With the advent of increasingly inexpensive access to brain imaging technology, neuroscience has entered a fascinating period of rapid advancement. The ability to generate images of what’s going on in our brains is hugely exciting, and the enthusiasm for trying to apply this science to education should come as no surprise.
However, neuroscience is probably the ‘wrong level of description’ to provide meaningful insight into classroom practice: observing the actions of particular groups of neurons, or activity in various regions in the brain is a long way from teaching a classroom full of children. Concepts like neuroplasticity, or findings about the role of dopamine in learning, provide few insights into how best to teach maths to 11 year olds. As professor of developmental neuropsychology, Dorothy Bishop says, “Neuroscientists can tell you which brain regions are most involved in particular cognitive activities and how this changes with age or training. But these indicators of learning do not tell you how to achieve learning. Suppose I find out that the left angular gyrus becomes more active as children learn to read. What is a teacher supposed to do with that information?”
There may come a point when it’s possible to attach electrodes to students and for a teacher’s hand held fMRI scanner to detect neurons firing and synaptic connections being formed in response to specific teaching activities, but for now that’s but a distant dream. Basically, neuroscience tells us little of direct, practical value.
That said, neuroscience does prove useful to education when it enables cognitive theories and models of how children learn to be tested. Take the example of dyslexia. For decades a debate raged between those who were convinced the condition was caused by a disorder of visual-perceptual system, and others who were equally sure that phonological problems were at dyslexia’s root. Brain imagining techniques have been able to shed much needed light on which of these rival hypotheses provides the better explanation. Currently, studies finding reduced activation in the left temporoparietal cortex suggest that dyslexia is better explained by phonological rather than visual perception explanations. This is invaluable information and lets teachers know that time will be much better spent embedding phoneme grapheme relationships than mucking about with coloured filters.
What teacher really need to know about neuroscience is the extent to which its language and imagery can be used to baffle and bamboozle. Several well-meaning but misguided attempts to apply neuroscience to teaching have led to a whole suite of myths and misconceptions. Sometimes these misconceptions are based upon ‘hyped’ versions or distortions of genuine findings, other times they appear entirely spurious; merely cloaking themselves in the language of neuroscience to give the ideas a veneer of plausibility. One of the most widely believed is the thoroughly debunked belief that students have different learning styles. Others include such hoary old chestnuts as the belief that we use only 10% of their brains (in fact we all use pretty much all of brain pretty much all of the time), the idea that people are preferentially “right-brained” or “left- brained” in the use of their brains (we’re not, we need all our brain in order to be logical and creative as anyone who’s ever tried to lop off one hemisphere or other very quickly learns) and the bogus belief that children’s cognitive development progresses via a fixed series of age-related stages.
These beliefs, despite having been comprehensively disproved, are remarkably persistent. This seems, at least in part, because people are easily persuaded by ideas when presented alongside neurological jargon. In one study into how neuroscientific explanations influence out thinking, participants were divided into four groups with each asked to read brief explanations of psychological phenomena, none of which required a neuroscientific explanation. Half the participants read good explanations, the other half bad explanations. Additionally, half the participants saw spurious neuroscientific justifications for the explanation specifying an area of activation in the brain which were entirely irrelevant to the explanation, whilst the other half did not. Participants then had to rate how satisfied they were with the explanations given for each phenomenon.
Although participants could tell the difference between the good and bad explanations, the presence of the irrelevant neuroscientific information led them to judge the explanations, particularly the bad explanations, more favourably. Unsurprisingly, non-experts are even more likely to be persuaded by explanations that use technical language and scientific terminology. There’s even evidence that we may find scientific articles more credible when merely a picture of a brain scan is included!
Example of an utterly fatuous claim based on spurious brain imaging
Are teachers too readily swayed by claims about child psychology or pedagogical techniques appearing to carry the stamp of authority offered by neuroscience? It seems our enthusiasm for neuroscience and our bias towards finding ‘brain-based’ ideas more plausible means that neuro-myths spread easily in education. As professionals we should be just ready to challenge neuro-myths in the staffroom, as we would be to tackle students’ misconceptions in our classrooms. Perhaps the first step is simply to be aware of common misconceptions related to how children learn, so that we can challenge bogus ideas about teaching.
