Keywords
Immunoturbidimetric assay
Hook effect
Submitted : 2024-06-18
Accepted : 2024-07-03
Published : 2024-07-18
Abstract
Objective: To investigate the hook effect in the detection of beta2-microglobulin (β2-MG) with different reagents as well as on two fully automated biochemical analyzers and their solutions. Methods: Using immunoturbidimetric assay for β2-MG as the research object, β2-MG levels were detected by different concentration gradients of β2-microglobulin samples in Liedemann, Mack, and Myriad reagents of three manufacturers on two automatic biochemical analyzers, and the difference of the hook effect was comparatively analyzed. Results: Leadman reagent showed the hook effect on the Beckman AU5800 automated biochemistry analyzer, while both Maccura and Mindray reagents did not show the hook effect. After the experiments, we found the limit value of the pre-zone check of Leadman reagent, and changed the parameters of the instrument, when the limit value of the pre-zone check was reached, the instrument automatically diluted the specimen five times and then detected it again. After changing the parameters of the instrument, the correlation between the three methods of detecting samples of different concentrations was r > 0.99. Conclusion: Before selecting the application of immunoturbidimetric reagents, we have to carry out the risk assessment of the hook effect and selectively set the parameters of the pre-zone check based on the highest concentration that may occur in the clinic; for the items that may have the hook effect, we have to selectively set the parameters of the pre-zone check when the ratio of average reaction rate and the immediate reaction rate is at the limit value, and the phenomenon of antigen excess may occur, the instrument will carry out automatic dilution before detection, so as to avoid the issuance of erroneous results of high-value samples due to the hook effect.
References
Haring N, Mahr HS, Mtindle M, et al., 2011, Early Detection of Renal Damage Caused by Fumaric Acid Ester Therapy by Determination of Urinary Beta2-Macroglobulin. Br J Dermatol, 164(3): 648–651.
Scarr D, Bjornstad P, Lovblom LE, et al., 2019, Estimating Glomerular Filtration Rate by Serum Creatinine, Cystatin C, and Beta2-Microglobulin in Older Adults; Results from the Canadian STUDY of Longevity in Type 1 Diabetes. Kidney Int Rep, 4(6): 786–796.
Colombo M, Looker HC, Farran B, et al., 2019, Serum Kidney Injury Molecule 1 and Beta2-Microglobulin Perform As Well As Larger Biomarker Panels for Prediction of Rapid Decline in Renal Function in Type 2 Diabetes. Diabetologia, 62(1): 156–168.
Shafi T, Levey AS, 2018, Measurement and Estimation of Residual Kidney Function in Patients on Dialysis. Adv Chronic Kidney Dis, 25(1): 93–104.
Li ZG, Zhou X, 2016, Correlation Between the Condition of Patients with Acute Cerebral Infarction and Serum Beta2-Microglobulin Levels. J Acute Dis, 5(4): 281–285.
Smith LK, He Y, Park JS, et al., 2015, Beta2-Microglobulin is a Systemic Pro-Aging Factor that Impairs Cognitive Function and Neurogenesis. Nat Med, 21(8): 932–937.
Teng X, 2015, Immunoturbidimetric Method for Prevention of Hook Effect in Fully Automated Biochemical Analyser. International Journal of Laboratory Medicine, (2015): 15–16.
Gao S, 2012, Exploration of Hook Effect Prevention in Immunoturbidimetric Analysis. Inner Mongolia Traditional Chinese Medicine, (2012): 91–92.
Miles LE, Lipschitz DA, Bieber CP, et al., 1974, Measurement of Serum Ferritin by a 2-Site Immunoradiometric Assay. Anal Biochem, 61(l): 209–224.
Kang H, Wang L, 2004, Prevention of Hook Effect in Immunoturbidimetric Assay. Clinical Biochemistry and Laboratory Medicine, 25(6): 551–552.
Zhang C, Lai C, Zhang L, 2019, Study on the Clinical Application of Anti-Cyclic Citrullinated Peptide Antibodies Determined by Immunoturbidimetric Method. Chinese Medical Science, 9(3): 82–84.
Wang CW, Cai YM, Mao DY, et al., 2023, Study on the Optimal Setting of Analysis Parameters for Immunoturbidimetric Assay of Fully Automatic Biochemical Analyser. China Medical Equipment, (11): 25–29.