Four major barriers prevent the easy appraisal of the natural hormonal levels that characterize the eight human prototypes.
Assays that fail to measure the variations of handedness with the degree of sensitivity established by Annett’s peg tests obstruct new insight and obscure potentially valuable observation. Annett’s work concluded that humans evolved as a random-handed species, which transitioned to right-handed when brains became lateralized for speech. Her peg tests measure degrees of right and random-handedness and are integral for establishing a locus related to social structure, disease/condition proclivity and maturation rate propensity. It is essential that different studies, particularly studies across cultures, compare apples to apples and use Annett’s protocols when measuring handedness.
It would be useful if Annett’s techniques were required to measure handedness around the world, quickly. Dietary changes within patrifocal societies may be skewing results dramatically. Aboriginal societies with a matrifocal foundation have almost completely disappeared. There are very few tools available to measure variations in societal balanced polymorphisms. Annett’s peg tests seem to measure the effects of testosterone and some indirect effects of estrogen fairly well.
The eight environmental variables noted above profoundly impact the hormone levels of males and females in a variety of contexts. To effectively measure the natural hormonal thresholds in ontogeny at any point, one must have an understanding of how that person’s hormonal levels are being influenced and altered by external variables. Adult hormone levels are dramatically impacted by a variety of factors. Existing studies show wild variation in results because these studies ignore influential variables. One study that measured testosterone levels neglected to take into consideration the time of day that levels were tested. In addition, the effects of stress cannot be underestimated. For example, measuring the testosterone levels of an autistic child in an institutional setting does little to provide an idea of that child’s base hormonal threshold, particularly if that child is on a standard institutional diet. Diet has been shown to have an effect on the symptoms of autism (Hjiej, Doyen, Couprie, Kaye & Contejean, 2008).
Some diseases and conditions appear at both ends of the left/right spectrum and occupy multiple poles of both matrifocal and patrifocal social structure. Annett approached dyslexia etiologies from a new perspective and established a protocol, which discovered that handedness congregated at both the extreme left and right ends of the spectrum. Diseases and conditions with more than one etiology often confound studies and frustrate attempts to discover patterns in social structure, handedness, hormonal constellations and ethnicity. It may seem that a disease such as schizophrenia, or a condition such as obsessive-compulsive disorder, does not always associate with a specific social structure or prototype predilection when more than one etiology is potentially in play.
Lastly, the season in which an individual is born affects the maturational delay and acceleration of that individual. Season of birth can thus help polarize a society’s social structure to either end of the spectrum. The effects of pineal-influenced testosterone levels may not merely be influencing those who live in migrating populations but also those who live in relative climatic extremes. When individuals within a society congregate at the hormonal extremes, vacating the balanced polymorphistic middle where those with the heterozygote advantage reside, it becomes nearly impossible to form conclusions about a society normally based on a seamless arc, or balance. In other words, climate and migration patterns influence the variables we’ve been noting.
These four conditions that inhibit high quality information regarding hormone levels—inconsistent handedness studies, untracked environmental variables, multiple pole disease/condition etiologies and season of birth effects—are primary reasons that the Geschwind/Galaburda hypothesis drew mixed support.
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Norman Geschwind and his colleagues suggested that a number of diseases and conditions tend to align with specific handedness and cerebral lateralization tendencies. Geschwind believed that the random-handed (often left-handers) and the anomalously dominant, both of whom exhibit cerebral hemispheres near the same size, were evolutionary derivations. I agree with Annett (2002) that the random-handed and anomalously dominant are our evolutionary forebears, but I’ve added that these ancestral genotypes are matrifocal in origin.
Approaching Geschwind and Galaburda’s (1987) thesis with a heterochronic/social structure perspective gives one the ability to hypothesize the etiologies of a host of diseases and conditions as well as suggest a relationship between handedness, hormonal associations, social structure, lateralization, ethnicity and environmental variables.
These are some of the diseases and conditions noted in the literature (mostly from Geschwind and Galaburda, 1987) that offer correlations with some of the variables addressed in this model: alcoholism, Alzheimer’s disease, anxiety, asthma, ataxia telangiectasia, atopic syndrome, attention deficit disorder, attention deficit hyperactivity disorder, autism, benign intracranial hypertension, bi-polar disorder, borderline personality disorder, breast cancer, congenital adrenal hyperplasia (CAH), cluster headaches, celiac disease, conduct disorder, congenital heart disease, dementia, depression, diabetes, Down’s syndrome, dyslexia, dystrophia myotonica, endometriosis, epilepsy, gastrointestinal issues, harelip, heart disease, Huntington’s disease, immune disorders, hyperkinetic syndrome, Kartagener syndrome, Klinefelter syndrome, Klippel-Feil syndrome, lupus erythematosus, migraine headaches, mital valve prolapse, narcissistic personality disorder, obesity, obsessive compulsive disorder, oppositional defiant disorder, osteoporosis, ovarian cysts, Parkinson’s disease, phobias, pilonidal sinus, polycystic ovary syndrome, prostate cancer, schizophrenia, scoliosis, spina bifida, stuttering, temporal lobe epilepsy, thyroid disorders, torticollis, Tourette’s syndrome, Turner syndrome and twinning. Cross reference these variables with handedness, social structure, maturation rates, ethnicity, family of origin, cerebral dominance and hormonal levels. All of these conditions offer opportunities to observe the relationships of these conditions and diseases to the eight human prototypes.
