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The effects of sex, nation, ethnicity, age and self-reported pubertal development on participant-measured right-left 2D:4D (Dr-l) in the BBC internet study

Published online by Cambridge University Press:  28 January 2022

J.T. Manning
Affiliation:
Applied Sports, Technology, Exercise, and Medicine (A-STEM), Swansea University, Swansea, United Kingdom
B. Fink*
Affiliation:
Biosocial Science Information, Biedermannsdorf, Austria Department of Evolutionary Anthropology, University of Vienna, Vienna, Austria Human Evolution and Archaeological Sciences (HEAS), University of Vienna, Vienna, Austria
L. Mason
Affiliation:
Applied Sports, Technology, Exercise, and Medicine (A-STEM), Swansea University, Swansea, United Kingdom
A. Kasielska-Trojan
Affiliation:
Plastic, Reconstructive and Aesthetic Surgery Clinic, Institute of Surgery, Medical University of Łódź, Łódź, Poland
R. Trivers
Affiliation:
Southfield, St. Elizabeth, Jamaica
*
*Corresponding author. Email: bfink@gwdg.de
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Abstract

Digit ratio (2D:4D) – a proxy for prenatal sex steroids – shows sex, nationality and ethnic differences and is linked to pubertal onset. It is unclear whether right-left 2D:4D (Dr-l) also correlates with prenatal sex steroids, as evidence of these differences has been less conclusive. The present study examined the effects of sex, nation, ethnicity, age and self-reported pubertal development (i.e. the rate of physical development and age at menarche [females] or first shave [males]) on Dr-l in a large online study (the BBC internet study). Digit lengths were self-measured in 201,865 adults (110,955 males) and the sample of nations included 41 countries. Participants reported the self-perceived rate of physical pubertal development on a five-point scale (from very slow to very fast) and provided information on the age at menarche or first shave. Adult (>17 years) males had lower Dr-l than females with weak effect size across 41 nations (males-females; d = −.065, p < .0001). There were sex and ethnicity effects on Dr-l across seven ethnic groups with males < females and lower Dr-l in Whites and Middle/Near Eastern participants compared to Asian, Black and Chinese respondents. Considering age effects, the authors focused on participants >12 years; there were stable sex differences and a weak positive effect of age on Dr-l. Dr-l showed a positive relationship with the rate of physical development and a negative relationship with age at menarche or first shave. Relationships were present in males and females with stronger effects in the latter. It is concluded that Dr-l shows a weak sex difference (males < females) independent of nation, ethnicity and age, and suggest that Dr-l is a proxy for prenatal sex steroids.

Type
Research Article
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 (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press

Introduction

Digit ratio (2D:4D) – the relative lengths of the second (2D) and fourth (4D) fingers – is thought to be a negative correlate of prenatal testosterone (T) and a positive correlate of prenatal oestrogen (E) (Zheng & Cohn, Reference Zheng and Cohn2011; Manning, Reference Manning2011). The first detailed consideration of these associations reported: i) 2D:4D was sexually dimorphic (males < females), ii) it showed stability across the age range of 2 to 25 years, and iii) its associations with target traits (in this case aspects of spermatogenesis) were strongest for right 2D:4D. The latter observation led to the suggestion that right 2D:4D was more sensitive to prenatal sex steroids than left 2D:4D (Manning et al., Reference Manning, Scutt, Wilson and Lewis-Jones1998). Many later studies have found right 2D:4D to be lower than left 2D:4D and more sexually dimorphic (for meta-analysis see Hönekopp & Watson, Reference Hönekopp and Watson2010). The side difference in 2D:4D suggests that the magnitude of right-left 2D:4D (Dr-l) may also be a correlate of prenatal sex steroids. This possibility was first suggested in connection with hand preference (Manning et al., Reference Manning, Trivers, Thornhill and Singh2000) and considered in detail by Manning (Reference Manning2002; for overall sex differences p. 21-22, spermatogenesis p. 27-30, waist-to-hip ratio p. 32-37, oestrogen levels p. 37-38). Subsequently, low Dr-l (putatively high prenatal T and low prenatal E) has been linked to a diverse set of sex-dependent traits such as the implicit need for power (Schultheiss et al., Reference Schultheiss, Frisch, Özbe, Ossmann, Schultheiss and Lentz2019) and elite performance in rugby (Bennett et al., Reference Bennett, Manning, Cook and Kilduff2010).

