Construction and Validation of an Intelligent Ultrasound Diagnostic System for the Spectrum of Neuroblastoma in Children

Overview

The goal of this observational study is to build an intelligent ultrasound diagnostic system that integrates pathological typing, risk stratification and prognosis assessment. The main question it aims to answer is: 1. Can the prediction model of neuroblastoma tumors (NTs) in children based on ultrasound images distinguish each pathological subtype? 2. Can the multimodal fusion model established based on clinical and pathological features identify high-risk patients, predict bone marrow metastasis, and estimate the therapeutic effect? 3. Can this ultrasound diagnostic system achieve a systematic and intelligent assessment of NTs patients to assist in clinical risk stratification and individualized treatment decisions?

Neuroblastic tumors (NTs) represent the most common extracranial solid tumors in childhood, with the vast majority of patients diagnosed with neuroblastoma (NB)-the subtype associated with the highest malignancy and poorest prognosis. These cases present significant challenges in clinical diagnosis and management, often leading to unfavorable overall outcomes. Histopathological examination remains the gold standard for definitive diagnosis and classification. However, this method is invasive, carries a risk of complications, and its diagnostic accuracy is subject to operator experience and biopsy sampling location. Although medical imaging allows for noninvasive tumor assessment, it primarily relies on subjective visual interpretation by physicians, resulting in limited accuracy and reproducibility in distinguishing between different NT subtypes. Radiomics, an emerging artificial intelligence-based imaging analysis approach, enables high-throughput extraction, analysis, and quantification of imaging features through automated algorithms, uncovering vast amounts of subvisual information. It has demonstrated considerable promise in the differential diagnosis, treatment evaluation, and outcome prediction of tumors. Current radiomics research on neuroblastoma is still in its early stages, with most studies focusing on modalities such as computerized tomography(CT), magnetic resonance imaging(MRI), and Positron Emission Tomography-Computed Tomography(PET-CT), while ultrasound-based radiomics investigations remain unexplored. Ultrasonography, owing to its unique advantages-including absence of ionizing radiation, real-time dynamic imaging, operational convenience, and low cost-has become the preferred imaging modality for pediatric tumor screening and follow-up. Consequently, integrating radiomics with ultrasonography to develop an intelligent diagnostic system capable of noninvasively and accurately assessing NTs holds significant clinical value and translational potential. Such a system would facilitate precise preoperative classification, patient risk stratification, and support for clinical decision-making. This study aims to construct and validate an intelligent ultrasound diagnostic system for pediatric neuroblastic tumors based on ultrasound radiomics features, as follows: 1. To build a prediction model for pediatric neuroblastic tumors (NTs) based on ultrasound images, achieving automated differential diagnosis of neuroblastoma (NB), ganglioneuroblastoma (GNB), and ganglioneuroma (GN). 2. On the basis of pathological classification, integrate clinical pathological features to establish a multimodal fusion model. The focus is on identifying high-risk patients, predicting bone marrow metastasis, and estimating treatment outcomes, providing a reference basis for clinical decision-making. 3. Integrate previous research results to construct a comprehensive intelligent ultrasound diagnostic system that integrates pathological classification, risk stratification, and prognosis assessment, achieving systematic and intelligent evaluation of NTs patients to assist in clinical risk stratification and individualized treatment decisions.