Tag Archive for: intellectual disability

girl with down syndrome

Study finds delayed oligodendrocyte progenitor maturation in Down syndrome

girl with down syndrome

People with Down syndrome (DS) can have moderate to severe intellectual disability, which is thought to be associated with changes in early brain development.

People with Down syndrome (DS) can have moderate to severe intellectual disability, which is thought to be associated with changes in early brain development. Children’s National Hospital experts discovered delayed maturation in oligodendrocyte progenitors in DS. Oligodendrocytes produce the white matter which insulates neural pathways and ensures speedy electrical communication in the brain. The researchers identified these delays by measuring gene expression at key steps in cell development, according to a new study published in Frontiers in Cellular Neuroscience.

The findings further suggest that brain and spinal cord oligodendrocytes differ in their developmental trajectories and that “brain-like” oligodendrocyte progenitors were most different from control cells, indicating that oligodendrocytes in the brains of people with DS are not equally affected by the trisomy 21.

“This is one of the critical steps towards identifying the key stages and molecular players in the DS white matter deficits,” said Tarik Haydar, Ph.D., director of the Center for Neuroscience Research. “With this knowledge, and with further work in this direction, we envision future therapies that may improve nerve cell communication in the brains of people with Down syndrome.”

The hold-up in the field

The mechanisms that lead to the reduction of white matter in the brains of people with DS are unknown. To better understand early neural precursors, they used isogenic pluripotent stem cell lines derived from two individuals with Down syndrome to study the brain development and spinal cord oligodendrocytes.

“I was excited that we discovered another example of how important it is not to generalize when studying DS brain development,” said Haydar. “This is one of several papers, from our group and others, that demonstrate how important it is to be very specific about the brain area and the developmental stage when investigating the causes of DS brain dysfunction.”

What’s next

Dysmaturation of oligodendrocyte cells are a relatively new discovery by the Haydar Lab, one of the preeminent labs in DS research. These results isolate specific steps that are affected in human cells with trisomy 21. They are using these results to develop a drug screening platform that may prevent altered generation of oligodendrocytes in the future.

You can read the full study “Sonic Hedgehog Pathway Modulation Normalizes Expression of Olig2 in Rostrally Patterned NPCs With Trisomy 21” in Frontiers in Cellular Neuroscience.

illustration of Research & Innovation Campus

NIH awards $6.7M to build additional lab space at Children’s National Research & Innovation Campus

Children’s National Hospital today announced a $6.7 million award from the National Institute of Health (NIH) for the new Children’s National Research & Innovation Campus (RIC). The funds will help transform a historic building on the former site of Walter Reed Army Medical Center into new research labs. The NIH construction grant marks the first secured grant funding for Phase II of the campus project, signaling continued momentum for the first-of-its-kind pediatric research and innovation hub.

The funding was announced as D.C. Mayor Muriel Bowser, D.C. Deputy Mayor for Planning and Economic Development John Falcicchio and D.C. Council Chair Phil Mendelson took their first tour of the already-renovated Phase I of the RIC. The campus began opening in early 2021 and brings together Children’s National with top-tier research and innovation partners: Johnson & Johnson Innovation – JLABS @ Washington, DC and Virginia Tech. They come together with a focus on driving discoveries and innovation that will save and improve the lives of children.

“This NIH award is the latest confirmation that we are creating something very special at the Children’s National Research & Innovation Campus,” said Kurt Newman, M.D., president and CEO of Children’s National. “Only the D.C. region can offer this proximity to federal science agencies and policy makers. When you pair our location with these incredible campus partners, I know the RIC will be a truly transformational space where we develop new and better ways to care for kids everywhere.”

The campus is an enormous addition to the BioHealth Capital Region, the fourth largest research and biotech cluster in the U.S., with the goal of becoming a top-three hub by 2023. The RIC exemplifies the city’s commitment to building the partnerships necessary to drive discoveries, create jobs, promote economic growth, treat underserved populations, improve health outcomes, and keep D.C. at the forefront of innovation and change.

“We are proud to officially welcome the Children’s National Research & Innovation Campus to the District and to the Ward 4 community,” said Mayor Bowser, after touring the campus. “This partnership pairs a world-class hospital with a top university and a premier business incubator – right here in the capital of inclusive innovation. Not only will our community benefit from the jobs and opportunities on this campus, but the ideas and innovation that are born here will benefit children and families right here in D.C. and all around the world.”

The NIH grant funding announced today will go toward the expansion and relocation of the DC Intellectual and Developmental Disabilities Research Center (DC-IDDRC). This research center will increase the efforts to improve the understanding and treatment of children with developmental disabilities, including autism, cerebral palsy, epilepsy, inherited metabolic disorders and intellectual disability.

The space where the new lab will be built used to be the Armed Forces Institute of Pathology Building, a portion of the Walter Reed Army Medical Center. The site closed and Children’s National secured 12 acres in 2016, breaking ground on Phase I construction in 2018.