Side differences in sexually dimorphic traits have been noted by Tanner (Reference Tanner1990), who suggested that in humans such traits tend to be more intensely expressed in the “male form” on the right side of the body and in the “female form” on the left. Such lateralization can be seen in true hermaphrodites in which the ovary is more often found on the left side of the body (Mittwoch & Mahadevaiah, Reference Mittwoch and Mahadevaiah1980). It also extends to the directional asymmetry of cognitive abilities. Men and women with right-larger gonads return high scores in male-favouring cognitive tasks and high scores in female-favouring tasks are linked to left-larger gonads in both sexes (Kimura, Reference Kimura1994). Patterns of development may shed light on the early origin of such side differences in ontogeny. In a mouse model, a molecular marker of cartilage differentiation (Sox9) shows sex differences in right paw 2D:4D (males < females) by embryonic day 17 but 2D:4D dimorphism is not found in the left paw. However, by embryonic day 21, both right and left paws show significant 2D:4D sex-dimorphism (Zheng & Cohn, Reference Zheng and Cohn2011). This indicates that the sexually dimorphic 2D:4D ratio in mice develops during a narrow window in early ontogeny and that the developmental rate of dimorphism differs between the right and left sides. Of relevance to the prenatal determination of Dr-l, Baxter et al. (Reference Baxter, Wood, Witczak, Bales and Higley2020) have reported associations between maternal sex steroids and offspring 2D:4D in a New World primate (Titi monkeys). In this species, sex differences in right 2D:4D are similar to that of humans (males < females). Maternal urine samples were collected 15–20 weeks before birth and assayed for T and E. High maternal concentrations of T and low levels of E were associated with low Dr-l.

In common with 2D:4D, the Dr-l may also be sexually dimorphic in humans (males < females) (e.g. Manning, Reference Manning2002, p. 27-30; Manning & Fink, Reference Manning and Fink2008). However, the evidence for the sex difference in Dr-l is mixed with some samples showing no dimorphism (e.g. Manning, Reference Manning2002, p. 21-22; Putz et al., Reference Putz, Gaulin, Sporter and McBurney2004), and little is known about its variation among nations and ethnic groups, whether it is stable with age and whether it relates to patterns of development. The present study considers Dr-l in the context of these variables using data from a large online sample (the British Broadcasting Company [BBC] internet study).

Previous research has documented associations between 2D:4D, Dr-l and prenatal sex steroids (see Breedlove, Reference Breedlove2010 for a review), including more recent research on associations between Dr-l and single-nucleotide polymorphisms (Zhanbing et al., Reference Zhanbing, Jie, Chunyue, Hong, Liang and Zhenghao2019; Zhang et al., Reference Zhang, Yang, Luan, Jia, Liu, Ma, Dang, Lu, Ma, Wang, Mu and Huo2021). However, these studies shed little light on whether Dr-l is sexually dimorphic and whether it correlates with many sexually dimorphic behavioural and physiological traits. Manning et al. (Reference Manning, Churchill and Peters2007) and Manning and Fink (Reference Manning and Fink2008) have considered sex differences in a large (n > 255,000) sample of self-reported 2D:4D and Dr-l in the BBC internet study. Both 2D:4D and Dr-l were sexually dimorphic (males < females) with an effect size for the former of right hand d = .20, left hand d = .15 and the latter d = .07, all p < .0001. These effect sizes are attenuated by imprecise finger measurement due to self-reported surveys. For example, mean sex differences in experimenter-measured 2D:4D are approximately d = .40 to .60 (Manning, Reference Manning2002). However, it is important to note that effect sizes for sex differences in Dr-l are less than half for those of 2D:4D. Perhaps, as a consequence of such small effect sizes, it remains unclear whether sexual dimorphism in Dr-l is widespread within and between national and ethnic groups.

