Skull-Conforming Acoustic Holographic Lenses for Transcranial Targeting

TL;DR

This paper presents a personalized, skull-conforming acoustic hologram approach that improves transcranial ultrasound targeting by compensating for skull-induced aberrations through a physics-based optimization and conformal interface.

Contribution

It introduces a novel skull-conforming holographic lens design integrated with a volumetric holography framework for improved transcranial ultrasound accuracy.

Findings

Numerical simulations show consistent focusing across subjects.

Ex vivo experiments confirm accurate acoustic field reconstruction.

The approach enhances coupling and reduces reflection losses.

Abstract

Transcranial focused ultrasound (tFUS) offers noninvasive access to deep brain circuits but remains limited by skull-induced phase aberration, acoustic impedance mismatch, and poor volumetric control of intracranial pressure fields. Conventional phased-array and planar holographic strategies compensate aberrations electronically or computationally, yet do not resolve geometric and coupling inconsistencies imposed by subject-specific cranial morphology. We introduce personalized skull-conforming acoustic holograms that physically encode individualized wavefront corrections into a conformal acoustic interface. Within a subject-specific volumetric holography (SSVH) framework, cranial geometry and therapeutic constraints are embedded into a physics-based optimization pipeline for holographic phase synthesis. The resulting lens is integrated with a skull- and skin-conforming coupling layer that enhances impedance continuity, reduces reflection losses, and stabilizes spatial alignment, enabling simultaneous aberration mitigation and efficient transcranial transmission. Numerical simulations across multiple subjects and targets demonstrate consistent volumetric focusing and reliable target coverage while maintaining pressure fields within safety limits. Experimental validation using an ex vivo human skull confirms accurate fabrication, effective acoustic coupling, and faithful reconstruction of designed three-dimensional acoustic fields. By unifying wavefront engineering with anatomical conformity, this work establishes skull-conforming acoustic holography as a scalable strategy for high-fidelity, anatomically adaptive transcranial ultrasound targeting.