Teaching math to children with WS

One of the most fascinating aspects of studying the WS brain is that they exhibit both strengths and weaknesses when it comes to brain function.  Very few disabilities have this combination of traits which makes WS a potential goldmine for learning how parts of the brain work together to complete tasks.  Scientists find the WS mind an amazing tool to unlocking some mysterious aspects of psychology.  The WS brain has amazing verbal and musical abilities paired with many educational difficulties in spatial learning and ability to focus.  These deficits can affect many aspects of the educational development of a child, including those in mathematics. 

The difficulties associated with math are complex in nature.  You will meet some students with WS who perform very poorly, others perform at grade level and still others only struggle with some areas such as time and money.  This unpredictability of math skills is something that psychologists find interesting.  It may lead to clues as to what areas of the brain are used for certain types of problem solving.  It may also open doors to understanding new teaching methods that could help many students who struggle with math- whether they have WS or not.  Due to the unique nature of the WS brain, much can be learned by our little ones.  Their unique abilities give psychologists clues to how humans learn. 

When compared to other intellectually challenged groups of students - such as those with Downs Syndrome, Turners syndrome and children diagnosed with math learning disabilities, those with WS have unique deficits.  The other groups tend to score low in all aspects of mathematics versus WS who have a mixture of high and low scores based on the skills required for each type of math skill assessed.

Brain science- why is math hard for my child?

There are two theories as to why those with WS struggle in math. One theory is that the grey matter in the parietal lobe of those with WS is known to exist in low amounts.  Grey matter is a collection of neurons (or nerve cells) that specialize in thinking and problem solving.  In general, the more grey matter in an area of the brain, the greater talent that person has to do those tasks.  The brain is covered in ridges called gyri.  Each gyri, built from grey matter, has its own job or function in one aspect of thinking.  For example, the precentral gyrus (also known as the motor cortex) is used to control when muscles contract in all parts of your body.  The post central gyrus (also known as the primary somatosensory cortex) is designed to identify touch and other sensory ques.  In between the gyri are narrow dips or grooves called sulci (sulcus).  These also contain grey matter and divide the functional regions of the cerebrum.  WS brain studies suggest that the intraparietal sulcus of the parietal lobe contains low amounts of grey matter.  This affects the intellectual ability of a person with WS to understand some parts of math, especially those that are related to spatial cues.  There is a well known link between the amount of grey matter and a person's IQ.  Lower IQ and intellectual disability which could explain a lower overall understanding of mathematics.

Another theory that explains math disability in those with WS is that their brain just works differently than most. In addition to low amounts of grey matter, there are impairments to the pathways that lead to the parietal lobe.  Some psychologists feel that difficulties related to math in kids with WS are more due to the flow of information within the brain rather than the amount of grey matter in the parietal lobe.  These pathways are made of white matter, which are made of neurons coated in fat.  The fat makes the messages move quickly from one area to another.  These pathways are used to link different gyri and sulci together to coordinate a more complex task.  There are some pathways that are used more often- like highways of the brain.  The dorsal stream pathway runs from the visual area of the brain up to the parietal area.  This stream is known to be impaired in WS and may be one reason why mathematics is difficult for kids with WS.  You can see in the picture, below, that the dorsal stream is used to figure out where things are in space.   

The other stream of information is called the ventral stream.  This flow of information is used to identify what things are in your environment.  This stream of information is actually used more in the WS brain and has links to short term memories and language.   Therefore the cognitive profile of someone with WS involves rich short term memories and language gifts yet they have a high amount of difficulty navigating spatially.  Based on these brain studies, there are theories that the spatial tasks involved in mathematics is weak yet verbal aspects of math are strong, giving them a lopsided ability to fully understand mathematics. Due to the quizzical nature of the WS mind there are several research studies that test these two theories. While no definitive answers exist, there are definite findings that the WS mind can learn math, though it must be addressed differently than a typical child would learn.

(Visit this post on my blog to learn more about the brain science associated with WS.)

Verbal vs. Spatial

When learning mathematics, there are two categories of problems- verbal math and spatial math.  Considering the dorsal stream being spatial and ventral stream being language based, anyone with some knowledge of WS could probably predict that kids with WS will score strong in verbal math and perform poorly on the spatial math.

Examples of verbal math are language centered- such as naming and identifying numbers and counting including counting by 5 and 10s.  These skills use the verbal stream of information and tend to be a relative strength for most kids with WS. 

