Wednesday, March 11, 2015

Excuse-making by School Children

My last column on "Blaming the Victim" was a departure from my usual emphasis on improving learning and memory. But it did set the stage for this current post on the crippling effect of allowing children to make excuses for underperformance in school.
Most of us know how common it is for kids to make excuses ("the dog ate my homework" syndrome). When we adults were young, we also probably made excuses, blaming the textbook, the teacher, the school, and whatever else could serve to avoid facing the real causes of the problems.
Why do kids do that? The main reason is their fragile egos. Confronting personal weakness is especially hard for kids when they are embedded in an adult culture that inevitably reminds them that they are relatively powerless kids.
I remember a recent dinner-table conversation with my competitive 6th grade granddaughter, who was complaining about a test in which some of the questions were not aligned well with the instruction, which itself was deemed confusing. I said, "I understand that others did do better than you on the test. Wasn't everybody facing the same handicap?" No answer. Then I added, "It doesn't matter who the teacher is or what instruction you get. If you are not first in the class, it is your fault." Again, no response.
One approach that parents and teachers use is to bolster children's egos by praising them richly and often. Too much of a good thing is a bad thing. Too much praise makes kids narcissistic. Anybody who is not aware of the raging narcissism in today's youngsters must not be around young people very much. The most obvious sign is the compulsive checking of e-mail and texting, all in an effort by a child to be at the center of attention.
I and other professors notice narcissism in college students. In a selective college, most students think they are "A" students, and because of low standards in secondary school and grade inflation they are actually told they are A students. If they don't make As in college, it is somebody else's fault (usually the professor).
Scholars are beginning to address this growing narcissism. Eddie Brummelman at the University of Amsterdam in the Netherlands and his colleagues studied 565 children between the ages of 7 to 12. They picked this age group because most other such studies have been in adults, and they believed that early adolescence is when children develop narcissistic traits such as selfishness, self-centeredness and vanity.
Over 18 months, the children and their parents were given several detailed questionnaires that were designed to measure narcissistic traits and parental behavior. There was a small but significant link at each stage between how much parents praised their children and how narcissistic the children were six months later. Because the effect was only small, it suggests that other things also make people selfish and self-centered. I suspect the effect is larger in the U.S.
Maybe school culture is part of the problem. As in Lake Woebegon, "all kids are above average." For brighter students, the instructional rigor is so low that these kids get a false sense of how smart they are and how easy it is to be an "A" student.
I suspect that another factor is that students are not taught enough about how to be realistically self-aware. They may not even know when they are making excuses unless adults call them on it. Too often, parents side with the student in criticizing a teacher when the real problem is with the child.
Some of the blame shifting comes from biology. It is in human nature to claim ownership of things we do that turn out well, but disown actions that yield negative consequences. Experiments support this conclusion. The most recent experiments had a primary focus on our sense of time in association with voluntary actions. The experimental design was based on prior evidence that the perceived estimate of time lag between when we do something and when we think we did it is an implicit index of our sense of ownership. Investigators asked people to press a key, which was followed a quarter of a second later by negative sounds of fear or disgust, positive sounds of achievement or amusement, or neutral sounds. The subjects were then asked to estimate when they had made the action and when they heard the sound. Timing estimation errors were easily measured by computer. Subjects sensed a longer time lag between their actions and the consequences when the outcome (the sound) was negative than when it was positive.

Teaching Kids to Deal with Failure


There is a common denominator to most self-limiting styles of living. It is a fear of failure. Children express this fear by making excuses, which has the unintended effect of blocking the path to success. Excuses may provide immediate relief of anxiety, but it creates a self-limiting learning style that assures continued underachievement.
Whatever one’s station in life, one axiom is paramount: for things to get better for you, you have to get better. This point is well illustrated in an inspiring rags-to-riches success book by A. J. Williams. He points out that a main reason that people do not make the changes they need to is that they are afraid of failure. But, paradoxically, learning from failure is how many people turn their lives around and become happier. Children, I have noticed, are highly resistant to personal change, maybe more so than adults. I am dismayed at how often I show children how to memorize more effectively and they just can't bring themselves to study in a different way. It is as if they don't believe me enough to even try new approaches. Or maybe they have convinced themselves they are mediocre and need the shield of excuses to keep others from detecting their weaknesses.
Louis Armstrong, the famous trumpeter, told an instructive story about fear when he was a boy. One day when his mother asked him to go down to the levee to fetch a pail of drinking water, he came back home with an empty pail. Upon noticing the empty pail, his mother said, “I told you to bring back a pail of water for us to drink. How come your pail is empty?” Louis replied, “There’s an alligator there, and I was scared to death.” His mother then said, “You shouldn’t be afraid. That gator is as afraid of you as you are of him.” To which Louis answered, “If that’s the case, then that water ain’t fit to drink.”
If there is an alligator keeping you away from what you need to do, have faith you will prevail over your demons. But as long as a child lets fear get in the way, her pail will stay empty.
Other kinds of fear are also self-limiting. Many children fear commitment to learning. Commitment exacts an emotional price requiring dedication, passion, and self-discipline. Children fear confusion and difficulty. They fear disapproval.
Kids need to put their under-performance in perspective. Failure and under-achievement are not permanent. They are not pervasive reflections of inadequacy. Children can acquire learning skills that lead to success. Unfortunately, schools don't teach much about learning skills, being focused on teaching to high-stakes tests.
Kids need to recognize their weakness and strive to fix them. But to bolster their motivation and general attitude about school, they need to recognize what they have done well and strive to do even more of that. Dwelling on under-performance is counter-productive.

