Posts Tagged ‘dyslexia’

Studying Japanese yields clues for kids with dyslexia learning English

July 11, 2011

The Wall Street Journal reports on recent research into the use of character-based languages such as the Japanese language kanji.

Learners with dyslexia struggle with the association between letters and sounds in English (a language in which words are comprised of groups of sounds that readers decode). However, character-based languages, where the characters represent complete words or ideas, are mastered through memorization, a skill that many students with dyslexia have mastered to compensate for their decoding struggles.

One study featured in the WSJ article looked at fMRI brain scans of dyslexic students and discovered that they use the same area of the brain to read English as do readers of kanji, a character-based Japanese language. This is different from the area of the brain used by typically developing English readers (and readers of kana, another Japanese language in which characters represent sounds instead of words or ideas).

As the article notes, we don’t cure dyslexia by teaching students in a character-based language. But it does offer some insight into how these kids’ brains are working differently and how teachers might be able to deliver reading-based content more effectively.

We have a link to a fantastic dyslexia study on our Web site. The study, performed at Stanford, is very consistent with the findings discussed in the WSJ article, as it supports the idea that students with dyslexia tend to make reading a more visual task, while typically developing readers integrate auditory processing as well.


The Thirsty Linguist reviews Oliver Sacks’ latest book “The Mind’s Eye”

March 31, 2011

Doctor and author Oliver Sacks is known for bringing neuroscience to the masses. In The Man Who Mistook His Wife for a Hat and Awakenings (which was made into a movie starring Robert DeNiro and Robin Williams), Sacks explores neurological disorders with the writing skills of a novelist.

Our friend, the Thirsty Linguist, reviews Sacks’ latest book, The Mind’s Eye, which explores the human experience of vision:

As in some of his previous books, Sacks presents case histories of individuals suffering from neurological injury or disease, and uses these histories as a means to probe the capacities of the mind. Lilian Kallir, for example, is a pianist who loses the ability to read, even though the rest of her vision remains intact and, puzzingly, she can still write. Sacks follows Lilian’s story over a period of three years, describing the coping strategies she develops, such as color-coding items in her home, as well as the new talents that arise unexpectedly with her condition, such as the ability to re-arrange musical pieces in her mind without consulting a score. Howard Engel, featured in another case history, is a writer who also loses the ability to read, but he approaches his situation differently: he rejects audiobooks, refuses to give up the world of text, and painstakingly learns his ABCs all over again.

Lilian’s and Howard’s cases both suggest that the brain has a specific location dedicated to reading. But it is not at all obvious why this should be so. Unlike spoken language, which evolved over hundreds of thousands of years, written language is a relatively recent cultural invention that offered no survival advantage to humans in primitive societies. Plasticity offers a potential answer to this conundrum: we can and do use structures in the brain for purposes very different from those for which they evolved. Sacks casts a wide net to gather evidence for this idea. He describes case histories of nineteenth century neurologists, who treated patients with symptoms similar to Lilian’s and Howard’s. He cites evolutionary thinkers from Charles Darwin and Alfred Russel Wallace to Stephen Jay Gould and Elisabeth Vrba, tracing the history of the notion of “exaptation,” a biological adaptation which gets put to a new use. He presents key results from imaging studies which demonstrate that different areas of the brain are active during reading versus listening. And he summarizes a computational study of over 100 writing systems which shows that, despite their diversity, these systems share basic visual signatures which resemble those found in natural settings.

The Mind’s Eye thus offers narrative science writing of the most satisfying kind. We delight in pedagogical moments because Sacks weaves them seamlessly into the case histories. We get drawn into the topics of evolution, brain imaging, and computation because we want to follow people like Lilian and Howard. “Make characters the matter of your narrative,” advises James Shreeve in A Field Guide for Science Writers, “and let the science spill from their relations.” Sacks does precisely that.