Examples of spatial math would be recognizing relationships between numbers such as using number lines, greater-than versus less-than and estimating amounts.  For example, on one test students were given a triangle with two numbers (such as 5 and 9) at the base and one number (such as 6) at the point.  The student was asked to choose the base number that is closest in size to the 6.  Children with WS performed poorly on this task, most likely due to the spatial disability that is so strong in WS.  In addition, if children or adults are given numbers and were asked to estimate which of them are closest together on a mental number line, those with WS had a much harder time identifying the correct answer.  They also had increased difficulty the closer those base numbers become.  If the outlying numbers are very different, they can usually figure out the answer..  the smaller the numerical gap, the more difficult the task becomes.  This ability does not tend to improve with age.  Many children with WS struggle with these same spatial tasks as they age and will need to learn how to compensate them with verbal memorization. 

Developing math skills

Studies that focus on WS mathematical disabilities vary greatly in their results.  Overall testing tends to show that young children with WS tend to score comparably to those who are typically developing.  As they mature and mathematics becomes more conceptual rather than concrete, some students begin to fall behind.  Also, as a young child, math tends to focus more on verbal ability- counting, naming numbers and memorizing basic math facts.  Children tend to excel in these task that require the ventral nerve stream.  As they age, the spatial concepts are introduced such as greater than/less than, money and telling time.  This is when parents often find their child struggling to understand mathematics.

In some of the mathematics studies, adults with WS performed math facts as expected for a typical adult.  Psychologists who studied the active areas of the brain in those participants have found that those with WS use different parts of their brains to solve those math tasks in contrast to the average person, thus suggesting that they are "wired differently".  This suggests that mathematics can be learned by those with WS but different methods of learning should be explored.  The path to success is different for those with WS because they think differently than the other children in their classroom.

Another theory of why mathematics becomes more difficult for a person with WS is due to developmental aspects of mathematics.  As a young learner, children use their frontal lobe to learn and recall mathematics facts and processes.  The frontal lobe is used when you have to think about difficult and more complex thoughts.  As students practice these mathematics principles they become rote and easy.  The task then in stored in areas of the parietal lobe, particularly in the back portion of the brain along that dorsal stream.  Therefore, adults can complete simple math that once challenged them mentally but now are more like reflexes.  Because the area where those reflexes are stored is atypical in WS, some psychologists think that maybe adults with WS do not store those principles in their parietal lobe but always use their frontal lobes to figure out those types of problems.

Strategies to help teach math

Because memorization is a strong skill for those with WS, the approach to learning mathematics should be language centered. Also, if a child with WS never really understands spatial math such as cardinality, number lines, etc. they should just move on to other skills that are more attainable. The mathematics instruction should be modified because some kids will never grow to understand those concepts despite the practice. They need to learn how to solve mathematics in other ways that focus on their verbal strengths rather than using spatial skills.

The Williams Syndrome association also provides a list of strategies, compiled by Dr. Karen Levine, that can be used to modify a child's curriculum.  These suggestions are based on the spatial difficulties that most individuals with WS may never really develop even into adulthood- such as telling time with a analog clock and counting money.

Karen Levine, Ph.D. suggests the following modifications:

• "Digital clocks and watches
• Calculator use
• Teach time concepts by personalizing
• Use wall calendars for daily, weekly and monthly schedules with events sketched or written in
• Encourage the elementary school aged child to have a date book
• Be flexible in curriculum, avoiding a rigid 'prerequisite' curriculum design
• Some children may never learn coin values but should move on to the next curriculum phase which they may be able to more readily understand" (WSA)

There is also extensive evidence that the use of music therapy can help improve a child's ability to learn difficult, spatial concepts such as money, time telling, measurements and fractions. There is so much out there in regards to using music to help kids with WS, I decided it was too much for just one post... Look for future posts on the use of music therapy to help improve math success!

Sources:

• Mathematical skill in individuals with Williams Syndrome: Evidence from a standardized mathematics battery
• Mathematical skills in Williams syndrome: insight into the importance of underlying representations; O'Hearn K
• Williams Syndrome Information for Teachers  by: Karen Levine, Ph.D.
• Music therapy resources related to academics

Visuo-spatial difficulties and how they cause motor delay

You're standing in a field, crouched in position for a fly ball.  Crack!  You hear bat against ball.  Your attention sharpens, your eyes focus on the movement in the air, you run to position your body in its path, hold out your glove, anchor your body to absorb the force, make adjustments in your stance and position as it approaches and you catch it.  All of these actions, although simple to most, are nearly impossible for someone with Williams syndrome.  As mentioned in other sections of this blog, those with Williams syndrome have low tone so their muscle strength and response is slow, but that is only part of the equation of motor delay.  Many of the brain studies that were discussed in the speech section of this blog focus on the spatial difficulties that are prominent in Williams syndrome (WS).  This section of the blog focuses on how this spatial disability inhibits movements in ways separate from low tone.

