After reading What we know (and think we know) about the learning brain?An?interview with Tracey?Tokuhama-Espinosa in Module 3: Lecture Materials & Resourc

After reading What we know (and think we know) about the learning brain An interview with Tracey Tokuhama-Espinosa in Module 3: Lecture Materials & Resources, please respond and discuss the following.  

  1. Please given an educational implication of one of the six principles in mind, brain and education science that she cites in Figure 1 that you were not aware of previously.
  2. Discuss how knowledge of the principle you selected will change your teaching or leadership practice.
  3. Provide an example of a mistaken belief that educators hold about learning and how holding that belief can impair a teacher’s effectiveness.
  4. Pick one of the tenets in mind, brain, and education science listed in Figure 2 that none of your classmates have chosen and provide an outside citation that supports it.

Module 3: Lecture Materials & Resources

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icon   Classical Conditioning & Brain, Cognitive, & Language Development

Read and watch the lecture resources & materials below early in the week to help you respond to the discussion questions and to complete your assignment(s).

(Note: The citations below are provided for your research convenience. Students should always cross-reference the current APA guide for correct styling of citations and references in their academic work.)

Read

· Durwin, C. C., & Reese-Weber, M. J. (2020).

· Chapter 5: Brain Development

· Chapter 6: Cognitive Development

· Chapter 7: Language Development

· Chapter 8: Behavioral Learning Theories

· Chapter 20: Intelligence and Giftedness

· Heller, R. (2018). What we know (and think we know) about the learning brain: An interview with Tracey Tokuhama-Espinosa.  Phi Delta Kappan100(4), 24-30.

·  Kappan the learning brain.pdf Download  Kappan the learning brain.pdf

Watch

· The Little Albert Experiment (6:20) Johncheezy. (2010, June 1).  The Little Albert Experiment [Video].  YouTube. The Little Albert ExperimentLinks to an external site. The Little Albert Experiment

· The importance of bilingualism (4:02) Thechildrens. (2011, March 29).  The importance of bilingualism [Video]. YouTube. The Importance of BilingualismLinks to an external site. The Importance of Bilingualism

· Sarah-Jayne Blakemore: The mysterious workings of the adolescent brain (14:26) TED. (2012, September 17).  Sarah-Jayne Blakemore: The mysterious workings of the adolescent brain [Video]. YouTube.  Sarah-Jayne Blakemore: The mysterious workings of the adolescent brainLinks to an external site. Sarah-Jayne Blakemore: The mysterious workings of the adolescent brain

· Teaching matters: scaffolding (5:13) eMedia Workshop. (2012, September 17).  Teaching matters: scaffolding [Video]. YouTube. Teaching Matters: ScaffoldingLinks to an external site. Teaching Matters: Scaffolding

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Supplemental Materials & Resources

None.

Module 3 Discussion

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icon  The Learning Brain

After reading  What we know (and think we know) about the learning brain An interview with Tracey Tokuhama-Espinosa in  Module 3: Lecture Materials & Resources,  please respond and discuss the following.  

1. Please given an educational implication of one of the six principles in mind, brain and education science that she cites in Figure 1 that you were not aware of previously.

2. Discuss how knowledge of the principle you selected will change your teaching or leadership practice.

3. Provide an example of a mistaken belief that educators hold about learning and how holding that belief can impair a teacher’s effectiveness.

4. Pick one of the tenets in mind, brain, and education science listed in Figure 2 that none of your classmates have chosen and provide an outside citation that supports it.

Submission Instructions:

· Your initial post should be at least 200 words, formatted, and cited in current APA style with support from at least 2 academic sources

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24 Kappan December 2018/January 2019

KAPPAN: Your professional experience has been extraor- dinarily varied. You’ve taught at the elementary, secondary, and university levels in multiple countries. You’ve worked in adult education, children’s television, online learning, counseling, and higher education administration. You’ve done research on multilingualism . . . How have your many roles and interests brought you to focus specifically on brain science and its implications for teaching and learning?

TOKUHAMA-ESPINOSA: I trace everything back to my dad, who was a great, great teacher. He was raised in Hawaii and went to UC Berkeley in the 1960s on a schol- arship to study nuclear physics, but he decided what he really wanted to be was a public school math teacher. He worked in some pretty tough neighborhoods in Northern California, and he always chose to teach the students who were struggling the most. He started something called the “F Club,” for example, for kids who had failed classes, so he could get them together and find a way to get back on track.