The Most Important Thing Kids Need to Learn


Excuse-making prevents a child from developing the attitude that will best serve them throughout life: a sense of personal efficacy, a state of perceived control over one's life. I explain this more thoroughly in my book, "Blame Game, How to Win It." But a summary here will have to suffice.
How children perceive their personal power determines how much effort they will expend to control their lives. If they lack a genuine sense of power, excuse-making applies salve to their wounded egos. Self-efficacy is not the same as self-esteem. Psychologist, Albert Bandura, puts it this way: “Perceived self-efficacy is concerned with judgments of personal capability, whereas self-esteem is concerned with judgments of self-worth.” Both are important for happiness, but it is perceived self-efficacy that drives academic achievement. One practical application where this distinction is apparently not recognized is with school teachers who think the cure for low achievement in school is to foster self-esteem. Teachers should emphasize self-efficacy. Children learn self-efficacy from teachers and parents who enable them to master their environment. Students who are filled with self-doubt do not put much effort into school work. They make excuses. As kids are progressively given the skills to achieve, they develop a sense of confidence in their ability to succeed, which will motivate them to strive for more achievement. When I was a kid, I only became a good student when I discovered, more or less by accident, that I could make good grades. Discovering that I could make good grades if I tried motivated me to do just that. This sense has to be earned. It does not come from excuses.


Sources:

Brummelman, Eddie, et al. (2015). Origins of narcissism in children. Proceedings of the National Academy of Sciences, DOI: 10.1073/pnas.1420870112

Klemm, W. R. (2008). Blame Game. How To Win It. Bryan, Tx.: Benecton.
           

Yoshie, et al. (2013). Negative emotional outcomes attenuate sense of agency over voluntary actions. Current Biology. Dx.doi.org/10.1016/j.cub2013.08.034

Wednesday, February 25, 2015

Study Smart Beats Study Hard

Keep your "nose to the grindstone" is the advice we often tell young people is an essential ingredient of learning difficult tasks. A joke captures the matter with the old bromide for success, "Keep your eye on the ball, your ear to the ground, your nose to the grindstone, your shoulder to the wheel: Now try to work in that position."