So, what does visuo-spatial mean?

Many individuals with WS have a hard time interpreting where they are in space.  They also struggle with directional orientation, such as understanding right from left and mirror images.  Visuo-spatial difficulties mean a person would have a hard time judging their surroundings, primarily with visual information, in order to understand where they are in their environment.  For example, imagine yourself navigating down a busy staircase.  It is crowded with people and you must walk in a cramped space.  Now make that stairway spiral and you must move with a swift motion to keep in pace with the crowd.  What do you do?  You may run your finger tips along the stair railing as you move.  You keep your eyes down to the ground to evaluate where you will step.  You tense up the trunk of your body for stability.  All of these actions are your adaptations to that environment.  Your fingertips are gathering information about your position and balance.  Your eyes relay info to your brain about where it is safe to step and your core is in guard to stabilize your body.  These are all visuo-spatial skills. 

People constantly interpret a large amount of sensory information about their environment.  You use peripheral vision, cues from receptors in your muscles about your physical orientation (proprioreceptors), balance information from the inner ear (the vestibular apparatus) and visual cues about what is around you in space.  Those with WS seem to have difficulty coordinating this information.  They struggle when presented with situations where they need to make shifts in their space, such as changing their posture on a crowded bus to let someone walk by.  This body awareness issue along with their difficulties in motor planning, spatial cues and directional cues make it hard for them to do planning activities such as when it is appropriate to cross a busy street or the ability to judge the speed of oncoming traffic.  This is one reason many of them do not drive as an adult (along with anxiety issues- see a future blog post on this topic) 

The directional disability also contributes to reasons why many of the individuals have difficulty understanding left from right, even as an adult and they have some difficulties understanding mirror images.  This directional disability also contributes to handedness.  Most children establish whether they are right handed or left handed by the age of 4-6.  Individuals with WS often don't achieve this until the age range of 5-8.  Many studies suggest this is due to the brain disorganization.  Most with WS will alternate between a preferred hand, use one hand for household tasks, such as eating, and another for writing.  They may alternate the use of their hand when activities require them to cross over the body to complete a task, such as building a large block tower.  Most with WS become left handed. 

There are several theories on why those with WS have this visuo-spatial disability:

• deletion of the LIM-kinase I gene.  There is research out there, although in its infancy, that the deletion of this gene is correlated with the visuo-spatial disability.  However, there are case studies of children missing this gene who do not display spatial delays, so evidence is inconclusive.
• A disconnect in the dorsal stream nervous pathway
• An atypical pattern of brain activity

It all has to do with the cellular pathways in the brain

Many of the researchers in brain studies are psychologists who study the brain function of children and adults with WS.  Their goal is to attempt to identify the areas of the brain that are medically classified as "dysfunctional" or have slower motor pathways.  Before getting into the brain studies, lets take a look at some basic brain anatomy that will help you picture why this "dysfunctional" classification is assigned.

Background on Neural pathways

The human brain is made up of many neurons, or nerve cells.  These cells have cell bodies that are unique in shape and extending from the main portion of the cell are processes or "arms", so to speak.  There are processes, called dendrites, that receive messages.  Sensory neurons sit outside the central nervous system and collect information from the environment using their dendrites.  These sensory neurons have endings called receptors that monitor the environment.  This message containing information about the environment is sent down a long process (or arm) called the axon to a second neuron in the central nervous system.  Neurons in the central nervous system, called association neurons, are located in the brain and spinal cord.  They function to process this sensory information- by interpreting what is happening around you and how the body should react to it.  Then, the association neuron will communicate a new message, send it down its axon to a motor neuron.  The axon releases a chemical (called a neurotransmitter) which travels across a gap and talks to the motor neuron.  This motor neuron then takes that message and tells the muscles how to move.

Inside the brain there are many of these "thinking" neurons.  Depending on where they are in the brain, they have different jobs.  Some areas of the brain receive visual information whereas a separate part receives auditory info, for example.  There are also areas that are for figuring out the sensory info and then a separate area for linking that info to a memory so you can label it or attach it to an emotion.  All of this takes quite a bit of coordination within the brain in order to take in information from multiple senses and combine it to create a scene of what is happening in your environment.

Neurons have jobs

There are special nerve tracts within the center portion of the brain that connect the all the sensory pathways so the brain can share the info.  These pathways are called white matter.  White matter is buried deep inside the brain and is the color white because of tiny cells that wrap themselves around the neurons, called myelin.  The myelin is a fatty layer that allows the message to move quickly down the axon.  It makes for very fast messages and is essentially a "highway" system of neurons that move info from one side of the brain to another. 

