Rushton, Race, and Twinning
2500 words
As is the case with the other lines of evidence that intend to provide sociobiological evidence in support of the genetic basis of human behavior and development (relating to homology, heritability, and adaptation), Rushton’s work reduces to no evidence at all. (Lerner, 2018)
Introduction
From 1985 until his death in 2012, J. P. Rushton attempted to marshal all of the data and support he could for a theory called r-K selection theory or Differential K theory (Rushton, 1985). The theory posited that while humans were the most K species of all, some human races were more K than others, so it then followed that some human races were more r than others. Rushton then collated mass amounts of data and wrote what would become his magnum opus, Race, Evolution and Behavior (Rushton, 1997). So in the r/K theory first proposed by MacArthur and Wilson, unstable, unpredictable environments favored an r strategy whereas a stable, predictable environments favored a K strategy. (See here for my response to Rushton’s r/K.)
So knowing this, one of the suite of traits Rushton put on his r/K matrix was twinning rates. Rushton (1997: 6) stated:
the rate of dizygotic twinning, a direct index of egg production, is less than 4 per 1,000 births among Mongoloids, 8 per 1,000 among Caucasoids, and 16 or greater per 1,000 among Negroids.
I won’t contest the claim that the rate in DZ twinning is higher by race—because it’s pretty well-established with recent data that blacks are more likely to have twins than whites (that is, blacks have a slightly higher chance of having twins than whites, who have a slightly higher chance of having twins than Asians) (Santana, Surita, and Cecatti, 2018; Wang, Dongarwar, and Salihu, 2020; Monden, Pison, and Smits, 2021)—I’m merely going to contest the causes of DZ twinning. Because it’s clear that Rushton was presuming this to be a deeply evolutionary trait since a highs rate of twins—in an evolutionary context—would mean that there would be a higher chance for children of a particular family to survive and therefore spread their genes and thusly would, in his eyes, lend credence to his claim that Africans were more r compared to whites who were more r compared to Asians.
But to the best of my knowledge, Rushton didn’t explain why, biologically, blacks would have more twins than whites—he merely said “This race has more twins than this race, so this lends credence to my theory.” That is, he didn’t posit a biological mechanism that would instantiate a higher rate of twinning in blacks compared to whites and Asians and then explain how environmental effects wouldn’t have any say in the rate of twinning between the races. However, I am privy to environmental factors that would lead to higher rates of twinning and I am also privy to the mechanisms of action that allow twinning to occur (eg phytoestrogens, FSH, LH, and IGF). And while these are of course biological factors, I will show that there are considerable effects of environmental interactions like diet on the levels of these hormones which are associated with twinning. I will also explain how these hormones are related to twinning.
While the claim that there is a difference in rate of DZ twinning by race seems to be true, I don’t think it’s a biological trait, nevermind an evolutionary one as Rushton proposed (because even if Rushton’s r/K were valid, “Negroids” would be K and “Mongoloids” would be r, Anderson, 1991). Nonetheless, Rushton’s r/K theory is long-refuted, though he did call attention to some interesting observations (which other researchers never ignored, they just didn’t attempt some grand theory of racial differences).
Follicle stimulating hormone, leutinizing hormone, and insulin-like growth factor
We know that older women are more likely to have twins while younger women are less likely (Oleszczuk et al, 2001), so maternal age is a factor. As women age, a hormone called follicle stimulating hormone (FSH) increases due to a decline in estrogen, and it is one of the earliest signs of female reproductive aging (McTavish et al, 2007), being one of the main biomarkers of ovarian reserve tested on day 3 of the menstrual cycle (Roudebush, Kivens, and Mattke, 2008). It is well established that twinning is different in different geographic locations, that the rate of MZ twins is constant at around 3.5 to 4 per 1,000 births (so what is driving the differences is the birth of DZ twins), and that it increases due to an increase in FSH (Santana, Surita, and Cecatti, 2018). We also know that pre-menopausal women who have given birth to DZ twins have higher levels of FSH on the third day of their menstrual cycle (Lambalk et al, 1998).
