Academic literature on the topic 'Sysmex XN-1000'

Background: DYMIND DH76 (DYMIND BIOTECH, China) is a new automated hematology system designed to provide CBC count, including a 5-part WBC differential count, and its analytical performance should be assessed before adoption for clinical use. Methods: The analyzer was evaluated according to the International Council for Standardization in Haematology guideline. The purposes of this study were to assess its analytical performance in comparison to SYSMEX XN 1000 hematology analyzer currently used in our laboratory, as well as to compare the automated and manual WBC differential. Results: Within-run precision in all concentration ranges was very good with coefficients of variation (CVs) between 0.02% and 2.5% except for platelets over 500×109/L (CV 9.5%). Within-batch imprecision showed CVs lower the declared deviation ranges. Accuracy (defined as trueness) was excellent for all CBC and white cell differential parameters, compared with the state of the art%. Linearity was confirmed with excellent regression coefficients (0.999-1.000), even in the lowest values, and carryover was ≤ 1%. Comparison between DYMIND DH76 and SYSMEX XN 1000 was also very good with correlation coefficients (R2) for WBC (1.000), RBC (0.999), hemoglobin (0.999) and PLT over 50×109/L (0.994) and R2 was lower but still acceptable (0.910) for PLT<50×109/L. R2 for neutrophils, lymphocytes, eosinophils, basophils, and monocytes were 0.974, 0.982, 0.957, 0.625, and 0.836, respectively, in the comparison between the manual and DYMIND DH76 automated differential WBC counts. Conclusions: With excellent analytical performance and acceptable comparative analysis, DYMIND DH76 hematology analyser covered the predefined international standards and requirements and is fully appropriate for clinical application.

Malaria remains a health problem in Indonesia. Microscopic examination with Giemsa staining is the gold standard for diagnosing malaria. The density of parasites correlates with the degree of severity and response to therapy of malaria. Malaria-causing plasmodium can be detected by Sysmex XN-1000 which is marked by abnormalities in the WDF, WNR and RET scattergram. This research aimed to determine the correlation of WDF, WNR and RET abnormal scattergram detected by Sysmex XN-1000 and the parasitemia index of malaria at the Merauke General Hospital. This was a cross-sectional study with observational approach conducted between November 2017 – February 2018 at the Merauke General Hospital. Positive malaria samples were stained with Giemsa, their parasitemia index was calculated, routine complete blood count using Sysmex XN-1000 was performed, and the scattergram abnormalities were then analyzed. There were 65 positive malaria samples as follows: P.falciparum (35%), P.vivax (60%), P.ovale (3.1%), and P.malariae (1.5%), but the species did not correlate with parasitemic index (p=0.691). Abnormalities of WDF and WNR scattergram were predominantly found than RET scattergram (80% vs. 27.7%). P.vivax predominantly caused abnormalities of the WDF and WNR scattergram in 36 of 39 samples (92.3%), whereas P.falciparum predominantly caused abnomalities of the RET scattergram in 14 of 23 samples (60.9%). There was 95% positivity of an abnormality in WDF/WNR/RET scattergram with a cut-off of > 5,0165.5/µL. There was correlation between WDF, WNR, RET scattergram detected by Sysmex XN-1000 and the parasitemia index.

Genetic hemoglobinopathies are the most common single-gene disorder worldwide. Some automated hematology analyzers have the capability of flagging individuals who may have hematological disorders based on complete blood count (CBC) biomarkers. We aimed to evaluate the accuracy of a hematology analyzer in identifying genetic hemoglobinopathies in Cambodian women and to determine which hematological biomarkers are the best predictors. A CBC was completed using a Sysmex XN-1000 analyzer and hemoglobinopathies were determined with capillary hemoglobin electrophoresis for 808 nonpregnant Cambodian women. Sysmex XN-1000 Interpretive Program (IP) messages, which flag potential hematological disorders, were produced from CBC results. Then, 2 × 2 tables were used to determine sensitivity and specificity of the IP message “Hemoglobin defect” to detect a genetic hemoglobinopathy. Receiver operating characteristic (ROC) analyses assessed the diagnostic ability of six CBC biomarkers to predict a genetic hemoglobinopathy. In total, 74% of women had a hemoglobinopathy (predominantly Hb E and α-thalassemia). “Hb defect” IP message sensitivity and specificity for genetic hemoglobinopathy detection were 10.4% and 98.6%, respectively. Variable selection strategies yielded a two-variable model including mean corpuscular volume (MCV) and red blood cell (RBC) count (AIC = 99.83, AUCROC = 0.98 (95% CI: 0.97, 0.99)) for the prediction of a homozygous EE disorder. Sensitivity and specificity values do not justify the use of Sysmex XN-1000 IP flag messages for identification of genetic hemoglobinopathies in Cambodian women. Development of an algorithm based on MCV and RBC biomarkers may optimize the screening ability of automated hematology analyzers.