If Sacks’ work intrigues you, you might also be interested in:

TED Talk: Dr. Michael Merzenich on Rewiring the Brain

March 23, 2011

Dr. Michael Merzenich is a pioneer in brain plasticity research. In this TED Talk, recorded in 2004, Dr. Merzenich describes impairments to the brain’s processing ability, and how we can train the brain back to normal processing:

We now have a large body of literature that demonstrates that the fundamental problem that occurs in the majority of children that have early language impairments, and that are going to struggle to learn to read, is that their language processor is created in a defective form. And the reason that it rises in a defective form is because early in the baby’s brain’s life the machine process is noisy. It’s that simple. It’s a signal to noise problem. Okay? And there are a lot of things that contribute to that. There are numerous inherited faults that could make the machine process noisier.

Every sound the child hears uncorrected is muffled. It’s degraded. The child’s native language is such a case is not English. It’s not Japanese. It’s muffled English. It’s degraded Japanese. It’s crap. And the brain specializes for it. It creates a representation of language crap. And then the child is stuck with it.

Now the crap doesn’t just happen in the ear. It can also happen in the brain. The brain itself can be noisy. It’s commonly noisy. There are many inherited faults that can make it noisier. And the native language for a child with such a brain is degraded. It’s not English. It’s noisy English. And that results in defective representations of sounds of words, not normal, a different strategy, by a machine that has different space constants. And you can look in the brain of such a child and record those time constants. They are about an order of magnitude longer, about 11 times longer in duration on average, than in a normal child. Space constants are about three times greater. Such a child will have memory and cognitive deficits in this domain. Of course they will. Because as a receiver of language, they are receiving it and representing it. And in information it’s representing crap. And they are going to have poor reading skills. Because reading is dependent upon the translation of word sounds into this orthographic or visual representational form. If you don’t have a brain representation of word sounds that translation makes no sense. And you are going to have corresponding abnormal neurology.

The point is is that you can train the brain out of this. A way to think about this is you can actually re-refine the processing capacity of the machinery by changing it. Changing it in detail. It takes about 30 hours on the average. And we’ve accomplished that in about 430,000 kids today. Actually about 15,000 children are being trained as we speak. And actually when you look at the impacts, the impacts are substantial.

Think of a classroom of children in the language arts. Think of the children on the slow side of the class. We have the potential to move most of those children to the middle or to the right side. In addition to accurate language training it also fixes memory and cognition speech fluency and speech production, And an important language dependent skill is enabled by this training — that is to say reading. And to a large extent it fixes the brain. You can look down in the brain of a child. in a variety of tasks that scientists have at Stanford, and MIT, and UCSF, and UCLA, and a number of other institutions. And children operating in various language behaviors, or in various reading behaviors, you see for the most extent, for most children, their neuronal responses, complexly abnormal before you start, are normalized by the training.

There’s some stuff about monkeys in the middle that went a little over our heads, but the talk is worth the 20 minute investment.

Learning to Read vs. Reading to Learn

March 1, 2011

Around 2nd or 3rd grade, students begin the transition from learning to read to reading to learn. In the process, they open their minds to a flood of critical information across disciplines. And to incorporate this new knowledge, students must have mastered the basics of reading and achieved automaticity.

At Scientific Learning’s Science of Learning blog, Terri Zezula addresses the criticality of automaticity for students to begin the transition to reading to learn:

In achieving automaticity, we free our brains – our working memories – from the details of the task, allowing us to use that brain power to do more, building on those sets of automatic skills. For our students, achieving automaticity  in reading is essential not only to their becoming effective readers, but becoming effective all-around learners. The majority of students make the shift from “learning to read” to “reading to learn” around second or third grade. At this stage, their reading skills have developed to a point of automaticity where they no longer need to use their working memory to facilitate the task of reading, and they can use that memory for things like interpretation, comprehension and creative thinking.

On the other hand, continues Zezula:

Imagine what learning becomes for the struggling student who does not develop this automaticity alongside his or her fellow students. As others begin to learn more and more from their reading, the struggling reader must engage their working memory in the challenge of getting through the letters and words of each sentence as opposed to using that valuable memory to glean meanings and assimilate information. As their reading skills lag, their overall ability to learn suffers.

