Recognizing Emotions After Brain Injury: Re-Learning a Critical Social Skill

• October 4, 2011 by Bill Jenkins, Ph.D.

For most of us, interpreting and expressing emotion is something deeply instinctive. But what happens when that ability to express ourselves or read another’s emotions goes awry? Imagine what can happen to a student’s classroom experience if they can’t make sense of something as simple as their teacher’s facial expression. In the past, these kinds of students have been seen as having behavior problems. So how can we help them succeed?

Research has shown that people with traumatic brain injuries often experience this same inability to interpret and respond to emotions, a condition called "affect recognition."

Barry Willer, professor of psychiatry and specialist in TBI (traumatic brain injury) of the University of Buffalo, tells the story of a man and his wife who came into his office with a problem. The woman had experienced a mild traumatic brain injury. While her husband was supporting her recovery as best he could, she consistently described his attitude as “indifferent. “ He was frustrated, to say the least.

“His wife didn’t know she wasn’t recognizing his emotions,” said Willer, recounting the story in a 2009 interview with Insciences Journal , “and he had no idea what was going on.”

This couple is by no means alone. Nearly fifty percent of all traumatic brain injuries result in problems interpreting and expressing emotion.

As educators, being able to connect with our students at an emotional level is essential to classroom success. Without that connection, the learning process can quite easily come to a halt. Thankfully, Willer has demonstrated that there is hope for this population, and that the human brain is quite capable of re-learning how to understand facial expressions and use that information to interpret emotion.

Willer and his team have developed two specific interventions that have shown positive results:

• Facial Affect Recognition (FAR): Individuals view faces on a computer screen that directs them to concentrate on specific elements of each face. "Look at the eyes. What are the eyes doing? What is the mouth doing?" and asks them to name the emotion.
• Stories of Emotional Inference (SEI): Participants are asked to read stories that describe events, along with character’s beliefs, wants and behaviors. From this information, participants are asked to infer the character’s emotions.

"What was so exciting about our preliminary study," says Willer, "is that someone may lose the ability to recognize emotions, but even 10 years later, they can re–learn the skill if given the right assistance."

As it turns out, the only emotion that traumatic brain injuries do not erase is "happy," which is very hard–wired and has an extensive amount of "redundant circuitry." Says Willer, "I don’t know how that happened, but we all can be glad it did."

For further reading:  Milders, M., Fuchs, S., & Crawford, J. R. Neuropsychological impairments and changes in emotional and social behaviour following severe traumatic brain injury. Journal of Clinical and Experimental Neuropsychology, 25, 2003. 157-172.

Related Reading:

Lifelong Learning and the Plastic Brain

5 Paths to Brain Health: Tips From Dr. Paul Nussbaum

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Categories: Brain Fitness, Brain Research, Reading & Learning

Tags: adaptivity, behavior, brain plasticity, brain training, cognitive skills, effort, memory, processing

Neural Prostheses: The Melding of Hardware, Software and Wetware

• September 20, 2011 by Bill Jenkins, Ph.D.

Earlier this year, I wrote about a researcher named Dr. Miguel Nicolelis at Duke University Medical Center and his work with a monkey named Aurora. Through placing implants in Aurora’s skull, Nicolelis was able to record Aurora’s motor nerve signals as she used a joystick to play a simple video game. He then used a computer algorithm to convert those signals into code to power a robotic arm. Over time, because of her brain’s ability to adapt and learn, Aurora taught herself how to control the movements of that robotic arm by just thinking about it.

What we see in Nicolelis’s work is the complex interplay of three different elements of a neural prosthetic system: hardware, software, and what has been come to be known as “wetware.”

• Hardware refers to the machine part of the system. This consists of the wires, computers, circuits, implants and manufactured devices that comprise the system.
• Software refers to the set of instructions, data and algorithms – in other words, the set of rules – that govern the function and operation of the hardware.
• Wetware refers to the combination of biological elements involved in the system, generally including muscles, hormones, nerves and the brain.