  

The outer surface of the brain, which sits around the outside of the white matter is called grey matter.  The grey matter creates what we called the "cerebral cortex".  This is where the "magic" happens.  The cortex is made up of unmyelinated neurons, or neurons that are "naked" without that fatty layer.  The messages are sent more slowly here.  In these regions, your brain decides what to do, problem solves and determines how you will behave.  It is well known that the higher IQ or the better "thinker" you are, the thicker this portion of the brain is.  The grey matter builds up in folds called gyri.  These ridges of the brain are the same on everyone, but they are thicker/thinner based on your genetics and how much you challenge yourself as a learner.  In between the gyri are shallow grooves called sulci. 

In the speech section of this blog, I mentioned that in brain studies, researchers have found that individuals with WS tend to have very thick gyri in areas that are strengths for them- particularly in the auditory region and language centers of the temporal lobe.  There are regions of the brain that have much thinner gyri.  These thinner areas of the occipital (visual) and parietal (sensory) lobes result in a visuo-spatial disability in those with WS.

Figure shows comparisons of gyri in controls (samples from the general public) versus gyri of individuals with WS.  Red areas indicate increases in gyri thickness and blue indicates smaller gyri.  Green shows areas that are comparable between the two groups. 


Streams- flow of information within the highway of the brain

The flow of sensory information that moves through the white matter in the brain can take a variety of different routes.  Two of the more important visual routes are the dorsal stream and the ventral stream. 

There is a section of grey matter in the back of the brain that makes up one gyrus in the parietal lobe.  This gyrus is smaller in the brain of someone with WS than in a typical person.  This section of the brain is involved in the dorsal visual stream.  In the dorsal visual stream, the brain uses visual information to interpret its surroundings, such as an obstacle, and determines how you will move around it.  This stream of information is very slow in an individual with WS due to the small amount of grey matter, making it more difficult for them to navigate.  Research has also shown that in individuals with WS, the brain often doesn't even use this stream when you'd expect it should.  In MRI's this area of the brain shows low activity during movement tasks.

The highlighted area on this picture shows the gyri that is abnormal in WS.  This disrupts the dorsal stream of visual information that is used to produce motor activities.

The ventral stream, in contrast is a strength for those with WS.  It involves information moving from the parietal lobe to the temporal lobe where the gyri are much thicker.  This stream of neural activity is used to recognize people using visual information and labeling.  In case studies, these streams can be tested fairly easily.  If you ask someone with WS to identify the a pathway through an obstacle course they could look at it and tell you where the midpoint of the path is (using the ventral stream) but if you ask them to walk it (which uses their dorsal stream) they would move very slowly and clumsily through the pathway.

Particular motor difficulties that are directly related to deficits in the dorsal stream and are seen in the majority (97%) of individuals with WS include:

• poor dexterity
• slow speed in movements with the arms and legs
• inability to move in response to visual information
• difficulty manipulating an object in the proper orientation to place it in a slot that is shape specific (such as a card in a slot or a block in a shape sorter) 

Problems with nervous pathways are a increasing area of study in WS research.  The nerve interactions between the frontal lobe and parietal lobe point toward behavioral difficulties that are very common in individuals with WS- including high distractability, inability to maintain prolonged attention to a task,  acting impulsively and having difficulty understanding global concepts (topics that are not concrete in thinking).  (Look for a future blog post on ADHD and behavioral profiles of individuals with WS.)


Making plans...

  

Another skill that is inhibited by dorsal stream dysfunction has to do with motor planning.  Motor planning means that the child would see what is in their environment (such as a ball flying at them through the air) have to think of how they want to respond (such as catch it), plan on what muscles need to be used to do so and where that ball will land in space and then relay the message to those muscles to complete the task.  Typically developing children will accomplish this task but many of those with WS often watch the ball as it hits them.  This disability in motor planning- often called apraxia, seems to be a difficulty in about 92% of individuals with WS.  This skill is even more difficult in certain situations such as bouncing the ball because they have to predict what direction it will land.  These tasks that require a person to use a familiar task and modify them to match the spatial information is very difficult for them.

The motor planning dysfunction will often delay their ability to throw and catch a ball.  Although most kids with WS will throw and catch a ball by the age of 6.5, they will likely have a lifelong inability to throw (51%) and catch (67%) in a coordinated fashion.  When throwing a ball, one must rotate their body, move their arm and often step forward with their leg.  Those with WS display an inability to do this at all ages.  They often will throw their arm but lack the body positioning and rotation in the upper body to make a decent throw.  The catching action is mainly due to the visuo-spatial tracking and motor planning required to predict where the ball will land and those skills needed to right the body and extend the arms quickly enough to catch the ball in time.  They simply process this information too slowly and inaccurately in order to accomplish the task.