Over the years of teaching, I have seen many highly conscientious students work like demons in their study yet don't seem to learn as much as they should for all the effort they put in. Typically, it is because they don't study smart.
In an earlier post, I described a learning strategy wherein a student should spend short (say 15-20 minutes) of intense study followed immediately by a comparable rest period of "brain-dead" activity where they don't engage with intense stimuli or a new learning task. The idea is that during brain down-time the memory of just-learned material is more likely to be consolidated into long-term memory because there are no mental distractions to erase the temporary working memory while it is in the process of consolidation.
Now, new research suggests that too much nose-to-the-grindstone can impair learning. Margaret Schlichting, a graduate student researcher, and Alison Preston, an associate professor of psychology and neuroscience at the University of Texas tested the effect of mental rest with a learning task of remembering two sets of a series of associated photo pairs.  Between the two task sets, the participants rested and were allowed to think about whatever they wanted. Not surprisingly, those who used the rest time to reflect on what they had just learned were able to remember more upon re-test. Obviously, in this case, the brain is not really resting, as it is processing (that is, rehearsing) the new learning. But the brain is resting in the sense that new mental challenges are not encountered.
The university press release quotes the authors as saying, "We've shown for the first time that how the brain processes information during rest can improve future learning. We think replaying memories during rest makes those earlier memories stronger, not just impacting the original content, but impacting the memories to come." Despite the fact that this concept has been anointed as a new discovery in a prestigious science journal, the principle has been well-known for decades. I have explained this phenomenon in my memory books as the decades-old term of "interference theory of memory,"
What has not been well understood among teachers is the need to alter teaching practices to accommodate this principle. A typical class period involves teachers presenting a back-to-back succession of highly diverse learning objects and concepts. Each new topic interferes with memory formation of the prior topics. An additional interference occurs when a class period is disrupted by blaring announcements from the principal's office, designed to be loud to command attention (which has the effect of diverting attention away from the learning material). The typical classroom has a plethora of other distractions, such as windows for looking outside and multiple objects like animals, pictures, posters, banners, and ceiling mobiles designed to decorate and enliven the room. The room itself is a major distraction.
Then, to compound the problem, the class bell rings, and students rush out into the hall for their next class, socializing furiously in the limited time they have to get to the next class (on a different subject, by a different teacher, in a differently decorated classroom). You can be sure, little reflection occurs on the academic material they had just encountered.
The format of a typical school day is so well-entrenched that I doubt it can be changed. But there is no excuse for blaring loudspeaker announcements during the middle of a class period. Classrooms do not have to be decorated. A given class period does not have to be an information dump on overwhelmed students. Short periods of instruction need to be followed by short, low-key, periods of questioning, discussion, reflection, and application of what has just been taught. Content that doesn't get "covered" in class can be assigned as homework—or even exempted from being a learning requirement. It is better to learn a few things well than many things poorly. Indeed, this is the refreshing philosophy behind the new national science standards known as "Next Generation Science Standards."
Give our kids a rest: the right kind of mental rest.

Sources:

http://www.nextgenscience.org/

http://scicasts.com/neuroscience/2065-cognitive-science/8539-study-suggests-mental-rest-and-reflection-boost learning.

Schlicthing, M. L., and Preston, A. R. (2014). Memory reactivation during rest supports upcoming learning of related content. Proc. Nat. Acad. Science. Published ahead of print, Oct. 20.


Dr. Klemm's latest book, available at most retail outlets, is "Mental Biology. The New Science of How the Brain and Mind Relate" (Prometheus). See reviews at http://thankyoubrain.com

Saturday, February 07, 2015

How Learning Cursive Might Improve Reading Efficiency and Hand-eye Coordination

When directing the writing by hand, the brain has to visually track rapidly changing positions of the pencil and control hand and finger movements. To learn such skills, the brain must improve its control over eye-movement saccades and the processing of visual feedback to provide corrective feedback. Both tracking and movement control require much more engagement of neural resources in producing cursive or related handwriting methods than in hand printing, because the movements are more complex and nuanced. Thus, learning cursive is a much greater neural activator, which in turn must engage much more neural circuitry than the less demanding printing.

The key to learning successful handwriting, whether cursive, italics, or calligraphy, is well-controlled visual tracking and high-speed neural responses to the corrective feedback. Scientists are now starting to study the mechanisms, but not yet in the context of education. Two recent reports, seemingly unrelated to each other or to cursive, examined visual tracking and found results that could have profound educational implications for both reading and hand-eye coordination training, as in learning to touch type.

Visual targets are fixed by saccades. One theory is that the eyes scan the target with a linked series of saccades, in this case the changes in cursive letter structure as the letters are being rapidly formed. We already know that the brain predicts eye movements based on what they see at each saccade fixation. This is how our visual world is made stable, even though the eyes are flicking around; otherwise, the image would jitter back and forth constantly. This suggests that visual image representation is integrated rapidly over many successive saccades. The degree of tracking speed, accuracy, and prediction error must surely influence how well the letters are transcribed during handwriting. The corollary is that the better one learns to write by hand, the better the brain is learning how to track visually.

Scientists used to think that these predictions were the source of error in estimating the position of seen objects. In handwriting, for example, the brain would assess the shape of part of a letter as you draw it and predict how and where the next portion of the letter should be added. Learning how to optimize the drawing then would be a matter of learning how to reduce prediction errors.
However, a new study tested the hypothesis that if localization errors really are caused by faulty predictions, you would also expect those errors to occur if an eye movement, which has already been predicted in your brain, fails to take place at the very last moment in response to a signal to abort the eye movement. The investigators (Atsma et al. 2014) asked test subjects to look at a computer screen and tracked eye movement fixation on a very small ball that appeared at various random positions. During this task, the brain must correctly predict where the eyes have to move to keep the eye on the ball.

