Behavioural genetics, also referred to as behaviour genetics, is a field of scientific research that uses genetic methods to investigate the nature and origins of individual differences in behaviour. While the name "behavioural genetics" connotes a focus on genetic influences, the field broadly investigates genetic and environmental influences, using research designs that allow removal of the confounding of genes and environment. Behavioural genetics was founded as a scientific discipline by Francis Galton in the late 19th century, only to be discredited through association with eugenics movements before and during World War II. In the latter half of the 20th century, the field saw renewed prominence with research on inheritance of behaviour and mental illness in humans (typically using twin and family studies), as well as research on genetically informative model organisms through selective breeding and crosses. In the late 20th and early 21st centuries, technological advances in molecular genetics made it possible to measure and modify the genome directly. This led to major advances in model organism research (e.g., knockout mice) and in human studies (e.g., genome-wide association studies), leading to new scientific discoveries.
Findings from behavioural genetic research have broadly impacted modern understanding of the role of genetic and environmental influences on behaviour. These include evidence that nearly all researched behaviors are under a significant degree of genetic influence, and that influence tends to increase as individuals develop into adulthood. Further, most researched human behaviours are influenced by a very large number of genes and the individual effects of these genes are very small. Environmental influences also play a strong role, but they tend to make family members more different from one another, not more similar.
Selective breeding and the domestication of animals is perhaps the earliest evidence that humans considered the idea that individual differences in behaviour could be due to natural causes.[1] Plato and Aristotle each speculated on the basis and mechanisms of inheritance of behavioural characteristics.[2] Plato, for example, argued in The Republic that selective breeding among the citizenry to encourage the development of some traits and discourage others, what today might be called eugenics, was to be encouraged in the pursuit of an ideal society.[2][3] Behavioural genetic concepts also existed during the English renaissance, where William Shakespeare perhaps first coined the terms "nature" versus "nurture" in The Tempest, where he wrote in Act IV, Scene I, that Caliban was "A devil, a born devil, on whose nature Nurture can never stick".[3][4]
Modern-day behavioural genetics began with Sir Francis Galton, a nineteenth-century intellectual and cousin of Charles Darwin.[3] Galton was a polymath who studied many subjects, including the heritability of human abilities and mental characteristics. One of Galton's investigations involved a large pedigree study of social and intellectual achievement in the English upper class. In 1869, 10 years after Darwin's On the Origin of Species, Galton published his results in Hereditary Genius.[5] In this work, Galton found that the rate of "eminence" was highest among close relatives of eminent individuals, and decreased as the degree of relationship to eminent individuals decreased. While Galton could not rule out the role of environmental influences on eminence, a fact which he acknowledged, the study served to initiate an important debate about the relative roles of genes and environment on behavioural characteristics. Through his work, Galton also "introduced multivariate analysis and paved the way towards modern Bayesian statistics" that are used throughout the scienceslaunching what has been dubbed the "Statistical Enlightenment".[6]
The field of behavioural genetics, as founded by Galton, was ultimately undermined by another of Galton's intellectual contributions, the founding of the eugenics movement in 20th century society.[3] The primary idea behind eugenics was to use selective breeding combined with knowledge about the inheritance of behaviour to improve the human species.[3] The eugenics movement was subsequently discredited by scientific corruption and genocidal actions in Nazi Germany. Behavioural genetics was thereby discredited through its association to eugenics.[3] The field once again gained status as a distinct scientific discipline through the publication of early texts on behavioural genetics, such as Calvin S. Hall's 1951 book chapter on behavioural genetics, in which he introduced the term "psychogenetics",[7] which enjoyed some limited popularity in the 1960s and 1970s.[8][9] However, it eventually disappeared from usage in favour of "behaviour genetics".