A previous post here at Thoughts from Be Amazing Learning addressed the same phenomemon:

We hear from parents a lot that their child does just fine with the mechanics of reading (decoding, spelling, etc.), but struggles with comprehension. Reading comprehension is a difficult task, as it represents the synthesis of so many language and literacy skills, from phonemic awareness to sequencing and working memory. As such, it takes time and a lot of practice to develop reading comprehension skills.

It’s important to note, however, that while kids may be struggling with comprehension, the root cause of their struggle may be more foundational in nature. For example, a child may decode well, but if his brain is working overtime on decoding, there may just not be anything left when it comes time to comprehend what he’s just read. Comprehension requires things like a working memory that’s developed enough to remember the beginning of a sentence when you get to the end. Or the first sentence of a paragraph when you get to the last. But if we can get a child’s brain to process more efficiently, the mechanics of reading become easier, which frees up energy for more complex tasks like comprehension.

The good news is that we can help kids’ brains process more efficiently. Just like we exercise our bodies in the gym or on the track to build physical fitness, we can build brain fitness through targeted exercises that adapt to our abilities. If you have a child struggling with reading comprehension or other learning challenges, visit our Web site at or call (800) 792-4809 to learn how developing foundational cognitive skills can help your child successfully make the transition to reading to learn.

More research on the importance of auditory processing abilities for reading

February 7, 2011

We were interested to see new research from Belgium that looks at the link between early auditory processing abilities and later reading struggles. Published in January in Research in Developmental Disabilities, the longitudinal study showed that auditory processing and speech recognition struggles in kindergarten and first grade corresponded to dyslexia diagnoses in the third grade.

This new research is in line with previous studies that have determined that the auditory centers of the brain in dyslexic readers are under-activated compared to their typically developing peers (interestingly enough, the visual centers of the brain in dyslexic readers are hyper-activated).

Given the criticality of developing auditory processing abilities in young children, what’s a parent to do?

On her Parent Smart blog, Dr. Martha Burns has a couple suggestions:

  • Bed time stories: “It doesn’t matter what the stories are. Many very young children love to hear the same storybook over and over, that is just fine.   Try to make a habit of 15 or more minutes a day of “quiet time” before bed in which your child selects a book and you read it together.” Dr. Burns includes age-specific suggestions for story time as well.
  • Audio books: “Rather than bringing a DVD player along on a trip, try audio-books. The advantage of an audio book over a DVD is that it builds listening skills which are critical for doing well in school and allows your child to follow along with the written pages as they listen to the book, so it builds reading skills as well.”

An intervention like the Fast ForWord programs may be appropriate as well. A study of public school children with Auditory Processing Disorder showed improvement in phonemic decoding and sight word reading abilities after training with Fast ForWord. And the Stanford study referenced above showed normalization of activity in critical areas of the brain used for reading and significant improvements in reading and oral language skills on a number of assessments after Fast ForWord training.

Fast ForWord vs. Cogmed

January 5, 2011

Be Amazing Learning offers programs that address foundational cognitive skills, rather than academic content. We work on helping children learn better. By developing skills such as working memory, attention, sequencing, and brain processing rates, our programs don’t simply give kids new academic knowledge; instead, they equip kids’ brains to better access and retain information they are exposed to, whether in the classroom or in daily life.

Two programs we use most frequently are Fast ForWord and Cogmed. Both programs are based on the concept of neuroplasticity (the lifelong ability of the brain to reorganize neural pathways based on new experiences). They both are computer-based interventions with rigorous daily protocols. And both have very solid foundational research behind them: Fast ForWord research and Cogmed research.

The programs differ in the cognitive skills they develop. Fast ForWord primarily develops auditory processing rates and auditory working memory, with additional training in sequencing and sustained attention. Cogmed primarily develops working memory (auditory and visual-spatial) and attention skills.

At Be Amazing Learning we recommend one or both of the programs for students, depending on the specific learning or behavior challenge they are dealing with. For example, we typically will recommend Cogmed for students struggling with ADD or ADHD. Cogmed addresses the underlying causes of inattentive behavior and improves attention by developing working memory and the ability to focus on multiple tasks and ignore distractions. (Poor auditory processing abilities can also contribute to attention challenges, and in these cases, the Fast ForWord programs may also be an effective intervention.)

