MRI

Building “digital twins” to test complicated surgeries

 

MRI

Syed Anwar, Ph.D., is developing self-supervised algorithms for medical imaging.

Syed Anwar, Ph.D., joins the growing AI initiative in the Sheikh Zayed Institute for Pediatric Surgical Innovation (SZI) at Children’s National Hospital with extensive research experience in machine learning and medical imaging from the University of Engineering and Technology in Taxila, Pakistan, the University of Sheffield, U.K., and the University of Central Florida through the Fulbright Scholars Program. At Children’s National, he’s grateful for the proximity between researchers and clinicians as he studies federated learning and works to build “digital twins” that allow medical teams to test complicated surgical and treatment plans on infants with disorders including Pierre Robin Sequence. This rare congenital birth defect is characterized by an underdeveloped jaw, backward displacement of the tongue and upper airway obstruction. Anwar works alongside Marius George Linguraru, D.Phil., M.A., M.Sc., principal investigator at SZI, and the Precision Medical Imaging Lab to increase AI capacity in all areas of pediatric care at the hospital.

Q: What is the focus of your research work?

A: The main theme is a digital twin. It’s an engineering innovation that people have been using for some time, especially in manufacturing and aviation. For example, you can create a digital simulation of an airplane with a flight simulator. Now, people are starting to use the power of data-driven digital twins for medical applications.

I’m working to create a digital twin for infants born with Pierre Robin Sequence, where they need to have surgical interventions for improving the structure of the bones in the jaws. It includes a lot of clinical approaches, including surgery and ways to address apnea and food intake.

There are multiple areas of clinical expertise involved. With a digital twin, we will have a digital representation of the patient, and the surgeon, the radiologist and other clinicians can experiment with a proposed intervention before actually touching the patient.

Syed Anwar

Syed Anwar, Ph.D., joins the growing AI initiative in the Sheikh Zayed Institute for Pediatric Surgical Innovation (SZI) at Children’s National Hospital.

Q: How else are you using your engineering background in your research?

A: Another part of my work is federated learning, which is a type of machine learning. In artificial intelligence, we want big data as the starting point to train our deep learning models. When studying children, this is not always possible because we have smaller data sets.

Federated learning is a tool that helps in these situations. Data is kept at a local site. We train a model to learn from all that data at the different sites. One benefit is that we don’t need to share the data, which is very useful for preserving patient privacy. But you can still apply deep learning models and develop AI solutions using the distributed data for improved clinical outcomes.

Q: What do you see as the main hurdles you have to overcome?

A: For all medical data, and particularly for kids, the amount of data we see in a children’s hospital is small, particularly for rare diseases.

The second hurdle is good, quality labels. For example, if you are doing tumor segmentation, you still need to have some ground rules from a radiologist showing which part of the image is the tumor.

These challenges come together in another focus of my research – self-supervised learning, meaning we can train a machine to learn from the data itself, without the labels or ground rules. From a machine learning point of view, I am in the process of developing self-supervised algorithms for medical imaging and in general for medical data. It’s an amazing time to be in this research area and to enable the translation of AI driven solutions for clinical workflows.

Q: What excites you about being at Children’s National and working at SZI?

A: I come from an engineering background, and my research area has been medical imaging for some time, mainly magnetic resonance imaging. Before coming here, I was working at a university in Pakistan, teaching machine learning and conducting research related to medical imaging and biomedical signal processing. But I was missing strong connections with people caring for patients at the hospital.

NCC PDI 2022 pitch competition winners

Five winners selected in prestigious pediatric device competition

The National Capital Consortium for Pediatric Device Innovation (NCC-PDI) announced five awardees chosen in its prestigious “Make Your Medical Device Pitch for Kids!” competition. Each received a share of $150,000 in grant funding from the U.S. Food and Drug Administration (FDA), with awards ranging from $20,000 to $50,000 to support the advancement of pediatric medical devices.

Consistent with its mission of addressing the most pressing pediatric device needs, this year’s competition, moderated by MedTech Innovator, welcomed medical device technologies that address the broad unmet needs of children. The pediatric pitch event was part of the 10th Annual Symposium on Pediatric Device Innovation, co-located with the MedTech Conference, powered by AdvaMed.

This year’s pediatric device innovation awardees are:

  • CorInnova – Houston, TX – Minimally invasive biventricular non-blood contacting cardiac assist device to treat heart failure.
  • Innovation Lab – La Palma, CA – Mechanical elbow brace stabilizes tremors for pediatric ataxic cerebral palsy to improve the performance of Activities of Daily Living (ADLs).
  • Prapela – Biddeford, ME – Prapela’s incubator pad is the first innovation to improve the treatment of apnea of prematurity in over twenty years.
  • Tympanogen – Richmond, VA – Perf-Fix replaces surgical eardrum repair with a nonsurgical clinic procedure
  • Xpan – Concord, Ont. – Xpan’s universal trocar enables safest and most dynamic access and effortless upsizing in conventional/mini/robotic procedures.

“We are delighted to recognize these five innovations with critical NCC-PDI funding that will support their journey to commercialization. Improving pediatric healthcare is not possible without forward-thinking companies that seek to address the most dire unmet needs in children’s health,” says Kolaleh Eskandanian, Ph.D., M.B.A, P.M.P, vice president and chief innovation officer at Children’s National Hospital and principal investigator of NCC-PDI. “We know all too well how challenging it is to bring pediatric medical devices to market, which is why we have created this rich ecosystem to identify promising medical device technologies and incentivize investment. We congratulate this year’s winning innovators and applaud their efforts to help bridge these important care gaps that are impacting children.”

Empowering Innovators

NCC-PDI is one of five consortia in the FDA’s Pediatric Device Consortia Grant Program created to support the development and commercialization of medical devices for children, which lags significantly behind the progress of adult medical devices. NCC-PDI is led by the Sheikh Zayed Institute for Pediatric Surgical Innovation at Children’s National and the A. James Clark School of Engineering at the University of Maryland, with support from partners MedTech Innovator and design firm Archimedic.

A pediatric accelerator program, powered by MedTech Innovator, the largest medical device accelerator in the world, is a key part of the network of resources and experts that NCC-PDI provides in support of pediatric innovators. All five of this year’s competition finalists had an opportunity to participate in the year-long accelerator program.

To date, NCC-PDI has mentored 250 medical device projects to help advance their pediatric innovations throughout all stages of the total product life cycle (TPLC).

Eskandanian adds that supporting the progress of pediatric innovators is a key focus of the new Children’s National Research & Innovation Campus, a one-of-its-kind ecosystem that drives discoveries that save and improve the lives of children. On a nearly 12-acre portion of the former, historic Walter Reed Army Medical Center in Northwest Washington, D.C., Children’s National has combined its strengths with those of public and private partners, including industry, universities, federal agencies, start-up companies and academic medical centers. The campus provides a rich environment of public and private partners which, like the NCC-PDI network, will help bolster pediatric innovation and commercialization.

NCC PDI 2022 pitch competition winners

A total of $150K was awarded to five pediatric innovations during the medical device pitch competition at the 10th Annual Symposium on Pediatric Device Innovation, hosted by the National Capital Consortium for Pediatric Device Innovation (NCC-PDI). Award winners include (from left to right): Zaid Atto, founder and CEO at Xpan; John Konsin, CEO and co-founder of Prapela; Elaine Horn-Ranney, co-founder and CEO at Tympanogen; William Altman, CEO at CorInnova; and Sharief Taraman, pediatric neurologist at CHOC and University of California-Irvine partnering with Innovation Lab. (Photo credit: Children’s National Hospital)

DNA molecule

NIH awards $1m grant to study visual system

DNA molecule

The team will focus its work on FXS, a genetic condition that causes changes in a gene called Fragile X Messenger Ribonucleoprotein 1 (FMR1).