So if FSH levels stay too high for too long then multiple eggs are released, which could lead to an increase in DZ twinning. FSH stimulates the maturation and growth of ovarian follicles, each of which contains an immature egg called an oocyte. FSH acts on the ovaries to promote the development of multiple ovarian follicles during pregnancy, a process which is called recruitment. In a normal menstrual cycle, only one follicle is stimulated to release one egg; but when FSH levels are elevated, this results in the development and maturation of more than one follicle which is known as polyovulation. Polyovulation then increases the chance of the release of multiple eggs during ovulation. Thus, if more than one egg is released during a menstrual cycle, and they both are fertilized, it can then lead to the development of DZ twins.
Along with FSH, we also have luetenizing hormone (LH). So FSH and LH act synergistically (Raju et al, 2013). LH, like FSH, isn’t directly responsible for the increase in twinning, but the process that it allows (playing a role in ovulation) is a crucial factor in twinning. So LH is responsible for triggering ovulation, which is the release of a mature egg from the ovarian follicle. (Ovulation occurs typically 24 to 36 hours after LH increases.) In a typical menstrual cycle, only one follicle is stimulated to release one egg, which is triggered by the surge in LH. But if there are multiple mature follies in the ovaries (which could be influenced by FSH), then a surge in LH can lead to the release of more than one egg. So the interaction of LH with other hormone like FSH, along with the presence of multiple mature follicles, can be associated with having a higher chance of having DZ twins. FSH therapies are also used in assisted reproduction (eg Munoz et al, 1995 in mice; Ferraretti et al, 2004; Pang, 2005; Pouwer, Farquhar, and Kremer, 2015; Fatemi et al, 2021).
So when it comes to FSH, we know that malnutrition may play a role in twinning, and also that wild yams—a staple food in Nigeria—increases phytoestrogens which increase FSH in the body of women (Bartolus, et al, 1999). Wild yams have been used to increase estrogen in women’s bodies (due to the phytoestrogens they contain), and it enhances estradiol through the mechanism of binding to estrogen receptor sites (Hywood, 2008). And since Nigeria has the highest rate of twinning in the world (Santana, Surita, and Cecatti, 2018), and their diet is wild yam-heavy (Bartolus, et al, 1999), it seems that this fact would go a long way in explaining why they have higher rates of twinning. Mount Sinai says that “Although it does not seem to act like a hormone in the body, there is a slight risk that wild yam could produce similar effects to estrogen.” It acts as a weak phytoestrogen (Park et al, 2009). (But see Beckham, 2002.) But when phytoestrogens are consumed, they can then bind to estrogen receptors in the body and trigger estrogenic effects which could then lead to the potential stimulation and release of multiple eggs which would increase the chance of DZ twinning.
One study showed that black women, in comparison to white women, had “lower follicular phase LH:FSH ratios” (Reuttman et al, 2002; cf Marsh et al, 2011), while Randolph et al (2004) showed that black women had higher FSH than Asian and white women. So the lower LH:FSH ratio could affect the timing and regulation of ovulation, and a lower LH:FSH level could reduce the chances of premature ovulation and could affect the release of multiple eggs.
Lastly, when it comes to insulin-like growth factor (IGF), this could be influenced by a high protein diet or a high carb diet. Diets high in high glycemic carbs can lead to increase insulin production which would then lead to increased IGF levels. Just like with FSH and LH, increased levels of IGF could also in concert with the other two hormones influence the maturation and release of multiple eggs during a menstrual cycle which would then increase the chance of twinning (Yoshimura, 1998). IGF can also stimulate the growth and development of multiple follicles (Stubbs et al, 2013) and have them mature early if IGF levels are high enough (Mazerbourgh and Monget, 2018). This could then also lead to polyovulation, triggering the release of more than one egg during ovulation. IGF can also influence the sensitivity of the ovaries to hormonal signals, like those from the pituitary gland, which then leads to enhanced ovarian sensitivity to hormones like FSH and LH which then, of course, would act synergistically increasing the rate of dizygotic twinning. (See Mazerbourgh and Monget, 2018 for a review of this.)
