An open-source MRI compatible frame for multimodal presurgical mapping in macaque and capuchin monkeys

Abstract

AbstractHighlights:We present a compact MRI-compatible stereotaxic frame for large nonhuman primates.The design is 3D printable, inexpensive, and matches size of an adult human head.Enabled real-time, accurate, MRI-guided deep-brain viral vector injection.Facilitated multimodal alignment for deep-brain electrophysiology planning.All computer-aided-design files are modularized and publicly available and editable.BackgroundHigh-precision neurosurgical targeting in nonhuman primates (NHPs) often requires presurgical anatomy mapping with noninvasive neuroimaging techniques (MRI, CT, PET), allowing for translation of individual anatomical coordinates to surgical stereotaxic apparatus. Given the varied tissue contrasts that these imaging techniques produce, precise alignment of imaging-based coordinates to surgical apparatus can be cumbersome. MRI-compatible stereotaxis with radiopaque fiducial markers offer a straight-forward and reliable solution, but existing commercial options do not fit in conformal head coils that maximize imaging quality.New methodWe developed a compact MRI-compatible stereotaxis suitable for a variety of NHP species (Macaca mulatta,Macaca fascicularis, andCebus apella) that allows multimodal alignment through technique-specific fiducial markers.Comparison with existing methodsWith the express purpose of compatibility with clinically available MRI, CT, and PET systems, the frame is no larger than a human head, while allowing for imaging NHPs in the supinated position. This design requires no marker implantation, special software, or additional knowledge other than the operation of a common large animal stereotaxis.ResultsWe demonstrated the applicability of this 3D-printable apparatus across a diverse set of experiments requiring presurgical planning: 1) We demonstrate the accuracy of the fiducial system through a within-MRI cannula insertion and subcortical injection of viral vectors. 2) We also demonstrated accuracy of multimodal (MRI and CT) alignment and coordinate transfer to guide a surgical robot electrode implantation for deep-brain electrophysiology.ConclusionsThe computer-aided design files and engineering drawings are publicly available, with the modular design allowing for low cost and manageable manufacturing.