Concerning correlations between Dr-l and sexually dimorphic traits, there are several examples in the literature for sex-dependent diseases and their links with patterns of development. One such is the association between breast cancer, left-handedness and Dr-l. Muller et al. (Reference Muller, Baglietto, Manning, McLean, Hopper and English2012) reported evidence from patterns of 2D:4D and Dr-l that suggested high prenatal T and E were linked to an increase in breast cancer risk. Left-handedness is associated with high prenatal T and increased risk of breast cancer in women (Ramadhani et al., Reference Ramadhani, Elias, van Noord, Grobbee, Peeters and Uiterwaal2005) and low Dr-l (high prenatal T) is related to a left-hand preference (Manning et al., Reference Manning, Trivers, Thornhill and Singh2000; Manning & Peters, Reference Manning and Peters2009). Early age at menarche has also been linked to increased risk of breast cancer and 2D:4D, particularly right-hand 2D:4D, has been reported to be negatively associated with age at menarche (e.g. Matchock, Reference Matchock2008; Manning & Fink, Reference Manning and Fink2011). In this regard, Dr-l may be associated with developmental patterns during puberty, including age at initiation of puberty in both girls and boys.

The present study explores the effects of sex, nation, ethnicity, age and self-perceived rate of physical development during puberty on participant-measured Dr-l. As a working hypothesis, it is assumed that Dr-l is a negative correlate of prenatal T and a positive correlate of prenatal E. Thus, Dr-l should show a sex difference (males < females) that is widespread across nations and ethnic groups and stable across age groups. Concerning the measures of pubertal development (self-perceived rate of physical development and age at menarche [females] or age that shaving began [males]), there is evidence that the timing of puberty is one correlate of prenatal androgenization. For example, high prenatal T is linked to late spermarche in boys (Cohen-Bendehan et al., 2005) and animal models have confirmed this association in males (Dela Cruz & Pereira, Reference Dela Cruz and Pereira2012). Therefore, it is predicted that high Dr-l will be linked to faster rates of self-perceived physical pubertal development across nations and ethnic groups.

Methods

The BBC internet study was a multi-ethnic and multi-national survey, hosted by the BBC on their Science and Nature website. It comprised around 200 questions concerning cognitive and behavioural tests and included information on demographics, personality, sexual behaviour, and physical characteristics, such as 2D:4D (see Reimers, Reference Reimers2007 for further details). A total sample of 255,116 participants completed all study tasks. In addition to ethnicity (Asian/Asian British, Black/Black British, Black other, Chinese, Middle/Near Eastern, Mixed Ethnic, White), participants provided information about their sex (male or female), age (integer 0 to 99 years), and where they resided (the United Kingdom, then 240 other countries). The predominant ethnicity was “White” (reported by 84.1% of participants), and the most commonly represented nations were the United Kingdom (46.9%), the United States (27.7%), Canada (5.2%), and Australia (3.6%) with 11 other nations represented by n >1,000 participants.

Participants responded to a two-question item concerning their self-perceived physical developmental rate at puberty. The questions were phrased as follows:

Compared to your classmates at school, was your rate of physical development, e.g. facial hair, breast development, during puberty”. Response options ranged from 1 (very slow) to 5 (very fast).

“How old were you when you started puberty (either when you started your first period or when you started shaving?)” Response options ranged up to 999 years old and these included some extreme values (0 years to 132 years). Therefore, the authors followed Manning and Fink (Reference Manning and Fink2011) in restricting the analyses to a range of 8 years to 17 years.