Researchers at Children’s National Hospital received a $1 million grant from the National Institutes of Health (NIH) to study the neural mechanisms behind visual deficits in fragile X syndrome (FXS). The work will provide new insights into how the visual system develops.

With the award from the National Eye Institute, the Children’s National team – led by Jason Triplett, Ph.D., principal investigator at the Center for Neuroscience Research – will work to unravel the poorly understood relationship between sensory deficits and neurodevelopmental disorders (NDDs). The findings are expected to provide clues into possible non-invasive therapeutics that could someday be used to resolve visual deficits in children with FXS and other disorders.

“Deficits in sensory processing, including vision, are common in many NDDs, but how these deficits arise is poorly understood, hampering the development of therapies,” Triplett said. “Using a powerful combination of molecular, anatomic and electrophysiologic techniques, we are hoping to get a comprehensive understanding of visual circuit development – and its disruption in fragile X syndrome.”

The big picture

The team will focus its work on FXS, a genetic condition that causes changes in a gene called Fragile X Messenger Ribonucleoprotein 1 (FMR1). The gene normally makes a protein needed for brain development, including the highly complex visual system. However, people with FXS do not properly make the protein, leading to a spectrum of developmental and cognitive delays.

Triplett’s team theorizes that ameliorating sensory deficits could improve other features of the disorder. Research has shown that sensory processing is critical for communication and learning, which are central components of the behavioral therapies aimed at treating intellectual delays and social anxiety.

Yet little is known regarding the neural basis of sensory deficits in FXS. Understanding how neuronal circuits are disorganized and dysfunctional in the context of the disorder will be a critical first step to developing therapeutics. In addition, given the prevalence of sensory dysfunction across NDDs, the work could have broader applications.

Children’s National Hospital leads the way

This NIH-supported work builds on prior research in the Triplett Laboratory. The collaborative nature among investigators in the Center for Neuroscience Research combined with the technical resources supported by the DC-Intellectual and Developmental Disabilities Research Center create an environment that maximizes the experimental capabilities of the Triplett Lab.

“We are so excited to continue this work,” Triplett said. “It highlights the importance of supporting fundamental research at the bench. We started with basic biological questions about how circuits wire up, and now we are embarking on research that could set the stage for potentially life-changing therapies.”

HIV virus

CRISPR gene editing identifies possible drug targets for HIV

HIV virus

Working with researchers at Johns Hopkins University, the Children’s National team used CRISPR gene technology to test drug targets that find and attack latent HIV, paving the way for drug treatments that may someday completely cure the virus.

Researchers at Children’s National Hospital have identified several new drug targets that may enhance the elimination of latent HIV in patients, a major bottleneck to the full treatment of the virus, according to new findings published in Science Translational Medicine.

Working with researchers at Johns Hopkins University, the Children’s National team used CRISPR gene technology to test drug targets that find and attack latent HIV, paving the way for drug treatments that may someday completely cure the virus. Currently, anti-retroviral therapies (ARTs) can only slow its progress.

Why we’re excited

“In less than one month, we were able to use CRISPR to test 20,000 gene candidates in one single experiment. It was an amazing application of the technology,” said Wei Li, Ph.D., a co-author of the study and assistant professor at the Center for Genetic Medicine Research at Children’s National. “The CRISPR technology provides a global, unbiased approach to understanding molecular aspects of HIV-1 infection, including the ways that HIV-1 enters cells and replicates. This research could someday revolutionize how we treat the virus pharmaceutically.”

The big picture

More than 30 million people worldwide live with HIV-1, the most common form of the virus that can eventually lead to AIDS. But no single agent can entirely eliminate HIV-1 in these patients.

Researchers have sought ways to attack this elusiveness and turned to the CRISPR gene-editing tool, which can locate specific bits of DNA inside a cell. They trained CRISPR screens on the HIV-1 genome to identify critical factors that allow or prevent the virus from lying latent. In the latter case, these pieces of DNA will be the ideal targets of a drug that will push the virus out of the latent stage so it can be targeted by therapies.

What’s ahead

The findings of the Children’s National and Johns Hopkins scientists point to novel drug therapies and validation systems that could someday eradicate HIV.

Bicna Song, a postdoctoral researcher in Li’s laboratory at the Center for Genetic Medicine, said that reversing HIV-1 latency will allow for the killing of infected cells and give researchers opportunities to actually cure patients with HIV.

“So far, no single latency-reversing agent – alone or in combination with another drug – has been shown to effectively reduce the latent reservoir size in persons living with HIV-1,” said Song, who contributed to the study. “With this work, we are meeting the urgent need to identify factors that can lead to new drug targets.”

lung ct scan

With COVID-19, artificial intelligence performs well to study diseased lungs

lung ct scan

New research shows that artificial intelligence can be rapidly designed to study the lung images of COVID-19 patients.

Artificial intelligence can be rapidly designed to study the lung images of COVID-19 patients, opening the door to the development of platforms that can provide more timely and patient-specific medical interventions during outbreaks, according to research published this month in Medical Image Analysis.

The findings come as part of a global test of AI’s power, called the COVID-19 Lung CT Lesion Segmentation Challenge 2020. More than 2,000 international teams came together to train the power of machine learning and imaging on COVID-19, led by researchers at Children’s National Hospital, AI tech giant NVIDIA and the National Institutes of Health (NIH).

The bottom line

Many of the competing AI platforms were successfully trained to analyze lung lesions in COVID-19 patients and measure acute issues including lung thickening, effusions and other clinical findings. Ten leaders were named in the competition, which ran between November and December 2020. The datasets included patients with a range of ages and disease severity.

Yet work remains before AI could be implemented in a clinical setting. The AI models performed comparably to radiologists when analyzing data similar to what the algorithms had already encountered. However, the AI was less valuable when trained on fresh data from other sources during the testing phase, indicating that systems may need to study larger and more diverse data sets to meet their full potential. This is a challenge with AI that has been noted by others too.

What they’re saying

“These are the first steps in learning how we can quickly and accurately train AI for clinical use,” said Marius George Linguraru, D.Phil., M.A., M.Sc., principal investigator at the Sheikh Zayed Institute for Pediatric Surgical Innovation at Children’s National, who led the Grand Challenge Initiative. “The global interest in COVID-19 gave us a groundbreaking opportunity to address a health crisis, and multidisciplinary teams can now focus that interest and energy on developing better tools and methods.”

Holger Roth, senior applied research scientist at NVIDIA, said the challenge gave researchers around the world a shared platform for developing and evaluating AI algorithms to quickly detect and quantify COVID lesions from lung CT images. “These models help researchers visualize and measure COVID-specific lesions of infected patients and can facilitate timelier and patient-specific medical interventions to better treat COVID,” he said.

Moving the field forward

The organizers see great potential for clinical use. In areas with limited resources, AI could help triage patients, guide the use of therapeutics or provide diagnoses when expensive testing is unavailable. AI-defined standardization in clinical trials could also uniformly measure the effects of the countermeasures used against the disease.

Linguraru and his colleagues recommend more challenges, like the lung segmentation challenge, to develop AI applications in biomedical spaces that can test the functionality of these platforms and harness their potential. Open-source AI algorithms and public curated data, such as those offered through the COVID-19 Lung CT Lesion Segmentation Challenge 2020, are valuable resources for the scientific and clinical communities to work together on advancing healthcare.