The experiment ended with one last ball on the screen, followed by a short flash of light near that ball. The person had to look at the last stationary ball while using the computer mouse to indicate the position of the flash of light. However, in some cases, a signal was sent around the time the last ball appeared, indicating that the subject was NOT allowed to look at the ball. In other words, the eye movement was cancelled at the last moment. The person being tested still had to indicate where the flash was visible.

Subjects did not make any mistakes in fixation on the light location during the abortion test, even though the brain had already predicted that it needed to fixate on the ball. Most mislocations occurred when the flash appeared at the moment the eye movement began. Thus, the errors seemed to be associated with neural commands for eye fixation, not with saccade predictions. The application for handwriting learning is that the neural circuits that control target fixation may be a major factor in learning how to write cursive well. Surely, these circuits would be responsive to training, though that was not done in this experiment. It would seem possible that these circuits might be trained via learning cursive to provide faster and more accurate visual tracking, which should have other benefits—as in reading.

A related study of visual tracking in monkeys reveals parallel processing during visual search (Shen and Paré. 2014). Recordings from neurons in the visual pathway during visual tracking of targets in a distracting field showed that in the untrained state, these neurons had indiscriminate responses to stimuli. However, with training the neuronal function evolved to predict where the moving target should be in advance of the actual saccade. Results also showed that more than half the neurons learned to predict where the next two eye movements (saccades) needed to be, which obviously suggests that accurate tracking can be accelerated without loss of information.

In short, learning cursive should train the brain to function more effectively in visual scanning. Theoretically, reading efficiency could benefit. I predict that new research would show that learning cursive will improve reading speed and will train the brain to have better hand-eye coordination. In other words, schools that drop cursive from the curriculum may lose an important learning-skills development tool. The more that students acquire learning skills, the less will be the need for "teaching to the test."

"Memory Medic's" latest books are 
Mental Biology (Prometheus) and Memory Power 101 (Skyhorse).

Sources:
Atsma, J. et al. (2014). No peri-saccadic mislocalization with abruptly cancelled saccades.
Journal of Neuroscience, 15 April 2014. ttp://www.jneurosci.org/content/34/16/5497.full.html


Shen, Kelly and ParĂ©, Martin. 2014.  Predictive saccade target selection in superior colliculus during visual search. The Journal of Neuroscience, 16 April 2014, 34(16): 5640-5648; doi: 10.1523/JNEUROSCI.3880-13.2014

Sunday, January 25, 2015

Health Benefits of Resveratrol: New Plaudits

Joe: My doctor told me to give up drinking, smoking, and fatty foods.
Sam: What will you do?
Joe: I think I’ll give up my doctor.

I try not to get too excited about memory benefits of supplements, because too often the claims are not substantiated by studies that are well controlled and peer reviewed. I now think resveratrol may be one of the few supplements that benefits brain function.

When I wrote my first blog on research on resveratrol benefits for brain function and memory, there were over 2,000 scientific papers.[1] Don't worry; I am only going to tell you about a few studies.

Resveratrol is an active ingredient in red wine. This compound has been credited for explaining why red-wine drinkers in France, who drink more wine than most people, are healthier than would be predicted by their lifestyle of little exercise and eating lots of cheese. The problem is most studies suggest you would have to drink a 100 or more glasses of red wine a day to get much resveratrol effect (and that effect would obviously be negated by a toxic dose of alcohol). An obviously more healthful choice is the highly concentrated pill forms of resveratrol that are now on the market.

Most of the protective biological actions associated with resveratrol have been associated with its scavenger properties for free radicals and the protective effects that it confers on the heart and diabetes. 

One important study comes from a diabetes research group in Brazil recently who reported a beneficial effect of resveratrol on diabetic rats.[2] Resveratrol (in a modest rat dose of 10 and 20 mg per kilogram per day for 30 days) prevented the impairment of memory induced by diabetes. Resveratrol may be protecting neuron terminals that diabetes can damage. An earlier study by another group showed resveratrol improved glucose metabolism and promoted longevity in diabetic mice.

Another benefit of resveratrol is the anti-oxidant property. The brain produces more free-radical damage than other organs, because it burns so much oxygen. Compared with other organs, the brain has especially low levels of antioxidant defense enzymes. 