The start of behavior genetics as a well-identified field was marked by the publication in 1960 of the book Behavior Genetics by John L. Fuller and William Robert (Bob) Thompson.[1][10] It is widely accepted now that many if not most behaviours in animals and humans are under significant genetic influence, although the extent of genetic influence for any particular trait can differ widely.[11][12] A decade later, in February 1970, the first issue of the journal Behavior Genetics was published and in 1972 the Behavior Genetics Association was formed with Theodosius Dobzhansky elected as the association's first president. The field has since grown and diversified, touching many scientific disciplines.[3][13]
The primary goal of behavioural genetics is to investigate the nature and origins of individual differences in behaviour.[3] A wide variety of different methodological approaches are used in behavioral genetic research,[14] only a few of which are outlined below.
Animal behavior genetic studies are considered more reliable than are studies on humans, because animal experiments allow for more variables to be manipulated in the laboratory.[15] In animal research selection experiments have often been employed. For example, laboratory house mice have been bred for open-field behaviour,[16]thermoregulatory nesting,[17] and voluntary wheel-running behaviour.[18] A range of methods in these designs are covered on those pages.
Behavioural geneticists using model organisms employ a range of molecular techniques to alter, insert, or delete genes. These techniques include knockouts, floxing, gene knockdown, or genome editing using methods like CRISPR-Cas9.[19] These techniques allow behavioural geneticists different levels of control in the model organism's genome, to evaluate the molecular, physiological, or behavioural outcome of genetic changes.[20] Animals commonly used as model organisms in behavioral genetics include mice,[21] zebra fish,[22] and the nematode species C. elegans.[23]
Some research designs used in behavioural genetic research are variations on family designs (also known as pedigree designs), including twin studies and adoption studies.[14] Quantitative genetic modelling of individuals with known genetic relationships (e.g., parent-child, sibling, dizygotic and monozygotic twins) allows one to estimate to what extent genes and environment contribute to phenotypic differences among individuals.[24] The basic intuition of the twin study is that monozygotic twins share 100% of their genome and dizygotic twins share, on average, 50% of their segregating genome. Thus, differences between the two members of a monozygotic twin pair can only be due to differences in their environment, whereas dizygotic twins will differ from one another due to environment as well as genes. Under this simplistic model, if dizygotic twins differ more than monozygotic twins it can only be attributable to genetic influences. An important assumption of the twin model is the equal environment assumption[25] that monozygotic twins have the same shared environmental experiences as dizygotic twins. If, for example, monozygotic twins tend to have more similar experiences than dizygotic twinsand these experiences themselves are not genetically mediated through gene-environment correlation mechanismsthen monozygotic twins will tend to be more similar to one another than dizygotic twins for reasons that have nothing to do with genes.[26]
Twin studies of monozygotic and dizygotic twins use a biometrical formulation to describe the influences on twin similarity and to infer heritability.[24][27]The formulation rests on the basic observation that the variance in a phenotype is due to two sources, genes and environment. More formally, V a r ( P ) = g + ( g ) + {displaystyle Var(P)=g+(gtimes epsilon )+epsilon } , where P {displaystyle P} is the phenotype, g {displaystyle g} is the effect of genes, {displaystyle epsilon } is the effect of the environment, and ( g ) {displaystyle (gtimes epsilon )} is a gene by environment interaction. The g {displaystyle g} term can be expanded to include additive ( a 2 {displaystyle a^{2}} ), dominance ( d 2 {displaystyle d^{2}} ), and epistatic ( i 2 {displaystyle i^{2}} ) genetic effects. Similarly, the environmental term {displaystyle epsilon } can be expanded to include shared environment ( c 2 {displaystyle c^{2}} ) and non-shared environment ( e 2 {displaystyle e^{2}} ), which includes any measurement error. Dropping the gene by environment interaction for simplicity (typical in twin studies) and fully decomposing the g {displaystyle g} and {displaystyle epsilon } terms, we now have V a r ( P ) = ( a 2 + d 2 + i 2 ) + ( c 2 + e 2 ) {displaystyle Var(P)=(a^{2}+d^{2}+i^{2})+(c^{2}+e^{2})} . Twin research then models the similarity in monozygotic twins and dizogotic twins using simplified forms of this decomposition, shown in the table.[24]
