MHFP Translational Research Grant Program

 

Deadline for Submission: April 1, 2024

Project Period: Maximum 12 months from July 1, 2024 to June 30, 2025

Who is Invited to Apply: Full time faculty, Residents, Post-Doctoral Researchers

Research Focus: Proposals that target the biology, diagnosis, treatment or outcome of patients with central nervous system anomalies.

Proposals should focus on the above areas and can be either basic, translational or purely clinical in nature. In addition, patient or family advocacy related projects are also welcome. Applications are due at midnight, April 1, 2024. Decisions about winning proposals will be made late April 2024.  All awardees will be presented at the Annual MHFP Research Symposium in the spring of 2024.

Amount of Funding: Up to $20,000 per proposal

Proposals will be evaluated based on:

  • Innovation
  • Feasibility of completion within the allotted time and budget
  • Potential impact on the biology, diagnosis, treatment or outcome of patients with central nervous system anomalies
  • Alignment with the overall goals of the MHFP

2023 MHFP Translational Grant Winners

Dr. Russell Taylor

Dr. Russell Taylor

Post-Doctoral Scholar

Dr.  Taylor’s work focuses on the gene CACNA1C, which is implicated in a range of congenital disorders, occurring in brain, cardiac and other tissues. This gene is classically understood to produce a voltage-gated ion channel, Cav1.2, but recent work from my lab has established that it also produces a transcription factor, CCT.  His working hypothesis is that dysregulation of this transcription factor CCT is at least partially responsible for the congenital anomalies seen within patients.

Dr. Runwei Yang

Dr. Runwei Yang

Post-Doctoral Scholar

Dr. Yang’s work focuses on Pathogenic SYNGAP1 mutations cause autism, epilepsy, and intellectual disability. His previous study developed splice-switching oligonucleotides (SSOs) targeting SYNGAP1 nonsense-mediated decay in human neurons and brain organoids, holding the possibility for treating SYNGAP1-associated disorders. This project will test the efficacy and toxicity of SSOs in a mouse model of SYNGAP1 haploinsufficiency.