Through choreographing the delicate dance between these three systemic elements, biomedical professionals are becoming more able to develop neural prosthetics that continue to improve the quality of life for any number of disabilities, substituting motor, sensory or cognitive capabilities that have been damaged as a result of injury or disease.

Today, biomedical research has given rise to any number of neural prostheses. Visual prosthetics stimulate the optic nerve to counter certain types of blindness. Spinal cord stimulators induce sensations to mask and control pain. Pacemakers work with the muscle and nerves of the heart to monitor and regulate the heartbeat and control fibrillation.

One of the most common applications of the neural prosthesis concept is in the cochlear implant. Dr. Michael Merzenich, professor emeritus and neuroscientist, was the Principal Investigator back during the development of the first cochlear implants at the University of California, San Francisco. The work showed that in as little as six months, patients were able to develop remarkable speech discrimination abilities. It was found that speech discrimination abilities improved over time due to the brain’s plastic ability to change and adapt to these new inputs.

According to the NIH’s National Institute on Deafness and Other Communications Disorders, over 59,000 adults and children have cochlear implants. Just like Aurora’s robotic arm, a cochlear implant involves the integration of hardware, software and wetware. But instead of using motor neurons to articulate robotic fingers, cochlear implants form the technological bridge between the world of sound and the ability to perceive that sound in someone whose ears cannot convert sound vibrations to a nerve impulse. While the ones we developed had a single channel, today’s devices have up to 120, which allows for better input fidelity through stimulating different parts of the auditory nerve.

Of the three elements of the neural prosthetic system, hardware, software and wetware, the only one of them that can be expected – even depended upon – to change over time is the wetware. Both because of normal development and brain plasticity, an individual’s ability to effectively use neural prosthetic will naturally change over time as the individual’s own nervous system adapts to make better use of the hardware and software.

As Dr. Nicolelis demonstrated with Aurora, wetware is an amazingly malleable apparatus. We might imagine these neural prosthetic systems as fantastically complex in terms of their hardware and software. That said, research out of the University of Washington, Seattle, has suggested that, because of brain plasticity, we may be able to use simpler algorithms in the external hardware and software, and depend upon the plasticity of the wetware to make optimal use of these devices.

In the end, we as humans, with our drive to heal and discover, seem to have a limitless ability to develop innovations to remedy our physical ills. And yet, it is the plasticity of our nervous system’s innate ability to adapt that will apparently allow us to make the most of these innovations.

For further reading:

Fallon, J. B., Irvine, D. Shepherd, R. Neural Prostheses and Brain Plasticity. J Neural Eng. 2009 December.

Moritz, C. T., Perlmutter, S. I., Ftez, E. E. Direct Control of Paralysed Muscles by Cortical Neurons. Nature. 2008 December.

Related Reading:

A Gymnast, A Cursor, and A Monkey Named Aurora

Dr. Martha Burns on Brain Plasticity

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Categories: Brain Fitness, Brain Research, Reading & Learning

Tags: auditory processing, brain plasticity, brain training, cognitive skills, innovation, processing, science

Improving Auditory Processing in Children with Autism Spectrum Disorder

• September 8, 2011 by Barbara Calhoun, Ph.D

Summary:  A recent study by Nicole Russo of Northwestern University and her colleagues, published in Behavioral and Brain Functions in 2010, evaluates whether auditory training programs such as Fast ForWord® can alleviate the auditory processing deficits so frequently seen in ASD children.

Russo’s study examines how effectively Fast ForWord could strengthen the auditory processing of speech sounds in similar ASD children. Her team hypothesized that such training would modify the neural processing of sound in children with ASD, and that such children “would show improvement in the neural encoding of speech syllables, including faster response timing, greater fidelity of the response relative to the stimulus, and more accurate pitch encoding over time.” (p. 3)

Results showed that training appeared to have benefited all participants in the experimental group, affecting their neural transcription of speech. According to Russo and her team, “each of the five children who underwent FFW training improved on at least one measure of cortical speech processing relative to the control group, with response timing improving in both quiet and noise for some children.” (p. 13)

Russo and her team were able to conclude that directed auditory training using Fast ForWord shows great promise for improving auditory processing in children with ASD – specifically, those high-functioning children who have hearing in the typical range. 

