Towards Non-contact 3D Ultrasound for Wrist Imaging

TL;DR

This paper presents a novel non-contact 3D ultrasound imaging method using a mechanical track to simplify probe movement, enabling low-cost, easy-to-deploy wrist imaging suitable for point-of-care applications.

Contribution

It introduces a mechanical track-based approach for non-contact US scanning that simplifies 3D reconstruction and can be integrated into existing ultrasound systems.

Findings

Successful ex-vivo and in-vivo experiments demonstrate effectiveness.

The system offers adjustable field of view and low-cost deployment.

Enables non-contact 3D wrist imaging for pediatric care.

Abstract

Objective: The objective of this work is an attempt towards non-contact freehand 3D ultrasound imaging with minimal complexity added to the existing point of care ultrasound (POCUS) systems. Methods: This study proposes a novel approach of using a mechanical track for non-contact ultrasound (US) scanning. The approach thus restricts the probe motion to a linear plane, to simplify the acquisition and 3D reconstruction process. A pipeline for US 3D volume reconstruction employing an US research platform and a GPU-based edge device is developed. Results: The efficacy of the proposed approach is demonstrated through ex-vivo and in-vivo experiments. Conclusion: The proposed approach with the adjustable field of view capability, non-contact design, and low cost of deployment without significantly altering the existing setup would open doors for up gradation of traditional systems to a wide range of 3D US imaging applications. Significance: Ultrasound (US) imaging is a popular clinical imaging modality for the point-of-care bedside imaging, particularly of the wrist/knee in the pediatric population due to its non-invasive and radiation free nature. However, the limited views of tissue structures obtained with 2D US in such scenarios make the diagnosis challenging. To overcome this, 3D US imaging which uses 2D US images and their orientation/position to reconstruct 3D volumes was developed. The accurate position estimation of the US probe at low cost has always stood as a challenging task in 3D reconstruction. Additionally, US imaging involves contact, which causes difficulty to pediatric subjects while monitoring live fractures or open wounds. Towards overcoming these challenges, a novel framework is attempted in this work.