Development of next-generation reference interval models to establish reference intervals based on medical data: current status, algorithms and future consideration.

IF 6.6 2区 医学 Q1 MEDICAL LABORATORY TECHNOLOGY
Chaochao Ma, Zheng Yu, Ling Qiu
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引用次数: 0

Abstract

Evidence derived from laboratory medicine plays a pivotal role in the diagnosis, treatment monitoring, and prognosis of various diseases. Reference intervals (RIs) are indispensable tools for assessing test results. The accuracy of clinical decision-making relies directly on the appropriateness of RIs. With the increase in real-world studies and advances in computational power, there has been increased interest in establishing RIs using big data. This approach has demonstrated cost-effectiveness and applicability across diverse scenarios, thereby enhancing the overall suitability of the RI to a certain extent. However, challenges persist when tests results are influenced by age and sex. Reliance on a single RI or a grouping of RIs based on age and sex can lead to erroneous interpretation of results with significant implications for clinical decision-making. To address this issue, the development of next generation of reference interval models has arisen at an historic moment. Such models establish a curve relationship to derive continuously changing reference intervals for test results across different age and sex categories. By automatically selecting appropriate RIs based on the age and sex of patients during result interpretation, this approach facilitates clinical decision-making and enhances disease diagnosis/treatment as well as health management practices. Development of next-generation reference interval models use direct or indirect sampling techniques to select reference individuals and then employed curve fitting methods such as splines, polynomial regression and others to establish continuous models. In light of these studies, several observations can be made: Firstly, to date, limited interest has been shown in developing next-generation reference interval models, with only a few models currently available. Secondly, there are a wide range of methods and algorithms for constructing such models, and their diversity may lead to confusion. Thirdly, the process of constructing next-generation reference interval models can be complex, particularly when employing indirect sampling techniques. At present, normative documents pertaining to the development of next-generation reference interval models are lacking. In summary, this review aims to provide an overview of the current state of development of next-generation reference interval models by defining them, highlighting inherent advantages, and addressing existing challenges. It also describes the process, advanced algorithms for model building, the tools required and the diagnosis and validation of models. Additionally, a discussion on the prospects of utilizing big data for developing next-generation reference interval models is presented. The ultimate objective is to equip clinical laboratories with the theoretical framework and practical tools necessary for developing and optimizing next-generation reference interval models to establish next-generation reference intervals while enhancing the use of medical data resources to facilitate precision medicine.

开发下一代参考区间模型,根据医疗数据建立参考区间:现状、算法和未来考虑。
实验室医学证据在各种疾病的诊断、治疗监测和预后方面发挥着举足轻重的作用。参考区间(RIs)是评估检验结果不可或缺的工具。临床决策的准确性直接依赖于参考区间的适当性。随着真实世界研究的增加和计算能力的进步,人们对利用大数据建立参考区间的兴趣日益浓厚。这种方法已证明具有成本效益并适用于各种不同的情况,从而在一定程度上提高了 RI 的整体适宜性。然而,当测试结果受年龄和性别影响时,挑战依然存在。依赖单一的 RI 或根据年龄和性别对 RI 进行分组可能会导致对结果的错误解释,从而对临床决策产生重大影响。为解决这一问题,下一代参考区间模型的开发应运而生。此类模型建立了一种曲线关系,可为不同年龄和性别类别的检测结果推导出不断变化的参考区间。通过在结果解释过程中根据患者的年龄和性别自动选择适当的参考区间,这种方法有助于临床决策,并能加强疾病诊断/治疗以及健康管理实践。下一代参考区间模型的开发使用直接或间接采样技术来选择参考个体,然后采用曲线拟合方法(如样条曲线、多项式回归等)来建立连续模型。根据这些研究,可以提出几点看法:首先,迄今为止,人们对开发下一代参考区间模型的兴趣有限,目前只有少数几个模型可用。其次,构建此类模型的方法和算法多种多样,其多样性可能会导致混淆。第三,构建下一代参考区间模型的过程可能很复杂,尤其是在采用间接采样技术时。目前,还缺乏有关下一代参考区间模型开发的规范性文件。总之,本综述旨在通过定义下一代参考区间模型、强调其固有优势和应对现有挑战,概述下一代参考区间模型的开发现状。它还介绍了建立模型的过程、先进算法、所需工具以及模型的诊断和验证。此外,还讨论了利用大数据开发新一代参考区间模型的前景。最终目的是为临床实验室提供开发和优化下一代参考区间模型所需的理论框架和实用工具,以建立下一代参考区间,同时加强对医疗数据资源的利用,促进精准医疗的发展。
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来源期刊
CiteScore
20.00
自引率
0.00%
发文量
25
审稿时长
>12 weeks
期刊介绍: Critical Reviews in Clinical Laboratory Sciences publishes comprehensive and high quality review articles in all areas of clinical laboratory science, including clinical biochemistry, hematology, microbiology, pathology, transfusion medicine, genetics, immunology and molecular diagnostics. The reviews critically evaluate the status of current issues in the selected areas, with a focus on clinical laboratory diagnostics and latest advances. The adjective “critical” implies a balanced synthesis of results and conclusions that are frequently contradictory and controversial.
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