“The optimal treatment of COVID-19 and other diseases hinges on the ability of clinicians to understand disease throughout populations – in both adults and children,” Linguraru said. “We are making significant progress with AI, but we must walk before we can run.”

baby getting heel prick

Researchers study murky findings in newborn screening panels with $3.7m NIH grant

baby getting heel prick

Children’s National received a grant to investigate the impact of newborn screening on families who receive an uncertain prognosis.

The National Institutes of Health (NIH) awarded Children’s National Hospital a $3.7 million grant to investigate the impact of newborn screening on the growing population of families who leave the testing with an uncertain prognosis.

Following the families longitudinally allows for a real-time view of the experiences of these children, sometimes referred to as “patients in waiting.”

Newborn screening is part of a universal, mandatory state health program that helps to identify inherited conditions that can affect a child’s health and survival. Millions of babies are screened annually for genetic, metabolic and endocrine disorders, using a few drops of blood from a prick to the heel; additional tests are done at the bedside such as hearing and heart screening. Sometimes, however, the results create medical odysseys and flag conditions that may never result in symptoms.

“For its first 50 years, newborn screening presented relatively consistent outcomes,” said principal investigator Beth Tarini, M.D., M.S., M.B.A., who serves as the associate director of the Center for Translational Research at Children’s National. “However, in the 21st century, new screening tests have created more ambiguous findings. As a result, we cannot accurately predict what type of symptoms a child may develop, when or if they will develop them, or how severe they will be. This is a lot to ask parents to deal with after the birth of a new child who appears otherwise healthy.”

Why it matters

The uncertainty can take a significant toll on parents by creating fear, anxiety and the medicalization of a child. However, to date, little long-term data exist to inform the care for these children. Ethically, that gap leaves clinicians unsure of how to weigh the benefit and harm of mandatory newborn screening programs. From a policy perspective, the drought of information leads to questions about how best to add disorders to newborn screening panels – an issue that will likely only grow as technology allows us to test for more conditions.

“We have a new group of children growing up and wondering when – or if – they will ever develop signs or symptoms of a disease,” Dr. Tarini said. “For some families, the information is an opportunity. For others, it becomes a burden. We owe it to these families to understand their experience and chart a sensible path forward to help them.”

What’s next

The four-year study will bring together researchers at Children’s National and Case Western University to analyze data and patient interviews from families in Virginia, Iowa and Oregon. The research team will include experts in newborn screening, genetics, health services, genetic counseling, psychology, bioethics and biostatistics.

Innovations for health equity: Food pharmacy app wins Hackathon

When families come into the endocrinology clinic, 66% of prediabetes and Type 2 diabetes patients screen positive for food insecurity. One remedy: a smartphone app envisioned by Children’s National Hospital researchers to communicate with families between visits and provide resources to help stock pantries with nutritious foods.

The Children’s National Food Pharmacy app is on its way from idea to reality, thanks to the inaugural Health Equity in Research Hackathon event at the Children’s National Research & Innovation Campus. This team-based, “Shark Tank”-like competition involved roughly 50 experts designing creative healthcare solutions that could be delivered through ubiquitous smartphones.

“It takes a village to raise a child, and we want to show that at Children’s National we are part of that community,” said food pharmacy founder and diabetes educator Alexis Richardson, M.S., R.D., L.D.N., C.D.C.E.S.

Why it matters

The rate of new-onset Type 2 diabetes increased by a staggering 182% during the first nine months of the COVID-19 pandemic. Now, the Children’s National food pharmacy provides families that screen positive for food insecurity during quarterly clinic appointments with a 50-pound bag of medically-tailored groceries.

The new app, as envisioned, would follow them home to connect them with food bank information and other nutritional resources, eliminating paper forms and other hurdles that get in the way of care.

What’s ahead

Children’s National leaders are committed to making the proposal a reality. “We are going to support today’s winner through the next steps to prepare them to enter the app development pipeline at the Sheikh Zayed Institute,” said Lisa Guay-Woodford, M.D., director for the Clinical and Translational Science Institute at Children’s National (CTSI-CN) and one of the main judges of the competition.

The app development will happen in the months ahead. Kevin Cleary, Ph.D., technical director of the Sheikh Zayed Institute of Pediatric Surgical Innovation, said the Hackathon planted the seeds. “It really depends on the drive of the individual to see the idea to fruition,” Cleary told competitors.

Other app entries were encouraged to continue their work:

  • The Surgical Checklist, led by Brian K. Reilly, M.D., co-director of the Cochlear Implant Program: this app would help patients and providers successfully navigate the often-confusing pre-operative checklist, including required physical exams, lab work, imaging and pre-procedure fasting. Reilly said the hospital handles about 15,000 cases a year, and about 10% are rescheduled, often for reasons that could be avoided with digital organization and reminders for families.
  • More than Determined, led by Pediatrician Jessica Lazerov, M.D., M.B.A.: this app aims to give time-strapped providers a platform to better understand and address social determinants of health – such as access to safe housing, education and jobs – that can promote better preventative care outcomes.

The Health Equity in Research Hackathon was created by the new Health Equity in Research Unit, a joint initiative between the CTSI-CN and the Center for Translational Research within the Children’s National Research Institute.

Dr. Lisa Guay-Woodford and the winners of the Health Equity in Research Hackathon

Dr. Lisa Guay-Woodford, director for the Clinical and Translational Science Institute, joins the winners of the inaugural Health Equity in Research Hackathon: the Children’s National Food Pharmacy. The team’s proposed app will connect families facing food insecurity with resources and guidance for nutritious eating.

Paper cutouts of silhouette

Successful autism and ADHD tools go digital

Paper cutouts of silhouette

A team is working to implement a successful, evidence-based online training and tele-support system for the Unstuck and On Target (UOT) program.

A team from Children’s National Hospital, Children’s Hospital Colorado and The Institute for Innovation and Implementation at the University of Maryland, Baltimore is working to implement a successful, evidence-based online training and tele-support system for the Unstuck and On Target (UOT) program. The program is now available for free to any parent or educator who needs it.

What is it?

Since 2020, this team has piloted UOT video training with 293 school-based staff across 230 elementary schools in Colorado and Virginia. The work follows a related PCORI-funded research project, Improving Classroom Behaviors Among Students with Symptoms of Autism Spectrum Disorder or Attention Deficit Hyperactivity Disorder, led by Children’s National and Children’s Colorado researchers. That project demonstrated the effectiveness of UOT at improving the executive functioning – or self-regulation skills including flexible thinking, planning and emotional-control – of school-aged children in Title 1 schools. The training focuses on the executive function of elementary school-aged children with autism spectrum disorder (ASD) or attention deficit hyperactivity disorder (ADHD).

In addition to creating more accessible training for educators, the team created short, free videos highlighting executive functioning tips and tricks that parents can employ at home. These videos, evaluated by 100 parents and revised based on their input, are now available to parents nationwide.

The availability of this training is possible due to a $2 million contract awarded to Children’s Hospital Colorado’s (Children’s Colorado) Pediatric Mental Health Institute and Children’s National by the Patient-Centered Outcomes Research Institute (PCORI) in 2020.

Why it matters

There are many children, including those in low-income or rural settings, that don’t have access to clinics that offer services to support executive functioning skills, such as planning and flexibility, that they need. But all children have access to a school. Now, UOT training is online and accessible so any school with internet access can offer UOT where school staff (including special educators, teachers, paraprofessionals and counselors) can actively teach students how to plan, set goals and be flexible. The team’s next goal is to create a comparable video training for the high school version of UOT.