One recent study has revealed resveratrol had protective effects against brain damage caused by a chemical that kills acetylcholine neurons. Injection of this toxin into the brain of rats impaired their memory performance in two kinds of maze tasks. The impairment was significantly reduced by repeated injection of resveratrol (10 and 20 mg/kg) per day for 25 days, beginning four days before the toxin injection.[3]

Another recent study examined effects on working memory in mice fed a resveratrol-supplemented diet for four weeks before being injected with a cytokine to induce inflammation and accelerate aging. Resveratrol significantly reduced memory impairment in the aged group, but not in the young adults[4]. The lack of benefit in young adults was a little misleading, in that there was a "ceiling effect" in that the young adults were not impaired by the cytokine injection.

 The practical issue for us is whether resveratrol will help cognitive function in humans, especially healthy humans. It seems likely because other substances that have strong anti-oxidant properties seem to improve memory capability. Because animal studies have shown promise for resveratrol in preventing or treatment several different conditions associated with aging, several human clinical trials have been initiated.[5]

 An impressive new study of older humans, male and female, has just been reported.[6] Twenty-three healthy, but overweight people completed 6 months of daily resveratrol intake (200 mg ― the commercial brand I take has 300 mg/capsule). A paired control group got placebo pills. A double-blind design assured that neither the subjects nor the experimenters knew which individuals were in each group during data processing. Memory tests of word recall revealed significant improvement in the resveratrol group. Resveratrol also increased brain-scan measures of functional connectivity, which identified linked neural activity between the hippocampus and several areas of cerebral cortex.

Because others had shown that resveratrol increased insulin sensitivity in humans, these authors examine several markers important to diabetes. Resveratrol decreased the standing levels of sugar-bound hemoglobin, a standard marker for glucose control.  

What foods besides red grapes have resveratrol? The most likely other sources you would eat or drink are blueberries, cranberries, and peanuts. It is not likely that you could drink or eat enough of such substances to get enough resveratrol to do much good. Because of the scientifically documented benefits of resveratrol, highly concentrated supplements are now on the market (I have been taking it for a couple of years). I haven't given up my two glasses of red wine each day, but I have started taking one of the supplements. I haven't seen any reports that high doses of resveratrol are toxic.




[2] Schmatz R, et al. (2009). Resveratrol prevents memory deficits and the increase in acetylcholinesterase activity in streptozotocin-induced diabetic rats. Eur J Pharmacol. 2009 May 21;610(1-3):42-8. Epub 2009 Mar 19.
[3] Kumar, A. et al. 2007. Neuroprotective effects of resveratrol against intracerebroventricular colchicine-induced cognitive impairment and oxidative stress in rats. Pharmacology.79 (1): 17-26. DOI: 10.1159/000097511
[4] Abraham, J., and Johnson, R. W. 2009. Consuming a diet supplemented with resveratrol reduced infection-related neuroinflammation and deficits in working memory in aged mice. Rejuvenation research. 12 (6): 445-453.  DOI: 10.1089/rej.2009.0888
[5] Smoliga, J. M. et al. (2011). Resveratrol and health – a comprehensive review of human clinical trials.  Mol. Nutrition Food Res. 55: 1129-1141
[6] Witte, A. V., et al. (2014) Effects of resveratrol on memory performance, hippocampal functional connectivity, and glucose metabolism in healthy older adults. J. Neuroscience. 34 23): 7862-7870.

"Memory Medic's latest book is for seniors (Improve Your Memory for a Healthy Brain. Memory Is the Canary in Your Brain's Coal Mine," available in inexpensive e-book format at https://www.smashwords.com/books/view/496252 See also his recent book, "Mental Biology. The New Science of How the Brain and Mind Relate" (Prometheus).

Saturday, January 03, 2015

Happy Thoughts Can Make You More Competent

“Life, liberty, and the pursuit of happiness:” some people might argue that the U.S. Constitution endorses hedonism, and indeed many politicians want to ignore or get rid of the Constitution, but not necessarily because of hedonism. We should not be dismissive about encouraging people to pursue happiness. Happiness can be good for your brain. Depression is surely bad for your brain.

Positive mood states promote more effective thinking and problem solving. A recent scholarly report[1] reviews the literature demonstrating that positive mood broadens the scope of attentiveness, enhances semantic associations over a wider range, improves task shifting, and improves problem-solving capability. The review also documents the changes in brain activation patterns induced by positive mood in subjects while solving problems. Especially important is the dopamine signaling in the prefrontal cortex.