So we know that black women have higher levels of IGF-1 and free IGF-1—but lower IGF-2 and IGFBP-3—than white women (Berrigan et al, 2010; Fowke et al, 2011). The higher IGF-1 levels in black women could lead to increase ovarian sensitivity to FSH and LH, and thus enhanced ovarian sensitivity could lead to the promotion and release of multiple eggs during ovulation. The lower IGF-2 levels could contribute to the balance of IGF-1 and IGF-2, which would then further influence the ovarian sensitivity to other hormones. IGFBP-3 is a binding protein which regulated the bioavailability of IGF-1, so lower levels of IGFBP-3 could lead to higher concentrations of free IGF-1, which would then further stimulate the ovarian follicles and could lead to polyovulation, leading to increased twinning. Though there is some evidence that this difference does have a “genetic basis” (Higgins et al, 2005), we know that dietary factors do have an effect on IGF levels (Heald et al, 2003).
Rushton’s misinterpretations
Rushton got a ton wrong, but he was right about some things too (which is to be expected if you’re looking to create some grand theory of racial differences). I’m not too worried about that. But what I AM worried about, is Rushton’s outright refusal to address his most serious critics in the literature, most importantly Anderson (1991) and Graves (2002 a, b). If you check his book (Rushton, 1997: 246-248), his responses are hardly sufficient to address the devestating critiques of his theory. (Note how Rushton never responded to Graves, 2002—ever.) Gorey and Cryns (1995) showed how Rushton cherry-picked what he liked for his theory while stating that “any behavioral differences which do exist between blacks, whites and Asian Americans for example, can be explained in toto by environmental differences which exist between them” while Ember, Ember, and Peregrine (2003) concluded similarly. (Rushton did respond to Gorey and Cryns, but not Ember, Ember, and Peregrine.) Cernovsky and Littman (2019) also showed how Rushton cherry-picked his INTERPOL crime data.
Now that I have set the stage for Rushton’s “great” scholarship, let’s talk about the response he got to his twinning theory.
Allen et al (1992) have a masterful critique of Rushton’s twinning theory. They review twinning stats in other countries across different time periods and come to conclude that “With such a wide overlap between races, and such great variation within races, twinning rate is probably no better than intelligence as an index of genetic status for racial groups.” They also showed that the twinning mechanism didn’t seem to be a relevant factor in survival, until the modern day with the advancement of our medical technologies, that is. So since twinning increases the risk for death in the mother (Steer, 2007; Santana et al, 2018). Rushton also misinterpreted numerous traits associated with twinning:
individual twin proneness and its correlates do not provide Rushton’s desired picture of a many-faceted r- strategy (even if such individual variation could have evolutionary meaning). With the exception of shorter menstrual cycles found in one study, the traits Rushton cites as r-selected in association with twinning are either statistical artifacts of no reproductive value or figments of misinterpretation.
Conclusion
I have discussed a few biological variables that lead to higher rates of twinning and I have cited some research which shows that black women have higher rates of some of the hormones that are related to higher rates of twinning. But I have also shown that it’s not so simple to jump to a genetic conclusion, since these hormones are of course mediated by environmental factors like diet.
Rushton quite clearly takes these twinning rate differences to be “genetic” in nature, but we are in the 2020s now, not the 1980s, and we now know that genes are necessary, but passive players in the formation of phenotypes (Noble, 2011, 2012, 2016; Richardson, 2017, 2021; Baverstock, 2021; McKenna, Gawne, and Nijhout, 2022). These new ways of looking at genes—as passive, not active causes, and as not special from any other developmental resources—shows how the reductionist thinking of Rushton and his contemporaries were straight out false. Nonetheless, while Rushton did get it right that there is a racial difference in twinning, the difference, I think, isn’t a genetic difference and I certainly don’t think they it lends credence to his Differential K theory, since Anderson showed that if we were to accept Rushton’s premises, then African would be K and Asians would be r. So while there also are differences in menarche between blacks and whites, this too also seems to be environmentally driven.