Studies have shown that although visuo-spatial difficulties are an issue for nearly everyone with WS, there are tools that children can learn to help minimize this disability.  Case studies frequently note that those individuals who learned or utilized verbal cues were better able to navigate obstacle courses.  For example, if the person who is walking through the course studies it first and vocalizes a plan, then as they walk they talk about how to move their body, they move less awkwardly and accomplish the task with better timing.   It is also important to note that individuals that participated in these studies had varying degrees of difficulty.  Some were only slightly impaired in the task and others had higher difficulties with most having a moderate level of challenge.  Therefore, while spatial navigation is a disability for all individuals with WS, the magnitude of that disability lies on a spectrum and can be different for each individual.

Walk this way

Poor motor abilities in an individual with WS extend to many other issues that are rooted in the nervous system.  Individuals with WS, especially in the early years, have a very distinguishable gait, or walk, that is described as clumsy and uncoordinated.  There are a variety of reasons for this.

First, young children who are new to walking have ingrained protective reflexes that they use to maintain balance.  If they find themselves fighting gravity or on an uneven surface, they will right their head over their body, tighten their core and throw their arms outwards to steady their bodies and protect them from a fall.  Kids with WS seem to lack this reflex (I can personally attest that my daughter has fallen many times without ever extending her arms out to catch herself, leading to minor head injuries). 

The majority (between 60-80%) of children with WS have gross motor delays or unorganized motor skills and delays associated with climbing stairs, walking down stairs, running, jumping (especially off an elevated surface), transitioning from one variegated surface to another, walking on uneven terrain (such as grass or mulch/sand), skipping and running.  These delays or motor planning deficiencies are associated with balance issues.  Balance is related to the processing of sensory information by the nervous system.  Approximately 60% of those with WS have balance processing disorders and another 80% have trouble interpreting gravitational signals.


Those with WS have trouble navigating quickly through obstacles that require them to take longer than average strides.  They improve this skill when sensory cues are present such as lights to step in to determine stride length.  But even with sensory cues their walk is much slower than typical.  This indicates there may be some dysfunction within the cerebellum, which is the part of the brain that controls balance and coordination.  Other cerebellar studies have found that in WS, the neocerebellar lobules are enlarged.

  These are regions on the sides of the cerebellum that have major nervous pathways that communicate with the thalamus and the cerebral cortex.  The thalamus is the main area in the center of the brain that associates sensory information with memory.  Major nerve tracts link problem solving to memory to the cerebellum through this nerve tract. 

Scientists have linked this stream directly to motor coordination when learning a new motor skill.  It's used for following a series of steps used to follow a motor procedure, such as riding a bike.  It coordinates limb movements in order to achieve the desired action.  This area of the cerebellum is also heavily linked to an area of the brainstem called the superior colliculi.  This is a visual reflex area that helps coordinate the motor movements in the eyes.  Dysfunction in this can lead to poor muscle control in the eyes and can be another cause of strabismus (see the eyes section of this blog).  The neocerebellar area also helps to coordinate motor movements used to coordinate speech.

Besides brian studies, there are other reasons individuals with WS may have a harder time with motor activities. 

• Tone- The ability for the nervous system to control muscle contractions in appropriate times; previously discussed in this blog (See the muscles section).
• Sleep- sleep is a well known difficulty for up to 97% of individuals with WS which can further affect cognitive development and motor planning.
• Vision- Although vision is not an issue for all children with WS, if a child has strabismis or crossing of the eyes sends conflicting information to the brain about the person's surroundings.  This can lead to increased delay in motor skills- particularly spatial understanding.  This is even more evident if the individual has lost vision in the weaker eye.  This causes the body to lose their depth perception.  Everything will appear flat and in 2 dimensions.  This will cause additional issues with motor development. (see the eye section of this blog)

 

Fine motor delays due to visuo-spatial disabilities

Spatial difficulties offer up difficulties in a variety of motor tasks.  Early in a child's life occupational skills will seem less serious than gross motor skills but as the child ages, their abilities will change and fine motor skills will become increasingly important as they gain independent living skills. 