“These free, accessible and effective tools for improving children’s social-emotional development are building skills that are more important today than ever,” said Lauren Kenworthy, Ph.D., director of the Center for Autism Spectrum Disorders at Children’s National. “The vast majority (96%) of caregivers and educators found these tools useful and relevant. That feedback is a testament to our team’s efforts to make sure these resources were created and validated as usable, approachable and actionable for everyone who needs them.”

More information

For educators – Find resources on Unstuck and On Target, including links to the free trainings, tips and tricks and FAQs. Teachers can also receive continuing education credits (CEUs) for this training.

For parents – Find resources on Unstuck and On Target’s parent training videos

For schools – Add free Unstuck and On Target parent videos to your school district’s relevant websites, landing pages and newsletters.

echocardiogram

AI may revolutionize rheumatic heart disease early diagnosis

echocardiogram

Researchers at Children’s National Hospital have created a new artificial intelligence (AI) algorithm that promises to be as successful at detecting early signs of rheumatic heart disease (RHD) in color Doppler echocardiography clips as expert clinicians.

Researchers at Children’s National Hospital have created a new artificial intelligence (AI) algorithm that promises to be as successful at detecting early signs of rheumatic heart disease (RHD) in color Doppler echocardiography clips as expert clinicians. Even better, this novel model diagnoses this deadly heart condition from echocardiography images of varying quality — including from low-resource settings — a huge challenge that has delayed efforts to automate RHD diagnosis for children in these areas.

Why it matters

Current estimates are that 40.5 million people worldwide live with rheumatic heart disease, and that it kills 306,000 people every year. Most of those affected are children, adolescents and young adults under age 25.

Though widely eradicated in nations such as the United States, rheumatic fever remains prevalent in developing countries, including those in sub-Saharan Africa. Recent studies have shown that, if detected soon enough, a regular dose of penicillin may slow the development and damage caused by RHD. But it has to be detected.

The hold-up in the field

Diagnosing RHD requires an ultrasound image of the heart, known as an echocardiogram. However, ultrasound in general is very variable as an imaging modality. It is full of texture and noise, making it one of the most challenging to interpret visually. Specialists undergo significant training to read them correctly. However, in areas where RHD is rampant, people who can successfully read these images are few and far between. Making matters worse, the devices used in these low resource settings have their own levels of varying quality, especially when compared to what is available in a well-resourced hospital elsewhere.

The research team hypothesized that a novel, automated deep learning-based method might detect successfully diagnose RHD, which would allow for more diagnoses in areas where specialists are limited. However, to date, machine learning has struggled the same way the human eye does with noisy ultrasound images.

Children’s National leads the way

Using approaches that led to successful objective digital biometric analysis software for non-invasive screening of genetic disease, researchers at the Sheikh Zayed Institute for Pediatric Surgical Innovation, including medical imaging scientist Pooneh Roshanitabrizi, Ph.D., and Marius Linguraru, D.Phil., M.A., M.Sc., principal investigator, partnered with clinicians from Children’s National Hospital, including Craig Sable, M.D., associate chief of Cardiology and director of Echocardiography, and cardiology fellow Kelsey Brown, M.D., who are heavily involved in efforts to research, improve treatments and ultimately eliminate the deadly impacts of RHD in children. The collaborators also included cardiac surgeons from the Uganda Heart Institute and cardiologists from Cincinnati Children’s Hospital Medical Center.

Dr. Linguraru’s team of AI and imaging scientists spent hours working with cardiologists, including Dr. Sable, to truly understand how they approach and assess RHD from echocardiograms. Building the tool based on that knowledge is why this tool stands apart from other efforts to use machine-learning for this purpose. Orienting the approach to the clinical steps of diagnosis is what led to the very first deep learning algorithm that diagnoses mild RHD with similar success to the specialists themselves. After the platform was built, 2,136 echocardiograms from 591 children treated at the Uganda Heart Institute fed the learning algorithm.

What’s next

The team will continue to collect data points based on clinical imaging data to refine and validate the tool. Ultimately, researchers will look for a way that the algorithm can work directly with ultrasound/echocardiogram machines. For example, the program might be run through an app that sits on top of an ultrasound device and works on the same platform to communicate directly with it, right in the clinic. By putting the two technologies together, care providers on the ground will be able to diagnose mild cases and prescribe prophylactic treatments like penicillin in one visit.

The first outcomes from the program were showcased in a presentation by Dr. Roshanitabrizi at one of the biggest and most prestigious medical imaging and AI computing meetings — the 25th International Conference on Medical Image Computing and Computer Assisted Intervention (MICCAI).

illustration of the brain

How the circadian clock could help the brain recover after injury

illustration of the brain

A type of brain cell that can renew itself is regulated by circadian rhythms, providing significant insights into how the body’s internal clock may promote healing after traumatic brain injuries (TBI).

A type of brain cell that can renew itself is regulated by circadian rhythms, providing significant insights into how the body’s internal clock may promote healing after traumatic brain injuries (TBI), according to new research from Children’s National Hospital.

Released in the latest issue of eNeuro, the findings open new avenues of investigation for future TBI therapies. These injuries are currently managed only with supportive care and rehabilitation, rather than targeted drug treatment options. The findings also underscore the importance of addressing circadian disturbances to help injured brains heal.

Many of the body’s cells follow a 24-hour rhythm driven by their genes known as the circadian clock. The Children’s National research team found that a relatively newly discovered type of brain cell ­– known as NG2-glia, or oligodendrocyte precursor cells ­– also follow a circadian rhythm. This cell type is one of the few that continually self-renews throughout adulthood and is notably proliferative in the first week after brain injuries.

“We have found evidence for the role of this well-known molecular pathway – the molecular circadian clock – in regulating the ability for these NG2-glia to proliferate, both at rest and after injury,” said Terry Dean, M.D., Ph.D., critical care specialist at Children’s National and the lead author of the paper. “This will serve as a starting point to further investigate the pathways to controlling cellular regeneration and optimize recovery after injury.”

Sometimes called “the silent epidemic,” TBI afflicts an estimated 69 million people worldwide each year, with injuries ranging from mild concussions to severe injuries that cause mortality or lifelong disability. In the United States alone, approximately 2.8 million people sustain TBI annually, including 630,000 children. TBI is the leading cause of death in people under age 45, and those who survive are often left with persistent physical, cognitive and psychological disabilities.

Yet no targeted therapies exist for TBI, creating a critical need to uncover the mechanisms that could unlock the regeneration of these NG2-glia cells, which are the most common type of brain cell known to proliferate and self-renew in adult brains.

“It is essential for researchers to know that cell renewal is coordinated with the time of day,” said Vittorio Gallo, Ph.D., interim chief academic officer and interim director of the Children’s National Research Institute. “With this knowledge, we can dig deeper into the body’s genetic healing process to understand how cells regulate and regenerate themselves.”

Monika Goyal

Researchers to address pain management inequities with over $4M NIH award

Monika Goyal

Over the years, research led by Dr. Goyal documented racial and ethnic inequities in the ED.

The National Institutes of Health (NIH) awarded Children’s National Hospital with over $4.2 million to address inequities in pain management for children that come into the emergency department (ED).

Why this matters

The ED is a strategic venue for addressing health inequities, where children account for more than 30 million visits annually.

“There are widespread inequities in the quality-of-care delivery for children. Because the factors contributing to these disparities arise on both individual and systemic levels, it is imperative that we develop interventions to achieve health equity,” said Monika Goyal, M.D., M.S.C.E., associate chief of Emergency Medicine at Children’s National Hospital and recipient of the award.