 

Content:  This study was published in Behavioral and Brain Functions in 2010 and was done at Northwestern University by Dr. Nicole Russo and her colleagues.   It evaluates whether auditory training programs, such as Fast ForWord, can alleviate the auditory processing deficits so frequently seen in children with autism spectrum disorders. Children with autism spectrum disorders or ASD demonstrate impairments in their use of language for social and communicative purposes.  These impairments are typically apparent prior to three years of age.

There is emerging evidence that the neural encoding of speech sounds may be impaired in some children with autism spectrum disorders leading to atypical auditory brainstem responses to speech sounds and difficulties processing speech-specific stimuli such as detecting speech in background noise. 

Since the Fast ForWord products provide auditory training including listening and sound-sequencing exercises, as well as exercises on auditory attention, auditory discrimination, phoneme discrimination, and memory, Dr Russo and her colleagues were interested in investigating the impact of the products on children with ASD.

High-functioning children with ASD who had participated in an earlier study were invited to partake in this one.   The children all had a formal diagnosis of autism spectrum disorder.  They had typical peripheral hearing, average mental abilities and average or near-average language scores.

Eleven boys with an average age of 9.2 completed the entire testing protocol and met the criteria.   The children were then given the option of taking part in the intensive auditory training. Five children opted for the training and formed the experimental group.  The other six children who opted not to take part in the training were willing to take part in the post-test and formed the control group. There was not a significant difference between the two groups in terms of age, IQ, or language ability.

Students in the experimental group used the intense intervention: the Fast ForWord Language Series which entailed the Fast ForWord Language product for an average for 20 days followed by Fast ForWord Language to Reading for an average of 32 days.

Auditory brainstem responses (ABRs) and Event-Related Potentials (ERP’s) were recorded from both groups.  These tests measure the size and the timing of electrical activity that occurs in the brainstem and brain in response to a sound.  In this case, the sounds were synthesized vowels that were heard in the presence of background noise, as well as in quiet.  Auditory brainstem responses are subcortical events occurring less than 10 ms after the stimuli is presented while  event-related potentials are cortical events occurring a few hundred milliseconds after the stimuli is presented.  Both ABR’s and ERP’s measure the aggregate response of neurons and neither requires active involvement by the participant. 

Due to the small number of participants, and the variations between them, the analysis involved defining a “typical change” as the average change for students in the control group plus one standard deviation, and defining a “significant change” for one of the participants as a change that was more than the control’s change plus one standard deviation. 

The researchers were particularly interested in subjects that had two or more measures with significant change.  All five students improved more than one standard deviation on at least two tests. The researchers concluded that there is Initial evidence that directed auditory training may improve auditory processing in a specific population of children with ASD – specifically high-functioning children with ASD who have hearing in the typical range.

They also concluded that computer-based training may benefit some children with ASD by acting on biological processes.

Read the complete report on this research at the link below:

Nicole M Russo, N., Hornickel, J., Nicol, T. Zeckler, S. Kraus, N. Biological changes in auditory function following training in children with autism spectrum disorders. Behavioral and Brain Functions 2010, 6:60.

Related Reading:

Understanding Autism in Children

Language Skills Increase 1.8 Years After 30 Days Using Fast ForWord

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Categories: Brain Fitness, Brain Research, Fast ForWord, Reading & Learning, Scientific Learning Research

Tags: auditory processing, autism, brain training, learning disabilities, processing rate, video

Separating Brain Fact from Brain Fiction: Debunking a Few Neuroscience Myths

• September 1, 2011 by Bill Jenkins, Ph.D.

