Introduction:
In multiple animal models of ischemic stroke, cerebellar fastigial nucleus stimulation (FNS) via implanted electrode has been shown to exert strong neuroprotective and collateral enhancement effects. Translational studies of FNS have been precluded due to the invasive nature of direct electrical stimulation. Recently, low-intensity focused ultrasound pulsation (LIFUP) has been used to stimulate deep hemispheric targets. Identifying achievable anatomic trajectories for LIFUP delivery is required for human trials.
Method:
Sagittal brain MRI T1 from 10 patients were analyzed. Potential pathways from the suboccipital (SO) region (transducer placement site) to the roof of the 4
th
ventricle (location of FN) were traced, evaluating paths both via the thinnest portion of the occipital bone (OB) and via the transforaminal window (TFW). Interindividual variations in trajectory distances (cm), thickness of the OB through which the beam passes (cm), and the projected neck flexion degree from neutral position required to achieve a TFW path were measured.
Results:
An achievable anatomic pathway for stimulation of the FN via LIFUP was identified in 100% of patients (Fig 1). In standard MR positioning, 90% had an available path through thin portions of the OB and 10% had a projected path through TFW. The mean distance from the skin at the SO region to the roof of 4
th
ventricle/FN was 7.2 cm (± 0.64cm). The mean OB thickness traversed by the beam was 0.3cm (±0.1). The projected required neck flexion to enable a TFW in all subjects was mean 9.3° (±5°).
Conclusions:
The distance for the LIFUP beam to travel from skin surface to FN via a suboccipital approach is well within the LIFUP penetration depth and all individuals had an accessible trajectory via the TFW through attainable degrees of head flexion, affording minimal ultrasonic energy dispersion and maximal focality. Ultrasound stimulation of fastigial nucleus is a feasible treatment strategy in human acute ischemic stroke.
Transcranial focused ultrasound stimulation of human primary visual cortex