Over the years, research led by Dr. Goyal documented racial and ethnic inequities in the ED management of pain among children with long bone fractures and appendicitis and disparities in the management of pain reduction for minoritized children.

“These findings indicate there are differences in health care quality even in settings with universal access,” she added.

The research goal

Dr. Goyal and her team aim to mitigate, and ultimately eradicate, health care inequities through evidence-based interventions. With the research support from the NIH, the team will advance this goal by:

  • Measuring how clinician (physician and nursing) implicit bias is associated with quality of care for pain management in children presenting to the ED with appendicitis or long bone fractures.
  • Using a stakeholder-engaged approach to develop patient- and caregiver-informed quality metrics related to pain management.
  • Develop and measure the impact of ‘Equity Report Cards’ and electronic health record (EHR)-embedded clinical decision support (CDS) tools to mitigate inequities in care delivery.

The bottom line

Most research to date has focused on documenting disparities. This research has the potential to move the needle in equity research by developing and testing interventions that seek to eradicate inequities in care delivery.

Cancer cells

Searching for the key to treating neuroblastoma tumors in kids

Cancer cells

Jianhua Yang, Ph.D., has dedicated his research to finding the molecular mechanism of neuroblastoma development and is working to develop novel therapeutics.

There continues to be an urgent need to identify novel therapies for childhood cancers. Neuroblastoma (NB) is the most common malignant solid tumor in children and contributes to more than 15% of all pediatric cancer-related deaths. Despite strides made in chemotherapy treatment over the past 30 years, NB largely remains an incurable disease. That’s why Jianhua Yang, Ph.D., associate professor and research faculty at the Center for Cancer and Immunology Research at Children’s National Hospital, has dedicated his research to finding the molecular mechanism of NB development and is working to develop novel therapeutics to target molecules he and his team identify in the lab.

Q: What has driven you to do this research?

A: In order to design better and potentially more effective NB treatment approaches, we must further understand the mechanism that activates NB development. We don’t know what that mechanism is yet, and that’s what we’re working to unlock. I felt with my training in cell biology and immunology, I could use that background to help develop novel therapies.

The research is hard and can often times feel frustrating. But I feel I’m working on something that has the potential to make a huge difference. I tell the researchers I work with that you have to really believe in what we’re doing. We’re doing something very different. Before I moved to D.C. to join Children’s National, I sent a text to a former mentor to let him know I was joining the team here to continue my work. His reply said, “I’ve always had confidence in you,” and it’s that type of encouragement that drives me to keep going.

Q: What is your current focus in this area?

A: Specifically, we’re working on two targets right now:

  1. To define the role and regulation of CaM kinase-like vesicle-associated (CAMKV) in NB development and examining the therapeutic potential of CAMKV kinase inhibition for treating NB in pre-clinical models. We’ve found that CAMKV is highly expressed in NB tumor samples and its kinase activity is required for tumor growth. So, if we knock out this gene, tumor cells will die. We’re studying how it is being activated, and if we can find out what causes it, we can find a way to inhibit its activation. Targeting CAMKV is a novel concept for treating NB. CAMKV kinase inhibitors may serve not only as stand-alone therapies but also as effective adjuncts to current chemotherapeutic regimens treating this aggressive pediatric malignancy.
  2. To define the role and regulation of transmembrane protein 108 (TMEM108) in NB development and examine the therapeutic potential of TMEM108 functional blockade for treating NB in pre-clinical models. Evolutionarily, in human genome it has no other family member, it’s a loner. And if you knock it out in NB tumor cells, tumor cells will die. We’re learning how it functions through our basic research, which is quite difficult. But we’re thinking if we can find the antibody to bind to it and block its function, we could stop the tumor from growing or even cause the tumor to die.

Q: What excites you about doing this work within the Center for Cancer and Immunology Research?

A: At Children’s National, I’ll be able to combine my work with the incredible work in immunotherapy that Drs. Catherine Bollard and Muller Fabbri are doing. I’m excited to be here to have that strong collaboration with their labs to develop new therapies.

In the next 5 years, I feel we’ll be able to identify good blocking antibodies that we can then test combinations of to see how it blocks tumor growth. If we can find ways to combine that antibody therapy with traditional chemotherapy options, we can achieve a real cure for NB.

Learn more about the Center for Cancer and Immunology Research.

Brain illustration

Paving the way toward better understanding and treatment of neonatal brain injuries

Brain illustration

The Gallo Lab’s latest research finds reduced expression of Sirt2 in the white matter of premature human infants and characterizes its role in white matter of the brain in normal conditions and during hypoxia.

Changes in myelination due to diffuse white matter injury are a common consequence of premature birth and hypoxic-ischemic injury due to asphyxia of sick term-born newborns. Hypoxic damage during the neonatal period can lead to motor disabilities and cognitive deficits with long-term consequences, including cerebral palsy, intellectual disability or epilepsy, which are often due to cellular and functional abnormalities.

The Gallo Lab, within the Center for Neuroscience Research at Children’s National Hospital, is focused on studying postnatal neural development and the impact of injury and disease on development and regeneration of neurons and glia. Their latest research, published in Nature Communications, finds reduced expression of Sirt2 in the white matter of premature human infants (born earlier than 32 weeks of gestation) and characterizes its role in white matter of the brain in normal conditions as well as during hypoxia.

What it means

The lab previously identified Sirt1 as important for the proliferative regenerative response of oligodendrocyte progenitor cells in response to chronic neonatal hypoxia. This new study characterizes the function of Sirt2 and finds that it acts as a critical promoter of oligodendrocyte differentiation during both normal brain development and after hypoxia.

It’s likely this reduced expression of Sirt2 contributes to the arrest in oligodendrocyte maturation and myelination failure seen in extremely low gestational age neonates. Therefore, targeting Sirt2 may be an opportunity to capture the early and small window of opportunity for therapeutic intervention.

How this moves the field forward

Sirtuins have been shown to play crucial therapeutic roles in various diseases, including aging, neurodegenerative disorders, cardiovascular disease and cancer. Identifying Sirt2 as a major regulator of white matter development and recovery and increasing the understanding of its protein and genomic interactions opens new avenues for Sirt2 as a therapeutic target for white matter injury in premature babies.

Why we’re excited

Interestingly, the team found that overexpression of Sirt2 in oligodendrocyte progenitor cells, but not mature oligodendrocytes, restores oligodendrocyte populations after hypoxia through enhanced proliferation and protection from apoptosis. This is exciting because:

  • It tells us that Sirt2 expression is very important for the transition from progenitor to differentiated oligodendrocyte.
  • It’s the first report, to the team’s knowledge, of Sirt2 regulating cell survival of oligodendrocytes.

Read more in Nature Communications

Healthcare icons

Children’s National Innovation Day aims to advance pioneering pediatric life science projects

Healthcare icons

Children’s National Research & Innovation Campus’ Innovation Day will feature life science projects focused on improving pediatric care.

Pioneering life science projects focused on improving pediatric care will be on display at the Children’s National Research & Innovation Campus when the hospital hosts its 2022 Innovation Day on Friday, August 26. Hosted by Children’s National Innovation Ventures, the program’s goal is to showcase life sciences and healthcare projects that are mature enough to look for a co-developer, strategic partner, investor or licensing vehicle.

“For us, a successful Innovation Day means we are able to match these entrepreneurs with the strategic partner they need at this stage of their device development journey,” says Kolaleh Eskandanian, Ph.D., M.B.A., P.M.P., vice president and chief innovation officer at Children’s National Hospital and executive director of the Sheikh Zayed Institute for Pediatric Surgical Innovation.

