Sekyonda Z, An R, Avanaki A, Fraiwan A, Gurkan UA. A Novel Approach for Glycosylated Hemoglobin Testing Using Microchip Affinity Electrophoresis.
IEEE Trans Biomed Eng 2023;
70:1473-1480. [PMID:
36315541 PMCID:
PMC10185434 DOI:
10.1109/tbme.2022.3218501]
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Abstract
OBJECTIVE
Effective management of diabetes largely benefits from early diagnosis followed by intensive long-term regulation of blood glucose. The levels of glycohemoglobin (HbA1 and HbA1c) have been used as standard biomarkers to assess long-term blood glucose concentrations for diabetes diagnosis and management. Gold standard laboratory methods for HbA1 and HbA1c testing are often costly and not widely available. Moreover, currently available point-of-care (POC) immunoassay-based glycohemoglobin tests may produce inaccurate test results for patients with co-existing diseases such as hemoglobin disorders and anemia. Here, we report a POC platform, HemeChip-GHb, for quantitative HbA1 detection leveraging paper-based affinity electrophoresis.
METHODS
We describe the design and development of the HemeChip-GHb test. Feasibility and accuracy of the HemeChip-GHb system were demonstrated by testing blood samples collected from healthy donors, patients with prediabetes, and patients with diabetes.
RESULTS
HbA1 levels measured with HemeChip-GHb show 0.96 correlation to the levels reported from the clinical standard HPLC tests, and with a bias of -0.72% based on Bland-Altman analysis. 99.6% of the HbA1 levels for paired HemeChip-GHb and HPLC fell within A and B zones of no difference in clinical outcome based on error grid analysis.
CONCLUSION
Using HemeChip-GHb we achieved accurate diabetes status detection with sensitivity and specificity of 100%.
SIGNIFICANCE
We presented a novel POC paper-based affinity electrophoresis platform that has the potential for accurately diagnosing diabetes, and addressing an unmet need for accurate and affordable diagnostics in resource-challenged environments.
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