Self help
Most children (80%) have delays in fine motor skills required for self help.  These can be related to directional disability (used to set a table, for example) but most are due to the visuo-spatial disability.  Through therapy, most of these skills can be mastered, but approximately 30% of adults still find difficulty in some skills such as tying shoes, buttoning clothing, etc. For example, many will have high difficulty using knife skills, such as those used to make a peanut butter sandwich.  They may have trouble grasping the knife, creating the motion to spread the butter, applying the proper amount of force and stabilizing the bread.  This takes motor planning and the ability to judge the environment of the bread and make small motor adjustments to have the proper movement.  Other self help skills such as writing, cooking, buttoning clothing, using a zipper and tying shoes are difficult for a person with WS due to the need to plan motor movements during these activities and have spatial awareness. One study found that, on average there is a 2 year delay in children with WS, aged 4-12, in both fine motor skills and gross motor skills that require visuo-spatial ability.

One major fine motor activity a child with WS will find difficulty in is the ability to manipulate objects in space, such as placing mail into a narrow slot.  This skill is processed by the dorsal stream in the parietal lobe of the cerebrum.  Other examples of difficult motor task include movement planning time.  In one case study, researchers had adults draw a line between two circles using a stylus.  When the shapes changed sizes, those with WS had significantly slower times completing the task.  This study linked difficulties with this task to the inability for those with WS to anticipate the movement of an object and plan their motor response to it.

Drawing

Most typical children will draw recognizable pictures of objects by the age of 5 or 6 whereas those with WS draw them closer to the age of 9 or 10.  This is due to the visuo-spatial delay.  They draw comparably, though, to peers with mental disabilities.  IQ and drawing ability do not match in WS indicating it is an area of disability.  It is also notable to say that they do eventually achieve the ability to do this task by adulthood.

This photo is from the study completed by Dr. Mervis et al. and it shows a drawing of a bicycle, completed by a 12 year old with WS.  All the components of the bike are present, but those with WS have a difficult time picturing how they are connected- a spatial skill.
Therapists have identified a strategy that help individuals with WS improve their ability to draw.  This should be used in OT sessions.  The increase in gains when using the face as a drawing tool stems to brain studies that show individuals with WS use their brain differently to interpret faces.  Typical adults will process facial recognition with the right side of their temporal lobe.  Those with WS use a much larger area of the brain and primarily use the left side of the brain to do this.  The study also had interesting evidence that those with WS use the same amount of processing to interpret the face of a picture of a person that is upright versus on that is flipped up side down.  In typical adults, there is a delay in processing the flipped images as the brain has to try and associate the image with what they'd look like right side up.  Those with WS use more brain activity looking at a face in any position than a typical person would and they use the same brain activity despite the picture orientation.


Ways to help improve their drawing skill is to allow them to draw motivating pictures- focus on drawing people, facial expressions, etc rather than shapes.  Kids showed greater gains when they had developmental interpretation therapy session to help them process how the picture should fit together.  They also improved with frequent practice.  Case studies show that in children, ages 4-6, who participate in the developmental interpretation sessions and practiced drawing people and houses showed significant gains in elaboration of the picture, increases in inclusion of objects, improved their ability to draw an object in its proper context (like a person in a house) and increased in the ability to combine features (all the parts of the picture connected in the proper ways such as heads were on necks and legs attached to bodies).  Improvement has also been shown to have the subject verbally express what they are drawing and how it should connect the lines.  When they talk through the process, the picture ends up more organized.

In the same study the kids were assessed again between the ages of 12-15.  After 6 years of growth, the ability to draw more organized pictures improved in all subjects of the study.  So, although the skill is delayed, it does improve with time.  In all age groups, the subjects were able to draw more organized pictures of people and flowers versus objects such as houses, bikes and animals. 

In conclusion

Visuo-spatial difficulties are an issue for all individuals with WS but with purposeful and educated therapists, there are skills and techniques that they can learn to help them overcome this obstacle and improve their self help and motor skills as they age.

Sources:

• http://www.nature.com/nrn/journal/v7/n5/full/nrn1906.html Primary source on brain studies linked to WS
• http://www.psych-it.com.au/Psychlopedia/article.asp?id=412 A summary of psychatric studies related to brain and behaviors in WS.
• http://www.dartmouth.edu/~rswenson/NeuroSci/chapter_8B.html Information on cerebellum function
• http://www.n-acetylaspartate.com/ Information on  the neurotransmitter, N-acetylaspartate
• Neurobiological models of visiospatial cognition in children with williams syndrome
• http://www.springerlink.com/content/p57121g83734300g/
• http://www.physio-pedia.com/index.php/William's_Syndrome#cite_note-Seventeen-16 An overview of Williams syndrome manifestations related to physio-motor intervention
• http://books.google.com/books?id=9E9q5112WBgC&pg=PA136&lpg=PA136&dq=motor+delay+williams+syndrome&source=bl&ots=LdcBfjN6p1&sig=4uSFQrsE1J7LibATNjKYZnFb6I8&hl=en&sa=X&ei=QVtIT62ACJD_sQLj_anNCg&ved=0CCkQ6AEwATgK#v=onepage&q=motor%20delay%20williams%20syndrome&f=false A google sampling from the book "Understanding Williams Syndrome"- used the sections of motor delay

