RESUMO
OBJECTIVES: The Siemens Point-of-Care Testing (POC) Atellica® VTLi high-sensitivity troponin I (hsTnI) device has been previously validated. Verification independently provides evidence that an analytical procedure fulfils concordance with laboratory assays, imprecision, and hemolysis interference requirements. METHODS: Five whole blood samples spanning the measuring interval were analysed 20 times in succession. Hemolysis interference was assessed at three troponin concentrations by spiking five hemolysate concentrations to plasma to achieve free hemoglobin concentrations 35-1,000â¯mg/dL. Concordance between whole blood (VTLi) and plasma on laboratory analysers (Beckman, Roche, Siemens) was assessed by Pearson correlation and kappa statistics at the (LOQ) and upper reference limit (URL). This was repeated for frozen plasma samples. RESULTS: Coefficients of variation for whole blood were <10â¯% for whole blood troponin concentrations of 9.2 and 15.9â¯ng/L, thus below the URL. Hemolysis positively interfered; at 250â¯mg/dL affecting the low troponin sample (+3â¯ng/L; +60â¯%) and high troponin sample (+37â¯ng/L; +24â¯%). Correlation coefficients were 0.98, 0.90 and 0.97 between VTLi and Beckman, Roche and Siemens assays respectively. Corresponding kappa statistics were 0.80, 0.73 and 0.84 at the LOQ and 0.70, 0.44 and 0.67 at the URL. CONCLUSIONS: Concordances between VTLi and laboratory assays were at least non-inferior to those between laboratory assays. Imprecision met manufacturer claims and was consistent with a high sensitivity assay. There is potential for hemolysis interference, highlighting the need for quality samples. The results support performance characteristics previously reported in validation studies, and the device offers acceptable performance for use within intended medical settings.
RESUMO
Objective: Familial hypercholesterolaemia (FH) variant positive subjects have over double the cardiovascular risk of low-density-lipoprotein-cholesterol (LDL-C) matched controls. It is desirable to optimise FH variant detection. Methods: We identified 213 subjects with FH gene panel reports (LDLR, APOB, PCSK9, and APOE) based on total cholesterol >310 mg/dL; excluding triglycerides >400 mg/dL, cascade screening, and patients without pre-treatment LDL-C recorded. Demographic, clinical and lipid parameters were recorded. Results: A 31/213 (14.6%) patients had pathogenic or likely pathogenic FH variants. 10/213 (4.7%) had variants of uncertain significance. Compared with patients without FH variants, patients with FH variants were younger (median age, 39 years vs. 48 years), had more tendon xanthomata (25.0% vs. 11.4%), greater proportion of first degree relatives with total cholesterol >95th percentile (40.6% vs. 16.5%), higher LDL-C (median, 271 mg/dL vs. 236 mg/dL), and lower triglycerides (median, 115 mg/dL vs. 159 mg/dL). The Besseling et al. model (c-statistic 0.798) improved FH variant discrimination over Friedewald LDL-C (c-statistic 0.724), however, Dutch Lipid Clinic Network Score (DLCNS) did not (c-statistic 0.665). Sampson LDL-C (c-statistic 0.734) had similar discrimination to Friedewald. Conclusion: Although tendon xanthomata and first degree relatives with high total cholesterol >95th percentile were associated with FH variants, DLCNS or Simon Broome criteria did not improve FH detection over LDL-C. Sampson LDL-C did not significantly improve discrimination over Friedewald. Although lower triglycerides and younger age of presentation are positively associated with presence of FH variants, this information is not commonly used in FH detection algorithms apart from Besseling et al.
RESUMO
OBJECTIVES: To describe a novel ß-globin variant that interferes with HbA1c analysis by cation exchange HPLC. DESIGN AND METHODS: Diabetes screening by HbA1c measurement was assessed using cation exchange HPLC and an immunoassay point-of-care analyzer. Routine hemoglobinopathy screening was performed including CBC, HbF and HbA2 measurement by cation exchange HPLC and capillary electrophoresis (CE). Further variant characterization was undertaken by ESI TOF mass spectrometry and DNA sequencing. RESULTS: Discordant HbA1c results were obtained for our subject, with elevated HbA1c of 52 mmol/mol measured by cation exchange HPLC and a normal level of 34 mmol/mol by immunoassay. Abnormal HbA1c peak shape prompted hemoglobinopathy screening to investigate potential variant interference. Cation exchange HPLC (using ß-thalassemia program) and CE results were apparently normal, with HbF and HbA2 detected within reference intervals. ESI TOF mass spectrometry revealed the presence of a variant ß-globin chain. A novel missense variant was confirmed at codon 121 of the ß-globin gene [ß121 (GH4) Glu>Asp; HBB: c.366A>C], which we have named Hb Westport. CONCLUSIONS: Hb Westport is a novel ß-globin variant that interferes with HbA1c measurement by Bio-Rad D-100 cation exchange HPLC, giving a falsely elevated result. This was clinically significant for our subject because the erroneously elevated HbA1c value was above the diabetes diagnostic threshold. Alternative methods for diabetes assessment should be considered in subjects with Hb Westport.