Participants self-measured 2D and 4D of right and left hands using the methodology of Manning et al. (Reference Manning, Scutt, Wilson and Lewis-Jones1998). They viewed a diagram of the hand and were instructed to measure their fingers on the ventral side of the digit from the fingertip to the most proximal crease with a conventional ruler. Measurements were reported to the nearest millimetre using dropdown menus. The 2D:4D was calculated by dividing the 2D by 4D digit lengths and Dr-l (the difference of right- minus left-hand 2D:4D) resulted from subtracting left from right 2D:4D. In the present study, the initial analyses were restricted to adults (>17 years) and in further analyses, considering the effect of age on Dr-l, the participants were >12 years. As in earlier reports, the tails of the 2D:4D distributions were removed by considering right and left 2D:4D within the range of ≥0.80 to ≤1.20.

Results

Descriptive statistics

The adult sample comprised 201,865 participants (110,955 males) of ages 18 to 99 years (M = 31.78, SD = 11.08) and the national sample included participants from 41 countries.

Dr-l in the adult sample ranged from −.400 to .400 with a mean of .001 (SD = .042). There was no indication for right or left skew of the Dr-l distribution (skew = .193) but it appeared leptokurtic with a higher and sharper central peak compared to the normal distribution (kurtosis = 7.921).

Sex and ethnic differences

There was a sex differences for Dr-l in the total sample and across nations with males having smaller values than females (males M = −.001, SD = .040; females M = .002, SD = .043, F[1,201863] = 195.61, p < .0001). Table 1 reports descriptive statistics of male and female Dr-l by nation together with effect sizes (Cohen’s d) for the sex difference (Figure 1). The mean effect size (male Dr-l – female Dr-l) was d = −.065 (a negative value denotes Dr-l male < female) and this differed from zero (t[40] = 4.88, p < .0001).

Table 1. Descriptive statistics (sample sizes, means and SD’s) for male and female Dr-l in 41 nations. A negative value of Cohen’s d effect size denotes the male mean Dr-l is lower than the female mean Dr-l

Figure 1. Effect sizes (Cohen’s d) for the sex difference in right-left 2D:4D (Dr-l) from participants of 41 nations.

Figure 2. The relationship between right-left 2D:4D (Dr-l) and self-perceived physical development in males and females.

With regard to ethnicity in the total sample, mean (SD’s and SE’s) values of Dr-l for seven ethnic groups are given in Table 2. Effect sizes for the sex differences varied from d = −.05 (Chinese) to −.12 and −.10 (Black/Black British and Black other, respectively). All values of d were negative, denoting lower mean Dr-l in males compared to females. A 2 (sex) x 7 (ethnicity) ANOVA with Dr-l as dependent variable showed an effect of sex (F[1,200597] = 32.45, p < .0001) and ethnicity (F[6,200597] = 8.84, p < .0001) but no interaction of sex * ethnicity (F[6,200597] = 0.83, p = .549). The mean sex difference was .003 independent from ethnicity. Whites and Middle/Near Eastern participants had the lowest mean Dr-l and Black participants had the highest mean Dr-l values. Significant differences were found for comparisons between Asian/Asian British vs. Black/Black British (mean difference = −.002, p < .05), Black other (-.003, p < .01), and White (.001, p < .01) participants; for Black/Black British vs. Middle/Near Eastern (.004, p < .01) and White (.004, p < .01) participants; for Black other vs. Middle/Near Eastern (.005, p < .001), Mixed Ethnic (.003, p < .05), and White (.004, p < .0001) participants; for Chinese vs. Middle/Near Eastern (.003, p < .01), and White (.003, p < .0001) participants; for Middle/Near Eastern vs. Mixed Ethnic (-.002, p < .05) participants; and for Mixed Ethnic vs. White (.001, p < .01) participants. The absence of an interaction between sex and ethnicity suggests that the effects on Dr-l were independent from one another.