The new space will offer highly cost-effective services and unique state-of-the-art research cores that are not available at other institutions, boosting the interdisciplinary and inter-institutional collaboration between Children’s National, George Washington University, Georgetown University and Howard University. Investigators from the four institutions will access the center, which includes hoteling laboratory space for investigators whose laboratories are not on-site but are utilizing the core facilities — Cell and Tissue Microscopy, Genomics and Bioinformatics, and Inducible Pluripotent Stem Cells.

“While we have explored outsourcing some of these cores, especially genomics, we found that expertise, management, training and technical support needed for pediatric research requires on-site cores,” said Vittorio Gallo, Ph.D., interim chief academic officer, interim director of the Children’s National Research Institute, and principal investigator for the DC-IDDRC. “The facility is designed to support pediatric studies that are intimately connected with our community. We operate in a highly diverse environment, addressing issues of health equity through research.”

The RIC provides graduate students, postdocs and trainees with unique training opportunities, expanding the workforce and talent of new investigators in the D.C. area. Young investigators will have job opportunities as research assistants and facility managers as well. The new labs will support these researchers so they can tackle pressing questions in pediatric research by integrating pre-clinical and clinical models.

Phase II will place genetic and neuroscience research initiatives of the DC-IDDRC at the forefront to treat a variety of pediatric developmental disorders. Other Children’s National research centers will also benefit from this additional space. The clinical and research campuses will be physically and electronically integrated with new informatics and video-communication systems.

The total projected cost of Phase II is $180 million, with design and construction to take up to three years to complete once started.

illustration of Research & Innovation Campus

Phase II will place genetic and neuroscience research initiatives of the DC-IDDRC at the forefront to treat a variety of pediatric developmental disorders. Other Children’s National research centers will also benefit from this additional space. The clinical and research campuses will be physically and electronically integrated with new informatics and video-communication systems.

illustration of brain showing cerebellum

Focusing on the “little brain” to rescue cognition

illustration of brain showing cerebellum

Research faculty at Children’s National in Washington, D.C., with colleagues recently published a review article in Nature Reviews Neuroscience that covers the latest research about how abnormal development of the cerebellum leads to a variety of neurodevelopmental disorders.

Cerebellum translates as “little brain” in Latin. This piece of anatomy – that appears almost separate from the rest of the brain, tucked under the two cerebral hemispheres – long has been known to play a pivotal role in voluntary motor functions, such as walking or reaching for objects, as well as involuntary ones, such as maintaining posture.

But more recently, says Aaron Sathyanesan, Ph.D., a postdoctoral research fellow at the Children’s Research Institute, the research arm of Children’s National  in Washington, D.C., researchers have discovered that the cerebellum is also critically important for a variety of non-motor functions, including cognition and emotion.

Sathyanesan, who studies this brain region in the laboratory of Vittorio Gallo, Ph.D., Chief Research Officer at Children’s National and scientific director of the Children’s Research Institute, recently published a review article with colleagues in Nature Reviews Neuroscience covering the latest research about how altered development of the cerebellum contributes to a variety of neurodevelopmental disorders.

These disorders, he explains, are marked by problems in the nervous system that arise while it’s maturing, leading to effects on emotion, learning ability, self-control, or memory, or any combination of these. They include diagnoses as diverse as intellectual disability, autism spectrum disorder (ASD), attention-deficit/hyperactivity disorder and Down syndrome.

“One reason why the cerebellum might be critically involved in each of these disorders,” Sathyanesan says, “is because its developmental trajectory takes so long.”

Unlike other brain structures, which have relatively short windows of development spanning weeks or months, the principal cells of the cerebellum – known as Purkinje cells – start to differentiate from stem cell precursors at the beginning of the seventh gestational week, with new cells continuing to appear until babies are nearly one year old.  In contrast, cells in the neocortex, a part of the brain involved in higher-order brain functions such as cognition, sensory perception and language is mostly finished forming while fetuses are still gestating in the womb.

This long window for maturation allows the cerebellum to make connections with other regions throughout the brain, such as extensive connections with the cerebral cortex, the outer layer of the cerebrum that plays a key role in perception, attention, awareness, thought, memory, language and consciousness. It also allows ample time for things to go wrong.

“Together,” Sathyanesan says, “these two characteristics are at the root of the cerebellum’s involvement in a host of neurodevelopmental disorders.”

For example, the review article notes, researchers have discovered both structural and functional abnormalities in the cerebellums of patients with ASD. Functional magnetic resonance imaging (MRI), an imaging technique that measures activity in different parts of the brain, suggests that significant differences exist between connectivity between the cerebellum and cortex in people with ASD compared with neurotypical individuals. Differences in cerebellar connectivity are also evident in resting-state functional connectivity MRI, an imaging technique that measures brain activity in subjects when they are not performing a specific task. Some of these differences appear to involve patterns of overconnectivity to different brain regions, explains Sathyanesan; other differences suggest that the cerebellums of patients with ASD don’t have enough connections to other brain regions.

