Outside of school, Max found plenty to occupy his time. When he was a toddler he became fascinated by wires and circuits, and as he grew older he developed a sophisticated interest in electronics. He especially liked experimenting with small-scale power generation, using sources like solar, wind, and water to generate electricity.
Max also developed a deep interest in nature, and he loved to spend time in the woods surrounding his home near Seattle. Max laid out a nature trail on his family's property, but as many Northwesterners have learned, he soon found that “walking” plus “woods” equals “wet feet.” So Max began to install an elaborate series of drains to remove the standing water that collected across his trail. He also built bridges over the spots he couldn't drain. Max's drainage project was remarkable for a child not yet ten years old. Not surprisingly, it did draw remarksâfrom psychologists.
When Max was in fourth grade his mother took him to be evaluated for his difficulties with schoolwork. The psychologist diagnosed ADHD. This seemed plausible given Max's problems with auditory-verbal working memory, distractibility, and lack of focus for schoolwork. However, the psychologist was also concerned by Max's “intense” interest in electronics and drainage, his focus on solitary pursuits, and his difficulty talking withâand likeâother children. So in addition to ADHD, the psychologist diagnosed Max with Asperger's syndrome, an autism spectrum disorder. As one of his recommendations, the psychologist suggested that Max take social skills classes.
Although Max's mother questioned the Asperger's diagnosis, she agreed that Max needed to improve his social skills, so she took him to see a speech-language pathologist (SLP). Fortunately, the SLP understood that social skills consist largely of complex rules for behavior that have been learned and practiced until they've become habits. Under the SLP's supervision, Max was taught social skills in a clear and explicit manner, and he practiced them during structured interactions with another child until these skills became automatic.
Max continued to improve both socially and academically. Between ages seven and a half and ten his reading vocabulary shot up from the 35th to the 98th percentile, and his math calculation rose from the 45th to the 99.9th. However, he still showed the lower Working Memory and Processing Speed scores that we typically find in our “young engineers.”
At that point, Max was making great strides in most areas, though his reading comprehension and fluency lagged behind his conceptual abilities, and his writing remained slow. He also made frequent errors in his writing with spelling, conventions, sentence structure (syntax), and organization. The following is an essay that Max wrote at age ten, which he entitled, “The Derte road.”
This trip we whent to bary my Grate Grandma on this dert road. So when we got on the road in are fourrunner my teeth were chattring but they stoped when we got on the bumpy port. It was 13 miles in to the drte road so I just relaxed . . .
We met Max shortly before his eleventh birthday. While the “numbers” from our testing mostly confirmed what others had found, our interpretation was somewhat different. We identified his challenges with reading and writing fluency, spelling, syntax, rote and working memory, focused attention for auditory-verbal material, processing speed, sequencing, and organization, but we also found many of the wonderful strengths that individuals with dyslexia often show. Max showed tremendous spatial and nonverbal reasoning powers, his understanding of math concepts was amazing, and his ability to interact knowledgeably on a wide range of complex scientific subjects was extremely impressive. We were also struck by the intellectual “flavor” Max displayed as he approached his work. He showed a charming naïveté and inventiveness on many tasks that children his age usually dash through without even giving a thought, so although his work was slower it was often more creative. Max also made many interesting observations that showed how his mind was reaching out to probe the connections between ideas.
We also discovered several important details about Max's family. Max's father has a Ph.D. in chemistry, and his mother has a degree in biochemistryâboth high M-strength fields. Max's mother also has dyslexia-related processing traits and talents. Although she struggled with reading and writing as a child, she now works as a medical writer. Both of Max's maternal grandparents were also scientists, and Max's great-grandmother has often remarked how much Max reminds her of his grandfather when he was a boy. Perhaps “family resemblance” provides a better explanation for Max's “intense” interest in drainage and erosion than autism, since his grandfather spent his career as a professor of geophysics at UCLA.
Ultimately, we made several suggestions to help Max in areas where he still struggled, but we also explained that in the most important respects Max was right on target for
his
developmentâthat is, for the kind of late-blooming growth and maturation that children display when they combine dyslexic processing, outstanding M-strengths, and procedural learning challenges.
M-Strengths and Development
We've shared Max's story because we want you to see what dyslexic children with impressive M-strengths look like while they're still developingâbefore their mature talents are fully apparent. While it's enormously helpful to look at the childhoods of successful dyslexic adults, sometimes the perspective provided by hindsight can make their successes seem almost inevitableâas if their challenges weren't really so severe, and they were never really at risk of failure. Somehow these stories can lack the power to convince us that the slow, awkward, inarticulate, inattentive, and dyslexic early elementary child before us might actually have a chance to become one of the great engineers, architects, designers, mechanics, inventors, surgeons, or builders of the twenty-first century. Yet this is often unquestionably true.
We constantly meet skeptics who respond by pointing out that not every child will become an Albert Einstein or an Isaac Newton. This is true, but even Einstein and Newton didn't
look
like “Einstein” and “Newton” in second grade: Einstein was remembered as a slow, uncooperative child with a nasty temper who repeated everything he said (echolalia), while Newton was remembered as a simpleton whose only apparent use was to make small wooden toys for his sisters and schoolfellows.