Rushton’s twinning thesis was his “best bet” at attempting to show that his r/K theory was “right” about racial differences. But the numerous devestating critiques of not only Rushton’s thesis on twinning but his r/K Differential K theory itself shows that Rushton was merely a motivated reasoner (David Duke also consulted with Rushton when Duke wrote his book My Awakening, where Duke describes how psychologists led to his “racial awakening”), so “The claim that Rushton was acting only as a scientist is not credible given this context” (Winston, 2020). Even the usefulness of psychometric life history theory has been recently questioned (this derives from Rushton’s Differential K, Sear, 2020).
But it is now generally accepted that Rushton’s r/K and the current psychometric life history theory that rose from the ashes of Rushton’s theory just isn’t a good way to conceptualize how humans live in the numerous biomes we live in.
Racial Differences in Motor Development: A Bio-Cultural View of Motor Development
3050 words
Introduction
Psychologist J. P. Rushton was perhaps most famous for attempting to formulate a grand theory of racial differences. He tried to argue that, on a matrix of different traits, the “hierarchy” was basically Mongoloids > Caucasoids > Negroids. But Rushton’s theory was met with much force, and many authors in many of the different disciplines in which he derived his data to formulate his theory attacked his r/K selection theory also known as Differential K theory (where all humans are K, but some humans are more K than others, so some humans are more r than others). Nonetheless, although his theory has been falsified for many decades, did he get some things right about race? Well, a stopped clock is right twice a day, so it wouldn’t be that outlandish to believe that Rushton got some things right about racial differences, especially when it comes to physical differences. While we can be certain that there are physical differences in groups we term “racial groups” and designate “white”, “black”, “Asian”, “Native American”, and “Pacific Islander” (the five races in American racetalk), this doesn’t lend credence to Rushton’s r/K theory.
In this article, I will discuss Rushton’s claims on motor development between blacks and whites. I will argue that he basically got this right, but it is of no consequence to the overall truth of his grand theory of racial differences. We know that there are physical differences between racial groups. But that there are physical differences between racial groups doesn’t entail that Rushton’s grand theory is true. The only entailment, I think, that can be drawn from that is there is a possibility that physical differences between races could exist between them, but it is a leap to attribute these differences to Rushton’s r/K theory, since it is a falsified theory on logical, empirical and methodological grounds. So I will argue that while Rushton got this right, a stopped clock is right twice a day but this doesn’t mean that his r/K theory is true for human races.
Was Rushton right? Evaluating newer studies on black-white motor development
Imagine three newborns: one white, one black and the third Asian and you observe the first few weeks of their lives. Upon observing the beginnings of their lives, you begin to notice differences in motor development between them. The black infant is more motorically advanced than the white infant who is more motorically advanced than the Asian infant. The black infant begins to master movement, coordination and dexterity showing a remarkable level of motoric dexterity, while the white infant shows less motoric dexterity than the black infant, and the Asian infant still shows lower motoric dexterity than the white infant.
These disparities in motor development are evidence in the early stages of life, so is it genetic? Cultural? Bio-cultural? I will argue that what explains this is a bio-cultural view, and so it will of course eschew reductionism, but of course as infants grow and navigate through their cultural milieu and family lives, this will have a significant effect on their experiences and along with it their motoric development.
Although Rushton got a lot wrong, it seems that he got this issue right—there does seem to be differences in precocity of motor development between the races, and the references he cites below in his 2000 edition of Race, Evolution, and Behavior—although most are ancient compared to today’s standards—hold to scrutiny today, where blacks walk earlier than whites who walk earlier than Asians.
Rushton (2000: 148-149) writes:
Revised forms of Bayley’s Scales of Mental and Motor Development administered in 12 metropolitan areas of the United States to 1,409 representative infants aged 1-15 months showed black babies scored consistently above whites on the Motor Scale (Bayley, 1965). This difference was not limited to any one class of behavior, but included: coordination (arm and hand); muscular strength and tonus (holds head steady, balances head when carried, sits alone steadily, and stands alone); and locomotion (turns from side to back, raises self to sitting, makes stepping movements, walks with help, and walks alone).
