The never-ending quest for antibody assays standardization and appropriate measurement units

M. Plebani, C. Galli
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引用次数: 1

Abstract

In this issue of the Journal, Hansen et al. are reporting an interesting observation on the proposed WHO standard for anti-SARS-CoV-2 antibodies [1]. In their opinion, introducing separate units for results obtained using neutralising antibody (Nab) assays and for results from binding antibody (bAb) assays is not appropriate as it represents ‘a deviation from international nomenclature conventions used by WHO to assign International Units to CRM’. In addition, the authors bring on a proposal to use a common term for international units (IU) while maintaining a distinction according to the target antibodies of different assays, e.g., neutralizing antibodies targeting specific portions of SARS-CoV-2 spike proteins, binding antibodies to spike or binding antibodies to the nucleocapsid. We recognize this point to be valid, but we would like to add some comments. From the reference they used [2] it looks like they consider the units of that WHO standard as SI units, that by definition have recognized dimensions and are independent of measurement procedure. However, this is not the case for biological controls where the measurand is classified as a class B. The three elements of a class B analyte, together making up the measurand, are the system (sample matrix) the component such as Ig class and target specificity, and the kind of quantity (e.g., the biological activity) [3]. As we commented in a previously published Editorial [4], the signal generated by antibody assays is influenced by the Ig class(es) involved and by the relative affinity to the antigenic targets, and thus to time after infection as a low affinity antibody response is raised in the early stages of infection and a high affinity characterizes past as well as chronic infections. Both factors (Ig classes andaffinity)will hamper the reliability of antibody standards that are usually preparedby pooling plasma specimens collected from many individuals whose infection stage is unknown. By a probabilistic estimate, majority of samples should come from people in late stages, with an overabundance of high affinity IgG, which willmake the standardization of different methods detecting only IgG, only IgMor all Ig classes (‘total’antibodyassays) an almost impossible task. A living example of the difficulties in manufacturing and using reliable standards for infectious diseases serology is provided by the standardization of IgG antibodies to Rubella virus, that has been proposed since many years but is still failing to reach a sustained agreement across assays, both in general and at the supposed ‘immunity’ threshold of 10 IU/mL [3]. We may therefore conclude that even adopting this target-based distinction proposed by Hansen et al. [1] will not be sufficient to harmonize, let alone standardize, the results generated by different SARS-CoV-2 antibody assays. We may also comment on this issue from a wider perspective. More than 30 years ago Roger Ekins established the two categories for assays employed in the biological sciences: analytical (or “structurally-specific”) and comparative (or ‘functionally specific’) [5], where the latter compare the relative effects of substances, or mixtures of substances, not necessarily of identical chemical structure, on a biological system and whose results should be representedbyunits of effect andnot byunits of “amount” of the substance(s) measured and therefore cannot be ‘standardized’ by the use of a calibrant. While this general statement may look harsh, we shall acknowledge that view and accept the metrologic imperfection of antibody assays. In this specific field, focusing on absolute thresholds or reference values does not looks feasible and efforts shall be better aimed to establish assay-independent ranges of antibody response that shall characterize different infection stages or satisfy clinical needs, such as establishing an adequate response to vaccination or the antibody levels that may trigger a medical intervention e.g., start or stop of a specific treatment or switch to a different schedule or drug combination.Whilewe totally agreewith the concerns raised by Hansen and Coll. to avoid an overflow of measurement units in laboratory medicine, which should create confusion *Corresponding author:MarioPlebani,DepartmentofMedicine-DIMED, University of Padova, Padova, Italy, E-mail: mario.plebani@unipd.it. https://orcid.org/0000-0002-0270-1711 Claudio Galli, Medical Affairs, Core Diagnostics, Abbott, Rome, Italy. https://orcid.org/0000-0002-0804-0387 Clin Chem Lab Med 2022; 60(7): 959–960
对抗体测定标准化和合适的测量单位的永无止境的追求
在本期《华尔街日报》上,Hansen等人报道了关于世卫组织抗sars - cov -2抗体[1]标准的有趣观察结果。他们认为,为使用中和抗体(Nab)测定法获得的结果和结合抗体(bAb)测定法获得的结果引入单独的单位是不合适的,因为这代表了“偏离了世卫组织用于为CRM分配国际单位的国际命名公约”。此外,作者还建议使用国际单位(IU)的共同术语,同时根据不同检测方法的靶抗体保持区别,例如,针对SARS-CoV-2刺突蛋白特定部分的中和抗体,刺突抗体或核衣壳抗体结合。我们承认这一点是正确的,但我们想补充一些意见。从他们使用[2]的参考资料来看,他们似乎认为世界卫生组织标准的单位是SI单位,根据定义,它们具有公认的尺寸,并且独立于测量程序。然而,在生物对照中,被测量物被分类为B类的情况并非如此。B类分析物的三个要素共同构成了测量物,它们是系统(样品基质)、组分(如g类和靶特异性)和数量(如生物活性)的种类(如[3])。正如我们在之前发表的Editorial[4]中所评论的那样,抗体检测产生的信号受所涉及的Ig类和与抗原靶点的相对亲和力的影响,因此受感染后时间的影响,因为低亲和力抗体反应在感染的早期阶段被提高,而高亲和力是过去和慢性感染的特征。这两个因素(Ig类和亲和力)都会妨碍抗体标准的可靠性,这些标准通常是收集许多感染阶段未知的个体的血浆标本。根据概率估计,大多数样本应该来自晚期患者,具有过量的高亲和力IgG,这将使检测IgG, igor所有IgG类(“总”抗体测定)的不同方法的标准化几乎是不可能的任务。风疹病毒IgG抗体的标准化是制造和使用传染病血清学可靠标准困难的一个生动例子,该标准多年来一直提出,但在一般和假定的“免疫”阈值10 IU/mL[3]下,仍未能在各种测定中达成持久的一致。因此,我们可以得出结论,即使采用Hansen等人提出的这种基于靶标的区分,也不足以统一(更不用说标准化)不同SARS-CoV-2抗体测定产生的结果。我们也可以从更广阔的角度来评论这个问题。30多年前,罗杰·埃金斯(Roger Ekins)建立了两类用于生物科学的检测方法:分析(或“结构特异性”)和比较(或“功能特异性”)[5],后者比较物质或物质混合物对生物系统的相对作用,不一定具有相同的化学结构,其结果应以效果单位表示,而不是以测量物质的“量”单位表示,因此不能通过使用校准剂来“标准化”。虽然这种笼统的说法可能看起来很苛刻,但我们应该承认这种观点,并接受抗体测定在计量学上的不完善。在这一特定领域,专注于绝对阈值或参考值似乎不可行,应更好地致力于建立独立于检测的抗体反应范围,以确定不同感染阶段的特征或满足临床需要,例如建立对疫苗接种的充分反应或可能引发医疗干预的抗体水平,例如开始或停止特定治疗或切换到不同的时间表或药物组合。虽然我们完全同意汉森和科尔提出的担忧。通讯作者:MarioPlebani,意大利帕多瓦大学医学部,E-mail: mario.plebani@unipd.it。https://orcid.org/0000-0002-0270-1711克劳迪奥·加利,医疗事务,核心诊断,雅培,罗马,意大利。https://orcid.org/0000-0002-0804-0387临床化学实验室医学2022;60 (7): 959 - 960
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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