The simplified Falconer formulation can then be used to derive estimates of a 2 {displaystyle a^{2}} , c 2 {displaystyle c^{2}} , and e 2 {displaystyle e^{2}} . Rearranging and substituting the r M Z {displaystyle r_{MZ}} and r D Z {displaystyle r_{DZ}} equations one can obtain an estimate of the additive genetic variance, or heritability, a 2 = 2 ( r M Z r D Z ) {displaystyle a^{2}=2(r_{MZ}-r_{DZ})} , the non-shared environmental effect e 2 = 1 r M Z {displaystyle e^{2}=1-r_{MZ}} and, finally, the shared environmental effect c 2 = r M Z a 2 {displaystyle c^{2}=r_{MZ}-a^{2}} .[24] The Falconer formulation is presented here to illustrate how the twin model works. Modern approaches use maximum likelihood to estimate the genetic and environmental variance components.[28]
The Human Genome Project has allowed scientists to directly genotype the sequence of human DNA nucleotides.[29] Once genotyped, genetic variants can be tested for association with a behavioural phenotype, such as mental disorder, cognitive ability, personality, and so on.[30]
Some behavioural genetic designs are useful not to understand genetic influences on behaviour, but to control for genetic influences to test environmentally-mediated influences on behaviour.[45] Such behavioural genetic designs may be considered a subset of natural experiments,[46] quasi-experiments that attempt to take advantage of naturally occurring situations that mimic true experiments by providing some control over an independent variable. Natural experiments can be particularly useful when experiments are infeasible, due to practical or ethical limitations.[46]
A general limitation of observational studies is that the relative influences of genes and environment are confounded. A simple demonstration of this fact is that measures of 'environmental' influence are heritable.[47] Thus, observing a correlation between an environmental risk factor and a health outcome is not necessarily evidence for environmental influence on the health outcome. Similarly, in observational studies of parent-child behavioural transmission, for example, it is impossible to know if the transmission is due to genetic or environmental influences, due to the problem of passive gene-environment correlation.[46] The simple observation that the children of parents who use drugs are more likely to use drugs as adults does not indicate why the children are more likely to use drugs when they grow up. It could be because the children are modelling their parents' behaviour. Equally plausible, it could be that the children inherited drug-use-predisposing genes from their parent, which put them at increased risk for drug use as adults regardless of their parents' behaviour. Adoption studies, which parse the relative effects of rearing environment and genetic inheritance, find a small to negligible effect of rearing environment on smoking, alcohol, and marijuana use in adopted children,[48] but a larger effect of rearing environment on harder drug use.[49]
Other behavioural genetic designs include discordant twin studies,[45] children of twins designs,[50] and Mendelian randomization.[51]
There are many broad conclusions to be drawn from behavioural genetic research about the nature and origins of behaviour.[3][52] Three major conclusions include: 1) all behavioural traits and disorders are influenced by genes; 2) environmental influences tend to make members of the same family more different, rather than more similar; and 3) the influence of genes tends to increase in relative importance as individuals age.[3]
It is clear from multiple lines of evidence that all researched behavioural traits and disorders are influenced by genes; that is, they are heritable. The single largest source of evidence comes from twin studies, where it is routinely observed that monozygotic (identical) twins are more similar to one another than are same-sex dizygotic (fraternal) twins.[11][12]
