E different iron markers using the internationally accepted cut-off values and iron content in the bone marrow as reference. The iron markers with the lowest sensitivities were plasma ferritin (15 , 11 when combined with CRP, and 1 when combined with age), transferrin (1 ) and TIBC (17 ). TfR-F index and MCHC had lower sensitivities (42 and 51 , respectively) than specificities (91 and 71 , respectively), while sTfR, TfR-F index by CRP, plasma iron and transferrin saturation had higher sensitivities (83 , 75 , 70 and 81 ) than specificities (50 , 56 , 54 and 40 , respectively), and all four parameters showed the highest accuracies (76 , 71 , 66 and 73 , respectively). The AUCROC for each marker are shown in Table 4. Ferritin, transferrin, sTfR, TfR-F index, transferrin saturation and TIBC had significantly higher AUCROC than 0.5. Among them, sTfR and TfR-F index showed AUCROC 0.75 (0.75 and 0.76 respectively) (Fig. 1), thus ROC curves from these two markers were used to explore new cut-off values with maximal sensitivity to identify ID. For sTfR the ROC curve showed no better cut-off than the current one of 1.76, which already had a sensitivity of 83 and a specificity of 50 . The ROC curve for TfR-F index showed that a cut-off of 0.86 instead of the current one of 1.5 (43 change) increased the sensitivity from 42 to 78 and theStatistical MedChemExpress Anlotinib AnalysisThe prevalence of iron stores deficiency diagnosed by each marker was estimated as the percentage of children with a value of that marker outside the internationally accepted normal range. The classification of ID by each marker was compared with the classification obtained using the “gold standard” (iron content in the bone marrow) to determine sensitivity, specificity and accuracy of each of them. To visualize the efficacy of each marker to detect ID, Receiver Operating Characteristics (ROC) curves were constructed and the areas under the resulting ROC curves (AUCROC) were calculated [46]. When a marker does not identify ID the ROC curve lies close to the diagonal and the AUCROC is close to 0.5. Therefore an AUCROC not statistically different to 0.5 indicates an ineffective test [47]. Only for those markers with an AUCROC 0.75, ROC curves were used to identify new cut-off values with maximal sensitivity to detect ID maintaining the specificity as high as possible over 50 . All comparisons were made for a two-tailed significance level of 0.05. The analysis was performed using the statistical software STATA (version 12.0, STATA Corporation, College Station, TX, USA).Results Characteristics of the Study ParticipantsA total of 443 anaemic children were recruited as cases for the case-control study and from them, 292 (66 ) underwent a bone marrow aspiration. Reasons for not performing the bone marrow aspiration were: age below 3 months in 32 (7 ) cases, potential risks of sedation in 65 (15 ) cases [history of seizures in 47 (11 ),Iron Deficiency Diagnosis and Infectionsaccuracy from 52 to 75 , but the specificity was reduced from 91 to 65 .DiscussionThis is the first study on the evaluation of iron markers to identify ID in a high K162 chemical information infection pressure setting among anaemic children with any degree of anaemia. The study compares iron markers to bone marrow iron content as the “gold standard”, and shows that detection of ID still remains unresolved in settings with high infection pressure, where ID is most prevalent and its diagnosis and management most needed. In agreement with a pre.E different iron markers using the internationally accepted cut-off values and iron content in the bone marrow as reference. The iron markers with the lowest sensitivities were plasma ferritin (15 , 11 when combined with CRP, and 1 when combined with age), transferrin (1 ) and TIBC (17 ). TfR-F index and MCHC had lower sensitivities (42 and 51 , respectively) than specificities (91 and 71 , respectively), while sTfR, TfR-F index by CRP, plasma iron and transferrin saturation had higher sensitivities (83 , 75 , 70 and 81 ) than specificities (50 , 56 , 54 and 40 , respectively), and all four parameters showed the highest accuracies (76 , 71 , 66 and 73 , respectively). The AUCROC for each marker are shown in Table 4. Ferritin, transferrin, sTfR, TfR-F index, transferrin saturation and TIBC had significantly higher AUCROC than 0.5. Among them, sTfR and TfR-F index showed AUCROC 0.75 (0.75 and 0.76 respectively) (Fig. 1), thus ROC curves from these two markers were used to explore new cut-off values with maximal sensitivity to identify ID. For sTfR the ROC curve showed no better cut-off than the current one of 1.76, which already had a sensitivity of 83 and a specificity of 50 . The ROC curve for TfR-F index showed that a cut-off of 0.86 instead of the current one of 1.5 (43 change) increased the sensitivity from 42 to 78 and theStatistical AnalysisThe prevalence of iron stores deficiency diagnosed by each marker was estimated as the percentage of children with a value of that marker outside the internationally accepted normal range. The classification of ID by each marker was compared with the classification obtained using the “gold standard” (iron content in the bone marrow) to determine sensitivity, specificity and accuracy of each of them. To visualize the efficacy of each marker to detect ID, Receiver Operating Characteristics (ROC) curves were constructed and the areas under the resulting ROC curves (AUCROC) were calculated [46]. When a marker does not identify ID the ROC curve lies close to the diagonal and the AUCROC is close to 0.5. Therefore an AUCROC not statistically different to 0.5 indicates an ineffective test [47]. Only for those markers with an AUCROC 0.75, ROC curves were used to identify new cut-off values with maximal sensitivity to detect ID maintaining the specificity as high as possible over 50 . All comparisons were made for a two-tailed significance level of 0.05. The analysis was performed using the statistical software STATA (version 12.0, STATA Corporation, College Station, TX, USA).Results Characteristics of the Study ParticipantsA total of 443 anaemic children were recruited as cases for the case-control study and from them, 292 (66 ) underwent a bone marrow aspiration. Reasons for not performing the bone marrow aspiration were: age below 3 months in 32 (7 ) cases, potential risks of sedation in 65 (15 ) cases [history of seizures in 47 (11 ),Iron Deficiency Diagnosis and Infectionsaccuracy from 52 to 75 , but the specificity was reduced from 91 to 65 .DiscussionThis is the first study on the evaluation of iron markers to identify ID in a high infection pressure setting among anaemic children with any degree of anaemia. The study compares iron markers to bone marrow iron content as the “gold standard”, and shows that detection of ID still remains unresolved in settings with high infection pressure, where ID is most prevalent and its diagnosis and management most needed. In agreement with a pre.