I remember walking down the street with him, and these big, burly guys would always come running over to say hi and tell him that they have a great job now, and they’re doing well, and they wouldn’t have made it without him . . . So I knew my dad was a brilliant teacher. But I always

What we know (and think we know) about the learning brain An interview with Tracey Tokuhama-Espinosa

Kappan’s editor talks with a leader in the international movement to translate findings from neuroscience into usable knowledge for educators.

By Rafael Heller

RAFAEL HELLER is the editor-in-chief of Kappan magazine.

wondered what was it, exactly, that made him so good at it. Was he just really smart about math? Did he have some mysterious knack for connecting with kids? What was it?

So that’s what drew me into education, this curiosity to figure out what makes somebody a great teacher, and why it is that some kids learn things easily but others struggle. Over time, that led me to neuroscience, which focuses on the organ that’s most important to teaching and learning: the brain. And, in turn, I realized that while recent findings from brain science can be incredibly helpful to educators, those findings haven’t really been incorporated into teacher preparation. Perhaps even more important, teachers have picked up a lot of misinformation about the human brain — “neuromyths” is the term I like to use — and these mistaken beliefs about how the brain works can easily lead them to teach in ways that are harmful to kids.

But let me say up front that I’m not trying to blame teach- ers for what they don’t know. A lot of the science is new, and teachers haven’t had enough opportunities to learn about it and see for themselves why it’s time to reconsider certain ideas.

KAPPAN: In your new book, you describe working with researchers from around the world to identify these neuro- myths, figure out where they come from, and explain why they’re not true. Tell us a bit about that work.

What We’ve learned about learning

V100 N4 kappanonline.org 25

reach a consensus on what’s known, at this point, about the science of learning. Given the existing evidence, what can we say for sure, and what can we say we with less certainty?

In 2017, I conducted a 10-year follow-up to the Delphi study, and around the same time I was asked by the OECD to be a part of an expert panel to clarify what should be teachers’ new knowledge based on all of these findings. In both projects, I heard a lot of agreement about important advancements in the study of teaching and learning, but I also heard experts voice this frustra- tion: Why do teachers still believe all these old myths about the brain, like the idea that we use only 10% of our brain power, or that some people are “right-brained” and others are “left-brained,” or that listening to classical music will make you smarter? For years we’ve been col- lecting and sharing the real findings, so why do teachers continue to believe things that aren’t true?

TOKUHAMA-ESPINOSA: In 2002, the Organization for Economic Cooperation and Development (OECD), which is based in Paris, did an international comparative study showing how teachers around the world just didn’t know enough about the brain. So, in 2007, while I was working on my doctoral dissertation, I decided to bring together a group of experts in neuroscience, psychology, and ed- ucation — called the Delphi panel — to look into ways to improve teachers’ pedagogical knowledge. In particular, how should teachers’ work be informed by recent advances in neuroscience?

The Delphi panel is sort of like the panels that have been convened in the U.S. by the National Academy of Sciences (NAS) — and, in fact, some of the members of the Delphi panel have been on NAS panels, too — but Delphi is more in- ternational. Basically, the idea is to convene a diverse group of researchers who are experts in their field to see if they can

TRACEY TOKUHAMA-ESPINOSA A native of California, Tracey Tokuhama-Espinosa is an education researcher affiliated with the Latin American Social Science Research Faculty (FLACSO) in Quito, Ecuador. She also teaches The Neuroscience of Learning at Harvard University’s Extension School, and she is a former member of the Organization for Economic Cooperation and Development (OECD) expert panel to redefine teachers’ new pedagogical knowledge due to contributions from technology and neuroscience.

Tokuhama-Espinosa has taught at every level, from kindergarten to the middle grades, high school, college, and adult education, and she has facilitated hundreds of workshops for teachers, administrators, and education policy makers around the world. She is the former director of the Institute for Teaching and Learning (IDEA) and director of online learning at the Universidad San Francisco de Quito, and she was founding dean of education at the American University in Quito. She currently heads Connections, which seeks to improve the quality of education through research, teacher training, and student support — with MESH, a U.K.-based charity, Connections offers a free online evidence-based platform (http://thelearningsciences.com, in English and Spanish) to help fill in gaps of pedagogical knowledge for the 21st century.

