Optimization of quantitative analysis method for carboxyhemoglobin in severely decomposed spleen tissue influenced by a reducing agent

IF 2.5 3区医学 Q1 MEDICINE, LEGAL

Forensic science international Pub Date : 2025-10-03 DOI:10.1016/j.forsciint.2025.112678

Miyeon Lee , Young-Hoon Jo , Doyeon Lee , Hyun Jee Kim , Wooyong Park

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Abstract

The concentration of carbon monoxide (CO) in a forensic sample is often determined by directly injecting blood into the oximeter. However, collection of blood sample is not always possible, especially when the subject is a severely decomposed cadaver. In this case, the CO concentration is determined by analyzing spleen tissue using gas chromatography with thermal conductivity detector (GC-TCD). In the previous study, spleen from 125 autopsy cases were analyzed which led to a conclusion that CO intoxication cannot be considered as a definitive cause of death when its concentration is lower than 30 %. The non-CO related cases where the concentration was as high as 30 % were because of high methemoglobin. Methemoglobin (MetHb) is a common product of hemoglobin oxidation caused by decomposition. Since MetHb is unable to bind with oxygen or carbon monoxide, it inhibits the CO saturation of the sample which is a critical step in constructing a calibration curve for CO calculation. Therefore, the importance of incorporating a reducing agent to lower MetHb by reducing it to normal hemoglobin has been proclaimed. To test the viability of reducing agent, where in this case Na₂S₂O₄, as a method to lower MetHb in spleen samples, preliminary tests on blood were conducted by comparing the result of the analysis with and without using the reducing agent. Blood samples with high MetHb were required, so an oxidating agent, sodium nitrite was added to spike the samples, as storing the already collected sample didn’t induce more decomposition and higher MetHb. Using the spiked blood samples, Na₂S₂O₄ was added in various concentrations and analyzed to find the appropriate amount, which was then applied to the spleen samples. The necessity of using the reducing agent was confirmed by comparing the results before and after adding Na₂S₂O₄ to the spleen samples, and the most appropriate concentration was found to be 0.1 mL of 0.574 M Na₂S₂O₄ per 1 mL of blood.

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还原剂影响下严重分解脾组织中碳氧血红蛋白定量分析方法的优化

法医样品中一氧化碳（CO）的浓度通常是通过直接将血液注射到血氧计中来测定的。然而，采集血液样本并不总是可行的，特别是当对象是一具严重腐烂的尸体时。在这种情况下，CO浓度是通过使用气相色谱热导检测器（GC-TCD）分析脾脏组织来确定的。在之前的研究中，对125例尸检病例的脾脏进行了分析，得出的结论是，当CO中毒浓度低于30% %时，不能将其视为确定的死亡原因。非一氧化碳相关病例浓度高达30 %是高铁血红蛋白所致。高铁血红蛋白（MetHb）是血红蛋白氧化分解的常见产物。由于MetHb不能与氧或一氧化碳结合，它抑制样品的CO饱和度，这是构建CO计算校准曲线的关键步骤。因此，加入还原剂的重要性，以降低甲基甲醚降低其正常血红蛋白已被宣布。测试的可行性还原剂,在这种情况下Na₂年代₂₄啊,作为一个方法来降低MetHb脾脏样本,对血液进行初步测试通过比较分析的结果和不使用还原剂。需要高甲基苯丙胺的血液样本，所以加入氧化剂亚硝酸钠来增加样本的峰值，因为储存已经收集的样本不会导致更多的分解和更高的甲基苯丙胺。利用加标后的血样，以不同的浓度加入Na₂S₂O₄并进行分析，找出合适的浓度，然后将其应用于脾脏样本。通过对比脾标本中加入Na₂S₂O₄前后的结果，确定了使用还原剂的必要性，并确定了最合适的浓度为每1 mL血液中加入0.574 M Na₂S₂O₄0.1 mL。

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来源期刊

Forensic science international 医学-医学：法

CiteScore

5.00

自引率

9.10%

发文量

285

审稿时长

49 days

期刊介绍： Forensic Science International is the flagship journal in the prestigious Forensic Science International family, publishing the most innovative, cutting-edge, and influential contributions across the forensic sciences. Fields include: forensic pathology and histochemistry, chemistry, biochemistry and toxicology, biology, serology, odontology, psychiatry, anthropology, digital forensics, the physical sciences, firearms, and document examination, as well as investigations of value to public health in its broadest sense, and the important marginal area where science and medicine interact with the law. The journal publishes: Case Reports Commentaries Letters to the Editor Original Research Papers (Regular Papers) Rapid Communications Review Articles Technical Notes.