Published studies reveal that a variety of techniques are used to momentarily manipulate mood. These have included making subjects temporarily happy or sad by asking subjects to recall emotionally corresponding past experiences or to view film clips or hear words that trigger happy or sad feelings,

The effect of happiness on broadened attentiveness arises because the brain has better cognitive flexibility and executive control, which in turn makes it easier to be more flexible and creative. Happy problem solvers are better able to select and act upon useful solutions that otherwise never consciously surface. Happiness reduces perseverative tendencies for errant problem-solving strategies. The broadened attentiveness, for example, allows people to attend to more stimuli, both in external visual space and in internal semantic space, which in turn enables more holistic processing. For example, in one cited study, experimenters manipulated subjects’ momentary mood and then measured performance on a task involving matching of visual objects based on their global versus local shapes. Happy moods yielded better global matching.

Other experiments report broader word association performance when subjects are manipulated to be happier. For example, subjects in a neutral mood would typically associate the word “pen” as a writing tool and would associate it with words like pencil or paper. But positive mood subjects would think also of pen as an enclosure and associate it with words like barn or pigs. This effect has been demonstrated with practical effect in physicians, who, when in a happy mood, thought of more disease possibilities in making a differential diagnosis.
The review authors reported their own experiment on beneficial happy mood effects on insightfulness, using a task in which subjects were given three words and asked to think of a fourth word that could be combined into a compound word or phrase. For example, an insightful response to “tooth, potato, and heart” might be “sweet tooth, sweet potato, and sweetheart.” Generating such insight typically requires one to suppress dominant “knee jerk” responses such as associating tooth with pain and recognize that pain does not fit potato while at the same time becoming capable of switching to non-dominant alternatives.

Other cited experiments showed that happy mood improved performance on “Duncker’s candle task.”  Here, subjects are given a box of tacks, a candle, and a book of matches, and are asked to attach a candle to the wall in a way that will burn without dripping wax on the floor. Subjects in a happy mood were more able to realize that the box could be a platform for the candle when the box is tacked to the wall.  

Such effects of happy moods seem to arise from increased neural activity in the prefrontal cortex and cingulate cortex, areas that numerous prior studies have demonstrated as crucial parts of the brain’s executive control network. Similar effects have been observed in EEG studies. Other research suggests that the happiness effect is mediated by increased release of dopamine in the cortex that serves to up-regulate executive control.
The review authors described a meta-analysis of 49 positive-psychology manipulation studies showing that momentary happiness is readily manipulated by such strategies as deliberate optimistic thinking, increased attention to and memory of happy experiences, practicing mindfulness and acceptance, and increasing socialization. The effect occurs in most normal people and even in people with depression, anxiety, and schizophrenia. Biofeedback training, where subjects monitor their own fMRI scans or EEGs, might be an even more effective way for people to train themselves to be happier.

The main point is that people can be as happy as they choose to be.

For more on how positive mood influences memory ability, see my new book, Memory Power 101 (http://skyhorsepublishing.com ). Memory Medic's latest book explores the biology of mind. See "Mental Biology. The New Science of How the Brain and Mind Relate" (Prometheus).

[1] Subramaniam, K. and Vinogradov, S. (2013). Improving the neural mechanisms of cognition through the pursuit of happiness. Frontiers in Human Neuroscience. 7 August. Doi: 10.3389/fnhum.2013.00452



Tuesday, December 23, 2014

Grit's Role in Learning

What do you think is the major determinant of whether our children excel in school? IQ? Good teachers? Good schools? Good standards and curricula? No, I say it is the students' motivation, or just plain grit. Other teachers think so too.

Education reporter, Libby Nelson, calls attention to the issue of grit in student learning achievement. Teachers and parents sometimes put too much emphasis on intelligence, when the more typical problem in education is that students don't try hard enough and are not sufficiently persistent in trying to achieve excellence.

Indeed, excellence is not even a goal for most students. Many students just want to do the minimum required to pass tests. A few students don't care at all. They just drop out. One student told a teacher friend of mine, "I don't need to learn this stuff. Somebody will always take care of me."

Nelson points to evidence of grit's importance with these examples:

·         West Point cadets who scored highest on a scale of grit were more likely to complete the grueling first summer of training.
·         National spelling bee contestants with more grit ranked higher than other contestants of the same age who had less grit.
·         College admissions officers know how important grit is (more important than SAT tests) but they don't know how to measure it other than grades, which of course may be inflated and inaccurate indicators of grit.

Clearly motivation is essential. I regard motivation as the cornerstone of what I call the "learning skills cycle." Learning begins with being motivated to learn, and successful completion of every step in the cycle strengthens motivation. However, every step in this cycle (organization, attentiveness, understanding/synthesis, memory, and problem solving/creativity) requires a degree of grit—the more, the better.