The brain is one of the most mysterious and misunderstood organs in the body. It represents the seat of our judgment, our senses, perceptions and our creativity.  More than any other aspect of our anatomy, the uniqueness of our brains is at the core of what makes us truly human.

While neuroscience advances every day, there are a number of myths about the brain that are accepted by many people as fact. As a scientist, I and my colleagues have worked to uncover the brain’s truths.  So what are some of these myths – and what are the true stories behind them to the best of our scientific knowledge?

Fiction: We use only a small percentage of our brains.

Fact: General thinking is that we use only about 10% of our brains. Nothing could be further from the truth. Brain scans such as MRI and PET scans show that we regularly use all parts of our brains. Certainly, different areas of the brain are activated during different types of tasks, and some parts of the brain are less critical to support vital functions than others. But as even small brain injuries can show, every part of the brain performs essential functions in how we process, communicate with, and move through the world around us. Read more at http://www.scientificamerican.com/article.cfm?id=do-we-really-use-only-10.

Fiction: The wrinkles on the surface of the brain appear and become more pronounced as we learn.

Fact: The ridges and crannies – more correctly, the gyri and sulci – on the surface of the brain actually all appear by the time a fetus is 40 weeks old. As the human brain evolved, gyri and sulci appeared as a result of the brain having to fold in upon itself as it grew larger to fit inside a correctly proportioned skull. While the gyri and sulci do not change as we learn, the brain itself – as we know from research in brain plasticity --  does continue to change throughout our lives.

Fiction: Brain damage is permanent.

This is an interesting myth, in that it is the result of ambiguous language. The brain is made up of a collection of neurons – brain cells – that are all networked together. When the brain suffers trauma and neurons are destroyed or damaged, those neurons cannot regenerate. In that sense, the damage to them is permanent. That said, those neurons are linked together at synapses to form complete networks. While a single neuron cannot be repaired, the pathways and connections throughout the brain can rewire themselves and form new pathways. If a connection is lost due to injury, we can reestablish that connection if the damage is not so acute that the entire network cannot be rewired. For a scholarly treatment of how the brain recovers from injury, see http://web.uvic.ca/~skelton/Teaching/General%20Readings/Robertson%20Murre%201999.pdf.

Fiction: A person is either “left-brained” or “right-brained.”

The theory goes that left-brained people are more logical and right-brained people are more creative. Certainly there are asymmetries associated with locations of certain brain functions. For example, mathematical computation and the grammar and vocabulary aspects of language seem to be controlled in most people in the left brain, while numerical approximation and comparison, along with interpretive aspects of language like prosody and intonation, appear to be controlled in the right.  These ideas date back to original research done in 1861 by French physician Pierre Paul Broca. Today, through MRI and PET imaging techniques, we have a much more complex view of the way the brain’s hemispheres control functions and interact with one another. The two perform a complex dance of information exchange that gives rise to our abilities. For a look at results of some of these MRI tests in children, see http://www.ncbi.nlm.nih.gov/pubmed/8780075.

Fiction: There are five senses: sight, smell, hearing, taste and touch.

These five are simply the ones that we are most aware of in our conscious minds, but we perceive and sense the world in a great many other ways. For example, “proprioconception” describes how our bodies are oriented in the world. “Nociception” is how we perceive pain. We sense changes in temperature. We sense balance. We feel thirst and hunger. We sense the passage of time. For a quick and easy description of the senses – in humans as well as other species – see http://en.wikipedia.org/wiki/Sense.

As scientists continue our search for the facts, there is much we don’t know; we are expanding our knowledge of the brain’s truths every day. As new discoveries are made, it is natural for facts to become distorted and reinterpreted with each new telling.   As educators and scientists, we should take the time to explain the truths about the brain and rectify any misunderstandings we may hear others repeat. The brain is amazing, and communicating the truths about it will further society’s understanding as a whole.