Table 2. Descriptive statistics (sample sizes, means, SD’s and SE’s) of Dr-l split by sex in seven ethnic groups. Values of t and p for sex differences and effect sizes (Cohen’s d) are given for each ethnicity. Negative values of d denote lower mean Dr-l in males compared to females

Table 3. Descriptive statistics (sample sizes, means, SD’s and SE’s) of Dr-l and sample sizes split by sex in 45 year groups (ages 13 years to 57 years)

Sex and age effects

To examine the effects of sex and age on Dr-l, the authors considered participants >12 years of age. The analysis focused on year groups with n >1,000 participants to maintain sufficient statistical power; thus, in the data set this included participants 13 to 57 years (Table 3).

A 2 (sex) x 45 (age) ANOVA with Dr-l as dependent variable showed an effect of sex (F[1,227052] = 121.80, p < .0001) and a much smaller (but significant) effect of age (F[44,227052] = 1.88, p < .001) but no interaction of sex * age (F[44,227052] = 0.87, p = .711). Males had lower Dr-l than females (mean difference = .003). The absence of an interaction between sex and age suggests that the effects on Dr-l were independent from one another.

Because the prior analysis of ethnicity influences on Dr-l showed a small but significant effect, the authors performed the analysis of sex and age effects on Dr-l again, this time restricting the sample to the largest ethnic group, i.e. White participants. There was an effect of sex (F[1,191385] = 110.80, p < .0001) and age (F[44,191385] = 1.88, p < .001) but no interaction of sex * ethnicity (F[44,191385] = 0.93, p = .608). Thus, the effects of sex and age are essentially the same in the total sample and for White participants only.

Pubertal physical development

The self-perceived rate of pubertal physical development is a subjective measure and that of age at menarche/first shave is an objective measure. To establish whether the former is related to the latter, the authors examined relationships between the two variables. For females (n = 88,963), the correlation was r = −.58, p < .0001. For males (n = 102,572), it was r = −.38, p < .0001.

A series of linear regression analyses were performed with self-perceived pubertal physical development (females and males), age at menarche (females) or first shave (males) as the dependent variables, and Dr-l, right or left 2D:4D together with participant’s age, as independent variables. These analyses were conducted separately for female and male participants, first with the total sample and then for White participants only.

In females (n = 90,031), Dr-l (B = .24, SE B = .08, beta = .01, p < .01) and participant’s age (B = −.004, SE B = .0003, beta = −.04, p < .0001) predicted self-perceived pubertal physical developmental rate albeit in opposite directions (i.e. a positive association for the former and a negative association for the latter). Dr-l was negatively associated with age at menarche (n = 89,228; B = −.34, SE B = .11, beta = −.01, p < .01) and positively with participant’s age (B = .005, SE B = .0005, beta = .04, p < .0001). Similar findings were obtained with right 2D:4D for self-perceived pubertal physical developmental rate (B = .44, SE B = .07, beta = .02, p < .0001; participant’s age B = −.004, SE B = .0003, beta = −.04, p < .0001) and age at menarche (B = −.37, SE B = .02, beta = −.01, p = .0001; participant’s age B = .005, SE B = .0005, beta = .04, p < .0001). Left 2D:4D was also positively related to self-perceived pubertal physical developmental rate (B = .29, SE B = .07, beta = .01, p < .0001; participant’s age B = −.004, SE B = .0003, beta = −.04, p < .0001) but not to age at menarche (B = −.14, SE B = .10, beta = −.005, p = .16; participant’s age B = .005, SE B = .0005, beta = .04, p < .0001).