  

Chiari Malformation

Chiari malformation (spoken as kee-AHR-ee) is a disorder of the skull where the cranium that holds the brain is small at its base.  The brain is cradled and protected in a casing of bone called the cranium.  The cranium is made up of 6 fused bones- the frontal bone, sphenoid bone, ethmoid bone, parietal bone, temporal bone and occipital bone.   The occipital bone is the most inferior or lowest bone in the cranium and it protects the back of the brain.

The occipital bone in humans is curved at the base which allows it to cradle the round brain tissue inside.  This curved portion of the occipital bone is called the posterior fossa and it sits just under the ridge in the back of the head that you can feel (called the occipital protrubance). 

The posterior fossa cradles the most posterior (back) and inferior (lowest) portion of the brain called the cerebellum.  The cerebellum is a smaller domain of the brain that coordinates motor function- such as balance and coordination.  It has many nerve tracts that communicate with the cerebrum where your brain "decides" on how to move and react to its environment.  Also in the cerebellum are tiny channels and chambers that act as canals to move nutrient-rich fluid (called cerebral spinal fluid or CSF) around the brain feeding it and cleansing it of waste.   CSF acts much like the blood supply but unlike blood, it does not carry cells other than those of your immune system; essentially protecting it from viral and bacterial infection.  The CSF travels through the cerebellum in a canal, called the cerebral aquaduct, that moves from the cerebral area down into the brainstem.  The CSF accumulates in a chamber that sits just under the cerebellum, called the 4th ventricle.  From here it drains down another canal into the spinal cord through the central canal.  At the base of the occipital bone is a large opening called the foramen magnum where the brain stem exits the cranium and leads to the spinal cord. 

In WS, mis-shapen cranial bones are prevalent making Chiari an unfortunate complication of the disorder for some.  When the cranium is formed during fetal development, some people's posterior fossa is mis-shapen.  This can happen in two ways.  First the base of the skull that fuses with the facial bones, called the clivus, can be shorter than normal consequently crowding the cerebellum.  The second malformation that can occur is in the tentorium cerebelli.  This is a fiberous covering that separates the cerebrum from the cerebellum.  This membrane when situated in a steep fashion pushes down on the cerebellum and crowds the space.

Due to the crowding, a portion of the cerebellum called the cerebellar tonsils can be compressed into the base of the skull and/or extend down into the foramen magnum (the hole where the brainstem exits the skull and becomes the spinal cord).  If the cerebellum is crowded in this space, the tonsils extend down into the hole and essentially block the passage way of the CSF flowing out of the 4th ventricle into the central canal of the spinal cord. 

The arrows in the picture on the left show the normal flow of CSF through the brain.  The picture on the right shows that when the cerebellum sits too low in the posterior fossa it cuts off the flow of the CSF around the cerebellum.

The severity of crowding can cause pressure to be exerted on the cerebellum creating neurological or motor issues.  It can also close off the channels where CSF moves causing it to build up pressure and stop its flow which essentially will cut of supply of CSF to parts of the brain stem and spinal cord. 

picture from www.chiariinstitute.com

Types of Chiari
Chiari Malformation can occur in various degrees of severity.  It is considered a congenital disorder (where it is formed at birth) but symptoms are often not witnessed until adolescence or early adulthood because the pressure can cause neurological damage over time.  In Williams Syndrome (WS), type 1 Chiari Malformation occurs in 10% of cases.  Type 1 is less severe and often is not accompanied by any symptoms.  It's found more commonly than the other types and is often diagnosed in conjunction with other neurological disorders rather than on its own.  Type I is often considered an adult form because it is often not usually discovered until later in life. 

A brain scan showing Chiari type 1.

There are also two other types of Chiari Malformation.  Type II, also called Arnold-Chiari Malformation is typically found in conjunction with a disorder of the spinal cord called spina bifida where the spine doesn't close properly during growth in-utero and the spinal cord protrudes from the back.  This type is usually discovered during pregnancy in an ultrasound because it is accompanied with other spinal abnormalities that are more obvious.  The third type, which is rare and most severe is Type III which leads to long term debilitating neurological issues and requires surgery and long term treatment. 

There is not much known if Chiari is a hereditary disorder.  There are a few documented instances where it seems to run in a few families but not much is known about genetic links to this disorder.

