocrinol Metab. 2001;281:E1172–E1181. doi: 10.1152/ajpendo.2001.281.6.E1172. [DOI] [PubMed] [Google Scholar]
  • 29.Gettler L.T., Agustin S.S., Kuzawa C.W. Testosterone, physical activity, and somatic outcomes among Filipino males. Am J Phys Anthropol. 2010;142:590–599. doi: 10.1002/ajpa.21282. [DOI] [PubMed] [Google Scholar]
  • 30.Vanbillemont G., Lapauw B., Bogaert V., De Naeyer H., De Bacquer D., Ruige J. Birth weight in relation to sex steroid status and body composition in young healthy male siblings. J Clin Endocrinol Metab. 2010;95:1587–1594. doi: 10.1210/jc.2009-2149. [DOI] [PubMed] [Google Scholar]
  • 31.Sayer A.A., Cooper C. Fetal programming of body composition and musculoskeletal development. Early Hum Dev. 2005;81:735–744. doi: 10.1016/j.earlhumdev.2005.07.003. [DOI] [PubMed] [Google Scholar]
  • 32.Patel H.P., Jameson K.A., Syddall H.E., Martin H.J., Stewart C.E., Cooper C. Developmental influences, muscle morphology, and sarcopenia in community-dwelling older men. J Gerontol A Biol Sci Med Sci. 2012;67:82–87. doi: 10.1093/gerona/glr020. [DOI] [PubMed] [Google Scholar]
  • 33.Kuh D., Bassey J., Hardy R., Aihie Sayer A., Wadsworth M., Cooper C. Birth weight, childhood size, and muscle strength in adult life: evidence from a birth cohort study. Am J Epidemiol. 2002;156:627–633. doi: 10.1093/aje/kwf099. [DOI] [PubMed] [Google Scholar]
  • 34.Verdijk L.B., Snijders T., Beelen M., Savelberg H.H., Meijer K., Kuipers H. Characteristics of muscle fiber type are predictive of skeletal muscle mass and strength in elderly men. J Am Geriatr Soc. 2010;58:2069–2075. doi: 10.1111/j.1532-5415.2010.03150.x. [DOI] [PubMed] [Google Scholar]
  • 35.Wells J.C. The programming effects of early growth. Early Hum Dev. 2007;83:743–748. doi: 10.1016/j.earlhumdev.2007.09.002. [DOI] [PubMed] [Google Scholar]
  • 36.Wells J.C., Chomtho S., Fewtrell M.S. Programming of body composition by early growth and nutrition. Proc Nutr Soc. 2007;66:423–434. doi: 10.1017/S0029665107005691. [DOI] [PubMed] [Google Scholar]
  • 37.Wells J.C. The thrifty phenotype: an adaptation in growth or metabolism? Am J Human Biol. 2011;23:65–75. doi: 10.1002/ajhb.21100. [DOI] [PubMed] [Google Scholar]
  • 38.Barbet J.P., Thornell L.E., Butler-Browne G.S. Immunocytochemical characterisation of two generations of fibers during the development of the human quadriceps muscle. Mech Dev. 1991;35:3–11. doi: 10.1016/0925-4773(91)90036-6. [DOI] [PubMed] [Google Scholar]

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