The conclusion that genetic influences are pervasive has also been observed in research designs that do not depend on the assumptions of the twin method. Adoption studies show that adoptees are routinely more similar to their biological relatives than their adoptive relatives for a wide variety of traits and disorders.[3] In the Minnesota Study of Twins Reared Apart, monozygotic twins separated shortly after birth were reunited in adulthood.[53] These adopted, reared-apart twins were as similar to one another as were twins reared together on a wide range of measures including general cognitive ability, personality, religious attitudes, and vocational interests, among others.[53] Approaches using genome-wide genotyping have allowed researchers to measure genetic relatedness between individuals and estimate heritability based on millions of genetic variants. Methods exist to test whether the extent of genetic similarity (aka, relatedness) between nominally unrelated individuals (individuals who are not close or even distant relatives) is associated with phenotypic similarity.[41] Such methods do not rely on the same assumptions as twin or adoption studies, and routinely find evidence for heritability of behavioural traits and disorders.[37][39][54]
Just as all researched human behavioural phenotypes are influenced by genes (i.e., are heritable), all such phenotypes are also influenced by the environment.[11][52] The basic fact that monozygotic twins are genetically identical but are never perfectly concordant for psychiatric disorder or perfectly correlated for behavioural traits, indicates that the environment shapes human behaviour.[52]
The nature of this environmental influence, however, is such that it tends to make individuals in the same family more different from one another, not more similar to one another.[3] That is, estimates of shared environmental effects ( c 2 {displaystyle c^{2}} ) in human studies are small, negligible, or zero for the vast majority of behavioural traits and psychiatric disorders, whereas estimates of non-shared environmental effects ( e 2 {displaystyle e^{2}} ) are moderate to large.[11] From twin studies c 2 {displaystyle c^{2}} is typically estimated at 0 because the correlation ( r M Z {displaystyle r_{MZ}} ) between monozygotic twins is at least twice the correlation ( r D Z {displaystyle r_{DZ}} ) for dizygotic twins. When using the Falconer variance decomposition ( 1.0 = a 2 + c 2 + e 2 {displaystyle 1.0=a^{2}+c^{2}+e^{2}} ) this difference between monozygotic and dizygotic twin similarity results in an estimated c 2 = 0 {displaystyle c^{2}=0} . It is important to note that the Falconer decomposition is simplistic.[24] It removes the possible influence of dominance and epistatic effects which, if present, will tend to make monozygotic twins more similar than dizygotic twins and mask the influence of shared environmental effects.[24] This is a limitation of the twin design for estimating c 2 {displaystyle c^{2}} . However, the general conclusion that shared environmental effects are negligible does not rest on twin studies alone. Adoption research also fails to find large ( c 2 {displaystyle c^{2}} ) components; that is, adoptive parents and their adopted children tend to show much less resemblance to one another than the adopted child and his or her non-rearing biological parent.[3] In studies of adoptive families with at least one biological child and one adopted child, the sibling resemblance also tends be nearly zero for most traits that have been studied.[11][55]
The figure provides an example from personality research, where twin and adoption studies converge on the conclusion of zero to small influences of shared environment on broad personality traits measured by the Multidimensional Personality Questionnaire including positive emotionality, negative emotionality, and constraint.[56]
Given the conclusion that all researched behavioural traits and psychiatric disorders are heritable, biological siblings will always tend to be more similar to one another than will adopted siblings. However, for some traits, especially when measured during adolescence, adopted siblings do show some significant similarity (e.g., correlations of .20) to one another. Traits that have been demonstrated to have significant shared environmental influences include internalizing and externalizing psychopathology,[57] substance use[58] and dependence,[49] and intelligence.[58]