Given the limitations of directly applying neuroscientific evidence to classroom settings, as a rule of thumb we should probably exercise professional scepticism when anyone claims that a method of teaching is ‘brain-based’ or supported by ‘neuroscience’. There’s a good chance that such terminology is being bandied about to persuade us rather than to genuinely justify the approach to teaching.
Even when the invocation of neuroscience is well-intentioned it’s often still unhelpful because neuroscience is the wrong level of description. Consider this recent blog post from LKMCo. Quite properly, it urges teacher to treat definitive claims about the efficacy of applications cognitive science to the classroom with caution. This much is uncontroversial. But then it cites a number of recent reports of neuroscientific ‘breakthroughs’ as evidence that our current knowledge about human memory is defunct. Fascinating as this study appears, where or how memories are stored in the brain are utterly irrelevant to classroom practice. The findings may cast doubt on current neurological theories of memory it has literally nothing to say about cognitive theories. It would be the equivalent of saying a new development in quantum physics means we should change the way chemical engineering plants operate. The idea that “functional reorganization of engrams and circuits underlying systems consolidation of memory” might in some way offer suggestions about how to cope with Year 9 period 1 on a Monday is absurd. On the other hand, the advice which comes from Cognitive Load Theory provides consistently useful insights into why children fail to learn and how teachers can adapt their practices in response.
Uncertainty certainly does still – and always will – remain. Science is always contingent. But the idea that seeing regions of mice brains light up will “send shockwaves through what are fast-becoming, accepted orthodoxies in education” is a trifle hyperbolic. For now, neuroscience offers teachers little beyond a very limited ability to corroborate or contradict psychological theories. A little less credulity when we see those brain images would go a long way.
So…some people struggle more with reading (and the label ‘dyslexic’ is slapped on them, which explains nothing). And what they need is…better reading instruction! Who would have thought it?
Have you seen this ?
http://waitbutwhy.com/2017/04/neuralink.html
This is Elon Musk’s take on the future of mankind (or some of them)
The term ‘dyslexia’ may be useful shorthand for someone who finds it difficult to learn to read an alphabetic script, and there can be no doubt that even with the best reading instruction children’s scores on reading and spelling tests will follow a more or less normal distribution, albeit displaced upwards anything up to one standard deviation. We’ve taught pupils who simply could not retain even the most basic gpcs without hundreds of exposures utilising a highly multi-sensory approach (nature designed us to use all of our senses together!). Typically, primary teachers conclude that the child ‘can’t learn phonics’ and give up far too early. If you stay with it, they all get there in the end.
This said, I agree with Rutter. In 1974, he pointed out that “the features said to characterize ‘dyslexia’ do not cluster together as they should if there were a single ‘dyslexic’ syndrome”. It is likely that dyslexia is an infinitely variable condition which can involve deficits of varying severity in one or more domains, as is suggested by the fact that children’s psychometric profiles do not remain stable over time. The ‘working memory’ model has recently gained credibility; for instance, if a pupil has just been taught that the letters ‘dge’ are the phonological equivalent of ‘j’, it will prove difficult to read the word ‘pledge’ if the first three letters cannot be translated to sound instantly and automatically
While I agree that coloured overlays are almost always a waste of time, this does not mean that visual processing is never problematic. When children report that the ‘words won’t stay still’, it is likely that their eyes are moving in mini-saccades to scramble the letters in an unfamiliar word to produce a word they can recognise more or less on sight. Fortunately, this ‘condition’ responds readily to intensive synthetic phonics and the use of a cursor to aid tracking.
See also https://www.researchgate.net/profile/Jeff_Bowers/publication/224869363_Bayesian_Just-So_Stories_in_Psychology_and_Neuroscience/links/5761486208ae244d0372a749.pdf
Some extraordinary claims with no references e.g. Moser et al findings described as ‘utterly fatuous’ and ‘spurious brain imaging’. Little distinction between the research findings and the claims made for them by others.