In common with females, male Dr-l was positively related to self-perceived pubertal physical developmental rate (n = 109,723; B = .15, SE B = .07, beta = .01, p < .05; participant’s age B = −.003, SE B = .0003, beta = −.04, p < .0001) and negatively related to age a first shave (n = 102,785, B = −.38, SE B = .12, beta = −.010, p < .01; participant’s age B = .02, SE B = .0004, beta = .11, p < .0001). Similarly, right 2D:4D was positively associated with self-perceived pubertal physical developmental rate (B = .14, SE B = .06, beta = .01, p < .05; age B = −.003, SE B = .0003, beta = −.04, p < .0001) and negatively related to age at first shave (B = −.22, SE B = .099, beta = −.01, p <.05). In contrast, left 2D:4D was not related to self-perceived pubertal physical developmental rate (B = .05, SE B = .06, beta = .001, p = .431; participant’s age B = −.003, SE B = .0003, beta = −.04, p < .0001), nor was it correlated with age at first shave (B = .04, SE B = .10, beta = .001, p = .70; participant’s age B = .02, SE B = .0004, beta = .11, p < .0001).

Considering White participants only revealed essentially the same findings as with the total sample. The analyses were as follows:

For females (n = 76,835), Dr-l (B = .25, SE B = .09, beta = .01, p < .01) and participant’s age (B = −.004, SE B = .0003, beta = −.05, p < .0001), were significantly related to self-perceived pubertal physical development rate and age. Dr-l was negatively associated with age at menarche (n = 76,188; B = −.38, SE B = .12, beta = −.010; p < .01) and positively with participant’s age (B = .003, SE B = .0005, beta = .03, p < .0001). Similar findings were again obtained with right 2D:4D (pubertal physical developmental rate, B = .42, SE B = .07, beta = .02, p < .0001; participant’s age B = −.004, SE B = .0003, beta = −.04, p < .0001) and age at menarche (B = −.47, SE B = .10, beta = −.02, p.< 0001; participant’s age, B = .003, SE B = .0005, beta = .03, p < .0001), and with left 2D:4D (pubertal physical development rate, B = .27, SE B = .08, beta = .01, p < .001; participant’s age B = −.004, SE B = .0003, beta = −.05, p < .0001), and age at menarche (B = −.22, SE B = .11, beta = −.008, p < .05; participant’s age (B = .003, SE B = .0005, beta = .03, p < .0001).

For males (n = 93,003), Dr-l (B = .22, SE B = .08, beta = .01, p < .01) and participant’s age (B = −.003, SE B = .0003, beta = −.04, p < .0001) predicted self-perceived pubertal physical development in the same directions as in females. Age at first shave was negatively related to Dr-l (n = 88,024, B = −.39, SE B = .13, beta = −.01, p < .05) and positively associated with participant’s age (B = .17, SE B = .0005, beta = 13, p < .0001). Similarly, right 2D:4D was positively associated with self-perceived pubertal development (B = .14, SE B = .07, beta = .01, p < .05; participant’s age B = −.003, SE B = .0003, beta = −.04, p < .0001) and negatively with age at first shave (B = −.30, SE B = .11, beta = −.009, p < .01; participant’s age B = .17, SE B = .0005, beta = .13, p = <.0001). There were no significant relationships between left 2D:4D and self-perceived pubertal development (B = −.001, SE B = .07, beta = .00007, p = .982; participant’s age B = −.003, SE B = .0003, beta = −.04, p < .0001), or age at first shave (B = −.03, SE B = .11, beta = .001, p = .76; participant’s age B = .02, SE B = .0005, beta = .13, p < .0001).

Therefore, high values of Dr-l were associated with faster rates of self-perceived physical development (females and males; Figure 2), earlier menarche (females) or earlier age at first shave (males) and this applied to participants in the total sample and for White participants only.