Related Reading:

Dr. Martha Burns on Brain Plasticity

How Learning to Read Improves Brain Function

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Categories: Brain Research, Reading & Learning

Tags: brain development, brain training, cognitive skills, decision making, infant brain, Innate abilities, processing

Still the Write Stuff: Why We Must Continue Teaching Handwriting

• August 23, 2011 by Sherrelle Walker, M.A.

When it comes to lost arts, we could argue that none is getting lost faster than handwriting. Since the personal computer and now the telephone have become the primary methods for recording our ideas, we simply do not write – I mean with an actual writing implement like a pen or pencil – as much as we used to.

So, we must ask ourselves, is this really a problem? Sure, one could argue that receiving a handwritten letter is more meaningful than getting one that is typed, but that’s an emotional opinion; it’s not a scientific argument. And aren’t professionals in all fields using more computers, tablets and handhelds to communicate, record and share ideas? So, what is the real value of learning handwriting skills versus being able to type 100 words per minute on a QWERTY keyboard?

At Indiana University, Dr. Karin Harman James, assistant professor in the department of psychological and brain sciences, focuses her research on how motor stimuli can influence our visual recognition, and how the brain changes as we have different experiences. This research provides a basis for a scientific argument for the continued instruction of handwriting.

In a 2008 study published in the Journal of Cognitive Science, adults were shown new characters as well as a mirror image of these characters after reproducing them through writing and keyboarding. When quizzed afterward, subjects were shown to have a “stronger, longer lasting recognition” of the characters’ correct orientation when they had written them by hand versus produced them by matching them to a keyboard button. This suggests that engaging the motor nerves to create the shapes by hand helped solidify the ability to identify such shapes.

In another study, James’ team took this idea to the next level to see what was actually going on inside the brain during these activities. They used a functional MRI to map brain activity in children as they looked at letters before and after letter-learning instruction. Their results showed that those who practiced writing the letters showed more brain activity than those who only looked at the letters. In addition, according to a 2010 report on the research in the Wall Street Journal Online, James said that after four weeks of training, the children who practiced writing skills showed brain activation similar to an adult’s.

Between these two studies, we see excellent examples of brain plasticity at work. James’ work demonstrates a clear connection between how engaging more of the brain in the activity of writing improves how letters are committed to memory. Given that letter recognition is an essential step for early readers, it’s easy to see why practicing writing letters is an essential component of the groundwork for later success.

Certainly, with limited time, schools try to maximize student achievement, and give them a baseline of skills that will allow them to continue to develop to optimize their success throughout life in an increasingly technology-based society. That said, based on James’ research, it’s quite clear that penmanship has an important place in the classroom, and not just as an important traditional skill.  In actually applying pen to paper, we allow our students to engage their brains in ways that typing on a keyboard cannot. And whether such an activity is done with pen and paper, a stylus and a tablet PC or chalk on a blackboard, it is in every student’s best interest to practice the “write” stuff.

For further reading:

The many health perks of good handwriting. Deardorff, Julie. Chicago Tribune, June 15, 2011. Referenced on August 14, 2011.

How handwriting trains the brain. Bounds, Gwendolyn. The Wall Street Journal Online, October 5, 2010. Referenced on August 14, 2011.

Writing strengthens orthography and alphabetic-coding strengthens phonology in learning to read Chinese. Guan, Connie Qun; Liu, Ying; Chan, Derek Ho Leung; Ye, Feifei; Perfetti, Charles A. Journal of Educational Psychology, Vol 103(3), Aug 2011, 509-522.

 

Related Reading:

Why Limit Screen Time? Scientific Research Explains

Ok, so you made a mistake. But look what you learned!

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Categories: Brain Fitness, Brain Research, Education Trends, Reading & Learning

Tags: brain development, brain plasticity, brain training, cognitive skills, creativity, digital natives, early learning, elementary learning, memory, processing, writing

Students who Struggle in the Mainstream: What their Homework Patterns May Tell You

• August 2, 2011 by Jacqueline Egli

Ms. Egli is Executive Director at Bridges Academy in Winter Spring, FL.

