1.1 这种做法确保了有效的灭活 ≥ 4日志 10 在不靶向逆转录病毒抗原的啮齿动物来源的细胞系中制造的单克隆抗体或免疫球蛋白G（IgG）Fc融合蛋白的制造过程中。啮齿动物逆转录病毒被用作啮齿动物细胞底物内源性逆转录病毒样颗粒的模型，这些颗粒可能存在于这些蛋白质的生产流中。 1.2 本规程规定的参数包括澄清度、Triton X-100洗涤剂浓度、保持时间、pH值和灭活温度。 1.3 这种做法可以与其他清除或灭活单元操作结合使用，这些操作与这种灭活机制正交，以实现啮齿动物逆转录病毒的充分全过程清除或失活。 1.4 该洗涤剂灭活步骤在单克隆抗体或IgG-Fc融合蛋白的澄清的无细胞中间体上进行。 1.5 以国际单位制表示的数值应视为标准。本标准不包括其他计量单位。 1.6 本标准并不旨在解决与其使用相关的所有安全问题（如有）。本标准的使用者有责任在使用前制定适当的安全、健康和环境实践，并确定监管限制的适用性。 1.7 本国际标准是根据世界贸易组织技术性贸易壁垒委员会发布的《关于制定国际标准、指南和建议的原则的决定》中确立的国际公认的标准化原则制定的。 ====意义和用途====== 3.1 啮齿动物衍生的细胞系广泛用于生产生物制药药物，如单克隆抗体和Fc融合蛋白。这些细胞系已被证明含有编码内源性逆转录病毒样颗粒或内源性逆转录病毒的基因。尽管缺乏证据表明这种啮齿动物逆转录病毒与人类疾病之间存在关联，但人类治疗方法的潜在污染引发了生物制药的安全问题。此外，病毒等外来因素可以从其他来源引入生物制药原料药的生产过程，潜在的安全问题可以归因于这些潜在的未知因素。 出于这些原因，有效的病毒清除是将安全性测试和工艺表征相结合的综合方法的一个重要方面，该方法确保了使用啮齿动物细胞系生产的生物制药产品的病毒安全性。 3.2 几十年来，溶剂/洗涤剂灭活已被广泛用于灭活血浆衍生生物药物疗法中的包膜病毒 ( 1. 3. ) . 3. 使用洗涤剂Triton X-100或聚山梨醇酯80以及有机溶剂tri（n- 丁基）磷酸盐（TNBP）已被用于通过破坏病毒包膜来灭活包膜病毒，从而降低包膜病毒附着并感染宿主细胞的能力 ( 4和 5. ) . 3.3 大多数单克隆抗体、重组蛋白和Fc融合蛋白的制造商都专注于在不存在TNBP的情况下使用洗涤剂Triton X-100或聚山梨醇酯80的病毒灭活方法 ( 6. ) ，这会干扰随后的生物处理步骤。洗涤剂单独灭活逆转录病毒的能力已在啮齿动物体内产生的单克隆抗体中得到证明- 衍生细胞系 ( 6. 9 ) 在2011年一次专门讨论生物加工中使用的病毒清除步骤的研讨会上 ( 7. ) ，一家公司的研究人员显示，在环境温度下与0.2%Triton X-100孵育60分钟，失活>5 log 10 X-MuLV在细胞培养基质中的四种不同mAb之间的相互作用。 3.3.1 在2011年的同一次研讨会上 ( 7. ) ，来自第二家公司的研究人员证实，蛋白质浓度和脂质浓度水平在0水平时对MuLV病毒失活没有可观察到的影响。 3%Triton X-100。此外，8种不同的单克隆抗体宿主细胞培养液（HCCF）用0.3%的Triton X-100在20 °C。有效的灭活， ≥ 4日志 10 在这些实验中对每种抗体都观察到MuLV病毒失活的抑制作用。 3.4 Quertinmont ( 8. ) 证明使用HCCF的0.45%（w/v）Triton X-100去污剂灭活步骤中的DNA水平、总蛋白浓度和脂质含量（超过1000µg/mL）在使用单克隆抗体和Fc融合蛋白灭活60分钟后对MuLV病毒的检测没有统计学意义。 此外，对三种不同生物药物浓度、总蛋白浓度、温度和Triton X-100浓度的独立分子进行了三项实验设计（DOE）稳健性研究。这些研究表明，当Triton X-100浓度为 ≥ 0.2 %, 温度在15之间 °C至25 °C，保持时间为 ≥ 60 在HCCF中为min。 3.5 布鲁梅尔和图内克蒂 ( 9 ) 显示使用1在所有时间点（0、5、30和60分钟）通过4mAb[2个IgGs和2个免疫球蛋白M（IgMs）]完全失活MuLV。 0%Triton X-100，保持60分钟。这15项研究的平均对数折减系数（LRF）为 ≥ 3.89对数 10 对研究数据的分析显示，较高水平的Triton X-100（1%）需要大的稀释以减轻MuLV指示细胞的细胞毒性。在这15项研究中测试的任何时间点都没有发现可检测的病毒，并且在这些研究中，声称的LRF完全取决于MuLV原料的起始病毒滴度。 3.6 这种逆转录病毒失活的程度可能取决于某些反应参数，包括澄清、Triton X- 100浓度、保持时间、pH和失活温度。然而，按照本规程的规定，管理能够提供强有力和有效的逆转录病毒灭活的参数，再加上其他清除单位的操作，可以确保有效地灭活逆转录病毒。 3.7 该实践包含了能够有效灭活逆转录病毒的参数，可用于特定病毒的病毒清除过程的模块化验证。

1.1 This practice assures effective inactivation of ≥ 4 log 10 of infectious rodent retrovirus (that is, reduction from 10 000 to 1 infectious rodent retrovirus or removal of 99.99 % of infectious rodent retroviruses) in the manufacturing processes of monoclonal antibodies or immunoglobulin G (IgG) Fc fusion proteins manufactured in rodent-derived cell lines that do not target retroviral antigens. Rodent retrovirus is used as a model for rodent cell substrate endogenous retrovirus-like particles potentially present in the production stream of these proteins. 1.2 The parameters specified for this practice are clarification, Triton X-100 detergent concentration, hold time, pH, and inactivation temperature. 1.3 This practice can be used in conjunction with other clearance or inactivation unit operations that are orthogonal to this inactivation mechanism to achieve sufficient total process clearance or inactivation of rodent retrovirus. 1.4 This detergent inactivation step is performed on a clarified, cell-free intermediate of the monoclonal antibody or IgG Fc fusion protein. 1.5 The values stated in SI units are to be regarded as standard. No other units of measurement are included in this standard. 1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use. 1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee. ====== Significance And Use ====== 3.1 Rodent-derived cell lines are widely used in the production of biopharmaceutical drugs such as mAbs and Fc fusion proteins. These cell lines have been shown to contain genes encoding endogenous retroviral-like particles or endogenous retrovirus. Despite the lack of evidence for an association between such rodent retroviruses and disease in humans, the potential contamination of human therapeutics raises safety concerns for biopharmaceutical drugs. Additionally, adventitious agents such as viruses can be introduced into a biopharmaceutical drug substance manufacturing process from other sources, and potential safety issues can be attributed to these potential unknowns. For these reasons, effective viral clearance is an essential aspect of an integrated approach combining safety testing and process characterization which ensures virus safety for biopharmaceutical drug products made using rodent cell lines. 