Symptoms

Most people with Chiari will experience headaches typically at the base of the head or neck and are often treated for pain.  Many end up with severe headaches after coughing and sneezing.   Other symptoms include changes in the voice and difficulty swallowing often with gagging or choking.  Because the cerebellum controls coordination, body movements can become difficult.  This can include spatial difficulties, dizziness, blurred vision, poor fine motor control (such as holding a pencil and writing), numbness and tingling in the hands and slurred speech.  Other symptoms that are considered more rare are sleep apnea, ringing in the ears, poor bladder control, scoliosis and chest pain.

Unfortunately for those with WS, the symptoms of Chiari malformation are common issues in WS such as coordination issues, gagging and swallowing issues and fine motor delays so it may be difficult to spot them if your child cannot communicate that they have a headache.

If Chari malformation is suspected a neurologist will often complete an MRI to assess the bone formation.  They will conduct a special test called a cine-MRI which tests the flow of the CSF through the brain to see if there is blockage. 

In some people with Chiari, syringomyelia may develop due to nerve tract damage.  In this complication, a canal or cyst will develop in the spinal cord and fills with fluid.  This can cause additional pressure in the canals that carry CSF and can cause further nerve damage.

Arrows indicate regions of syringomyelia

Treatment
Surgery is the only treatment that can stop neurological damage to the central nervous system and depending on the severity several surgeries may be needed to effectively repair the cranial crowding.  If there is any doubt about need for surgery it will usually be delayed.  There are three reasons a neurologist would suggest surgery for this disorder: 1. There is obvious neurological damage especially if it worsens over time; 2. If other spinal cord issues are present as well (such as tethered cord, scoliosis, spina bifida, etc); and 3. If the symptoms of Chiari greatly affect the person's ability to cope day to day (such as if the headaches are too great to manage). 

The surgery itself is called decompression surgery.  The goal of the surgery is to relieve pressure exerted on the channels that carry CSF so that proper flow is restored and to relieve any pressure exerted on the cerebellum by the skull.  This is accomplished by performing an occipital craniectomy which means they remove some of the skull bone at the base of the skull to increase the space in the occipital posterior fossa.  This may  not require going into the brain itself; it focuses on changing the shape of the bone.  The surgery can also include a C1 laminectomy which is surgical change to the first bone in the vertebrae (cervical vertebrae #1).  In this procedure, they remove an archway that surrounds the spinal cord and possibly the ridge that forms the portion of the spine that you feel when you touch the back.  The goal of this is to relieve pressure where the cranium and vertebrae meet (where the headaches often exist).  In these sections where the bone is removed, the tough brain coverings that sit underneath the bone remain intact. 

At this point of the surgery some surgeons (5-10%) stop; about 45% also remove dura mater (called a duraplasty) which is the most common type of surgery for this disorder.  Dura mater (meaning "tough mother") is the very tough covering that surrounds the brain and spinal cord.  It has the consistency of thin plastic, like that of a water bottle.

 The dura mater would be cut and then a synthetic patch of it would be sewn in to increase the area and free up more space.  This procedure, called a graft, can use tissue from the patient itself, bovine pericardium (a sack lining that surrounds the heart of the cow) or synthetic material.  The material used is really the preference of the surgeon.  There is no research that shows one is better than another. 

From here another 45% of doctors will also remove the second layer surrounding the brain called the arachnoid space.  This layer is part of the channel system that skirts CSF around the brain and it often has lesions in it that when broken, can free up room for the cerebellum.  In some cases, the surgeon may also shrink the cerebellar tonsils themselves by either cauderizing them (which makes them shrink) or resecting them (cutting a portion out) to relieve the crowding and open up the channels for CSF flow.  This manipulation of the cerebellum itself is more risky because by interrupting the arachnoid layer, the patient can be exposed to risks of bacterial or viral infections in the brain such as meningitis. 

During surgery, ultrasounds are often use to constantly assess the flow of the CSF and the position of the cerebellar tonsils as room is freed up.  The success of the surgery really depends on the patient's severity and how the brain is compressed.  Some patients only need one surgery but approximately 30%, typically those with spinal or cranial deformities and other spinal complications, will need follow-up surgeries because the condition will relapse later in life.

What to do if you suspect Chiari
If you suspect Chiari malformation in your child with WS, it is important to see a neurologist.  The Mayo Clinic has a great web page with information you should bring to your first meeting and a list of questions to ask so you are well informed about the condition.



Sources used in this blog post:
National Institute of Neurological Disorders and Stroke
Chari and Syringomyelia Foundation
The Mayo Clinic

Upright Health: Posterior fossa and Chiari Malformation