For Scientists
RSZ TNC Pilot Research Grants
Each year, the Rosamund Stone Zander Translational Neuroscience Center sponsors up to four $100,000 awards to BCH investigators for one-year pilot projects, with the possibility for a renewal the subsequent year.
The Rosamund Stone Zander Translational Neuroscience Center (RSZ TNC) Pilot Research Grants support translational research on neurodevelopmental disorders within the domains of Preclinical Research, Drug Discovery, Mechanism-based Therapeutic Development, Translational Biomarkers, and Gene-based Clinical Research and Trials.
Projects that include Equity, Diversity, and Inclusion (EDI) and Community Engagement initiatives will be prioritized such as inclusion of diverse populations and intentional reduction of linguistic, cultural, and economic barriers to research participation.
The first pilot grants were awarded in October 2021. All one-year grant recipients have the opportunity to apply for a second year of funding pending the achievement of explicit milestones.
For more information, please contact TNC@childrens.harvard.edu.
Pilot Research Grant Application
TIMELINE
- Letter of Intent due: June 14, 2024
- Final application due: August 30, 2024
- Awards announced: October 23, 2024
- Funds available: November 1, 2024
Please submit LOI and application to TNC@childrens.harvard.edu.
Eligibility
Applications will be accepted from all faculty of Boston Children’s Hospital (employed by BCH or a BCH affiliated foundation) including Staff Scientists and Instructors (MD, PhD, MD-PhD, or equivalent).
Process
The initial application will consist of a 2-page Letter of Intent (LOI). The LOI will be screened to examine if the proposed research project supports the goals of the RSZ TNC. The screening process will be performed by a multidisciplinary committee representing established researchers at BCH and chaired by the Director of the RSZ Translational Neuroscience Center. Following the initial screening, an invitation will be sent to selected investigators to submit the full application. Please state the domain of research to which your proposal pertains in both the letter of intent and application. Following committee review of final applications, awards will be announced. Funds will be available November 1, 2024.
Letter of Intent
For research proposals, the LOI consists of 1-2 pages of the hypothesis and specific aims. The aims should include a brief description of the research design and methods.
All LOI applications must be submitted to TNC@childrens.harvard.edu. An email confirmation of receipt will be returned to the applicant. The LOI must be submitted by 5 pm on June 14, 2024. Applicants will be notified if invited to submit a full application for review.
2023 Awardees
Translational Biomarkers and Therapeutic Development for Very Young Children Diagnosed with Autism Spectrum Disorder and Co-occurring Anxiety
Susan Faja, PhD and Katherine Driscoll, PhD | Division of Developmental Medicine
This study has the broad goal of evaluating new tools that could be used to improve the clinical care of autistic preschoolers who have co-occurring anxiety diagnoses. It plans to test four measures of the physical response to stressful situations because they have been validated in older autistic and neurotypical children, are feasible for autistic preschoolers, and provide an objective way to measure elevated anxiety prior to intervention or reduced anxiety following intervention. It will collect these measures before intervention to examine whether baseline scores predict intervention response, one month later to ensure that they provide a reliable measure of functioning, and after a behavioral intervention to examine whether changes in scores correspond to intervention response. It will use a behavioral intervention, Being Brave, that has been successfully used to reduce anxiety with autistic preschoolers to examine the four potential measures of anxiety response and regulation.
Discovery of Exosome-Based Biomarkers of Brain Development in Preterm Infants
Christopher Elitt, MD, PhD | Department of Neurology
Zhigang He, PhD | F.M. Kirby Neurobiology Center
Premature birth is a major problem is the United States and worldwide, disproportionally impacting Black and Brown families. Infants born early are at high risk for brain injuries, particularly injuries to the cells (oligodendrocytes) that later produce the insulation (myelin) around the wires in the brain. There is increasing evidence that nutritional deficits may underlie some of these injuries. A major problem is identifying babies in the Neonatal Intensive Care Units who have abnormal brain development from insufficient nutrition or other insults. This study proposes a new approach to discover biomarkers using tiny bubbles (exosomes) that are released by all cells into the blood. The exosomes contain information from the original cell (DNA, RNA, protein) providing a window into brain development. This study has recruited nearly 50 very preterm infants with blood, urine and breast milk samples, as well as obtained a picture of their brain (MRI) when they left the hospital. It will isolate exosomes, count the number of copies of every RNA (instructions from genes to make proteins) and then determine associations of these RNAs with zinc intake, blood zinc concentrations, brain development and body growth. These experiments are likely to discover biomarkers that can be introduced rapidly into the NICU, as well as identify novel genes or pathways critical for brain development and brain injury in preterm infants.
Identifying Novel Network-based EEG Biomarkers of Drug-Resistant and Surgery-Resistant Epilepsy in Children
Eleonora Tamilia, PhD | Division of Newborn Medicine
Alexander Rotenberg, MD, PhD | Department of Neurology
One of the most effective treatments for children with drug resistant epilepsy (DRE) is brain surgery for the removal of the brain area(s) that cause them to have seizures. However, most children with DRE spend precious years trying ineffective drugs while continuing to experience uncontrolled seizures. It would be ideal if we could make the diagnosis of DRE as soon as a patient experience their first seizure/s: However, it is quite unknown how to recognize DRE in a child that presents seizures until the lengthy process of trying several ASMs.