Students who maintain average grades, but appear to be expending an excessive amount of time and effort to maintain those grades may have underlying learning deficits. As educators, we shouldn’t overlook the fact that students who require more time for completing assignments seem to show a disparity between what they have learned in class and how they perform on high stakes assessments. They may in fact be struggling with various learning challenges such as weakness in memory function, inability to process large volumes of information, vocabulary deficits and poor abilities in written expression.

Working with University of Central Florida Communications Disorders doctoral candidate Janet Proly, I had the opportunity to collaborate on a single-subject designed study of three promising high school students who appeared to be successful in their classes but also had significant hidden learning deficits.

The three students, twin 10^th-grade boys in a general education program and a 12^th-grade student who attended a magnet health and science academy, expressed concern over their struggle to keep up with their respective workloads of studying, reading and comprehending assignments, and their performance on tests like the FCAT. All reported that it took them three times the amount of actual time to complete their homework, citing that they had to re-read assignments multiple times in order to master the information. This inefficient learning caused all three boys to receive lower than expected scores on the state assessment, possibly compromising their ability to obtain a standard high school diploma.  All three students approached me to inquire about participating in a summer reading program hosted by Bridges Academy, and thus became candidates for our collaborative study on the impact of improving reading fluency using computer technology for intervention.

Proly and I structured a single subject design study to determine the impact of using computer technology formulated to improve processing and working memory, as well as oral reading fluency. We modeled our study after the 2010 study published by Wexler, Vaughn, Roberts, and Denton.^[i] The school offered a summer program to the three students. Using the Fast ForWord Literacy and Reading Assistant products for the six-week planned intervention would address recommendations for an alternative fluency intervention with a higher degree of intensity, and the inclusion of interventions that focus on processing.

After an initial assessment, the students participated in the intervention. We conducted a post-intervention assessment, and then assessed the students once again six months after the intervention. All three students demonstrated significant improvement in their reading fluency, and gains of more than two years on average in word attack and comprehension skills. The three students sustained these gains even though all three were no longer receiving any support or intervention.

This study, along with the focus on adolescent literacy, has increased interest in addressing the needs of middle and high school students who report these kinds of challenges in three specific programs: the UCF Communications Disorders Clinic; the UCF Communications Disorders Doctoral Program; and the Bridges Academy private school. As our results indicate, these short term computer interventions, through focusing on working memory, reading fluency and processing speed, have significant potential to help capable students succeed both in classes and on annual assessments.

In 2008 alone, over 20,000 high school students in the state of Florida dropped out of the public high school program. Did they leave because it was simply too hard to keep up? Could we have kept them in school if we had been able to provide a short term intervention that could not only have engaged them, but improved their learning and achievement? My collaborators and I all believe the answer to both of these questions is, absolutely, yes.

So what comes next? Our plan is to work together on an expanded study for the 2011-12 academic year that will take place at the private school and the UCF Communications Disorders Clinic.  In reaching more participants, our plan – and our hope – is to continue to demonstrate program effectiveness and change the lives of more students for the better.

 

[i] Wexler, J., Vaughn, S., Roberts, G. & Denton, C.A. (2010), The efficacy of repeated reading and wide reading practice for high school students with severe reading disabilities. Learning Disabilities Research & Practice, 25(1), 2-10.

 

Related Reading:

Inspiring Fluency: One School’s Journey to Improve Reading Skills

One Half Year Increase in One Month with Reading Assistant

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Attend one of our popular webinars with thought leaders in learning. Live and pre-recorded webinars are available. Register today!