Genetic effects on human behavioural outcomes can be described in multiple ways.[24] One way to describe the effect is in terms of how much variance in the behaviour can be accounted for by alleles in the genetic variant, otherwise known as the coefficient of determination or R 2 {displaystyle R^{2}} . An intuitive way to think about R 2 {displaystyle R^{2}} is that it describes the extent to which the genetic variant makes individuals, who harbour different alleles, different from one another on the behavioural outcome. A complementary way to describe effects of individual genetic variants is in how much change one expects on the behavioural outcome given a change in the number of risk alleles an individual harbours, often denoted by the Greek letter {displaystyle beta } (denoting the slope in a regression equation), or, in the case of binary disease outcomes by the odds ratio O R {displaystyle OR} of disease given allele status. Note the difference: R 2 {displaystyle R^{2}} describes the population-level effect of alleles within a genetic variant; {displaystyle beta } or O R {displaystyle OR} describe the effect of having a risk allele on the individual who harbours it, relative to an individual who does not harbour a risk allele.[59]
When described on the R 2 {displaystyle R^{2}} metric, the effects of individual genetic variants on complex human behavioural traits and disorders are vanishingly small, with each variant accounting for R 2 < 0.3 % {displaystyle R^{2}<0.3%} of variation in the phenotype.[3] This fact has been discovered primarily through genome-wide association studies of complex behavioural phenotypes, including results on substance use,[61] personality,[62] fertility,[63] schizophrenia,[36] depression,[62][64] and endophenotypes including brain structure[65] and function.[66] There are a small handful of replicated and robustly studied exceptions to this rule, including the effect of APOE on Alzheimer's disease,[67] and CHRNA5 on smoking behaviour, and ALDH2 (in individuals of East Asian ancestry) on alcohol use.[68]
On the other hand, when assessing effects according to the {displaystyle beta } metric, there are a large number of genetic variants that have very large effects on complex behavioural phenotypes. The risk alleles within such variants are exceedingly rare, such that their large behavioural effects impact only a small number of individuals. Thus, when assessed at a population level using the R 2 {displaystyle R^{2}} metric, they account for only a small amount of the differences in risk between individuals in the population. Examples include variants within APP that result in familial forms of severe early onset Alzheimer's disease but affect only relatively few individuals. Compare this to risk alleles within APOE, which pose much smaller risk compared to APP, but are far more common and therefore affect a much greater proportion of the population.[69]
Finally, there are classical behavioural disorders that are genetically simple in their etiology, such as Huntington's disease. Huntington's is caused by a single autosomal dominant variant in the HTT gene, which is the only variant that accounts for any differences among individuals in their risk for developing the disease, assuming they live long enough.[70] In the case of genetically simple and rare diseases such as Huntington's, the variant R 2 {displaystyle R^{2}} and the O R {displaystyle OR} are simultaneously large.[59]
In response to general concerns about the replicability of psychological research, behavioral geneticists Robert Plomin, John C. DeFries, Valerie Knopik, and Jenae Neiderhiser published a review of the ten most well-replicated findings from behavioral genetics research.[52] The ten findings were:
Behavioural genetic research and findings have at times been controversial. Some of this controversy has arisen because behavioural genetic findings can challenge societal beliefs about the nature of human behaviour and abilities. Major areas of controversy have included genetic research on topics such as racial differences, intelligence, violence, and human sexuality.[71] Other controversies have arisen due to misunderstandings of behavioural genetic research, whether by the lay public or the researchers themselves.[3] The notion of heritability is easily misunderstood to imply causality.[72] When behavioral genetics researchers say that a behavior is X% heritable, that does not mean that genetics causes up to X% of the behavior. Instead, heritability is a statement about population level correlations.
