Abstract
Laser-based diagnostics and therapeutics show
promise for many neurological disorders. However, the poor transparency
of cranial bone (calvaria) limits the spatial resolution and interaction
depth that can be achieved, thus constraining opportunity in this
regard. Herein, we report preliminary results from efforts seeking to
address this limitation through use of novel
transparent
cranial implants made from nanocrystalline yttria-stabilized zirconia
(nc-YSZ). Using optical coherence tomography (OCT) imaging of underlying
brain in an acute murine model, we show that signal strength is
improved when imaging through nc-YSZ implants relative to native
cranium. As such, this provides initial evidence supporting the
feasibility of nc-YSZ as a
transparent
cranial implant material. Furthermore, it represents a crucial first
step towards realization of an innovative new concept we are developing,
which seeks to eventually provide a clinically-viable means for
optically accessing the brain, on-demand, over large areas, and on a
chronically-recurring basis, without need for repeated craniectomies.
Transparent
cranial implants could serve as a critical enabler for laser-based
diagnosis and treatment of many neurological disorders. However, the
intrinsic brittleness of
transparent
implants reported thus far predisposes them to catastrophic
fracture-based failure, thus limiting opportunity for clinical
translation. Novel nanocrystalline
transparent
implants are reported herein that seek to address this limitation
through use of zirconia, a tough ceramic with well-proven
biocompatibility in other chronic implantation applications.
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