“Data continues to show that the national Capital Region (NCR) remains one of the most robust life sciences and technology hubs in the country with no shortage of visionary leaders. There is no better place to conduct this important work as we seek more ways to advance pediatric medical technologies to improve health outcomes.”

A total of 17 projects will be showcased at the event, with each having up to 10-minute window to make their presentation. All attendees will be provided a survey, enabling valuable feedback for presenters as they look to take their next strategic step on the pathway to further development and commercialization.

In addition to presenting projects, the 2022 Innovation Day will also feature startup companies whose mission is aligned with Children’s National’s quest to bring novel pediatric medical products to patients and families. Throughout the day, attendees will have the opportunity to meet with the hospital’s researchers, academic entrepreneurs and prominent stakeholders in the life science and healthcare innovation ecosystem in the region. Interested investors and strategics can also request one-on-one meetings with startups and research teams.

Eskandanian, who also serves as the executive director of the FDA-funded National Capital Consortium for Pediatric Device Innovation (NCC-PDI), notes that accelerating this pathway to commercialization for pediatric products will bring more viable technologies to market, an important step in addressing the ongoing development disparity in innovations developed for children versus adults.

“For too long, children have been left behind in the development and commercialization of medical products and we remain committed to altering the trend,” Eskandanian says. “Children’s National’s Innovation Ventures team is working closely with the presenting innovators to provide any and all support that we can to get these products to the next stage.”

Registration for Children’s National’s 2022 Innovation Day is currently open. Those interested in attending the day-long showcase can register at https://conta.cc/3CrAfTl.

Supporting the progress of pediatric innovators is a key focus of the new Children’s National Research & Innovation Campus, a one-of-its-kind ecosystem that drives discoveries that save and improve the lives of children. On a nearly 12-acre portion of the former, historic Walter Reed Army Medical Center in Northwest Washington, D.C., Children’s National has combined its strengths with those of public and private partners, including industry, universities, federal agencies, start-up companies and academic medical centers. The campus provides a rich environment of public and private partners which, like the NCC-PDI network, helps to bolster pediatric innovation and commercialization.

Researchers hope to uncover puzzling mechanism of vision loss in kids with $2.7M DOD award

The Department of Defense Neurofibromatosis Research Program awarded Children’s National Hospital $2.7M to better understand a pediatric tumor as a blinding disease. The study design will specifically focus on targeting immune responses during the development of the tumor as a means to prevent or preserve vision before the tumor-associated irreversible neurological damage.

Why it matters

Nearly 20% of individuals with neurofibromatosis type 1 (NF1) develop tumors along the anterior visual pathway, involving optic nerves, optic chiasm and optic tracts, known as NF1-associated optic pathway gliomas (NF1-OPGs). This tumor is mainly diagnosed in children younger than seven years, which could lead to a lifelong disability.

NF1-OPGs often grow extensively along the optic pathway, and surgery is a high-risk treatment option. Consequently, human tumor tissues are rarely available for research.

Why we’re excited

“We are very excited about this research because, if successful, we will provide a strategy to treat patients with NF1-OPGs before visual impairment becomes irreversible,” said Yuan Zhu, Ph.D., scientific director and Gilbert Family Endowed professor at the Gilbert Family Neurofibromatosis Institute and senior investigator at the Center for Cancer and Immunology Research, both part of Children’s National. “We combine the expertise of glioma at the Children’s National and retinal biology at the NIH/NEI.”

The research will combine the synergistic expertise between Zhu on NF1 and OPG using pre-clinical models and Drs. Han-Yu Shih and Wei Li at the National Eye Institute of the National Institutes of Health (NIH/NEI) on retinal biology and immunology.

What’s unique

To shed light on the chemical signaling that occurs in the optical nerve with the presence of gliomas, the research approach will have three aims:

  • Isolate and characterize this abnormally infiltrating inflammatory cells and perform multi-omics experiments, including sophisticated genomic, epigenomic and transcriptomic assays, to study them during OPG initiation and progression.
  • Prevent or alleviate OPG-associated nerve damage, RGC death and vision loss.
  • Develop a novel model using the newly established genetic system to identify signals that induce inflammatory responses.
Robert J. Freishtat

Robert Freishtat, M.D., M.P.H., named as Connor Family Professor in Research and Innovation

Robert J. Freishtat

“The Connor Family Professorship will allow my team to act rapidly upon potential transformative discoveries for children’s health” said Dr. Freishtat. “There is no greater honor than to carry the Connor family name as we follow in Dr. Edward Connor’s footsteps to drive breakthroughs that will benefit all children. I am eternally grateful for their support.”

Children’s National Hospital named Robert Freishtat, M.D., M.P.H., as the first Connor Family Professor in Research and Innovation at Children’s National Hospital.

Dr. Freishtat serves as Chief Biotechnology Officer and Senior Investigator, Center for Genetic Medicine Research in the Children’s National Research Institute. He is also a Professor with Tenure in Pediatrics, Emergency Medicine, Genomics and Precision Medicine at The George Washington University School of Medicine and Health Sciences.

About the award

Dr. Freishtat joins a distinguished group of 42 Children’s National physicians and scientists who hold an endowed chair. Professorships at Children’s National support groundbreaking work on behalf of children and their families and foster new discoveries and innovations in pediatric medicine. These appointments carry prestige and honor that reflect the recipient’s achievements and donor’s forethought to advance and sustain knowledge.

Dr. Freishtat is an internationally recognized translational researcher. He is the principal investigator for multiple international collaboratives studying intercellular communication in organ injury/repair. He has authored or co-authored more than 140 articles and book chapters in the fields of lung injury, asthma, obesity, exosomes and emergency medicine.

In 2020, Dr. Freishtat founded the Office of Biotechnology at Children’s National to fast-track novel ideas and forge industry partnerships so solutions can reach patients sooner.

“The Connor Family Professorship will allow my team to act rapidly upon potential transformative discoveries for children’s health” said Dr. Freishtat. “There is no greater honor than to carry the Connor family name as we follow in Dr. Edward Connor’s footsteps to drive breakthroughs that will benefit all children. I am eternally grateful for their support.”

The Connor family, through their vision and generosity, are ensuring that Dr. Freishtat and future holders of this professorship will launch bold, new initiatives to rapidly advance the field of pediatric research and innovation, elevate our leadership and improve the lifetimes of children.

About the donors

Dr. and Mrs. Connor are longtime donors and members of the Children’s National community. Dr. Connor previously served as Director of the Office of Innovation Development and a member of the executive team at the Clinical and Translational Science Institute. His institutional involvement continues through service, formerly as a board member for the Children’s National Research Institute and more recently as a member of the Research, Education, and Innovation Advisory Board. Mrs. Connor, a clinical microbiologist and educator, has worked throughout her career creating a legacy of young people in science.

“We strongly believe in the power of academic entrepreneurship to improve the health and wellbeing of children. This endowment is our way of supporting Children’s National’s work in research and innovation and recognizing Dr. Freishtat’s leadership as an outstanding physician-scientist and role model in clinical and translational pediatrics.”

 

a quote from Joelle Simpson

Five leading children’s hospitals secure funding to enhance future pandemic readiness

a quote from Joelle Simpson A group of children’s hospitals from across the country will coordinate on the response to future pandemics and other disasters through a new $29 million grant from the Health Resources and Services Administration (HRSA). The group, known as the Pediatric Pandemic Network (PPN), will focus on the unique needs and challenges to children during pandemics and disasters, ensuring that health equity is at the forefront of emergency planning.