Based on this premise, the first aim of this study is to test whether we can identify drug resistant epilepsy (DRE) using the scalp EEG data recorded very early in the course of the disease, by developing a new methodology that focuses on understanding the brain network. For children with DRE, a significant challenge is to understand whether they will actually benefit from brain surgery or not, since not all patients with DRE can become seizure free with brain surgery. Thus, a second aim of this is to predict whether a patient will benefit from brain surgery by analyzing scalp EEG data recorded before surgery. To this purpose, a new methodology is proposed that estimates whether the area/s of the brain that cause the seizures can be fully targeted during brain surgery (and thus stop the seizures) or not.
Developing Splice-Modulating ASO Strategies For CDKL5 Deficiency Disorder
Timothy Yu, MD, PhD | Division of Genetics and Genomics
Heather Olson, MD, MS | Department of Neurology
Antisense oligonucleotides (ASOs) are promising drugs comprised of 15-20 nucleotide snippets of chemically modified RNA molecules that can be customized to modulate specific gene-splicing patterns for treating genetic disorders. The goal of this project is to develop ASO therapeutic strategy for CDKL5 deficiency disorder (CDD), a severe developmental and epileptic encephalopathy with no established disease modifying therapies. The present authors found at least 20 patients carrying CDKL5 mutations within in-frame exons beyond the kinase domain that are skippable, and more within exons that could be skipped with a combined exon skipping strategy to maintain the reading frame. This study will develop and test ASOs to rescue CDKL5 pathogenic variants by inducing in-frame exon deletions. Successful completion of this project will provide a foundation for launching new interventional clinical trials for CDD.
2022 Awardees
EEG Biomarkers of Preferential Psychostimulant Treatment Response in Children with ADHD.
Anne Arnett, PhD and Eugenia Chan, MD, PhD | Division of Developmental Medicine
This study aims to identify electroencephalography (EEG) and event related potential (ERP) biomarkers of preferential response to two commonly prescribed psychostimulants, among treatment-naïve children with attention deficit hyperactivity disorder (ADHD). The results of this investigation will improve understanding of individual differences in neurobiological mechanisms of ADHD and provide preliminary data for a large-scale clinical trials aimed at developing a precision medicine care model for pharmacological treatment of ADHD.
Circadian Biology of EHMT1 and Sleep-associated Neurodevelopmental Collapse in Kleefstra Syndrome.
Jonathan Lipton, MD, PhD and Siddharth Srivastava, MD | Department of Neurology
The goal of this study is to establish a collaborative translational pipeline to investigate the mechanistic bases for sleep dysfunction in the neurodevelopmental disorder (NDD) Kleefstra Syndrome (KS). It will implement a combination of patient derived cells, circadian rhythm studies, cell biology and biochemistry coupled with clinical assessments of a clinical cohort with Kleefstra Syndrome to investigate the molecular mechanisms by which mutations in the EHMT1 enzyme result in circadian rhythm disruption, and address an important gap in knowledge in child neurology that has eluded mechanistic understanding and therapeutic development.
Novel tools for selective and reversible modulation of neuronal gene expression and brain activity
Xin Tang, PhD | Department of Neurosurgery
This study aims to pioneer a novel approach of silencing brain activities focally and reversibly through injection of small molecule compounds that increase Kir2.1 expression. It seeks to develop two high-throughput screening-compatible assays that are sensitive and robust in detecting endogenous Kir2.1 expression levels in neurons, and will provide a proof-of-concept for a novel focal molecular therapy that has considerable clinical promise to support personalized surgical planning, by enabling clinicians to identify the precise anatomical loci that are safe for surgical removal and efficacious for treating diseases such as epilepsy.
2021 Awardees
Development of Mechanism-Based Therapeutics for Kabuki Syndrome (KS).
Maxwell G. Heiman, PhD and Olaf Bodamer, MD, PhD | Division of Genetics and Genomics
The goal of this study is to leverage Kabuki Syndrome (KS) patient sample repositories and innovative KS animal models to screen a collection of 10,000 drugs and identify those that ameliorate KS symptoms. This will be the first step in providing families with a drug therapy targeted specifically to treating this disorder.
Translational Gene Therapy for DFNB16 Hearing Loss Patients
Jeffrey R. Holt, PhD and Olga Shubina-Oleinik, PhD | F.M. Kirby Neurobiology Center at Boston Children’s Hospital
This study aims to develop methods that allow gene sequences to be divided into two components for delivery into the sensory cells of the inner ear, focusing on the large STRC gene, a common cause hereditary hearing loss in humans. The researchers will test the strategy in human inner ear cells generated from stem cells, anticipating this strategy will help with development of new treatments for genetic hearing loss.
Atlas based Analysis of Abnormalities in Brain Microstructure in Fetuses with Congenital Heart Disease (CHD)
Camilo Jaimes, MD | Department of Radiology
This study will utilize a technique called diffusion MRI to evaluate the brains of fetuses with Congenital Heart Disease. The goal of this project is to create automated and semi-automated image processing pipelines that make this technology scalable and accessible. To do this, the researchers propose the creation of the first set of fetal specific anatomic labels which can be propagated to individual subjects using computational neuroimaging technology. This will allow comparison of large groups of patients, without manually segmenting each individual. The rich anatomic detail of these segmentations will allow identification of emergent differences which can be used to study prenatal brain development in fetuses with a wide array of clinical indications.
Identifying EEG-Based Biomarkers of Language and Cognitive Development in Down Syndrome (DS) and Fragile X Syndrome (FXS)
Carol L. Wilkinson, MD, PhD | Division of Developmental Medicine
Nicole Baumer, MD, MEd | Department of Neurology
This study will collect EEG data from preschool-aged children with Down Syndrome and compare them to typically developing children and as children with Fragile X Syndrome. EEG-markers that are found in this study could be used as an objective way to look at developmental prognosis and will help the development of effective behavioral and medication therapies.