Sysmex XN-1000 hematology analyzer is an automated 5-part diff analyzer (eosinophils, basophils, neutrophils, lymphocytes, and monocytes). In the calculated area, the type of difference between the Sysmex hematology device and other hematology devices is Immature Granulocyte (IG), Nucleated Red Blood Cell (NRBC), and High Fluorescent Lymphocytes Count (HFLC). The cells calculated in the HFLC area are atypical lymphocytes. In patients with dengue hemorrhagic fever, it is often found atypical lymphocytes called blue plasma lymphocytes. The purpose of this study was to determine the description of HFLC in patients with dengue fever using the hematology analyzer Sysmex XN-1000. A descriptive retrospective study was conducted during April-May 2017. The subjects of the study were adult patients diagnosed with dengue hemorrhagic fever with WHO criteria. Of the 47 samples of Dengue Hemorrhagic Fever (DHF) patients, the average HFLC results were between 2.0-32.3%, which was 11.5%, while the average range of normal HFLC values was between 0.0-1.4% and was 0.3%. In cases of DHF, there is an increase in HFLC. This is likely to be attributed to atypical lymphocyte increase in dengue hemorrhagic fever. Further research with more varied samples still needs to be done.

BackgroundThe Sysmex XN haematology instrument performs automatic reflex testing, depending on sample results. A nucleated red blood cell (NRBC) count is provided on all samples. The instrument has a smaller footprint (34%) than previous Sysmex XE analysers.MethodsAn evaluation comparing all results to the Sysmex XE-2100 and manual microscopic differential and morphology (n=390) was performed followed by a workflow study of 1000 samples to compare speed of operation and number of blood films reviews required from both systems.ResultsThe new features on the instrument are: (1) white cell and NRBC channel, all samples include the NRBC count; (2) white cell precursor channel: false positive flags for blasts, abnormal lymphocytes and atypical lymphocytes are reduced significantly without a statistical increase of false negatives; (3) low white cell count mode: suggested setting of <0.5×109/l. An extended count is more precise and provides an accurate differential. Fluorescent platelet count is performed in a dedicated channel. If the red cell or platelet size histograms are abnormal or if the platelet count is low, then a fluorescent platelet count is automatically performed. Good correlation with the XE-2100 and manual differential was found and the improved results compared to the reference flow cytometric analysis for platelet counts, especially below 30×109/l (XE-2100, R2=0.500; XN, R2=0.875).ConclusionThe XN showed reduced sample turnaround time of 10% and reduced number of blood films for examination, 49% less than the XE-2100 without loss of sensitivity with more precise and accurate results on low cell counts.

AbstractA 1½-year-old female child presented with swelling in thoracolumbar region and delayed developmental milestones. The routine hemogram analysis on Sysmex XN 1000 showed flags of white blood cell (WBC) abnormal scattergram and lymphocytosis. The peripheral smear examination showed Alder–Reilly (AR) granules leading to a suspicion of underlying Mucopolysaccharidosis (MPS). Further clinical workup, radiographic studies, chemical test lead to the confirmatory diagnosis of MPS. A flag of abnormal WBC scattergram and AR anomaly are the hematological findings that can be seen in a case of MPS.

