METHODS: This is a prospective case-control study. We registered 80 patients and 60 healthy controls from Jan 2009 to Dec 2013. Complete blood counts, prothrombin time, activated partial thromboplastin time, protein C, protein S, antithrombin, serum ferritin, liver enzymes; HbsAg and Anti- HCV were evaluated.
RESULT: There were 42 males and 38 females with mean age of 12.30±5.50 years. The mean protein C, protein S and antithrombin in patients and control were 58.25±22.5 versus 110.67±22.60, 67.90±19.58 versus 98.70±21.54 and 89.73±18.09 versus 104.0±10.98 (p<0.001) respectively. Protein C was predominantly deficient in 65% followed by protein S and antithrombin in 35% and 20% respectively. Protein C deficiency divulged positive correlation with protein S deficiency (p = 0.035) and antithrombin deficiency with hemoglobin of ≤8gm% (p<0.0025). No significant correlation of prothrombotic markers was established with maternal characteristics, hepatic dysfunction, hepatitis and serum ferritin.
CONCLUSION: Substantial decrement in prothrombotic markers, primarily protein C, may be implicated in elevated thrombosis; however follow-up data is required to establish definitive thromboembolic events.
METHODS: We illustrate the results of a large cohort of newly diagnosed adults ITP from southern Pakistan. The study extended from January 2009-December 2013. Complete blood counts, HbsAg, Anti-HCV, ANA, stool for Helicobacterpylori were done on all. HIV, TSH, anti-dsDNA, RA factor, APLA and direct coombs test were evaluated in cases where indicated.
RESULTS: A total of 417 patients were included with a mean age of 40.95±14.82 years. Primarily disease was observed in the 3rd decade of life. Male to female ratio was 1:1.5. Mean platelets count was 46.21±27.45x109/l. At diagnosis 43.16% (n=180) patients had hemorrhagic manifestations whilst 56.8% (n=237) were asymptomatic. None of the patient presented with visceral, retropharyngeal or intracranial bleed. The prevalence of secondary ITP was substantially higher (64.8%) as compared to primary ITP (35.2%). Secondary ITP was predominantly seen in HCV reactive patients (24.4%) followed by helicobacter-pylori infection (11%). Nevertheless 16.4% patients had underlying autoimmune disorders. Providentially no study subject was found to be HIV reactive.
CONCLUSIONS: Our study revealed predominance of secondary ITP. However bleeding manifestations and degree of thrombocytopenia were high in primary-ITP. Infectious etiology followed by autoimmune disorders is mainly implicated for secondary ITP in our setting.
METHODS: This prospective study was conducted from February 2015 to February 2016. Samples from seronegative donors were run on multiplex assay (Cobas, S-201 system platform, Roche) in a batch of six [MP-NAT]. In case of reactive pool, tests were run on every individual sample [IDNAT].
RESULTS: Of 16957 donors, 16836 (99.2%) were replacement donors and the remaining 121 (0.7%) were voluntary donors, with a mean age of 29.09 ± 7.04 years. After serologic screening of all 16957 donors, 955 (5.6%) were found to be reactive; 291(1.71%) were reactive for hepatitis-B surface antigen, 361 (2.12%) for antibody to hepatitis C virus (anti-HCV), 14 (0.08%) for antibody to human immunodeficiency virus, 287 (1.69%) for syphilis and 2 (0.01%) for malaria. 14 (0.08%) NAT reactive donors were identified after testing the 16002 seronegative donors, with an overall NAT yield of one reactivity out of 1143 blood donations; 10 donors for HBV-DNA (HBV NAT yield-1:1600) and remaining 4 for HCV-RNA (HCV-NAT yield-1:4000). None were HIV positive.
CONCLUSION: NAT has improved the safety attributes in blood products. Although the positivity rate for NAT testing is low but in view of the high prevalence of transfusion transmitted infections in our country, we recommend the parallel use of both serology and NAT screening of all donated blood.