Similar results have been found for children up to about age 3 elsewhere in the United States, in Jamaica, and in sub-Saharan Africa (Curti, Marshall, Steggerda, & Henderson, 1935; Knobloch & Pasamanik, 1953; Williams & Scott, 1953; Walters, 1967). In a review critical of the literature Warren (1972) nonetheless reported evidence for African motor precocity in 10 out of 12 studies. For example, Geber (1958:186) had examined 308 children in Uganda and reported an “all-round advance of development over European standards which was greater the younger the child.” Freedman (1974, 1979) found similar results in studies of newboms in Nigeria using the Cambridge Neonatal Scales (Brazelton & Freedman, 1971).
Mongoloid children are motorically delayed relative to Caucasoids. In a series of studies carried out on second- through fifth-generation Chinese-Americans in San Francisco, on third- and fourth-generation Japanese-Americans in Hawaii, and on Navajo Amerindians in New Mexico and Arizona, consistent differences were found between these groups and second- to fourth-generation European-Americans using the Cambridge Neonatal Scales (Freedman, 1974, 1979; Freedman & Freedman, 1969). One measure involved pressing the baby’s nose with a cloth, forcing it to breathe with its mouth. Whereas the average Chinese baby fails to exhibit a coordinated “defense reaction,” most Caucasian babies turn away or swipe at the cloth with the hands, a response reported in Western pediatric textbooks as the normal one.
On other measures including “automatic walk,” “head turning,” and “walking alone,” Mongoloid children are more delayed than Caucasoid children. Mongoloid samples, including the Navajo Amerindians, typically do not walk until 13 months, compared to the Caucasian 12 months and Negro 11 months (Freedman, 1979). In a standardization of the Denver Developmental Screening Test in Japan, Ueda (1978) found slower rates of motoric maturation in Japanese as compared with Caucasoid norms derived from the United States, with tests made from birth to 2 months in coordination and head lifting, from 3 to 5 months in muscular strength and rolling over, at 6 to 13 months in locomotion, and at 15 to 20 months in removing garments.
Regarding newer studies on this matter, there are differences between European and Asian children in the direction that Rushton claimed. Infants from Hong Kong displayed a difference sequence of rolling compared to Canadian children. There does seem to be a disparity in motoric development between Asian and white children (Mayson, Harris, and Bachman, 2007). These authors do cite some of the same studies like the DDST (which is currently outdated) which showed how Asian children were motorically delayed compared to white children. And although they put caution on their findings of their literature review, it’s quite clear that this pattern exists and it is a bio-cultural one. So they conclude their literature review writing “the literature reviewed suggests differences in rate of motor development among children of various ethnic origins, including those of Asian and European descent” and that “Limited support suggests also that certain developmental milestones, such as rolling, may differ between infants of Asian and European origin.” Further, cultural practices in northern China—for example, lying them on their backs on sandbags—stall the onset of walking in babies sitting, crawling, and walking by a few months (Karasik et al, 2011).
This is related to the muscles that are used to roll from a supine to prone position and vice versa. Since some Asian children spend a longer time in apparatuses that aren’t conducive to growing a strong muscular base to be able to roll from the supine to prone position, to crawl and eventually walk, this is the “cultural” in the “bio-cultural” approach I will argue for.
One study on Norwegian children found that half of the children were waking by 13 months (the median) while 25 percent were walking by 12 months and 75 percent were walking by 14 months (Storvold, Aarethun, and Bratberg, 2013). One reason for the delayed response time could be supine sleeping, which was put into effect during the Back to Sleep program to mitigate causes of death from SIDS. Although it obviously saved tens of thousands of infant lives, it came at a cost of slightly stunted motoric development. It also seems that there is poor predictive value for infant milestones such as walking when it comes to health (Jenni et al, 2012).
