在低资源环境下用于儿童人体测量的全自动3D成像系统的准确性:南苏丹马拉卡勒的有效性评估(预印本)

Eva Leidman, Muhammad Ali Jatoi, Iris Bollemeijer, Jennifer Majer, Shannon Doocy
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引用次数: 0

摘要

背景:在人道主义环境中采用3D成像系统需要与手动测量相当的精度,尽管与严峻的环境相关的额外限制。目的:本研究旨在评估由Body Surface Translations股份有限公司开发的AutoAnthro 3D成像系统(第三代)测量的儿童身高和中上臂围(MUAC)的准确性。方法:在2021年9月至2021年10月期间在南苏丹马拉卡勒平民保护区进行的两阶段集群调查中,对设备准确性进行了研究。选定家庭中所有6至59个月大的儿童都符合资格。根据2006年世界卫生组织儿童生长标准研究中使用的方案,由2名人体测量师对每个儿童进行手动测量。然后,另一个枚举器使用装有自定义软件AutoAnthro和Intel RealSense 3D扫描仪的三星Galaxy 8手机捕捉扫描结果。扫描使用全自动算法进行处理。多元逻辑回归模型适用于评估调整后的成功扫描几率。测量的准确性使用Bland-Altman图进行视觉评估,并使用平均偏差、一致性极限(LoAs)和个体差异的95%精度区间进行量化。与调查枚举员和Body Surface Translations Inc开发人员远程进行了关键信息员访谈,以了解测试版测试、培训、数据采集和传输方面的挑战。结果:539名符合条件的儿童获得了手动测量,其中234名(43.4%)儿童成功进行了扫描测量。至少10.4%(56/539)的儿童的看护人拒绝同意扫描采集;其他扫描未成功传输到服务器。儿童的人口统计学特征(年龄和性别)、身高和MUAC都与扫描衍生测量的可用性无关;扫描得出的身高测量值的平均偏差为-0.5(95%CI−2.0至1.0),MUAC为0.7(95%CI 0.4-1.0)。对于身材,95%的LoA为-23.9厘米至22.9厘米。对于MUAC,95%的LoA为-4.0厘米至5.4厘米。所有准确性指标因团队而异。新冠肺炎大流行相关的物理距离和旅行政策限制了验证设备算法的测试,并阻止了开发人员进行现场培训和现场监督,对扫描捕获、处理和传输的质量产生了负面影响。结论:扫描得出的测量结果对于当前技术的广泛采用来说不够准确。尽管该软件显示出了前景,但还需要对软件算法进行进一步投资,以解决扫描传输和极端现场环境的问题,并改善现场监督。团队准确性的差异提供了证据,证明对培训的投资也可以提高绩效。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Accuracy of Fully Automated 3D Imaging System for Child Anthropometry in a Low-Resource Setting: Effectiveness Evaluation in Malakal, South Sudan.

Background: Adoption of 3D imaging systems in humanitarian settings requires accuracy comparable with manual measurement notwithstanding additional constraints associated with austere settings.

Objective: This study aimed to evaluate the accuracy of child stature and mid-upper arm circumference (MUAC) measurements produced by the AutoAnthro 3D imaging system (third generation) developed by Body Surface Translations Inc.

Methods: A study of device accuracy was embedded within a 2-stage cluster survey at the Malakal Protection of Civilians site in South Sudan conducted between September 2021 and October 2021. All children aged 6 to 59 months within selected households were eligible. For each child, manual measurements were obtained by 2 anthropometrists following the protocol used in the 2006 World Health Organization Child Growth Standards study. Scans were then captured by a different enumerator using a Samsung Galaxy 8 phone loaded with a custom software, AutoAnthro, and an Intel RealSense 3D scanner. The scans were processed using a fully automated algorithm. A multivariate logistic regression model was fit to evaluate the adjusted odds of achieving a successful scan. The accuracy of the measurements was visually assessed using Bland-Altman plots and quantified using average bias, limits of agreement (LoAs), and the 95% precision interval for individual differences. Key informant interviews were conducted remotely with survey enumerators and Body Surface Translations Inc developers to understand challenges in beta testing, training, data acquisition and transmission.

Results: Manual measurements were obtained for 539 eligible children, and scan-derived measurements were successfully processed for 234 (43.4%) of them. Caregivers of at least 10.4% (56/539) of the children refused consent for scan capture; additional scans were unsuccessfully transmitted to the server. Neither the demographic characteristics of the children (age and sex), stature, nor MUAC were associated with availability of scan-derived measurements; team was significantly associated (P<.001). The average bias of scan-derived measurements in cm was -0.5 (95% CI -2.0 to 1.0) for stature and 0.7 (95% CI 0.4-1.0) for MUAC. For stature, the 95% LoA was -23.9 cm to 22.9 cm. For MUAC, the 95% LoA was -4.0 cm to 5.4 cm. All accuracy metrics varied considerably by team. The COVID-19 pandemic-related physical distancing and travel policies limited testing to validate the device algorithm and prevented developers from conducting in-person training and field oversight, negatively affecting the quality of scan capture, processing, and transmission.

Conclusions: Scan-derived measurements were not sufficiently accurate for the widespread adoption of the current technology. Although the software shows promise, further investments in the software algorithms are needed to address issues with scan transmission and extreme field contexts as well as to enable improved field supervision. Differences in accuracy by team provide evidence that investment in training may also improve performance.

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