Categories: Fast ForWord, Reading & Learning, Reading Assistant, Special Education

Tags: academic success, accelerate learning, at-risk, attention, brain training, cognitive skills, high school learning, improving reading skills, intervention, learning disabilities, processing, reading comprehension, reading intervention, struggling students, student growth, technology in education

5 Paths To Brain Health: Tips From Dr. Paul Nussbaum

• July 5, 2011 by Carrie Gajowski

As the webinar coordinator here at Scientific Learning, I hosted yet another fascinating webinar about brain health with Dr. Paul Nussbaum in early May called “Brain Health Across the Lifespan”.  Dr. Nussbaum combined humor with interesting facts about the brain and the webinar ended up being one of our best sessions to date.  He provided a simple yet comprehensive look at the brain and how it functions. 

One interesting story Dr. Nussbaum shared was about the development and eventual delaying of the onset of Alzheimer’s disease based on lifestyle choices.  He cited research that has been done at autopsy that shows that there can be evidence of Alzheimer’s disease in the brain that has never manifested in memory problems during a person’s life.   

Dr. Nussbaum concluded that if you look at the individual’s life, you might find that they had a higher education level or more demanding occupation or participated in complex and varied activities throughout life, building up a stronger and more “fit” brain and delaying the onset of the disease.

He then covered 5 important aspects to brain health and suggested some activities that can keep your brain fit and healthy throughout your lifetime:

1. Nutrition:  Eat more “good” fats including Omega-3 fatty acids, more fruits and vegetables, and fewer “bad” fats and processed foods. 
2. Socialization:  Stay involved with life and develop a personal mission and hobbies along with building networks of family and friendships.
3. Physical Activity: Be mobile and active.  Walk, play, run, garden, exercise, bike, hike.  These activities can help reduce the risk of dementia later on in life.
4. Mental Stimulation:  Learn a second language, learn sign language, travel, play board games, and either play or listen to music.
5. Spirituality:  Slow down, meditate, and learn relaxation procedures.  Identify what your stressors are and how they affect you and then identify ways to handle them.

To find out more about Brain Health, watch our previously recorded webinar or visit Dr. Nussbaum’s website.

Related Reading:

Lifelong Leaning and the Plastic Brain

Educating Kids about Nutrition and the Brain

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Categories: Brain Fitness, Reading & Learning

Tags: brain training, cognitive skills, effort, exercise, health and well being, language learning, memory, musical training, play, Scientific Learning events, webinar

Fast ForWord Featured on ABC 7 News

• June 17, 2011 by Norene Wiesen

For those of you who missed the ABC 7 News spot last night, here's another chance to hear the success story of students at Korematsu Discovery Academy in Oakland, CA, who have seen reading test gains of 1.5 years, on average, since beginning the Fast ForWord program earlier this year. 

"You don't normally see that kind of gains," said the school's principal, Charles Wilson. "And it's not the kids fault, it's the system's fault for not providing the interventions that they need."

Wilson made the program available to his students for the first time this year with a $30,000 tech grant he received from the district.  He is now working on getting another grant to extend the program to all students at his school next year.

Scientific Learning's own Dr. Bill Jenkins is featured as well, discussing the science behind the program.

For parents interested in home use, learn about our BrainPro service which provides Fast ForWord software and an online tutor.

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Attend one of our popular webinars with thought leaders in learning. Live and pre-recorded webinars are available. Register today!

Categories: Brain Fitness, Brain Research, Fast ForWord, Reading & Learning, Scientific Learning Research

Tags: academic success, accelerate learning, brain training, child reading development, cognitive skills, improving reading skills, increased test scores, student reading growth, technology in education, reading test gains

7 Amazing Discoveries from Brain Research

• June 2, 2011 by Carrie Gajowski

As the webinar coordinator and moderator here at Scientific Learning, I’ve had the privilege of hearing many wonderful speakers on a variety of compelling topics.  Of all of the webinars I’ve presided over, one of my favorites was the one presented by Eric Jensen in September, 2010, titled “7 Amazing Discoveries from Brain Research.” For that webinar, our most highly-attended ever, Eric took complex concepts about the brain and made them more “user friendly” and interesting.  At the end of the session, I was excited to go learn and study more on my own about the brain and how it functions!

