ABSTRACT
Introduction: Automated body fluid (BF) analysis is gradually replacing the traditional methods of cell counting in all BFs. This study was done to analyze the high-fluorescence (HF)-BF parameter generated on Sysmex XN-1000 and study its correlation with the presence of malignant cells in the body fluids. A correlation between manual and automated differential counts was also done. Materials and Methods: A total of 1985 samples including 797 ascitic fluids (AF), 532 pleural fluids (PF), and 656 cerebrospinal fluids (CSF) were run on Sysmex XN-1000 in BF mode and cytopathology was available for 924 BFs including 389 AF, 379 PF, and 156 CSF. Both manual and automated methods were used for cell differential and cell morphology. Results: Of the 924 samples with corresponding cytopathology, malignancy was found in 59 samples. The HF-BF%/100 WBCs (24.8 ± 72.5) and HF-BF#/?L (329.86 ± 932.35) for malignant BF samples were found to be significantly higher than the nonmalignant samples (4.41 ± 8.1) and (19.57 ± 61.91), respectively. Receiver–operator-characteristic curve cutoffs for all BF for percentage and absolute HF-BF were 2.85%/100 WBCs and >12/?L. A good correlation was found between the manual and automated WBC differential counts in all fluids except CSF with total count <5/?L. Conclusions: BFs can be reliably analyzed on automated analyzers. HF-BF parameter is helpful in identifying malignant samples but cannot be totally relied upon. If HF-BF%/# are above the lab-generated cutoffs, microscopy should be done. A complete validation study on HF-BF parameter in BF mode is desired to set the standards for the analysis of serious effusions.
ABSTRACT
Effect of myocardial ischaemia on the bioantioxidants levels in the cat heart was evaluated. In addition, effect of curcumin, an anti-inflammatory and anti-thrombotic drug, and quinidine, a standard antiarrhythmic drug, was also studied in the cat. Myocardial ischaemia was induced by the ligation of left descending coronary artery. Quinidine (1 mg/kg, iv) was administered 15 min prior to while curcumin (100 mg/kg, ip) was given 30 min before ligation. Hearts were removed 4 h post coronary artery ligation. Levels of glutathione (GSH), malonaldelhyde (MDA), myeloperoxidase (MPO), superoxide dismutase (SOD), catalase (CAT) and lactate dehydrogenase (LDH) were estimated in the ischaemic and non-ischaemic zones. Both the drugs protected the animals against decrease in the heart rate and blood pressure following ischaemia. In the ischaemic zone, after 4 h of ligation, an increase in the level of MDA and activities of MPO and SOD (cytosolic fraction) were observed. Quinidine and curcumin pretreatment prevented the ischaemia-induced elevation in MDA contents and LDH release. Curcumin pretreatment did not prevent the increase in MPO activity while quinidine did. Results obtained indicate alterations in the bioantioxidants following ischaemia and both curcumin and quinidine prevented ischaemia induced changes in the cat heart.