Hungarian Brain Research Program(2017-1.2.1-NKP-2017-00002) Támogató: NKFIH
Szakterületek:
Klinikai neurológia
Describing intracortical laminar organization of interictal epileptiform discharges
(IED) and high frequency oscillations (HFOs), also known as ripples. Defining the
frequency limits of slow and fast ripples. We recorded potential gradients with laminar
multielectrode arrays (LME) for current source density (CSD) and multi-unit activity
(MUA) analysis of interictal epileptiform discharges IEDs and HFOs in the neocortex
and mesial temporal lobe of focal epilepsy patients. IEDs were observed in 20/29,
while ripples only in 9/29 patients. Ripples were all detected within the seizure
onset zone (SOZ). Compared to hippocampal HFOs, neocortical ripples proved to be longer,
lower in frequency and amplitude, and presented non-uniform cycles. A subset of ripples
(≈ 50%) co-occurred with IEDs, while IEDs were shown to contain variable high-frequency
activity, even below HFO detection threshold. The limit between slow and fast ripples
was defined at 150 Hz, while IEDs' high frequency components form clusters separated
at 185 Hz. CSD analysis of IEDs and ripples revealed an alternating sink-source pair
in the supragranular cortical layers, although fast ripple CSD appeared lower and
engaged a wider cortical domain than slow ripples MUA analysis suggested a possible
role of infragranularly located neural populations in ripple and IED generation. Laminar
distribution of peak frequencies derived from HFOs and IEDs, respectively, showed
that supragranular layers were dominated by slower (< 150 Hz) components. Our findings
suggest that cortical slow ripples are generated primarily in upper layers while fast
ripples and associated MUA in deeper layers. The dissociation of macro- and microdomains
suggests that microelectrode recordings may be more selective for SOZ-linked ripples.
We found a complex interplay between neural activity in the neocortical laminae during
ripple and IED formation. We observed a potential leading role of cortical neurons
in deeper layers, suggesting a refined utilization of LMEs in SOZ localization.