Combined thrombolytic and anticoagulant therapy for venous thrombosis in children.

OBJECTIVES: To evaluate safety, efficacy, and outcome after combination thrombolytic and anticoagulant therapy. STUDY DESIGN: An open nonrandomized clinical protocol with prospective standardized monitoring and data collection. Children with a documented first episode of deep vein thrombosis were treated with urokinase 4400 U/kg load and per hour with unfractionated heparin at 10 U/kg/h. At 48 hours heparin infusions were increased to achieve a therapeutic level for 5 days. Children were given therapeutic warfarin for at least 3 months. Outcome was assessed at 48 hours and > or =1 year with history, physical examination, high-resolution imaging, and Doppler ultrasonography +/- impedance and photo plethysmography. RESULTS: Thirty-two children were treated. There was 1 thrombotic death, 1 nonfatal thrombus progression, and 1 pulmonary embolism. At 48 hours half of the children showed substantial clot lysis, and on follow-up these children had complete resolution and had no symptoms. Three children with poor early clot lysis had recurrent thromboemboli, pulmonary embolism, or both, 2 had limb pain and swelling, and 2 had asymptomatic swelling. Two children had minor bleeding, whereas systemic reactions were common. CONCLUSIONS: Combination therapy in children (urokinase and unfractionated heparin) was safe and efficacious. A prospective, randomized, controlled study in children is needed.

Lupus anticoagulant and protein S deficiency in children with postvaricella purpura fulminans or thrombosis.

OBJECTIVE: The objective of this study was to determine the cause of purpura fulminans, disseminated intravascular coagulation, or thrombosis in seven children with varicella. All children were found to have a lupus anticoagulant and acquired protein S deficiency. Thrombosis in five children was associated with presumed or documented infection with streptococcus. STUDY DESIGN: Coagulation tests included determinations of the activated partial thromboplastin time, the prothrombin time, the dilute Russell viper venom time, the prothrombin F 1 + 2 fragment, the C4b-binding protein (C4b), total and free protein S antigen, and clotting activities of factors II, V, VII, and X and of protein C and protein S. Autoantibodies to phospholipids, cardiolipin, and protein S were determined in enzyme-linked immunosorbent assays. RESULTS: All children had a lupus anticoagulant and acquired protein S deficiency. Thrombosis in five children was associated with presumed or documented infection with streptococcus. All children transiently expressed free protein S deficiency, elevated levels of IgG, IgM, or both binding to protein S, the lupus anticoagulant, and increased concentration of the F 1+2 fragment. Four children also had antiphospholipid or anticardiolipin antibodies. In one child a purified IgG fraction cross-reacted with both protein S and a specific varicella antigen. CONCLUSIONS: A subset of children with varicella infection, some of whom are coinfected with streptococcus, are prone to development of a lupus anticoagulant and an autoantibody to protein S, which results in acquired free protein S deficiency. Such children are at risk of having life-threatening thrombotic events.

Thrombosis in otherwise well children with the factor V Leiden mutation.

OBJECTIVE: To determine whether resistance to activated protein C caused by the factor V Leiden mutation (Arg506 to Gln) is associated with thrombosis occurring during childhood. STUDY DESIGN: Children with thrombosis were screened for activated protein C resistance. Children found resistant to activated protein C had DNA analysis for the factor V Leiden mutation. Family members of the children with activated protein C resistance were similarly studied. RESULTS: Three of fourteen children examined had abnormal normalized activated protein C sensitivity ratios. One child had protein S deficiency. The children had hyperlipidemia. Molecular confirmation of the factor V Leiden mutation was obtained for all three children. Family members of each of the three children were affected. CONCLUSIONS: Children have thromboses in association with the factor V Leiden mutation, as do adults. This mutation may be identified as an isolated risk factor or in association with other risk factors for thrombosis.

Severe neonatal protein C deficiency: prevalence and thrombotic risk.

Severe deficiencies of protein C, a pivotal coagulation-regulatory protein, have been reported in neonates as an apparently transient condition. In this prospective study, cord blood was collected at 193 deliveries and assays of protein C were correlated with clinical status, other coagulation results, and outcome. Protein C levels of less than 0.1 unit/ml were found most frequently in preterm infants with respiratory distress, infants of diabetic mothers, and infants of twin gestations. Levels of protein C correlated with levels of factor VIII activity but did not correlate with markers of consumptive coagulopathy. A protein C level less than 0.1 unit/ml was significantly correlated with the subsequent onset of thrombosis, even when the effects of gestational age and birth weight were excluded. Low cord blood levels of protein C may reflect delayed maturation or increased turnover in certain infants and appear to convey an independent risk of thrombosis, but the critical concentration of protein C necessary to maintain neonatal hemostasis is not known.

Severe protein C deficiency in newborn infants.

Eleven infants initially seen in the neonatal period had levels of protein C suggestive of homozygous protein C deficiency but as an apparently acquired condition. Family studies failed to document parental carrier status, the clinical course was not typical of that reported with homozygous protein C deficiency, and protein C levels increased in all restudied infants, six of whom received heparin anticoagulation. No infant had evidence of vitamin K deficiency. Care is advised in the evaluation of infants with low levels of protein C. Parental blood studies, delayed testing, and serial assays can help to establish the correct diagnosis.

Vitamin K deficiency in the newborn infant: prevalence and perinatal risk factors.

The prevalence of vitamin K deficiency in newborn infants and the influence of perinatal risk factors were studied prospectively in 934 infants. A noncarboxylated prothrombin assay to detect proteins induced in vitamin K absence (PIVKA-II) was used to determine the presence of vitamin K deficiency; of 934 cord blood samples assayed, 2.9% were positive for PIVKA-II (0.015 to 0.15 U/ml). All infants found to have detectable PIVKA-II were born at term. The number of infants positive for PIVKA-II was greater in the group small for gestational age (7.4%) than in those appropriate (2.7%) or large (3.1%) for gestational age. Nine categories of perinatal risk groups were defined: however, the majority of infants who were PIVKA-II positive (63%) were normal. All infants received prophylactic vitamin K, and no infant with PIVKA-II in the cord sample subsequently had clinical bleeding. In two patients the rate of 50% disappearance of PIVKA-II after vitamin K administration approximated 70 hours. Two PIVKA-II positive patients with active bleeding or disseminated intravascular coagulation had an accelerated disappearance of 20 to 40 hours. The long disappearance time of PIVKA-II in a steady state may allow detection of vitamin K deficiency despite administration of vitamin K. The majority of cases of neonatal vitamin K deficiency occurred in normal newborn infants. Therefore, all infants should receive prophylactic vitamin K at birth.