Validating a Comprehensive Neurovascular Systems Architecture of Pericytes to Advance Translational Research in Neurodegenerative Disease Modeling

Partner Description

USC Keck School of Medicine – Neurovascular Research Group
The Neurovascular Research Group at the University of Southern California Keck School of Medicine is internationally recognized for leadership in blood–brain barrier biology, pericyte function, and neurovascular contributions to neurodegenerative and cerebrovascular diseases. The group integrates advanced experimental models with translational neuroscience to uncover mechanisms underlying Alzheimer’s disease, stroke, and related disorders.

Challenge

Pericytes are central regulators of the neurovascular unit, controlling blood–brain barrier integrity, cerebral blood flow, and inflammatory signaling. Dysfunction of these cells is strongly implicated in neurodegenerative and neurovascular diseases. However, existing research was fragmented across reductionist studies focused on isolated pathways or cell types. This fragmentation limited the ability to understand pericyte biology as an integrated system interacting with endothelial cells, astrocytes, and neurons. Moreover, no comprehensive systems-level model of pericyte molecular mechanisms had undergone rigorous, independent, peer-reviewed experimental validation, creating a major barrier to translational adoption.

How CytoSolve® Helped

CytoSolve® collaborated with USC investigators to validate a comprehensive computational systems architecture of pericytes in neurovascular disease. CytoSolve® provided a distributed, mechanistic modeling platform capable of integrating thousands of peer-reviewed molecular pathways governing pericyte contractility, signaling, adhesion, and multicellular crosstalk within the neurovascular unit.

The architecture generated quantitative, dynamic predictions of pericyte behavior under disease-relevant conditions, including hypoxia and amyloid exposure. Importantly, the framework was fully computable, enabling direct hypothesis testing and systematic comparison with USC’s in vitro and in vivo experimental datasets. This tight integration of computation and experimentation allowed for rigorous evaluation of the model’s predictive accuracy and biological fidelity.

Key Benefits Realized

  • Independent, peer-reviewed validation of a full-scale pericyte systems architecture
  • Confirmation of previously unrecognized feedback loops and crosstalk mechanisms driving neurovascular dysfunction
  • Quantitative, dynamic predictions aligned with experimental observations
  • Establishment of a new systems-level standard for studying pericyte biology
  • Identification and prioritization of mechanistic targets relevant to blood–brain barrier repair and neuroprotection
  • Accelerated translational insight into Alzheimer’s disease, stroke, and related neurovascular disorders

Outcome

The collaboration between USC Keck School of Medicine and CytoSolve® achieved the first peer-reviewed experimental validation of a comprehensive systems architecture of pericytes in neurovascular disease. This milestone culminated in a landmark publication in Nature Neuroscience, elevating the field’s understanding of pericyte-driven pathology and establishing a predictive, validated framework for future drug discovery and mechanistic studies. The case study exemplifies how CytoSolve®’s infrastructure enables scientifically rigorous, peer-validated systems architectures that translate complex multicellular biology into high-impact discoveries and precision medicine advances.