Funded Projects

This team aims to be the first to study the cellular and molecular impact of traumatic brain injury by studying genetic material in human cerebrospinal fluid. This will help clinicians and researchers ID markers of brain resilience after injury, and ultimately improve treatment for severe TBI.

The purpose of this collaborative project is to study neuronal mechanisms associated with social stress. In particular we will test whether the energy producing systems, known as mitochondria, in a specific set of brain cells are important to confer resilience to stressful stimuli. This research may lead to treatments of stress and anxiety disorders. 

Our ability to detect and interpret sounds relies on specialized sensory cells within the snail-shaped hearing organ of the inner ear—the cochlea. These hair cells sense physical movement and then convert that mechanical stimulus into a biological signal that we perceive as sound. These mechano-sensory cells perform this task within microseconds and can do so for sub-nanomechanical stimuli.

My proposed visit to the Van De Ville lab is centered on the idea to expand our methods beyond brain tumors to other neurological diseases using the Van De Ville lab’s expertise in neuro-imaging. Imaging genomics has been focused mainly on oncology; however, other neurological diseases can be studied in the same way.

Brain data analyses involves many steps and every step is prone to errors and uncertainties. Ignoring uncertainties can potentially leading to overconfident conclusions. To improve reproducibility it is important to propagate errors throughout the anlaysis.

Humans naturally learn to generate and process complicated sequential patterns. For example, a concert pianist can learn an enormous repertoire of memorized music. In neuroscience, it is widely thought that synaptic plasticity – the process by which the connections between neurons change response to experience – underlies such remarkable behavior.

Human movement results from the coordination of muscles, tendons, joints, and other physiological elements.

Although you’re aware of the light that you see, light also affects us in ways that you might not appreciate. These so called “non-image forming” (NIF) pathways were recently discovered, they start in the human eye before projecting to over a dozen brain regions. They modulate aspects of human function including our daily rhythms, our sleep patterns, the way we feel and the way we think.

Schistosomiasis is a parasitic disease second only to malaria in its human health and economic impact on tropical nations.

Using new animal models such as the African killifish, this team aims to develop approaches to predict individual brain aging trajectories early in life based on behaviors that can be modulated to promote healthy memory, executive function and processing speed as well as counter dementia.

This team will explore the idea that neurotoxic protein aggregates seen in neurodegenerative disorders act at the synaptic connections between cells, and that resilience against these disorders may come from natural synapse-supporting factors that could be transformed into new forms of therapy.

This team aims to better understand how Parkinson's disease attacks the brain's basic motor programs and to spawn novel therapies against the disease using gene-editing technology.

This team proposes the first comprehensive study of how mitochondrial DNA is related to cognitive function and susceptibility to dementia in a diverse population of over 11,000 adults. The outcomes of this study will provide insight into possible racial disparities in brain health.

This team plans to study whether changes in neurons in the midbrain that regulate sleep, wakefulness, and immunity could contribute to aging and neurodegeneration. If successful, this information could rescue deficits in sleep and restore a normal immune profile.

This team plans to map how age-related dysfunction of cellular waste disposal in lysosomes could lead to neurodegenerative diseases, potentially laying the foundation for a map of organelle function in the brain.

This team aims to define a network of genes that contribute to stress resistance in neurons and identify how it could be activated to enhance brain resilience and protect against neurodegenerative disease.

This team aims to discover whether the brain’s endocannabinoid system is dysregulated during aging, triggering inflammation via molecules called prostaglandins. If so, a drug that decouples these systems might restore a youthful brain state and rescue cognitive function.

This team will study the brains of individuals who lived past ninety with their cognitive function intact, using advanced tissue imaging and computer science to understand mechanisms of resilience that could slow neurodegeneration and preserve brain health.