Similarly, for students with dyslexia, we typically recommend the Fast ForWord programs, as they attack the auditory processing disorders that cause reading difficulties. And there’s great research on students with dyslexia showing significant improvements in reading and oral language skills on a number of assessments, as well as normalization of activity in critical areas of the brain used for reading after Fast ForWord training.

And in some cases, such as for students struggling with executive function disorder, we might recommend both programs, because they both effectively develop and strengthen the cognitive skills associated with successful executive function, including :

  • Memory – The ability to store information and ideas.
  • Attention – The ability to focus on information and tasks, and ignore distractions.
  • Processing Rate – The rate at which a student is able to accurately perceive and manipulate information.
  • Sequencing – Placing the detail of information in its accustomed order.

The bottom line is that nearly every child can benefit from improved brain processing efficiency.  Wherever your child is, Be Amazing Learning can help move them forward. Our programs have been proven to be effective with many types of learners of all ages, from students with diagnosed learning difficulties, to those simply struggling with homework or reading. With Cogmed and Fast ForWord at our disposal, we can design an effective training program to develop a range of foundational cognitive skills and improve academic potential and performance.

Traditional Tutoring vs. Cognitive Training

January 4, 2011

Traditional tutoring offers additional help in a particular subject area or with a particular skill. It can be an effective addition to content delivered in the classroom, especially because it can frequently be tailored to a child’s individual needs.

Be Amazing Learning is different because the programs we offer (Fast ForWord and Cogmed) address foundational cognitive skills, rather than academic content. We work on helping children learn better. By developing skills such as working memory, attention, sequencing, and brain processing rates, our programs don’t simply give kids new academic knowledge; instead, they equip kids’ brains to better access and retain content they are exposed to, whether in the classroom or with a tutor.

Additionally, training cognitive skills with Be Amazing Learning is a one-time shot: kids build their brain fitness with the programs, then move on to better academic performance. Once children have cognitive training, they stay “fit” by using their new cognitive skills. Studies have shown that the improvements in cognitive skills we can help your child achieve are both substantial and enduring. For example, a 4-year longitudinal study conducted at Dallas Independent School District that showed that students who trained with Fast ForWord programs achieved significant gains in reading, and maintained those gains relative to their peers.

For more information about how cognitive training can help your child, visit our Web site or call (800) 792-4809.

Children of the Code

September 29, 2010

Reading is such an incredibly complex task that it’s not notable that some students struggle with reading, but rather miraculous that any of us can read at all. The Children of the Code project calls attention to the problems that we face when our children do not learn to read:

We don’t look at reading difficulties through the lens of how to improve the ‘teaching’ of reading, instead through the lens of ‘understanding the challenges involved in learning to read’ –  from the learner’s perspective.

The Children of the Code web site teems with information about reading challenges from experts in the field, including Sally Shawitz, who has used neuro-imaging to understand the basic nature of reading and reading difficulties, and  Paula Tallal, whose foundational research into the link between oral and written language led to the development of Fast ForWord.

At Be Amazing Learning, we are committed to offering individualized, validated solutions for students who are struggling with reading. We are intrigued with depth and breadth of interviews on the Children of the Code site from experts in the fields of neuroscience, cognitive psychology, linguistics, instructional design, literacy, and teaching. If you have an interest in reading difficulties you should take a look at this great site.

Be Amazing Learning now offers Reading Assistant to develop reading fluency

April 6, 2010

Be Amazing Learning now offers Reading Assistant from Scientific Learning. Brought to you by the same people who developed the highly effective Fast ForWord programs, Reading Assistant is a scientifically-based intervention  that combines advanced speech verification technology with the latest reading science to help students strengthen their reading fluency, vocabulary and comprehension.

Using research-validated speech verification technology, Reading Assistant “listens” to a student as he or she reads aloud. Monitoring for signs of difficulty, the program intervenes with assistance when the student is challenged by a word. Students re-read passages several times to build automaticity, and are assessed to determine their level of comprehension by skill.