Black Caribbean, black African and Indian infants were less likely to show delays in gross motor milestones compared to white infants. But Pakistani and Bangladeshi infants were more likely to be delayed in motoric development and communicative gestures, which was partly attributed to socio-cultural factors (Kelly et al, 2006). Kelly et al (2006: 828) also warn against genetic conclusions based on their large findings of difference between white and African and Caribbean infants:
The differences we observed between Black African and Black Caribbean compared with White infants are large and remain unaffected after adjusting for important covariates. This makes it tempting to conclude that the remaining effect must be a consequence of genetic differences. However, such a conclusion would be prematurely drawn. First, we have not included the measurement of genetic factors in our analysis, and, therefore, the presence of such effects cannot be demonstrated. Second, speculating on such effects should only be done alongside recognition that the model we have been able to test contains imperfect measurement.
It has also been observed that black and white children achieved greater mastery of motoric ability (locomotor skills) compared to Asian children but there was no difference by age group (Adeyemi-Walker et al, 2018). It was also found that infants with higher motor development scores had a lower weight weight relative to their length as they grew. So it was found that delayed motor development was associated with higher weight relative to length (Shoaibi et al, 2018). Black infants are also more motorically advanced and this is seen at up to two years of age (Malina, 1988) while black children perform better on tests of motor ability than white children (Okano et al, 2001). Kilbride et al (1970) also found that Baganda infants in Uganda showed better motoric ability than white American children. Campbell and Heddeker (2001) also showed that black infants were more motorically advanced than infants of other races.
It is clear that research like this blows up the claim that there should be a “one-size fits all” chart for motoric development in infants and that there should be race-specific milestones. This means that we should throw out the WEIRD assumptions when it comes to motoric development of infants (Karasik et al, 2011). They discuss research in other cultures where African, Caribbean and Indian caregivers massage the muscles of babies, stretch their limbs, toss them in their air, sit them up, and walk with them while helping them which then shapes their muscles and has them learn the mind-muscle connections needed to be able to learn how to eventually walk. And it also seems that random assignment to exercise excelerates how quickly an infant walks. White infants also sit at 6 months while black infants sit at 4 months. Nonetheless, it is clear that culture and context can indeed shape motoric development in groups around the world.
A bio-cultural view of motor development
When it comes to biological influences on motor development, sex and age are two important variables (Escolano-Perez, Sanchez-Lopez, and Herrero-Nivela, 2021). Important to this, of course, is that the individual must be normal, and they must have a normal brain with normal vision and spatial skills. They must be able to hear (to eventually follow commands and hear what is going on in their environment to change their course of action if need be). Further, the child’s home environment and gestational age influence different portions of motoral development (Darcy, 2022). After infants begin crawling, their whole world changes and they process visual motion better and faster, being able to differentiate between different speeds and directions, so a stimulating environment for the infant can spur the development of the brain (Van der Meer and Van der Weel, 2022). Biological maturation and body weight also affect motor development. Walking develops naturally, but walking and motor competence need to be nurtured for the child to reach their full potential; lower motor competence is related to higher body weight (Drenowatz and Greier, 2019).
One study on Dutch and Israeli infants even found—using developmental niche construction—that “infant motor development indeed is at least partly culturally constructed [which] emphasizes the importance of placing infant motor development studies into their ‘cultural cradle‘ (Oudgeneong, Atun-Eni, and Schaik, 2020). Gross motor development—rolling over, crawling, alternating kicks, moving from lying to sitting, and having tummy time—is recognized by the WHO. Further, children from different cultures have different experiences, which also could lead to, for example, not doing things that are conducive to the development of gross motor development (Angulo-Barroso et al, 2010). Moreover, motor development is embodied, enculturated, embedded, and enabling (Adolph and Hoch, 2020). It is also known that differences in the cultural environment “have a non-negligible effect on motor development” (Bril, 1986). Motor development also takes place in physical environments and is purposive and goal-directed (Hallemans, Verbeque, and de Walle, 2020).
