Neurovascular coupling reflex from contralateral stimulation: System setup

Abstract

Aims/Purpose: Neurovascular coupling (NVC) is the blood flow modulation in response to stimuli and has been extensively studied in the brain. Concerning the human retina, this behaviour has been only measured in the ipsilateral eye, where stimuli and observed effects involve the same eye. This work aims to set up the hardware to assess NVC in the contralateral eye and demonstrate its feasibility in edifying human retina‐retina or cortico‐retinal connections.Methods: Adaptive optics (AO) is a cutting‐edge technology in retinal fundus imaging, offering exceptional spatial resolution. The NVC effect was successfully assessed using the RTX1, an AO retinal camera capable of ipsilateral stimulation. The possible effects of contralateral stimulation can be readily assessed by providing RTX1 with an external flickering device. Furthermore, connecting the thread between previous fMRI results and photic stimulation in the ipsi‐ and contralateral retina can offer valuable information on uncharted interocular or brain‐retina neural pathways and lead to cost‐effective and non‐invasive biomarkers for neurodegenerative diseases or early brain vasculature impairment diagnosis.Results: Even though further optimization of flicker‐related parameters is necessary to investigate the contralateral NVC response, preliminary tests showed the successful integration of a fully operational contralateral stimulation prototype with the RTX1. The entire procedure has been documented, and all components have been thoroughly evaluated.Conclusions: These preliminary assessments precede a clinical study involving patients with type 1 Diabetes Mellitus and a control group of healthy individuals. It follows previous fMRI studies that showed impaired NVC in type 2 diabetic patients by measuring the BOLD (Blood Oxygen Level‐Dependent) response using block and event‐related optical stimuli. A comparative analysis of the findings aims to demonstrate the potential role of neurovascular uncoupling in the early pathogenesis of diabetic retinopathy.