The five hospitals are:

  • Children’s National Hospital in Washington, D.C. (lead institution)
  • Ann & Robert H. Lurie Children’s Hospital of Chicago
  • University of Alabama at Birmingham Department of Pediatrics at Children’s of Alabama
  • Children’s Mercy Kansas City
  • Seattle Children’s

“As the current pandemic has proven to the world, pandemics and public health crises magnify pre-existing environmental, health, social and economic inequities,” said Joelle Simpson, M.D., M.P.H., principal investigator of this grant and division chief of Emergency Medicine and medical director of Emergency Preparedness at Children’s National. “Communities of color not only feel the impact of pandemics and disasters far more severely than others, but also have more difficulty obtaining aid and assistance. If the needs of vulnerable populations are not addressed in emergency planning, the national disaster preparedness strategy could fail for all.”

The hospitals recognize that while the COVID-19 pandemic has been devastating for the entire world, the pediatric population in particular has been challenged by a lack of established coordination among pediatric care providers. In addition to addressing health equity, the funding facilitates the following:

  • Establishing pathways to gather and disseminate research-informed insights into how to care for children in a future pandemic to both medical providers and community organizations.
  • Developing a telehealth infrastructure to support the care of acutely ill children and expand mental health access.
  • Expanding pediatric-focused emergency preparedness and planning with a focus on behavioral health, social support, and educational services, all of which are typically provided by community organizations.

The hub for this grant will be located at the newly opened Children’s National Research & Innovation Campus – the site of the former Walter Reed Army Medical Center in Washington, D.C. Work will take place in the renovated Armed Forces Institute of Pathology, where past investigators made seminal discoveries in infectious diseases and pandemics. The former campus was named after Walter Reed because of his work around discovering the cause and prevention of outbreaks of yellow fever. This modern-day team of physician researchers intends to make equally important contributions to future pandemics and other disasters to help preserve the health of our nation’s children.

In September 2021, HRSA launched the Regional PPN by funding five pediatric hospitals to support the planning and preparation of children’s hospitals to respond to a global health threat. This new grant doubles the size and reach of the network in order to benefit all children in the nation.

Marshall and Karen Summar

Marshall Summar, M.D., receives Lifetime Achievement Award for rare disease work

Marshall Summar

For making strides to improve the lives of the rare disease community, the National Organization for Rare Disorders (NORD®) recognized Marshall Summar, M.D., with a Lifetime Achievement Award.

For making strides to improve the lives of the rare disease community, the National Organization for Rare Disorders (NORD®) recognized Marshall Summar, M.D., chief of the Division of Genetics and Metabolism and the director of the Rare Disease Institute at Children’s National Hospital, with a Lifetime Achievement Award.

This award honors individuals for outstanding career-long achievement on behalf of the rare disease community and commitment to improving the lives of those affected by rare diseases. It has been presented only a few times over NORD’s nearly 40-year history, most recently to former NIH Director Francis Collins, M.D., Ph.D., in 2015 and to clinician and researcher Robert Campbell, M.D., of Children’s Hospital of Philadelphia in 2018.

“I am honored to receive this award from NORD. It is so special to be recognized by the leading rare disease organization. This award comes from the work of so many people over the years, particularly our great team at Children’s National,” said Dr. Summar. “This acknowledgement of what we have done to date just gets me more excited about the future!”

Dr. Summar developed and launched the world’s first Rare Disease Institute at Children’s National in 2017, which is now located on the Children’s National Research & Innovation Campus, a first-of-its-kind pediatric research and innovation hub in Washington, D.C.

The institute, which includes the largest clinical group of pediatric geneticists in the nation, focuses on developing the clinical care field of the more than 8,000 rare diseases currently recognized and advancing the best possible treatments for children with these diseases.

Marshall and Karen Summar

Marshall and Karen Summar.

“Dr. Summar’s passion for serving patients is at the core of everything he does,” said Debra Regier, M.D., medical director of the Rare Disease Institute. “His mentorship for the next generation of medical and biochemical geneticists has become his legacy.”

The work Dr. Summar has done over the course of his career has resulted in new drugs in FDA trials for patients with congenital heart disease and premature birth. He also holds more than 60 patents and has published more than 160 peer-reviewed research studies.

“Beginning with his work as a clinician in the 1980s, Dr. Marshall Summar has spent a career forging partnerships, advocating at the highest level and developing new ways to treat rare disease patients,” said Peter L. Saltonstall, president and CEO of NORD.

“Dr. Summar served on the NORD Board of Directors for nine years, including six years as Chairman, and so we at NORD have been lucky enough to have years of firsthand experience with his leadership, community-building and innovation efforts in the rare disease field. This award is a recognition and appreciation for sustained excellence, including critical work with organizations such as the American College of Medical Genetics, the National Institutes of Health, NORD, and the Rare Disease Institute at Children’s National. For decades of commitment to families and organizations combating rare diseases, NORD is thrilled to present the Lifetime Achievement Award to Dr. Marshall Summar at the 2022 Rare Impact Awards,” Saltonstall added.

Learn more about the Rare Disease Institute at Children’s National.

Drs. Bollard and Hanley

Research into a new way to combat solid tumors earns part of a $25M award

Drs. Bollard and Hanley

Catherine Bollard, M.D., M.B.Ch.B., and Patrick Hanley, Ph.D.

Children’s National Hospital has developed multi-antigen specific T cells that have shown success in pre-clinical models in attacking pediatric solid tumors. Now the promising area of research earned a major boost from the Cancer Grand Challenges — founded in 2020 by the two largest funders of cancer research in the world – Cancer Research UK and the National Cancer Institute in the U.S.

This award supported the foundation of NexTGen, a team of scientists and clinicians with expertise in immunology, proteomics, mathematics and more, across eight institutions in the U.S., U.K. and France. Catherine Bollard, M.B.Ch.B, M.D., director of the Center for Cancer and Immunology Research at Children’s National, and Martin Pule, M.D., clinical associate professor at the University College of London are the co-leads of this effort.

The NexTGen team is one of four Cancer Grand Challenges’ new teams, representing a total investment of $100M to diverse, global teams to take on some of the toughest challenges in cancer research. NexTGen will create a new approach that performs clinical and basic research together to facilitate real-time knowledge exchange from the lab to the clinic and back again.

While the more widely known CAR T-cells have made tremendous progress for patients with B-cell leukemias, lymphomas and other blood cancers, the CAR T-cell field has not made the same impact for adult and pediatric solid tumors.

“A tumor cell is very clever because it tries to hide from the immune system by deleting or down regulating targets that the T cell is directed towards,” said Dr. Bollard.

Dr. Bollard further discusses the importance of having patient voices during the decision-making process in this quest, her hopes for their program and the concept of the combining tumor antigen-specific T cells with CAR-T cells that her team will develop.

Q: Can you explain the NexTGen vision?

A: The overall vision is that we will have developed the next generation of cell therapies to cure children with refractory solid tumors by the end of the five years. It is important to move the field forward, so we wanted to be innovative in our approach to this grand challenge for these children who have no other therapeutic options left.

Q: What are the most three important components of this project?

A: First, science and diplomacy played a significant role in bringing in the right set of investigators from diverse scientific backgrounds. What started as a conversation using the universal language of science, it quickly became an international project to address this complex issue. Second, we worked very hard with our patient advocates during the writing process, and they will be working side by side with the investigators at the bench and clinic. Third, we were the only group to have clinical trials in our proposal starting very early in the grant funding period, which is unprecedented.

Q: Can you describe NexTGen’s research model?

A: From our experience in leukemia, we know that progress is greatly accelerated if discovery occurs hand-in-hand with clinical development. Therefore, unlike classical programs where years of pre-clinical discovery and developmental work is required before the clinical translation, we will take a non-conventional non sequential approach.