Discussion

The present study found that Dr-l from participant-measured digit lengths is sexually dimorphic such that, in comparison to females, males tend to have lower 2D:4D in their right hand compared to their left (male Dr-l < female Dr-l). The dimorphism remained significant after the effect of age was removed. The effect size of the sex difference (males-females) across 41 nations was d = −.065, i.e. it is less than that for 2D:4D (right hand d = 2.0, left hand d = .15). Across the national sample, there was one country with no difference in male-female Dr-l (Greece, d = 0), seven nations with male > female Dr-l (ranging from d = − .007 [Turkey] to .130 [Romania], and 33 nations with male < female Dr-l (ranging from d = −.010 [Ireland] to −.240 [United Arab Emirates]). Further analysis revealed an effect of ethnicity with low Dr-l in Whites and Middle-Eastern peoples, intermediate values among Asian and Chinese groups, and high Dr-l in Black participants. The self-perceived puberty rate was negatively correlated with the reported age at menarche in females (r = −.58) and the age at first shave in males (r = −.38). Menarche is a developmental milestone that may be more memorable than the first shave, and this may account for the sex difference in the strength of these associations. The self-perceived pubertal physical developmental rate was associated with Dr-l and onset of puberty (age at menarche/first shave) in both males and females. It is to be noted that the former measure of puberty timing is a relative one that may be more appropriate for comparisons within groups such as nations. It is less relevant to comparisons within ethnic groups. Age at menarche/first shave is an absolute variable that can be used across nations and ethnic groups. Therefore, the stability of the sex difference in Dr-l in both nations and ethnic groups is relevant to self-perceived and absolute rates of pubertal development.

A pattern of sexual dimorphism that is widespread across nations, independent of ethnic groups and age, and which correlates with the rate of physical development suggests Dr-l is a universal human marker for sex steroids. The evidence indicates that low Dr-l is associated with high T and low E, while high Dr-l correlates with low T and high E. In this regard, Dr-l shares many of its properties with 2D:4D. Whether it is also a correlate of prenatal sex steroids which retains its information across all age groups remains somewhat of an open question because the data of the present study did not extend to participants younger than 13 years. However, low Dr-l is linked to left-lateralized hand preference in Afro-Caribbean children (Manning et al., Reference Manning, Trivers, Thornhill and Singh2000) in addition to a left-hand preference for writing across nations and ethnicities in the BBC internet study (Manning & Peters, Reference Manning and Peters2009). This suggests that Dr-l is an early correlate of sex-dependent behaviours that include handedness.

In addition to containing information about prenatal sex steroids, the Dr-l may also correlate with androgen production in challenging situations (Manning et al., Reference Manning, Kilduff, Cook, Crewther and Fink2014). Thus, the organizational effects of early exposure to androgen and oestrogen may prime the endocrine system to respond to aggressive challenges. Such challenges may provoke short-term spikes of T which are themselves associated with increases in strength (Kilduff et al., Reference Kilduff, Cook, Bennett, Crewther, Bracken and Manning2013; Crewther et al., Reference Crewther, Cook, Kilduff and Manning2015; Crewther & Cook, Reference Crewther and Cook2019). These situations are regularly met with during sporting encounters. Performance in aggressive contact sports (e.g. rugby) has been reported to be linked to Dr-l. Players with low Dr-l are often chosen from their squad to represent their first team and their nation and are prolific try scores (Bennett et al., Reference Bennett, Manning, Cook and Kilduff2010). Competitive situations, such as track races, also represent a challenge for which endurance is important. Low Dr-l has been reported to correlate with high maximal oxygen uptake (VO2max), high velocity at VO2max, and high maximum lactate concentration (Hill et al., Reference Hill, Simpson, Millet, Manning and Kilduff2012). It is not known whether the association between Dr-l and such endurance measures is correlated with T changes in response to competitive challenges. A note of caution must be sounded here, in that links between Dr-l and androgen responses to challenge have not always been replicated (e.g. Ribeiro et al., Reference Ribeiro, Neave, Morais, Kilduff, Taylor and Butovskaya2016). Non-replication of links between Dr-l and sex-dependent traits may, in part, result from difficulties in accurately measuring Dr-l.

