Litcius/Paper detail

Establishing density-dependent longitudinal sound speed in the vertebral lamina

Rui Xu, Meaghan A. O’Reilly

2022The Journal of the Acoustical Society of America12 citationsDOIOpen Access PDF

Abstract

Focused ultrasound treatments of the spinal cord may be facilitated using a phased array transducer and beamforming to correct spine-induced focal aberrations. Simulations can non-invasively calculate aberration corrections using x-ray computed tomography (CT) data that are correlated to density (ρ) and longitudinal sound speed (cL). We aimed to optimize vertebral lamina-specific cL(ρ) functions at a physiological temperature (37 °C) to maximize time domain simulation accuracy. Odd-numbered ex vivo human thoracic vertebrae were imaged with a clinical CT-scanner (0.511 × 0.511 × 0.5 mm), then sonicated with a transducer (514 kHz) focused on the canal via the vertebral lamina. Vertebra-induced signal time shifts were extracted from pressure waveforms recorded within the canals. Measurements were repeated 5× per vertebra, with 2.5 mm vertical vertebra shifts between measurements. Linear functions relating cL with CT-derived density were optimized. The optimized function was cL(ρ)=0.35(ρ−ρw)+ cL,w m/s, where w denotes water, giving the tested laminae a mean bulk density of 1600 ± 30 kg/m3 and a mean bulk cL of 1670 ± 60 m/s. The optimized lamina cL(ρ) function was accurate to λ/16 when implemented in a multi-layered ray acoustics model. This modelling accuracy will improve trans-spine ultrasound beamforming.

Topics & Concepts

LaminaVertebraAcousticsSpeed of soundTransducerMaterials scienceBeamformingScannerUltrasoundWaveformTransverse planePhysicsBiomedical engineeringAnatomyComputer scienceOpticsMedicineTelecommunicationsVoltageQuantum mechanicsUltrasound and Hyperthermia ApplicationsUltrasound Imaging and ElastographyUltrasound in Clinical Applications