Determination of erythrocyte count in cerebrospinal fluid (CSF-EPC) is used to exclude various intracranial hemorrhage, especially subarachnoid hemorrhage (SAH). SAH means a bleeding between the pia mater and arachnoidea which occurs due to rupture of an aneurysm in the subarachnoid space. Manual counting of erythrocytes in the cerebrospinal fluid with Bürkers chamber and microscopy has been the gold standard for the past decades, but the manual method is time consuming and requires great experience. The purpose of this study was to evaluate if manual analysis of  CSF-EPC with counting chamber, and light microscopy can be replaced by automated analysis of CSF-EPC with Hematology Analyzer XN-1000 (Sysmex). Fortyeight cerebrospinal fluid samples with various concentrations of erythrocytes ware prepared by diluting known concentration of erythrocytes in cell-free CSF. Prepared CSF-samples with added erythrocytes were analyzed first on the XN-1000. Thereafter, manual counting of erythrocytes was performed using Bürkers counting chamber. A linear regression was established to describe the correlation between the automated analysis of the CSF-EPC and manual analysis of the CSF-EPC. Imprecision in the analysis of the CSF-EPC on the XN-1000 (Sysmex) was assessed by within-run imprecision. A very good correlation (r = 0.999) was found between the XN-1000 and manual counting. For results in the lower range, 100 - 5000 (106/L), correlation was also good (r = 0.997). The coefficient of variation was 19,8 % at CSF-EPC of 370 x 106/L and 3.1 % at CSF-EPC of 25 950 x 106/L. The sensitivity for analysis of CSF-EPC on XN-1000 was 370 x 106/L. The conclusion is that the analysis of Csv-EPC on XN-1000 can be used for clinical diagnostics of CSF- samples. However, it should be noted that XN-1000 has poor sensitivity for low CSF-EPC values < 370 x 106/L. To ensure high diagnostic quality even in CSF-samples with low erythrocyte counts are recommended a reference limit of < 500 x 106/L as a practical cut off for supplemental microscopic counting in routine healthcare laboratories.
SAMMANFATTNING Bestämning av antalet erytrocyter i cerebrospinalvätska (Csv-EPK) används för att utesluta olika intrakraniella blödningar, särskilt subaraknoidalblödning (SAB). SAB betyder en blödning mellan pia mater och araknoidea som uppstår på grund av ruptur av ett aneurysm i subaraknoidalrummet. Manuell räkning av antalet erytrocyter i cerebrospinalvätska med Bürkers kammare och mikroskopi har varit den gyllene standarden under de senaste decennierna, men den manuella metoden är tidskrävande och kräver stor erfarenhet. Syftet med detta examensarbete var att utvärdera om manuell analys av Csv-EPK med räknekammare och ljusmikroskopi kan ersättas med automatisk analys av Csv-EPK med hematologianalysatorn XN-1000 (Sysmex). Fyrtioåtta cerebrospinalvätskeprover med varierande koncentrationer av antalet erytrocyter framställdes genom att späda kända koncentrationer av erytrocyter i cellfri Csv. Framställda Csv-prover med tillsatta erytrocyter analyserades först på XN-1000. Efter detta utfördes manuell räkning av erytrocyter i Bürkers kammare. En linjär regression upprättades för att beskriva korrelation mellan automatiserad analys av Csv-EPK och manuell analys av Csv-EPK. Imprecisionen avseende analys av Csv-EPK på XN-1000 (Sysmex) bedömdes genom inom-serie-imprecision. En mycket god korrelation (r = 0,999) fanns mellan XN-1000 och manuell räkning. För analysresultat inom det lägre område 100 - 5000 (106/L) var korrelationen också god (r = 0,997). Variationskoefficienten var 19,8 % vid Csv-EPK på 370 x 106/L respektive 3,1 % vid Csv-EPK på 25950 x 106/L. Känsligheten för analys av Csv-EPK på XN-1000 var 370 x 106/L. Slutsatsen är att analys av Csv-EPK på XN-1000 kan användas för klinisk diagnostik av Csv-prover. Däremot bör det noteras att XN-1000 har sämre känslighet för låga Csv-EPK värden < 370 x 106/L. För att kunna säkerställa hög diagnostisk kvalitet även på Csv-prover med låga erytrocytantal rekommenderas en referensgräns på < 500 x 106/L som praktisk cut off för kompletterande mikroskopisk räkning vid rutinsjukvårdslaboratorier.

Syre transporteras från lungorna, via blodet bundet till erytrocyternas hemoglobin, till kroppens alla celler. En hemoglobinkoncentration i blodet under referensintervallet definieras som anemi och påverkar hela kroppen och försämrar den fysiska prestationsförmågan. Järnbristanemi är en anemi med otillräcklig järntillförsel till benmärgen på grund av tomma järnförråd (absolut järnbrist) eller försvårat järnutnyttjande (funktionell järnbrist). Analysparametern HYPO på analysinstrumentet Advia 2120 (Siemens) mäter andelen hypokroma erytrocyter (erytrocyter med lågt hemoglobininnehåll) och anses vara en av de bästa parametrarna för att påvisa funktionell järnbrist. Analysparametern Hypo-He på analysinstrumentet XN-1000 (Sysmex) är en forskningsparameter för samma ändamål. Syftet med detta arbete var att jämföra markörer för funktionellt järnstatus och utvärdera om analysen HYPO på Advia 2120 kan ersättas med Hypo-He på XN-1000. Fyrtiofyra patientprover, på vilka HYPO var beställt, analyserades, först på XN-1000 och därefter på Advia 2120. En linjär regressionmodell gjordes för att beskriva korrelationen mellan analyserna HYPO och Hypo-He. Imprecisionen för analysen Hypo-He beräknades genom inom-serie- och total-serie-imprecision. Korrelationen mellan analyserna var måttligt stark (r = 0,7185 (absoluta värden) och r = 0,8081 (logaritmerade värden)), dock med många analysresultat inom det lägre området. Variationskoefficienten för Hypo-He beräknades till mellan 0 % - 9,5 %. För att kunna avgöra om Hypo-He kan ersätta HYPO som indikator på funktionell järnbrist krävs kompletterande studier på välkaraktäriserade patientprover med varierande analysvärden inkluderande värden för HYPO på mer än 10 %.