Experimenter-measured digit (2D or 4D) lengths show high repeatability, and error in measurement is very small in comparison to differences in digit length between individuals (Manning et al., Reference Manning, Scutt, Wilson and Lewis-Jones1998). For values of 2D:4D, the error is composed of that from 2D and 4D, and for Dr-l the error includes that from right 2D, right 4D, left 2D and left 4D. Simply put, it is difficult to accurately measure Dr-l. The problem is compounded when digit lengths are participant-measured rather than experimenter-measured. It is suggested that multiple measures of Dr-l be taken to reduce measurement error. For example, Hill et al. (Reference Hill, Simpson, Millet, Manning and Kilduff2012) considered the relationships between 2D:4D (right 2D:4D, left 2D:4D and Dr-l) and maximal oxygen uptake in a sample of teenage boys. Digit lengths were measured from photocopies taken three times over five months. The mean Dr-l (SD) of the three measurements was 0.014 (.024), i.e. the SD was considerably smaller than that from self-measurement of digit length in the present study (SD, males = .040 to females = .043). The high SD values for the latter have probably arisen from elevated rates of random measurement errors. This is likely to attenuate the effect sizes reported from studies in which digit length is self-measured. Effect sizes may also be reduced by difficulties in recall of pubertal timing. Furthermore, the age when shaving commenced could be influenced by cultural expectations regarding the acceptability of facial shaving.

In conclusion, the current study found Dr-l to be sexually dimorphic (males < females) with a small effect size (male-female d = −.065) which is likely to be attenuated by random measurement errors in the large self-measured sample. The sex difference was widespread across a sample of 41 nations, it was present within ethnic groups and it remained significant after the influence of age was removed. Concerning ethnicity, Dr-l differed across groups such that White and Middle-Eastern peoples had low Dr-l, intermediate values were found in Asian and Chinese participants and high values among Black people. Dr-l was positively associated with the self-perceived physical developmental rate during puberty in females and males and negatively with age at menarche (females) and first shave (males) in the total sample (including seven ethnicities) and the largest ethnic group (i.e. Whites). Collectively, these findings suggest that Dr-l, in common with 2D:4D (in particular right 2D:4D), is a negative correlate of prenatal T and a positive correlate of prenatal E. The organizational changes associated with prenatal sex steroids are thought to relate to pubertal sex hormones that determine patterns of puberty. Consistent with this the authors have found evidence that Dr-l relates positively to the self-perceived speed of pubertal development. Further work is necessary to establish whether, in common with right 2D:4D, Dr-l is established prenatally and is stable during development from birth to 12 years.

Disclosure Statements

Funding

This research received no specific grant from any funding agency, commercial entity, or not-for-profit organization.

Conflict of interest

The authors have no conflicts of interest to declare.

Ethical approval

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national and institutional committees on human experimentation and with the Helsinki Declaration of 1975, as revised in 2008.

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Figure 0

Table 1. Descriptive statistics (sample sizes, means and SD’s) for male and female Dr-l in 41 nations. A negative value of Cohen’s d effect size denotes the male mean Dr-l is lower than the female mean Dr-l

Figure 1

Figure 1. Effect sizes (Cohen’s d) for the sex difference in right-left 2D:4D (Dr-l) from participants of 41 nations.

Figure 2

Figure 2. The relationship between right-left 2D:4D (Dr-l) and self-perceived physical development in males and females.

Figure 3

Table 2. Descriptive statistics (sample sizes, means, SD’s and SE’s) of Dr-l split by sex in seven ethnic groups. Values of t and p for sex differences and effect sizes (Cohen’s d) are given for each ethnicity. Negative values of d denote lower mean Dr-l in males compared to females

Figure 4

Table 3. Descriptive statistics (sample sizes, means, SD’s and SE’s) of Dr-l and sample sizes split by sex in 45 year groups (ages 13 years to 57 years)