Perhaps the most controversial subject has been on race and genetics,[71] where fringe research groups have claimed that observed racial differences on a behavioral trait are a product of racial differences in allele frequencies. Such claims are made most frequently to differences between White and Black racial groups. These are complicated issues that are extremely difficult to resolve due to the confounding of the racial group and environmental experience, such as discrimination and oppression. Indeed, race is a social construct that is not very useful for genetic research. Instead, geneticists use concepts such as ancestry, which is more rigorously defined.[73] For example, a so-called "Black" race may include all individuals of relatively recent African descent ("recent" because all humans are descended from African ancestors). However, there is more genetic diversity in Africa than the rest of the world combined,[74] so speaking of a "Black" race is without a precise genetic meaning.[73]
Qualitative research has fostered arguments that behavioural genetics is an ungovernable field without scientific norms or consensus, which fosters controversy. The argument continues that this state of affairs has led to controversies including race and IQ, instances where variation within a single gene was found to very strongly influence a controversial phenotype (e.g., the "gay gene" controversy), and others. This argument, made by Aaron Panofsky in his book Misbehaving Science, further states that because of the persistence of controversy in behavior genetics and the failure of disputes to be resolved, behavior genetics does not conform to the standards of good science.[75]
The scientific assumptions on which parts of behavioral genetic research are based have also been criticized as flawed.[72] Genome wide association studies are often implemented with simplifying statistical assumptions, such as additivity, which may be statistically robust but unrealistic. Critics further contend that, in humans, behavior genetics represents a misguided form of genetic reductionism based on inaccurate interpretations of seriously flawed statistical analyses.[76] Studies comparing monozygotic (MZ) and dizygotic (DZ) twins assume that environmental influences will be the same in both types of twins, but this assumption may also be unrealistic. In reality MZ twins are treated more alike than DZ twins,[72] which itself may be an example of evocative gene-environment correlation, suggesting that one's genes influence their treatment by others. It is also not possible in twin studies to completely eliminate effects of the shared womb environment, although studies comparing twins who experience monochorionic and dichorionic environments in utero do exist, and indicate limited impact.[77] Studies of twins separated in early life include children who were separated not at birth but part way through childhood.[72] The effect of early rearing environment can therefore be evaluated to some extent in such a study, by comparing twin similarity for those twins separated early and those separated later.[53]
View original post here:
Behavioural genetics - Wikipedia
- The Smell Of Death Has A Strange Influence On Human Behavior - IFLScience - October 26th, 2024 [October 26th, 2024]
- "WEIRD" in psychology literature oversimplifies the global diversity of human behavior. - Psychology Today - October 2nd, 2024 [October 2nd, 2024]
- Scientists issue warning about increasingly alarming whale behavior due to human activity - Orcasonian - September 23rd, 2024 [September 23rd, 2024]
- Does AI adoption call for a change in human behavior? - Fast Company - July 26th, 2024 [July 26th, 2024]
- Dogs can smell human stress and it alters their own behavior, study reveals - New York Post - July 26th, 2024 [July 26th, 2024]
- Trajectories of brain and behaviour development in the womb, at birth and through infancy - Nature.com - June 18th, 2024 [June 18th, 2024]
- AI model predicts human behavior from our poor decision-making - Big Think - June 18th, 2024 [June 18th, 2024]
- ZkSync defends Sybil measures as Binance offers own ZK token airdrop - TradingView - June 18th, 2024 [June 18th, 2024]
- On TikTok, Goldendoodles Are People Trapped in Dog Bodies - The New York Times - June 18th, 2024 [June 18th, 2024]
- 10 things only introverts find irritating, according to psychology - Hack Spirit - June 18th, 2024 [June 18th, 2024]