3.2 Solvent/detergent inactivation has been widely used for decades to inactivate enveloped viruses in blood plasma derived biopharmaceutical therapies ( 1- 3 ) . 3 Solvent/detergent systems using the detergents Triton X-100 or Polysorbate 80 along with the organic solvent tri(n-butyl)phosphate (TNBP) have been used to inactivate enveloped viruses by disrupting the viral envelope thereby reducing the ability of the enveloped virus to attach to and then infect the host cell ( 4 and 5 ) . 3.3 Most manufacturers of mAbs, recombinant proteins, and Fc fusion proteins have focused on viral inactivation methods using the detergent Triton X-100 or Polysorbate 80 in the absence of TNBP ( 6 ) , which can interfere with subsequent bioprocessing steps. The ability of the detergents alone to inactivate retroviruses has been demonstrated in monoclonal antibodies produced in rodent-derived cell lines ( 6- 9 ) . At a 2011 workshop devoted to viral clearance steps used in bioprocessing ( 7 ) , investigators from one firm showed incubation with 0.2 % Triton X-100 for 60 min of hold time at ambient temperature inactivated >5 log 10 of X-MuLV across four separate mAbs in cell culture matrices. 3.3.1 At the same 2011 workshop ( 7 ) , investigators from a second firm confirmed that levels of protein concentration and lipid concentration had no observable effect on MuLV virus inactivation at levels of 0.3 % Triton X-100. Additionally, eight different monoclonal antibody Host Cell Culture Fluids (HCCF), were treated with 0.3 % Triton X-100 for a 60 min hold time at 20 °C. Effective inactivation, ≥ 4 log 10 of inactivation of MuLV virus, was seen for each antibody in these experiments. 3.4 Quertinmont ( 8 ) demonstrated that DNA level, total protein concentration, and lipid content (exceeding 1000 µg/mL) in a 0.45 % (w/v) Triton X-100 detergent inactivation step using HCCF were not statistically significant to the detection of MuLV virus following 60 min of inactivation using both monoclonal antibodies and Fc fusion proteins. Additionally, three Design of Experiment (DOE) robustness studies were carried out for three separate molecules varying biological drug concentration, total protein concentration, temperature, and Triton X-100 concentration. These studies demonstrated effective viral inactivation when Triton X-100 concentration is ≥ 0.2 %, temperature is between 15 °C to 25 °C, and hold time is ≥ 60 min in HCCF. 3.5 Blumel and Tounekti ( 9 ) showed complete inactivation of MuLV across 4 mAbs [2 IgGs and 2 immunoglobulin M (IgMs)] for all time points (0, 5, 30, and 60 min) using 1.0 % Triton X-100 for a 60-min hold time. The average log reduction factor (LRF) for these 15 studies was ≥ 3.89 log 10 . Analyses of the study data showed the higher level of Triton X-100 (1 %) necessitated a large dilution to mitigate cytotoxicity of the MuLV indicator cells. No detectable virus was seen at any of the time points tested across these 15 studies and the claimed LRF was completely dependent on the starting viral titer of the MuLV feed stock in these studies. 3.6 The extent of this retroviral inactivation could be dependent on certain reaction parameters including clarification, Triton X-100 concentration, hold time, pH, and inactivation temperature. However, managing parameters that give robust and effective retrovirus inactivation as specified by this practice, in conjunction with other clearance unit operations, can assure effective retroviral inactivation. 3.7 This practice incorporates parameters that give effective retrovirus inactivation, which can be used as modular validation of the viral clearance process for the specified viruses.