Tokuhama-Espinosa is the author of eight books, including Neuromyths: Debunking False Ideas about the Brain (W.W. Norton, 2018), and dozens of peer-reviewed articles on topics ranging from multilingualism to 21st-century skills to the study of mind, brain, and education. Her current research focuses on improving the indicators used to measure educational quality and translating findings from neuroscience into usable knowledge for teachers. She received her bachelor’s in international relations and in communications from Boston University, her master’s in education from the Harvard University Graduate School of Education, and her Ph.D. from Capella University.

26 Kappan December 2018/January 2019

which — since bigger is assumed to be better — they took to mean that men have more brain power. Of course, it didn’t occur to them that if men’s and women’s brains differ in size, that’s just because men’s and women’s bodies tend to differ in size overall. And in any case, we’ve come to understand since then that our human potential to learn doesn’t have to do with brain size or the total number of neurons — learning has to do with the connections we create among neurons.

Now I’m not saying that there aren’t any differences to be found between male and female brains (or the amounts of hormones males and females tend to produce, which do in- fluence behavior). For example, there was a brain imaging study that observed that when doing certain types of spa- tial reasoning and math problems, boys and girls activated different neural networks. But there’s no evidence that this translates to differences in intelligence or potential. It’s not that girls can’t reason spatially just as well as boys; they just use a different network to get the same solution — and with a tiny bit of training, they perform at the same level.

So yes, you can point to some very small differences between male and female brains. What’s so important to remember, though, is that the differences among men, and the differences among women, are far greater than the dif- ferences between men and women.

KAPPAN: Is that how neuromyths get started? Scientists observe a small difference, or they report a single finding, and people blow it out of proportion?

TOKUHAMA-ESPINOSA: Right, a little bit of scientific knowledge can be a dangerous thing. We just haven’t done very much to help teachers become scientifically literate.

Many of us came to the conclusion that if we want teach- ers to understand how students actually learn, we’re going to have to start by clearing away these mistaken beliefs. So that’s when I decided to write this new book on neuromyths.

KAPPAN: Give us a few more examples. Obviously, we can’t review all 70 of the neuromyths that you describe in the book, but what are a few of the most prevalent myths that teachers tend to believe, and what makes them so harmful?

TOKUHAMA-ESPINOSA: There’s the idea that students have differing “learning styles,” which has been debunked many times. Or the idea that male and female brains are fundamentally different from one another. Or the idea (popularized by some of the early brain research) that specific abilities are locked into specific parts of the brain — spatial ability in one part, reading in another, math in another, and so on.

Or take multitasking. A lot of people, including a lot of teachers, think they’re good at it — and a lot of people insist that women are better at it than men! But the fact is that nobody can multitask, not if we’re talking about tasks that put a significant cognitive load on your attention and memory. Sure, if you’re talking on the phone with your mom, you might be able to chop vegetables at the same time. But chopping vegetables doesn’t require much mental energy. It’s a routine activity you’ve habituated over time. You’ve more or less automated this particular skill, so you can do it while telling your mom about your day. But you can’t tell your mom about your day while you’re also trying to read a recipe. It’s inefficient. You get distracted. At best, you can shift back and forth between those two tasks.

My own kids tell me they like to listen to music while they do their homework. It’s relaxing, they say, and it doesn’t take up any of their working memory. And they’re right, as long as they just have the music on in the back- ground. But as soon as they start checking their text mes- sages, they’re no longer doing their homework. They might argue that they have this special capacity to multitask, but it’s just not happening. And the same goes for teachers. They might think they can go over Johnny’s homework while they’re also listening to Mary explain why she was late to class, but they can’t really do both things at once and pay the necessary attention.

KAPPAN: You mentioned the widespread belief that male and female brains are different. Is that just old-fashioned sexism, or is there a specific origin to that idea?

TOKUHAMA-ESPINOSA: Both. And this is one area where it’s hard to separate the bias from the science itself. You can go back to the 1800s, for example, when scientists discovered that men tend to have slightly larger brains than women,

I knew my dad was a brilliant teacher. But I always wondered what was it, exactly, that made him so good at it.

V100 N4 kappanonline.org 27

Doesn’t it try to be something like a Consumer Reports for K-12 education?

