Sepsis-induced changes in spectral segregation and kinetics of brain oscillatory states

Abstract

Abstract Sepsis-associated encephalopathy (SAE) is a frequent severe complication of sepsis and the systemic inflammatory response syndrome, associated with high mortality and long-term neurological consequences in surviving patients. One of the main clinical sings of SAE are discontinuous sleep periods that are fragmented by frequent awakening. Even though this brain state fragmentation strongly impacts the functionality of the nervous- as well as other systems, its underlying network mechanisms are still poorly understood. In this work, we therefore aim at characterizing the properties and dynamics of brain oscillatory states in response to SAE in an acute rat model of sepsis induced by high dose LPS (10 mg/kg). To focus on intrinsically generated brain state dynamics, we used a urethane model that spares oscillatory activity in REM- and NREM-like sleep states. Intraperitoneal LPS injection led to a robust instability of both oscillatory states resulting in several folds more state transitions. Using power spectra analysis we identified opposing shifts in low frequency oscillations (1–9 Hz) in REM and NREM-like states under influence of LPS. This resulted in increased similarity between both states. Moreover, the state-space jitter in both states increased as well, pointing to higher within-state instability. The reduction of inter-state spectral distances in 2-D state space, combined with increased within-state jitter might represent a key factor in changing the energy landscape of brain oscillatory state attractors, and hence lead to altered sleep architecture. Their emergence during sepsis might point to a mechanism underlying severe sleep fragmentation as described both in sepsis patients and SAE animal models.