This is the Moser et al. (2011) article: http://cpl.psy.msu.edu/wp-content/uploads/2011/12/Moser_Schroder_Moran_et-al_Mind-your-errors-2011.pdf
The caption shown above is NOT from that article, and this caption does NOT reflect what that article states… I do agree that the figure wasn’t necessary in the original article.
So pleased you decided to focus your opprobrium on a caption:)
I’m not blaming Moser – but to claim that those images have anything to do with mindsets is utterly fatuous and the use of the images is spurious.
David it was given as an example to further your argument so it is fair game.
That being said am I being a bit thick Luc as it does seem the caption shown above is showing an image taken directly from the Moser paper you linked to. They seem to be saying that the higher Pe amplitude voltage represents the more effective response by those with a growth mindset. (With the image chosen to represent this). In confession i have not read the article fully or with care yet so I may have mis-understood.
Can’t figure out how you could have missed that but can’t see what I have missed. I will look at it carefully at the weekend but if you could point me to your key points that would be appreciated Luc.
Michael, the picture is from the article of Moser et al., but the accompanying caption (“Brain activity in individuals with a fixed and growth mindset”) is from somewhere else (no idea where it comes from), See Figure 1 of the Moser et al. article for the original caption. It is not a “difference in brain activity” that is always present, this is only about differences (in Pe) that occur after an error was made. The (long) caption of Figure 1 in the original article makes this clear, the caption of Figure 2.1 from an unknown article is misleading. Makes me curious about the source of this Figure 2.1 🙂
Got it. Couldn’t see a tree for the wood there.
I’m focusing my opprobrium on inaccuracies. Can’t see the point of replacing one lot with another.
Where’s the inaccuracy? That image is used by Jo Boaler to misrepresent Moser’s research.
There’s no indication in your post that the figure you’ve included is from Jo Boaler, rather than from Moser et al. Or of what Boaler or Moser et al said about it. It’s an inaccurate representation.
No it isn’t
So where’s the explanation in the post?
I assumed that no one sensible would require one.
Never make false assumptions.
Well, that’s certainly a good rule of thumb. In this case I’m not sure my assumption was false 🙂
I agree with Sue that the additional detail would have been helpful, but David is right that it’s not an inaccuracy per se, and the lack of additional detail doesn’t undermine his overall point. This is a blog, not a scientific paper seeking publication.
“Growth mindset” is a lot like “dyslexia”: it can mean what we want it to mean–we’re in real Humpty-Dumpty territory here.. Looking at the illustration, we can see that even the ears warm up when pupils are in this magic new condition. I’d say that ‘utterly fatuous’ is putting it mildly.
Perhaps you should elaborate a little on this and inform APA about the potential problems with Principle #1 in their “TOP 20 PRINCIPLES FROM PSYCHOLOGY FOR PreK–12 TEACHING AND LEARNING” report?
http://www.apa.org/ed/schools/teaching-learning/top-twenty-principles.pdf
I have: https://www.learningspy.co.uk/psychology/top-20-principles-from-psychology-for-teaching-and-learning/
Nice. And definitely not “Humpty-Dumpty territory” nor “bollocks” 🙂
Perhaps you could add a link to http://www.edweek.org/ew/articles/2015/09/23/carol-dweck-revisits-the-growth-mindset.html
I agree Tom Dyslexia does seem to have a pretty wide menu as it can be prepared in many ways. The variations between definitions are wide ranging from a measurable deficit in reading age to a cocktail of conditions.. Most of my knowledge comes from The Dyslexia Debate by Prof Elliot who lays this out in detail though it is a book that does you no favors when trying to read it. I like to think of it as a educational subway were you build your own disorder out of what ever ingredients you like.