Of the seven discoveries presented in this webinar, the one that I found to be most intriguing was the concept that our emotions can influence our minds and bodies.  For years, people have discussed the connection between emotions and the body but now there is research being done that proves that there is indeed a link.  For example, one study cited in this webinar indicates that there are approximately 6 – 8 emotions that are innate and the rest are taught by parents, teachers, friends, technology, etc.  If children aren’t given the opportunity to learn about a wide range of emotions, this gives them not only  less of an ability to handle conflicts and issues that might come up for them but could hinder their learning process.

To learn more about brain research discoveries that can help you in the classroom and beyond, be sure to check out the recorded webinar. 

To learn more about Eric Jensen, visit the Jensen Learning website.

Related Reading:

Brain Plasticity: Using Advances in Technology for Better Living

You Unplugged: Finding Balance with Extended Reading, Writing, and Thinking Time

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Attend one of our popular webinars with thought leaders in learning. Live and pre-recorded webinars are available. Register today!

Categories: Brain Research, Reading & Learning

Tags: brain training, elementary school learning, emotions in learning, high school learning, how children learn, middle school learning, Scientific Learning events, teacher impact, webinar

Grammar Skill Improvement with Fast ForWord Software

• May 19, 2011 by Barbara Calhoun, Ph.D

This study was part of Dr. Beth Rogowsky’s doctoral research and was published in her dissertation in 2010.  At the time of this study, Dr. Rogowsky was an experienced educator.  Returning for her doctorate at Wilkes University in Pennsylvania, Dr. Rogowsky was interested in data-driven decisions, and wanted to know whether the Fast ForWord products would improve the grammatical skills of a group of typical middle school students.  The middle school in which Dr. Rogowsky taught had four marking periods each year.  During each marking period, students took two elective courses. 

During the 2009-2010 school year, the sixth graders were randomly assigned to use Fast ForWord during one of their electives; one-fourth of the students during each marking period.  The students who used Fast ForWord during the 3^rd marking period formed the experimental group in Dr. Rogowsky’s study while the students who were scheduled to use Fast ForWord later formed the comparison group.  Students’ grammar skills were evaluated at the beginning and end of the 3^rd marking period.

Study participants were 81 sixth graders.  Group 1 consisted of 40 students who used Fast ForWord during the third marking period.  Group 2 consisted of 41 students who did not use Fast ForWord until after the study was over.  Students were assessed at the beginning and end of the study (January and April).

Using the 40-Minute protocols that require students to use the products 40 minutes a day, five days a week, the students first used Fast ForWord Literacy.  After they finished Fast ForWord Literacy, students used Fast ForWord Reading Level 2.  Students were evaluated at the start of the study, and again at the end, with the Written Expression Scale from the Oral and Written Language Scales, also known as the OWLS.  The written section evaluates students’ knowledge of convention and content.  Convention covers a variety of areas including spelling, capitalization and punctuation, linguistics, modifiers, phrases, verb form while content includes details, coherence, unity, and the presence of supporting ideas.  Students are scored on a scale where 100 is average, and the standard deviation is 15.

At the start of the study, there was not a statistically significant difference between the scores of the students in the two groups.  On average, students in both groups were a bit above the 50^th percentile which corresponds to a score of 100. However, after the experimental group used the Fast ForWord products, there was a statistically significant difference between the scores of the two groups, and there were statistically significant increases in the scores of the group that had used Fast ForWord products. The results of this study led Dr. Rogowsky to conclude that the Fast ForWord products can improve students’ grammar skills and the improvements are evident in a classwide implementation.

Rogowsky, B. (2010). The Impact of Fast ForWord® on Sixth Grade Students’ Use of Standard Edited American English. Doctor of Education dissertation, Wilkes University. 

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Categories: Brain Fitness, Fast ForWord, Reading & Learning, Scientific Learning Research

Tags: academic success, accelerate learning, brain training, increased test scores, middle school learning, student growth, technology in education, video, writing