- 32 animals that act weirdly human sometimes - Livescience.com - May 24th, 2024 [May 24th, 2024]
- NBC Is Using Animals To Push The LGBT Agenda. Here Are 5 Abhorrent Animal Behaviors Humans Shouldn't Emulate - The Daily Wire - May 24th, 2024 [May 24th, 2024]
- New study examines the dynamics of adaptive autonomy in human volition and behavior - PsyPost - May 24th, 2024 [May 24th, 2024]
- 30000 years of history reveals that hard times boost human societies' resilience - Livescience.com - May 12th, 2024 [May 12th, 2024]
- Kingdom of the Planet of the Apes Actors Had Trouble Reverting Back to Human - CBR - May 12th, 2024 [May 12th, 2024]
- The need to feel safe is a core driver of human behavior. - Psychology Today - April 15th, 2024 [April 15th, 2024]
- AI learned how to sway humans by watching a cooperative cooking game - Science News Magazine - March 29th, 2024 [March 29th, 2024]
- We can't combat climate change without changing minds. This psychology class explores how. - Northeastern University - March 11th, 2024 [March 11th, 2024]
- Bees Reveal a Human-Like Collective Intelligence We Never Knew Existed - ScienceAlert - March 11th, 2024 [March 11th, 2024]
- Franciscan AI expert warns of technology becoming a 'pseudo-religion' - Detroit Catholic - March 11th, 2024 [March 11th, 2024]
- Freshwater resources at risk thanks to human behavior - messenger-inquirer - March 11th, 2024 [March 11th, 2024]
- Astrocytes Play Critical Role in Regulating Behavior - Neuroscience News - March 11th, 2024 [March 11th, 2024]
- Freshwater resources at risk thanks to human behavior - Sunnyside Sun - March 11th, 2024 [March 11th, 2024]
- Freshwater resources at risk thanks to human behavior - Blue Mountain Eagle - March 11th, 2024 [March 11th, 2024]
- 7 Books on Human Behavior - Times Now - March 11th, 2024 [March 11th, 2024]
- Euphemisms increasingly used to soften behavior that would be questionable in direct language - Norfolk Daily News - February 29th, 2024 [February 29th, 2024]
- Linking environmental influences, genetic research to address concerns of genetic determinism of human behavior - Phys.org - February 29th, 2024 [February 29th, 2024]
- Emerson's Insight: Navigating the Three Fundamental Desires of Human Nature - The Good Men Project - February 29th, 2024 [February 29th, 2024]
- Dogs can recognize a bad person and there's science to prove it. - GOOD - February 29th, 2024 [February 29th, 2024]
- What Is Organizational Behavior? Everything You Need To Know - MarketWatch - February 4th, 2024 [February 4th, 2024]
- Overcoming 'Otherness' in Scientific Research Commentary in Nature Human Behavior USA - English - USA - PR Newswire - February 4th, 2024 [February 4th, 2024]
- "Reichman University's behavioral economics program: Navigating human be - The Jerusalem Post - January 19th, 2024 [January 19th, 2024]
- Of trees, symbols of humankind, on Tu BShevat - The Jewish Star - January 19th, 2024 [January 19th, 2024]
- Tapping Into The Power Of Positive Psychology With Acclaimed Expert Niyc Pidgeon - GirlTalkHQ - January 19th, 2024 [January 19th, 2024]
- Don't just make resolutions, 'be the architect of your future self,' says Stanford-trained human behavior expert - CNBC - December 31st, 2023 [December 31st, 2023]
- Never happy? Humans tend to imagine how life could be better : Short Wave - NPR - December 31st, 2023 [December 31st, 2023]
- People who feel unhappy but hide it well usually exhibit these 9 behaviors - Hack Spirit - December 31st, 2023 [December 31st, 2023]
- If you display these 9 behaviors, you're being passive aggressive without realizing it - Hack Spirit - December 31st, 2023 [December 31st, 2023]
- Men who are relationship-oriented by nature usually display these 9 behaviors - Hack Spirit - December 31st, 2023 [December 31st, 2023]
- A look at the curious 'winter break' behavior of ChatGPT-4 - ReadWrite - December 14th, 2023 [December 14th, 2023]
- Neuroscience and Behavior Major (B.S.) | College of Liberal Arts - UNH's College of Liberal Arts - December 14th, 2023 [December 14th, 2023]
- The positive health effects of prosocial behaviors | News | Harvard ... - HSPH News - October 27th, 2023 [October 27th, 2023]
- The valuable link between succession planning and skills - Human Resource Executive - October 27th, 2023 [October 27th, 2023]
- Okinawa's ants show reduced seasonal behavior in areas with more human development - Phys.org - October 27th, 2023 [October 27th, 2023]