Specifically, in the NexTGen Program, clinical development will start early with three cutting-edge clinical studies evaluating engineered T-cell technologies that we have recently developed understanding that there are some questions that can ONLY be answered in the clinic. To that end, clinical and translational data from these clinical trials will be able to feed into and enrich the discovery and pre-clinical science throughout the NexTGen Program in a circular fashion to promote this research program that goes from bedside to bench and back.

Q: How is Children’s National leading the way?

A: Children’s National is leading one of the three clinical trials that combine our non-gene engineered tumor antigen-specific T-cell platform with gene engineered T cells to generate a novel T-cell therapy against relapsed /refractory solid tumors. Combining tumor antigen specific T cells with the CAR T-cell platform represents a novel concept that may have more potency against these hardest to treat tumors in children.

Q: Why is it so important to include the patient voice during the discussion and decision making?

A: Because we are also physicians and scientists, we do not forget the patient and their families. Thus, we have a robust patient advocacy group embedded in this vision. The group will co-develop summaries explaining the challenges NextGen will address, how this will be achieved and how results will be used, with major input in clinical trial design and consent documents as well as key input into how patient tissue samples can be used to facilitate research discoveries. The patient advocacy team will also help find broad representation from multiple geographical locations of advocates with lived experience of different cancer types, including bereaved relatives and cancer survivors. These and many more strategies applied with patient advocacy groups will elevate the call for a broader and accelerated adoption of CAR-T clinical trials to broaden access to all patients.

Q: What excites you most about this?

A: What excites me the most is working with this incredible group of scientists, physicians and patient advocates all with rich and deep expertise who bring together an extensive and diverse knowledge base. The fact that we will be all working together toward a common goal of curing pediatric solid tumors in the next five to 10 years is extraordinarily energizing. This sizeable international collaboration comprises the right talent to get this done. It is also highly exciting to simultaneously have three clinical trials running in parallel with the discovery science and the pre-clinical work. I am extremely optimistic that we will realize NexTGen’s vision to bring next generation engineered T-cell therapies to the routine care of children with solid tumors within a decade.

Dr. Bollard and her laboratory

Catherine Bollard, M.D., M.B.Ch.B., selected to lead global Cancer Grand Challenges team

Dr. Bollard and her laboratory

Cancer Grand Challenges NexTGen team members (left to right): Amy Hont, M.D., AeRang Kim, M.D., Nitin Agrawal, Ph.D., Catherine Bollard, M.D., M.B.Ch.B., Conrad Russell Cruz, M.D., Ph.D., Patrick Hanley, Ph.D., and Anqing Zhang.

A world-class team of researchers co-led by Catherine Bollard, M.D., M.B.Ch.B., director of the Center for Cancer and Immunology Research at Children’s National Hospital, has been selected to receive a $25m Cancer Grand Challenges award to tackle solid tumors in children. Cancer Grand Challenges is a global funding platform, co-founded by Cancer Research UK and the National Cancer Institute in the U.S., that supports a community of diverse, global teams to come together, think differently and take on some of cancer’s toughest challenges.

The Cancer Grand Challenges NexTGen team, co-led by University College London’s Martin Pule, M.D., will be working to develop next-generation cell therapies for children with solid cancers. Cancer is a leading cause of death by disease in children worldwide. Although survival has increased for some pediatric cancers, such as blood cancers, survival for some solid tumors has seen little improvement for more than 30 years. The team hopes to build a much deeper understanding of childhood cancers and develop and optimize novel therapies for children with solid tumors, ultimately hoping to improve survival and diminish the lifelong toxicities often experienced by survivors.

“With our Cancer Grand Challenge, we hope to bring next-generation CAR T-cell therapies to children with solid tumors,” said Dr. Bollard. “What excites me most is the energized, passionate group of people we’ve brought together to take this challenge on. Big problems remain to be addressed, but we believe they can be solved, and that we’re the team to solve them.”

“NexTGen represents crucial and overdue work. It has hope written all over,” said Sara Wakeling, patient advocate on the team and CEO and co-founder of Alice’s Arc, a children’s charity for rhabdomyosarcoma. “NexTGen hopes to transform the way these aggressive solid tumors are treated with less toxic side-effects, giving the children a real chance at growing up and realizing their potential. I’m so proud to be part of this exceptional team of scientists, clinicians and advocates who want to change the story for those diagnosed.”

The NexTGen team unites scientists and clinicians with expertise in immunology, proteomics, mathematics and more, across eight institutions throughout the U.S., U.K. and France. The Children’s National investigators that will also join are:

  • Nitin Agrawal, Ph.D., associate professor in the Center for Cancer and Immunology Research at Children’s National.
  • Conrad Russell Cruz, M.D., Ph.D.,principal investigator for the Program for Cell Enhancement and Technologies for Immunotherapies at Children’s National.
  • Patrick Hanley, Ph.D., chief and director of the cellular therapy program at Children’s National and leader of the Good Manufacturing Practices laboratory.
  • Amy Hont, M.D., oncologist in the Center for Cancer and Immunology Research at Children’s National.
  • AeRang Kim, M.D., oncologist in The Center for Cancer and Blood Disorders at Children’s National.
  • Holly Meany, M.D., oncologist in The Center for Cancer and Blood Disorders at Children’s National.
  • Anqing Zhang, biostatistician in the Biostatistics and Study Methodology Department at Children’s National.

The team, co-funded by Cancer Research UK, the National Cancer Institute and The Mark Foundation for Cancer Research, aims to bring much needed new treatments to children with solid cancers.

The NexTGen team is one of four new teams announced today as part of Cancer Grand Challenges, representing a total investment of $100m to diverse, global teams to take on some of the toughest challenges in cancer research.

“Cancer is a global issue that needs to be met with global collaboration. This investment in team science encourages diverse thinking to problems that have long hindered research progress,” said David Scott, Ph.D., director of Cancer Grand Challenges, Cancer Research UK. “Cancer Grand Challenges provides the multidisciplinary teams the time, space and funding to foster innovation and a transformative approach. NexTGen is one of four newly funded teams joining a scientific community addressing unmet clinical needs across cancer research.”

Find out more

Cancer Grand Challenges supports a global community of diverse, world-class research teams with awards of £20m/$25m to come together, think differently and take on cancer’s toughest challenges. These are the obstacles that continue to impede progress and no one scientist, institution or country will be able to solve them alone. Cancer Grand Challenges teams are empowered to rise above the traditional boundaries of geography and discipline.

Founded by the two largest funders of cancer research in the world – Cancer Research UK and the National Cancer Institute* in the U.S. – Cancer Grand Challenges aims to make the progress against cancer we urgently need. Cancer Grand Challenges currently supports more than 700 researchers and advocates across 10 countries, representing 11 teams are supported to take on 10 of the toughest challenges in cancer research.

The Cancer Grand Challenges NexTGen team, announced June 16, 2022, is taking on the initiative’s Solid Tumours in Children challenge. It is led by Dr. Bollard (Children’s National) and Dr. Pule (University College London), along with 23 co-investigators and 7 patient advocates, and is spread across eight institutions across the U.S., U.K. and France: Cardiff University; Children’s Hospital of Philadelphia; Children’s National Hospital; INSERM; the Institute of Cancer Research; Stanford Medicine; Stanford University; University College London. The Cancer Grand Challenges NexTGen team is funded by Cancer Research UK, the National Cancer Institute in the U.S. and The Mark Foundation for Cancer Research.

*The National Cancer Institute is part of the National Institutes of Health.