Reading Assistant

Reading material in Reading Assistant contains highly-illustrated selections grouped in topical clusters, many with a science or social studies theme. This organization helps students build a body of knowledge and also read common vocabulary in different contexts. The content is divided into four grade bands:

  • K-3: Contains selections that relate to young reader’s interests and experiences while building world knowledge and vocabulary. Drawn from authentic contemporary, classic, and multicultural literature, the selections include a variety of genre, from rhymes and predictable fiction to nonfiction.
  • Grades 4-5: Contains selections that relate to the independence and broadening interests of upper elementary students. Drawn from authentic contemporary, classic, and multicultural literature, clusters include a variety of genre—fiction, historical fiction, jokes, poetry, folktales, and biography—and range in reading level from Grade 1 to Grade 5.
  • Grades 6-8: Contains selections that relate to middle schoolers’ interests as well as topics from science, social studies, and literature standards. Drawn from authentic contemporary, classic, and multicultural literature, clusters include a variety of genre—fiction, personal narratives, jokes, poetry, eyewitness accounts and journals, expository nonfiction, and biography—and range in reading level from Grade 2 to Grade 5.
  • Grades 9-12: Contains selections that relate to adolescents’ interests as well as topics from science, social studies, and literature standards. Drawn from authentic contemporary, classic, and multicultural literature, clusters include a variety of genre—fiction, personal narratives, jokes, poetry, eyewitness accounts and journals, expository nonfiction, and biography—and range in reading level from Grade 3 to Grade 12.

As with the Fast ForWord programs, Be Amazing Learning continuously monitors student progress, customizes instruction, and helps motivate students. Our detailed reports pinpoint student learning needs with in-depth analysis of comprehension skills and strategies as well as level of thinking.

Reading Assistant is appropriate for students who have completed programs in the Fast ForWord Language or Fast ForWord Literacy series, or who simply need help developing fluency. It can be run concurrently with programs from the Fast ForWord Reading series.

Call today for more information about how to incorporate Reading Assistant into your summer!

How otherwise bright people struggle to read

January 5, 2010

We frequently hear from parents of bright kids who are just having a tough time with reading. A new study, published in the January 1, 2010 issue of the journal Psychological Science, looks at the relationship between intelligence and reading ability.

From Medical News Today:

The researchers found that in typical readers, IQ and reading not only track together, but also influence each other over time. But in children with dyslexia, IQ and reading are not linked over time and do not influence one another. This explains why a dyslexic can be both bright and not read well.

The study examined data from the Connecticut Longitudinal Study, an ongoing 12-year study of cognitive and behavioral development in a representative sample of 445 Connecticut schoolchildren. The researchers each child in reading every year and tested for IQ every other year.

From Sally E. Shaywitz, M.D., the Audrey G. Ratner Professor in Learning Development at Yale School of Medicine’s Department of Pediatrics, and co-director of the newly formed Yale Center for Dyslexia and Creativity:

“I’ve seen so many children who are struggling to read but have a high IQ,” said Shaywitz. “Our findings of an uncoupling between IQ and reading, and the influence of this uncoupling on the developmental trajectory of reading, provide evidence to support the concept that dyslexia is an unexpected difficulty with reading in children who otherwise have the intelligence to learn to read.”

Typical readers learn how to associate letters with a specific sound. “All they have to do is look at the letters and it’s automatic,” Shaywitz explained. “It’s like breathing; you don’t have to tell your lungs to take in air. In dyslexia, this process remains manual.” Each time a dyslexic sees a word, it’s as if they’ve never seen it before. People with dyslexia have to read slowly, re-read, and sometimes use a marker so they don’t lose their place.

So what’s the answer for parents with otherwise bright kids who struggle with reading? Shaywitz’ previous research into dyslexia suggests that a neurological signature for dyslexia is under activation of the parieto-temporal region of the brain. A Stanford University study that examined brain imaging scans of children with dyslexia who used Fast ForWord programs showed normalization of activity in this critical area of the brain (used for reading). Furthermore, the students in the Stanford study showed significant improvements in reading and oral language skills on a number of assessments.

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