- How humans use their sense of smell to find their way | Penn Today - Penn Today - October 27th, 2023 [October 27th, 2023]
- Wrestling With Evil in the World, or Is It Something Else? - Psychiatric Times - October 27th, 2023 [October 27th, 2023]
- Shimmying like electric fish is a universal movement across species - Earth.com - October 27th, 2023 [October 27th, 2023]
- Why do dogs get the zoomies? - Care.com - October 27th, 2023 [October 27th, 2023]
- How Stuart Robinson's misconduct went overlooked for years - Washington Square News - October 27th, 2023 [October 27th, 2023]
- Whatchamacolumn: Homeless camps back in the news - News-Register - October 27th, 2023 [October 27th, 2023]
- Stunted Growth in Infants Reshapes Brain Function and Cognitive ... - Neuroscience News - October 27th, 2023 [October 27th, 2023]
- Social medias role in modeling human behavior, societies - kuwaittimes - October 27th, 2023 [October 27th, 2023]
- The gift of reformation - Living Lutheran - October 27th, 2023 [October 27th, 2023]
- After pandemic, birds are surprisingly becoming less fearful of humans - Study Finds - October 27th, 2023 [October 27th, 2023]
- Nick Treglia: The trouble with fairness and the search for truth - 1819 News - October 27th, 2023 [October 27th, 2023]
- Science has an answer for why people still wave on Zoom - Press Herald - October 27th, 2023 [October 27th, 2023]
- Orcas are learning terrifying new behaviors. Are they getting smarter? - Livescience.com - October 27th, 2023 [October 27th, 2023]
- Augmenting the Regulatory Worker: Are We Making Them Better or ... - BioSpace - October 27th, 2023 [October 27th, 2023]
- What "The Creator", a film about the future, tells us about the present - InCyber - October 27th, 2023 [October 27th, 2023]
- WashU Expert: Some parasites turn hosts into 'zombies' - The ... - Washington University in St. Louis - October 27th, 2023 [October 27th, 2023]
- Is secondhand smoke from vapes less toxic than from traditional ... - Missouri S&T News and Research - October 27th, 2023 [October 27th, 2023]
- How apocalyptic cults use psychological tricks to brainwash their ... - Big Think - October 27th, 2023 [October 27th, 2023]
- Human action pushing the world closer to environmental tipping ... - Morung Express - October 27th, 2023 [October 27th, 2023]
- What We Get When We Give | Harvard Medicine Magazine - Harvard University - October 27th, 2023 [October 27th, 2023]
- Psychological Anime: 12 Series You Should Watch - But Why Tho? - October 27th, 2023 [October 27th, 2023]
- Roosters May Recognize Their Reflections in Mirrors, Study Suggests - Smithsonian Magazine - October 27th, 2023 [October 27th, 2023]
- June 30 Zodiac: Sign, Traits, Compatibility and More - AZ Animals - May 13th, 2023 [May 13th, 2023]
- Indiana's Funding Ban for Kinsey Sex-Research Institute Threatens ... - The Chronicle of Higher Education - May 13th, 2023 [May 13th, 2023]
- Have AI Chatbots Developed Theory of Mind? What We Do and Do ... - The New York Times - March 31st, 2023 [March 31st, 2023]
- Scoop: Coming Up on a New Episode of HOUSEBROKEN on FOX ... - Broadway World - March 31st, 2023 [March 31st, 2023]
- Here's five fall 2023 classes to fire up your bookbag - Duke Chronicle - March 31st, 2023 [March 31st, 2023]
- McDonald: Aspen's like living in a 'Pullman town' - The Aspen Times - March 31st, 2023 [March 31st, 2023]
- Children Who Are Exposed to Awe-Inspiring Art Are More Likely to Become Generous, Empathic Adults, a New Study Says - artnet News - March 31st, 2023 [March 31st, 2023]
- DataDome Raises Another $42M to Prevent Bot Attacks in Real ... - AlleyWatch - March 31st, 2023 [March 31st, 2023]
- Observing group-living animals with drones may help us understand ... - Innovation Origins - March 31st, 2023 [March 31st, 2023]
- Mann named director of School of Public and Population Health - Boise State University - March 31st, 2023 [March 31st, 2023]
- Irina Solomonova's bad behavior is the star of Love Is Blind - My Imperfect Life - March 31st, 2023 [March 31st, 2023]
- Health quotes Dill in article about rise of Babesiosis - UMaine News ... - University of Maine - March 31st, 2023 [March 31st, 2023]
- There's still time for the planet, Goodall says, if we stay hopeful - University of Wisconsin-Madison - March 31st, 2023 [March 31st, 2023]
- Relationship between chronotypes and aggression in adolescents ... - BMC Psychiatry - March 31st, 2023 [March 31st, 2023]