So putting this all together, we have conceptualized motor development as a dynamic process which is influenced by a complex interplay of biological and cultural factors (Barnes, Zieff, and Anderson, 1999). Biological factors like sex, age, health, sensory abilities, and socio-cultural factors like home environment and developmental niches explain motor development and differences in them between individuals. The cultural differences, though, can impede motoral development, and not allow one to reach milestones they would have otherwise reached in a different cultural environment, just like if one couldn’t hear or see would have trouble reaching developmental milestones.
Children of course grow up in cultural environments and contexts and so they are culturally situated. So what this means is that both the cultural and social environment the child finds themselves in will of course then influence their physical and mental development and lead them to their milestones they hit which is dictated by the normal biology they have which then is allowed by the socio-cultural environment they are born into. So we have the bio-cultural view on motor development, and beyond the cultural environment the child finds themselves in, the interactions they have between parents and caregivers—more knowledgeable others—can be pertinent to their motor development and reaching of developmental milestones. Cultural practices and expectations could emphasize certain milestones over others and then guide the child towards the trajectory. So the framework recognizes that normal biology and sensory perceptions are needed for the development of normal motor development, but that cultural and social differences in that context will spur motor development in the child who finds themselves in different cultures.
Conclusion
Was Rushton right about this? Yes, I think he was. The recent literature on the matter speaks to this. But that doesn’t mean that his r/K selection theory is true. There are differences in motor development between races. But what is interesting is the interaction between biological and cultural factors that spur motor development. The question of black motor precocity, however, is a socio-political question, since science is a social convention influenced by the values of the scientist in question. Now, to the best of my knowledge, Rushton himself never carried out studies on this, he just collated them to use them for his racial trait matrix. However, it’s quite clear that Rushton was politically politically and socially motivated to prove that his theory was true.
But physical differences between the races are easy enough to prove, and of course they are due to biological and cultural interactions. There are differences in skin color and their properties between blacks and whites (Campiche et al, 2019). There is a 3 percent center of mass difference between blacks and whites which explains why each race excels at running and swimming (Bejan, Jones, and Charles, 2010). There are differences in body composition between Asians and whites which means, at the same BMI, Asians would have thicker skin folds and higher body fat than whites (Wang et al, 1994; WHO expert consultation, 2004; Wang et al, 2011). Just like at the same BMI, blacks have lower body fat and thinner skin folds than whites (Vickery, Cureton, and Collins, 1988; Wagner and Heyward, 2000; Flegal et al, 2010). There are differences in menarche and thelarche between blacks and whites (Wagner and Heyward, 2000; Kaplowitz, 2008; Reagan et al, 2013; Cabrera et al, 2014; Deardorff et al, 2014; ). There are differences in anatomy and physiology and somatotype between blacks and whites and these differences would explain how the races would perform on the big four lifts. There are interesting and real physical differences between races.
So obviously, what is considered “normal” is different in different cultures, and motor development is no different. So just like I think we should have different BMI and skin fold charts for different races, so too should we have different developmental milestones for different races and cultures. The discussion here is clear, since what is “average” and “normal” is different based on race and culture. Like for instance, black babies begin walking around 11 months, white babies around 12 months and Native American babies at 13 months. So while parents may be worried that their child didn’t hit a certain developmental milestone like walking, sitting, rolling, taking a bio-cultural approach will assuage these worries.
Nonetheless, while Rushton was right about race and motor development, we need to center his research project in context. He was clearly motivated, despite the numerous and forceful critiques of his framework, to prove that he was right. But the continuance of Rushton pushing his theory up until his death shows me that he was quite obviously socially and politically motivated, contrary to what he may have said.
We have approached this paper from the stance that science is a social activity, with all observations influenced by, as well as reflective of, the values of scientists and the political leanings of the sociocultural context within which research is conducted. We suggest that when questions of group difference are pursued in science, awareness of how the categories themselves have been shaped by social and historical forces, as well as of the potential effects on society, is important. (Barnes, Zieff, and Anderson, 1999)
NotPoliticallyCorrect 