TOKUHAMA-ESPINOSA: Yes and no. On the Delphi panel, we looked at the What Works Clearinghouse, but we found that its goal is much narrower than what we were trying to do. Mostly, the clearinghouse evaluates specific educational programs and interventions, but we set out to take stock of the underlying knowledge base, from across the learning sciences. We didn’t ask whether this or that intervention works in the classroom. Rather, we asked, what does neuroscience tell us about teaching and learning?

For example, we reviewed the research on sleep patterns and how they relate to memory and learning, and we looked at the research on nutrition and stress and depression and their effects on learning . . . These topics aren’t going to show up in the What Works Clearinghouse, but they are critically important for edu- cators to understand.

KAPPAN: In your book, you explain that the 2017 panel was able to reach agreement on six core principles (see Figure 1). These are findings, drawn from a mountain of re- search in the neurosciences, that panelists found to be true about how all brains work, regardless of context or culture. Further, you identified an additional 21 tenets (see Figure 2). These are also supported by very strong evidence, but the panelists couldn’t reach quite the same level of consensus on them — some argued that these may not be universally true; they may vary somewhat by individuals and across contexts and cultures.

So when the popular media (who love simple Mars-Venus kinds of stories) report that a new brain imaging study shows that boys and girls use different neural networks to solve math problems, how are teachers supposed to know that, in reality, this isn’t such an important finding?

One danger is that teachers will see the news report as con- firmation of their existing assumptions about male-female differences. Unconsciously, at least, it will shape how they treat boys and girls in the classroom, or how they interpret boys’ and girls’ performance. So if Anna’s having trouble with math, then on some level the teacher will assume it’s because Anna’s a girl — because, after all, didn’t they say on the news that girls aren’t as good as boys at spatial reasoning?

And another danger is that there’s a lot of commercial benefit to be had by playing up these differences and exploiting people’s misunderstandings about the signifi- cance of individual scientific studies. Actually, this is an is- sue that I wish I could have addressed more in my book, but my editors urged me not to because they were worried that if I went after some of the commercial programs, we’d face lawsuits. But you can probably guess some of the companies that I’m talking about. You see their ads all the time on TV, all these toys, devices, pills, and software that are supposed to boost your kids’ memory or make them smarter.

KAPPAN: But every new product claims to be the one that’s finally cracked the code, right? If you’re a parent or an educator, it’s hard not to be swayed by an advertisement that says, “Sure, all those earlier products were phony, but we’ve created an app based on the newest brain science, and this one really does work.”

TOKUHAMA-ESPINOSA: True, so let me say this bluntly: It’s always good to be skeptical about commercial products based on brain research. Don’t be fooled by how many scientists a company has on its advisory board, or what they’ve been able to teach rats in the lab, or even what they’ve been able to teach some kids under controlled con- ditions. It’s just not that straightforward to turn research findings into effective programs and apps. If it sounds too good to be true, it probably is.

That’s why it was so exciting to work with the Delphi panel, where the whole idea was to bring all of these super-skeptical scientists together to set the advertising aside, look very carefully at the existing evidence, and say “OK, this approach has our blessing . . . and that idea truly is worthy of bringing into classrooms.” It’s very cool for a group like that to be able to reach consensus on some spe- cific principles that teachers can really stand behind.

KAPPAN: Isn’t that what the U.S. Department of Education’s What Works Clearinghouse is supposed to do?

It’s always good to be skeptical about commercial products based on brain research.

28 Kappan December 2018/January 2019

TOKUHAMA-ESPINOSA: Well, most people can get to be pretty good at certain things, especially things that involve mo- tor learning, like playing the piano. Your brain adapts to what it does most, so if you spend a lot of time rehearsing a skill, you’re going to improve. Again, that’s the good news: We can help every kid to make real progress in school and life.

But there’s a limit. If you have a Tiger Mom who makes you spend 10,000 hours practicing the piano, then you’re probably going to reach a pretty high level of proficiency. But if it’s not in your nature to become a truly great pianist, then you won’t be a gifted musician, no matter how many hours you put into it. Not everybody has the potential to be a genius.

KAPPAN: How would you integrate these principles and tenets into teacher preparation? And if all teachers under- stood these things, what difference would that make?

TOKUHAMA-ESPINOSA: Experienced teachers know all sorts of things — either intuitively or from reading and professional development — about what works and what doesn’t. They probably know, for instance, that it’s important, early in a lesson, to elicit students’ background knowledge about a topic. But the question is, why is it so valuable to assess prior knowledge? Why should you provide explicit instruction in metacognitive strategies, getting students to think about their own learning? Why is it so important to ask kids how they figured out a math problem?