These findings could clarify research from Children’s National and elsewhere that has shown that babies born prematurely often sustain cerebellar injuries due to multiple hits, including a lack of oxygen supplied by infants’ immature lungs, he adds. Besides having a sibling with ASD, premature birth is the most prevalent risk factor for an ASD diagnosis.

The review also notes that researchers have discovered structural changes in the cerebellums of patients with Down syndrome, who tend to have smaller cerebellar volumes than neurotypical individuals. Experimental models of this trisomy recapitulate this difference, along with abnormal connectivity to the cerebral cortex and other brain regions.

Although the cerebellum is a pivotal contributor toward these conditions, Sathyanesan says, learning more about this brain region helps make it an important target for treating these neurodevelopmental disorders. For example, he says, researchers are investigating whether problems with the cerebellum and abnormal connectivity could be lessened through a non-invasive form of brain stimulation called transcranial direct current stimulation or an invasive one known as deep brain stimulation. Similarly, a variety of existing pharmaceuticals or new ones in development could modify the cerebellum’s biochemistry and, consequently, its function.

“If we can rescue the cerebellum’s normal activity in these disorders, we may be able to alleviate the problems with cognition that pervade them all,” he says.

In addition to Sathyanesan and Senior Author Gallo, Children’s National study co-authors include Joseph Scafidi, D.O., neonatal neurologist; Joy Zhou and Roy V. Sillitoe, Baylor College of Medicine; and Detlef H. Heck, of University of Tennessee Health Science Center.

Financial support for research described in this post was provided by the National Institute of Neurological Disorders and Stroke under grant numbers 5R01NS099461, R01NS089664, R01NS100874, R01NS105138 and R37NS109478; the Hamill Foundation; the Baylor College of Medicine Intellectual and Developmental Disabilities Research Center under grant number U54HD083092; the University of Tennessee Health Science Center (UTHSC) Neuroscience Institute; the UTHSC Cornet Award; the National Institute of Mental Health under grant number R01MH112143; and the District of Columbia Intellectual and Developmental Disabilities Research Center under grant number U54 HD090257.

child measuring his stomach

Cognitive function does not predict weight-loss outcome for adolescents

child measuring his stomach

Though young people with intellectual disabilities or cognitive impairment have greater rates of obesity and other comorbidities that impact their health and well-being, primary care providers are often reluctant to discuss or refer these patients for weight-loss surgery due to concerns about their ability to assent to both the surgery and the ongoing diet and lifestyle changes after surgery.

However, a study in Pediatrics authored by psychologists at Children’s National Health System finds that these young people, including those with Down syndrome, have similar weight-loss trajectories to those with typical cognitive function after bariatric surgery. The study is the first to look at post-surgical outcomes for this subgroup of adolescent bariatric surgery patients.

“It’s challenging to ensure that an adolescent who is cognitively impaired understands what it means to undergo a surgical procedure like bariatric surgery, but we do find ways to ensure assent whenever possible, and make sure the patient also has a guardian capable of consent,” says Sarah Hornack, Ph.D., a clinical psychologist at Children’s National and the study’s first author. “A very important determinant of post-surgical success for any young candidate, however, is a support structure to help them with weight-loss surgery requirements. Often, we see that adolescents with lower cognitive function already have a well-established support system in place to assist them with other care needs, that can easily adapt to providing structure and follow through after weight-loss surgery, too.”

The study reviewed outcomes for 63 adolescents ranging in age from 13 to 24 years old with an average body mass index of 51.2, all of whom were part of the bariatric surgery program at Children’s National Health System. The participants were diagnosed with cognitive impairment or intellectual disability via standardized cognitive assessments as part of a preoperative psychological evaluation or through a previous diagnosis. This study adds to the body of research that is helping to create standard criteria for bariatric surgery in adolescents and teenagers.

Children’s National is one of only a few children’s hospitals with accreditation from the Metabolic and Bariatric Surgery Accreditation and Quality Improvement Program of the American College of Surgeons and the American Society for Metabolic and Bariatric Surgery to offer bariatric surgery for adolescents with severe obesity. The extraordinary diversity of the patient population in Washington, D.C., including high rates of young people with obesity, allows the team to collect more comprehensive information about successful interventions across subgroups, including cognitive impairment or developmental disabilities, than nearly every other center in the United States.

“We’re happy to contribute evidence that can help families and care providers make informed health decisions for young people with intellectual disabilities or cognitive impairments. So many families are hoping to make sure that their children, despite disabilities, can be as healthy as possible in the long term,” says Eleanor Mackey, Ph.D., who is also a clinical psychologist at Children’s National and served as the study’s senior author. “Though the sample size is small, it does give credence to the idea that for many adolescents and teenagers, weight loss surgery may be a really viable option regardless of pre-existing conditions such as intellectual ability or cognitive function.”