Even though evidence of classroom success may be thin for many high M-strength children with dyslexia, they often display their creative potential quite clearly outside the classroom, in their desires to build, experiment, draw, and create. Recall compact disc inventor James Russell building his remote-control boat at age six, Lance Heywood “tinkering” on his electronics projects, or Max building his nature trail and experimenting with solar power. These activities should be taken much more seriously because for a dyslexic child with substantial M-strengths, a toy is never “just a toy” or a drawing “just a doodle.” These activities provide a window into their future, and failure to regard them seriously does these children a grave disservice. One amazing young child with dyslexia whom we saw in our clinic built a K'nex structure so elaborate that it won second prize in a nationwide competition; yet when he brought it to school and asked his teacher if he could show it to the class he was told, “We don't have time for that; we have important work to do.” Another was scolded by his teacher for doodling: “If you spend all day drawing buildings on your papers, you'll never get anywhere.” Ironically, this child's father is a successful architect who makes his living in just that way.
When he was young, pioneering neurosurgeon Dr. Fred Epstein showed a sustained interest only in mechanical activities, like building elaborate model airplanes. Because of his dyslexia, Epstein barely made it through college and was initially rejected by all twelve of the medical schools to which he applied. However, as an adult Epstein developed many new and highly innovative surgical techniques for treating previously inoperable spinal cord tumorsâtechniques that saved literally thousands of children's lives. It's important to realize that when Epstein was devising these techniques he wasn't using skills he'd picked up in some classroom but the skills he'd developed at his workbench in the garage, building model airplanes.
1
To identify our next generation of talented engineers, inventors, and physicists, we shouldn't be using pencil-and-paper “talent searches” or seeing who's fastest at the “mad math minutes.” We should be searching for spatial prodigies in LEGO Stores and hobby shopsâjust like athletic scouts hang around ball fields. Many of our next generation's great Material reasoners are currently struggling in school while their talents are going unrecognized, and we owe it to them to pay closer attention to the ways that they typically develop.
CHAPTER 9
Key Points about M-Strengths
M
aterial reasoningâthe ability to reason about the physical characteristics of objects and the material universe
â
represents one of the most common and important talent sets found in individuals with dyslexic processing styles. Key points to remember about M-strengths are:
⢠The ultimate purpose of M-strengths is to create a continuous, interconnected series of 3-D perspectives as a basis for reasoning about real-world, global, or big-picture spatial features, rather than about fine-detail or 2-D features.
⢠The spatial imagery perceived by individuals with M-strengths may take many forms, from clear visual imagery to nonvisual perceptions like force, shape, texture, or movement.
⢠The form that spatial imagery takes is less important than the uses to which the reasoner can put it.
⢠M-strengths often bring trade-offs like symbol reversals and subtle language challenges.
⢠Individuals with dyslexia in generalâand those with prominent M-strengths in particularâshow a late-blooming pattern of development, and their developmental progress should be judged on its own terms, rather than by standards created to judge nondyslexics.
⢠Individuals with dyslexia who show prominent M-strengths may struggle in the early grades but often show signs of impressive creativity outside the classroom.
⢠Dyslexic children with prominent M-strengths have tremendous potential and often grow up to become remarkable and creative people.
Let's end this section by returning full circle to where we began: with Lance Heywood and his family. Not long after we interviewed Lance, we got a call from his wife, Jenny. She had some questions about their older son, Daniel. We'd seen Daniel in our clinic several years earlier. Like his father, Daniel is dyslexic; and like his father, Daniel has remarkable M-strengths.
For the last five years, Daniel has supplemented his homeschooling curriculum with courses at a state university. His coursework has focused on the spatially related disciplines in which he excels, like physics and higher math. Like his father, Daniel often solves problems in his own unique ways, rather than using procedures he's been shown in class; but he usually gets the answers right, as his outstanding grades attest.
Daniel's also been a member of the university's robotics team, and for the last several years he's traveled with them to compete against other universities. One year he designed a crucial component for the team's Mars rover, which finished second in a national competition.
Jenny informed us that Daniel was now applying for full-time enrollment at several colleges with strong engineering and biorobotics programs. Daniel wants to learn to build medical devices for people with physical disabilities. Jenny mentioned one of the schools to which Daniel was applying, and we told her we had a contact there Daniel might like to meetâthe department chair, in fact.
We'd seen her children. For dyslexia.
PART IV
I-Strengths
Interconnected Reasoning
CHAPTER 10
The “I” Strengths in MIND
“E
verything is about relationships. Things are as they are because of their relationships with everything else. You can't just look at anything in isolation.”
As Jack Laws spoke to us by phone from his home in San Francisco, it became clear that his view of relationships and interconnection wasn't just a throwaway line but a true expression of his way of understanding and experiencing the world. It's a view he's shared with the growing number of readers of his amazing field guides on the wildlife of California, published under the name his parents gave him in tribute to another great California naturalist: John Muir Laws.
Anyone who's read Jack's field guides or attended his lectures knows that he's a teacher of exceptional skill. But as a child Jack never expected he'd have anything to teach because he found it so hard to learn.
Jack was in the second or third grade when he first realized “there was something odd going on with my brain.” Even though he was clearly bright and hardworking, he seemed unable to learn many things his classmates mastered easily, like reading, getting his letters to face the right way, and memorizing math facts.
Jack's parents took him for evaluation, and he was given a diagnosis of dyslexia. Targeted learning therapy greatly reducedâbut didn't eliminateâhis challenges with reading, spelling, writing, and math. “The therapists tried to tell my teachers how to help me learn, but the diagnosis of âdyslexia' wasn't a part of their training, and they weren't in a place where they could really hear it. This was new stuff, and I had teachers who thought that the best way to make me learn was to embarrass me more in front of the rest of the studentsâand that didn't really work for me. So I was bumped around to a number of different schools. I was smart enough to see that other kids could do this stuff, but try as I might I couldn't, and over time I became increasingly convinced that I just wasn't one of the âsmart kids.'”