As applied to specific learning tasks, grit is central to all the ideas in the learning skills cycle. In the case of memory, for example, the well-known strategy of deliberate practice requires disciplined grit. Students diligently need to use established memory principles in a systematic way. This includes constructing a systematic learning strategy that includes organizing the learning materials in an effective way, intense study focus in short periods, elimination of interferences, use of mnemonic devices, and frequent rehearsals repeated in spaced intervals. Learning success depends on mental discipline and persistence.

Students differ enormously in their level of grit. It would be nice if we knew how to teach grit. Surely, parental influence is central. Parents lacking in grit are unlikely to model or teach it to their children. Some schools, especially private schools, teach grit by having high expectations and programs that help students discover the positive benefits that come from having more grit. One of those benefits is confidence, because grit promotes achievement and achievement develops confidence.

Confidence in the ability to learn is necessary for a student to try hard to learn. Here is the area where teaching skills count most: showing students they can learn difficult material and thereby building the confidence to take on greater learning challenges.

Students who have passionate goals are much more likely to invest effort and persistence in doing what is needed to achieve those goals. It is unrealistic to expect grade-school children to have well-formulated career goals. But certainly by early high-school, students should be forming specific lifetime goals. What a career goal is probably does matter as much as having one in the first place. Achieving a goal, regardless of whether it is later abandoned or not, teaches a youngster that grit is necessary for the achievement. The student learns that grit has a payoff.

Grit may not always lead to excellence in students with innate limited abilities. But grit allows such students to "become all they can be," as the Army recruitment slogan claims. Moreover, the benefits of grit perpetuate beyond success at any one learning challenge. Learning anything requires physical and chemical changes in the brain needed to store the positive attitudes that come from learning success and the learning content itself. In other words, the more you know, the more you can know.


Source:

http://www.vox.com/2014/10/9/6835197/grit-kipp-noncognitive-skills-duckworth-teaching

"Memory Medic's new book has just been released: "Improve Your Memory for a Healthy Brain." Smashwords.com


Friday, December 12, 2014

The Neuroscience of Why Children Play

All children, if given the chance, will play, preferably with other children. The games they play
are often creative, rough and tumble, and of course―fun. Some consequences are obvious:

·         Fun is a positively reinforcing emotion. It makes kids happy.
·         Play encourages exploration with fewer constraining boundaries than the drone of regular life.
·         Play is an effective way to socialize and make friends.
·         Play stimulates initiative and engagement, rather than passively observing what others do.

But there is another less obvious reason, one that is biological. In a review in the American Journal of Play (yes, there really is a scholarly journal on play), evidence is provided from controlled studies in rats and some primates. These studies show that when young animals are encouraged to play they develop improved social competence, cognition, and emotional regulation later in life. Play experience also makes them more adaptable to unexpected situations.

It is true that play is not a developmental feature in all species. The capacity (and need) for play is most evident in higher mammals with developed neocortex and that live in complex social environments. Play fighting is adaptive in predator species, like bears and lions that depend on aggression for survival as adults. In all species that exhibit juvenile play, play is a developmental tool that promotes the neocortical executive control regions to control other neural systems.

Play fighting is especially interesting because the juveniles must construct and obey certain rules. They intuitively recognize that they must not bite too hard, for example, and must give the opponent at chance to win sometimes or at least hold their own in the contest. The juveniles are clearly learning self-control, which will serve them well as adult. This reminds me of the touch football games that kids play.

Species that most obviously exhibit juvenile play are humans, dogs, cats, and ravens. In species where adults play, play can have immediate functions such as defusing social tensions and dominance relationships. Rats are an interesting case. They engage in juvenile play much more than other rodent species. Adult rats seem to exhibit novel mental capabilities, especially those involving social interactions that are not so prominent in other rodents.

When members of a play-oriented species are denied access to juvenile play, they can become dysfunctional adults. For example, rats raised in social isolation show physical and chemical deficiencies in their brains and they have behavioral abnormalities linked to impaired executive control function. They show excessive anxiety to stressful or fear-inducing situations. They over-react to benign social interactions. They are less able to coordinate movements with a partner, both in sexual and non-sexual contexts. They are less able to solve mental tasks. Similar problem are seen in monkeys deprived of juvenile play. Being raised by a surrogate mother is emotionally and intellectually devastating, but less so if the surrogate is robot-like and can interact in play-like behavior with the infant.