As a statemented Dyslexic (using the flawed IQ system) I found it ironic how the many flaws of “condition” such as poor co-ordination (disappeared after I started exercising) poor organizational skills (disappeared when my job required to me to use a planning system)
poor short memory (now only effects me when I think something is unimportant and irrelevant).and unique way of viewing the world (Google helped me find plenty of people who see it the same). Naturally I am still a creative genius (until I mention I studied science) and my handwriting is atrocious (they gave up trying to remedy it as they didn’t want to subject me to any emotional trauma, but bad writing is in no way a hindrance as a teacher).
You’ve obviously read ‘The Gift of Dyslexia’!
My extensive experience teaching kids to read bears out your experience: once they learn to read, ‘dyslexics’ aren’t all that different from anyone else. Our assessments cost a fraction of what educational psychologists charged–all we did was give them standardised reading and spelling tests, which helped us decide where to start.
The notion that pupils require bespoke teaching is a good money-spinner for faux-professionals and SENDCO courses, but as we’ve known since the 1970s Abt Associates report on the Follow Through programme, effective teaching focuses on the skills that need to be learned, and not the putative learning style or disability of the pupil.
This is not to say that people don’t vary greatly in their ability to learn to read. But as one of our pupils commented, ‘If dyslexia is a gift, they can have it back’.
I have indeed read that pseudo-scientific book. I quiet enjoyed it and it is unfortunate it is utterly wrong. The Dyslexia debate is a much more useful book though a decidedly less pleasant read.
The most useful definition of Dyslexia I have read is “persistent reading difficulties unresponsive to evidence based intervention and without alternative explanation such as general learning difficulties”. This would be expected to effect only a few percentage points of the population.
Some might disagree with this assessment but I thoroughly imagined every permutation of the book in 3 D space and as a naturally expert physicist even included most permutations in higher dimensions as well.
‘Dyslexia’ cannot be a simple, single syndrome. If ‘it’ is anything real, ‘it’ might be various conditions, none of them specific to literacy.
Neuroimaging is a tremendously wonderful tool for revealing lesions in the brain. At this it excels. It is much, much less wonderful at examining process. The pretty pictures it produces should be used less as demonstration and more as tentative indication. They are often fraudulently used as the ‘sciency’ illustration which manipulates the reader (as we know such illustrations do).
For a fun counterblast to this trend, look up Craig Bennett and his demonstration that you can ‘show’ that a dead salmon will react if you show it emotionally charged pictures while it is lying in a scanner.
It could still be a single syndrome (though unlikely to be simple). Do agree that it is vastly more probable to be various conditions, none of them specific to literacy.
Liked the dead salmon study especially the idea of culinary post-processing.
should have changed none of them specific to literacy to many of them not specific to literacy.
Really good to read a more critical take on euro-education. I think a sociological perspective is also helpful as it points to questions such as why, when the term ‘dyslexia’ lacks a widely accepted, precise meaning, do some researchers (and their funders) think it’s a good idea to conduct experiments on newborns seeking neurological markers for being at risk of dyslexia five years on? Also, I’m not sure cognitive load theory offers that much; so far I’ve only really come across it when being used to justify particular teaching techniques such as DI or rote learning. From the linked article, seems to me that a more productive approach would be to take the epistemological character of the subject as starting point, work out what concepts, procedural skills and knowledge is required, what sequence etc. and from this work out concrete techniques, supporting material etc in relation to specific class.
Whats euro-education? The experiments on newborn babies, is that so the images can be studied later when we have data on who has developed reading difficulties?
If you accept Cognitive load theory then it would impact your epistemological character approach significantly, beyond just being concrete. It would imply that the steps need to be very small with emphasis on developing automatic recall of basic principles. You would factor that in when working out what sequence and supporting materials you are going to use.
Clearly ‘euro’ was a typo – a bit unfair to pick-on. Other than that, I entirely support your point about Cognitive Load Theory. It should be a fundamental building block with regards to how we approach instruction for all people.
If you believe the theory is valid, which admittedly I do. I wondered if euro-education was a political thing and not a typo.
Hi David,
Do you have any info on spaced learning based on R. Douglas Fields’ Making Memory Stick article from Scientific American (2005)?
http://www.innovationunit.org/sites/default/files/Spaced_Learning-downloadable_1.pdf
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