This is the added value that teachers get when you introduce them to the neuroscience. They don’t just learn that a teaching practice has evidence behind it; they learn

The question is, if we know these principles and tenets to be true, then so what? What are the implications for K-12 education?

TOKUHAMA-ESPINOSA: Let’s start with the first prin- ciple, which states that while all brains share some basic similarities in structure, all brains are also unique. Every person begins with their own, unique genetic makeup, and they also have their own life experiences, which influence the neural pathways they create in their brains.

KAPPAN: In other words, we’re shaped by a combination of nature and nurture?

TOKUHAMA-ESPINOSA: Yes. And free will. And that’s good news, since it means we’re not totally constrained by our genetics or past experiences, but also our choices. But at the same time, there’s also sad news here: Free will has its limits. It’s just not true that we can rewire our brains to become whoever we want. The My Fair Lady story has to go out the window. If the kids in my class have had totally different life experiences — some of them super-enriched and others super-constrained — then it’s not realistic to think that I can get them all to the same place in the same amount of time with the same activities.

KAPPAN: I’m assuming, then, that you disagree with Malcolm Gladwell’s argument that anybody can become suc- cessful at anything if they put 10,000 hours of practice into it.

FIGURE 1.

Principles in mind, brain and education science (2017)

PRINCIPLE 1 Human brains are as unique as human faces. While the basic structure of most human brains is the same (similar parts in similar regions), no two brains are identical. The genetic makeup unique to each person combines with life experiences (and free will) to shape neural pathways.

PRINCIPLE 2 Each individual’s brain is differently prepared to learn different tasks. Learning capacities are shaped by the context of the learning, prior learning experiences, personal choice, an individual’s biology and genetic makeup, pre- and perinatal events, and environmental exposures.

PRINCIPLE 3 New learning is influenced by prior experiences. The efficiency of the brain economizes effort and energy by ensuring that external stimuli are first decoded and compared, both passively and actively, with existing memories.

PRINCIPLE 4 The brain changes constantly with experience. The brain is a complex, dynamic, and integrated system that is constantly changed by individual experiences. These changes occur at a molecular level, whether simultaneously, in parallel, or even before they are visible in behavior.

PRINCIPLE 5 The brain is plastic. Neuroplasticity exists throughout the life span, though there are notable developmental differences by age.

PRINCIPLE 6

There is no new learning without some form of memory and some form of attention. Most school learning requires well-functioning working, short-, and long-term memory systems and conscious attention. However, procedural learning, habituation, sensitization, and even episodic memory can occur without conscious attention.

Source: Tokuhama-Espinosa, T. (2018). Neuromyths: Debunking False Ideas about the Brain. New York, NY: W.W. Norton.

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If we want teachers to understand how students actually learn, we’re going to have to start by clearing away these mistaken beliefs.

why it tends to be effective. And that puts them in a better position to figure out what’s working and what’s not in their own classroom. If you understand how important motivation is to learning, say, then you’ll be more aware of the need to assess students’ motivation, or to figure out why one kid doesn’t seem to be motivated by something that’s working for everybody else in the class. Or, for example, if you understand that the human brain interprets a speaker’s facial expressions and tone of voice much faster than the words they’re saying, then you’ll be more careful about your own classroom demeanor.

I think this is the best way to empower teachers. If they know the science, then that allows them to be better researchers in the classroom. And, you know, teachers do more experiments in a day than a neuroscientist

FIGURE 2.

Tenets in mind, brain, and education science (2017)

TENET 1 Motivation influences learning.

TENET 2 Emotions and cognition are mutually influential.

TENET 3 Stress influences learning.

TENET 4 Anxiety influences learning.

TENET 5 Depression influences learning.

TENET 6 Learning is influenced by both challenge and threat as perceived by the learner.

TENET 7 Reactions to facial expressions are both universal and highly individualized.

TENET 8 The brain interprets tones of voices unconsciously and almost immediately.

TENET 9 Humans are social beings who learn from and with each other.

TENET 10 Attention is a complex phenomenon comprising multiple systems.

TENET 11 Most learning does not occur linearly.

TENET 12 Learning involves conscious and unconscious processes.

TENET 13 Learning is developmental (nature and n

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