Juvenile play sculpts the brain to be more adaptable later in life. In modern human society, juvenile play is often obstructed by such externals as over-scheduling, too much adult supervision, and too many restrictions. The restrictions are often for reasons of safety, which is understandable in today's world. When I was a child, we had a lot more freedom to play, and in safety. It was not unusual in the summer time for a kid to leave home after breakfast and not return until supper, going alone to a park or neighbor kid's house to play unsupervised as we wished. Sadly, that is too much freedom these days. In this respect, the "good old days" really were the "good old days."

Source:

Pellis, S. M., Pellis, V. C., and Himmler, B. T. (2014). How play makes for a more adaptable brain. Ame. J. Play. 7 (1) 73-98


"Memory Medic's new book has just been released: "Improve Your Memory for a Healthy Brain." Smashwords.com

Monday, November 24, 2014

How Schools Make Learning Harder Than Necessary

Keep your "nose to the grindstone" is the advice we often give as an essential ingredient of learning difficult tasks. An old joke captures the problem with the old bromide for success, "Keep your eye on the ball, your ear to the ground, your nose to the grindstone, your shoulder to the wheel: Now try to work in that position."

Over the years of teaching, I have seen many highly conscientious students work like demons in their study yet don't seem to learn as much as they should for all the effort they put in. Typically, it is because they don't study smart. And sometimes the problem is created by the teachers' method of instruction.

In an earlier post, I described a learning strategy wherein a student should spend repeated short (say 10-15 minutes) of intense study followed immediately by a comparable rest period of "brain-dead" activity where they don't engage with a new learning task. The idea is that memory of the just-learned material is more likely to be consolidated into long-term memory because there are no mental distractions to erase the temporary working memory while it is in the process of consolidation.

Now, new research now suggests that too much nose-to-the-grindstone can impair learning.
Margaret Schlichting, a graduate student researcher, and Alison Preston, an associate professor of psychology and neuroscience at the University of Texas tested the effect of mental rest with a learning task of remembering two sets of a series of associated photo pairs.  Between the two task sets, the participants rested and were allowed to think about whatever they wanted. Not surprisingly, those who used the rest time to reflect on what they had learned earlier were able to remember more upon re-test. Obviously, in this case, the brain is not really resting, as it is processing (that is, rehearsing) the new learning. But the brain is resting in the sense that no new mental challenges are encountered.

The university press release quotes the authors as saying, "We've shown for the first time that how the brain processes information during rest can improve future learning. We think replaying memories during rest makes those earlier memories stronger, not just impacting the original content, but impacting the memories to come." Despite the fact that this concept has been anointed as a new discovery in a prestigious science journal, the principle has been well-known for decades. I have explained this phenomenon in my memory books as the well-established term of "interference theory of memory,"

What has not been well understood among teachers is the need to alter teaching practices to accommodate this principle. A typical class period involves teachers presenting a back-to-back succession of highly diverse learning objects and concepts. Each new topic interferes with memory formation of the prior topics. An additional interference occurs when a class period is disrupted by blaring announcements from the principal's office, designed to be loud to command attention (which has the effect of diverting attention away from the learning material). The typical classroom has a plethora of other distractions, such as windows for looking outside and multiple objects like animals, pictures, posters, banners, and ceiling mobiles designed to decorate and enliven the room. The room itself is a major distraction.

Then, to compound the problem, the class bell rings, and students rush out into the hall for their next class, socializing furiously in the limited time they have to get to the next class (on a different subject, by a different teacher, in a differently decorated classroom). You can be sure, little reflection occurs on the academic material they had just encountered.

The format of a typical school day is so well-entrenched that I doubt it can be changed. But there is no excuse for blaring loudspeaker announcements during the middle of a class period. Classrooms do not have to be decorated. A given class period does not have to be an information dump on overwhelmed students. Short periods of instruction need to be followed by short, low-key, periods of questioning, discussion, reflection, and application of what has just been taught. Content that doesn't get "covered" in class can be assigned as homework—or even exempted from being a learning requirement. It is better to learn a few things well than many things poorly. Indeed, this is the refreshing philosophy behind the new national science standards known as "Next Generation Science Standards."

Give our kids a rest: the right kind of mental rest.

Sources:


Schlichting, M. L., and Preston, A. R. (2014). Memory reactivation during rest supports upcoming learning of related content Proc. Nat. Acad. Science. Published ahead of print October 20, 2014.

http://scicasts.com/neuroscience/2065-cognitive-science/8539-study-suggests-mental-rest-and-reflection-boost-learning/

http://www.nextgenscience.org/


Dr. Klemm's latest book, available at most retail outlets, is "Mental Biology. The New Science of How the Brain and Mind Relate" (Prometheus).