Preeti Jaggi1, Wei Wang, Igor Dvorchik, Beth Printz, Erika Berry, John P Kovalchin, Karen Texter, Octavio Ramilo, Jane C Burns, Adriana H Tremoulet. 1. From the *Department of Pediatrics, Nationwide Children's Hospital and The Ohio State University, Columbus, Ohio; †Department of Statistics, Clinical Research Institute, Nationwide Children's Hospital, Columbus, Ohio; ‡Department of Pediatrics, University of California San Diego, La Jolla, California, and §Rady Children's Hospital San Diego, San Diego, California.
Abstract
BACKGROUND: We sought to determine if fever in the early postintravenous immunoglobulin (IVIG) time period (first 36 hours after IVIG completion) for Kawasaki disease, with or without additional infliximab, can predict IVIG resistance and coronary artery abnormalities (CAA). METHODS:Acute Kawasaki disease subjects enrolled in a clinical trial of infliximab plus IVIG (n = 96) versus placebo/IVIG (n = 94) had temperatures recorded every 6 hours after completion of IVIG infusion. Fever was defined as temperature >38.0°C; patients with persistent or recrudescent fever >36 hours after completion of IVIG were classified as IVIG resistant. Multivariable logistic regression by fever pattern was performed to predict outcomes (IVIG resistance and CAA). RESULTS: There was no difference in the time to defervescence between the infliximab/IVIG group (n = 96) versus placebo/IVIG group (n = 94). There was no fever after completion of IVIG in the majority of subjects [66% of those with no CAA (n = 139) and 76.5% of those with CAA, (n = 51)]. Although subjects with at least 1 fever 24-36 hours post-IVIG had a higher probability of IVIG resistance [odds ratio = 30.6 (95% confidence interval: 6.7-139.8); P < 0.0001], fever at 24-36 hours was not associated with higher likelihood of CAA. There were also 11% (n = 19) of IVIG responders who had fever at 24-36 hours post-IVIG. The majority of subjects with CAA (43 of 51, 84.3%) were identified by the initial echocardiogram, so the effect of fever on development of CAA could not be assessed. CONCLUSIONS:Fever in the first 36 hours after IVIG completion is not predictive of CAA. Our data support refraining from retreatment until 36 hours after completion of IVIG.
RCT Entities:
BACKGROUND: We sought to determine if fever in the early postintravenous immunoglobulin (IVIG) time period (first 36 hours after IVIG completion) for Kawasaki disease, with or without additional infliximab, can predict IVIG resistance and coronary artery abnormalities (CAA). METHODS:Acute Kawasaki disease subjects enrolled in a clinical trial of infliximab plus IVIG (n = 96) versus placebo/IVIG (n = 94) had temperatures recorded every 6 hours after completion of IVIG infusion. Fever was defined as temperature >38.0°C; patients with persistent or recrudescent fever >36 hours after completion of IVIG were classified as IVIG resistant. Multivariable logistic regression by fever pattern was performed to predict outcomes (IVIG resistance and CAA). RESULTS: There was no difference in the time to defervescence between the infliximab/IVIG group (n = 96) versus placebo/IVIG group (n = 94). There was no fever after completion of IVIG in the majority of subjects [66% of those with no CAA (n = 139) and 76.5% of those with CAA, (n = 51)]. Although subjects with at least 1 fever 24-36 hours post-IVIG had a higher probability of IVIG resistance [odds ratio = 30.6 (95% confidence interval: 6.7-139.8); P < 0.0001], fever at 24-36 hours was not associated with higher likelihood of CAA. There were also 11% (n = 19) of IVIG responders who had fever at 24-36 hours post-IVIG. The majority of subjects with CAA (43 of 51, 84.3%) were identified by the initial echocardiogram, so the effect of fever on development of CAA could not be assessed. CONCLUSIONS:Fever in the first 36 hours after IVIG completion is not predictive of CAA. Our data support refraining from retreatment until 36 hours after completion of IVIG.
Authors: Lynn A Sleeper; L Luann Minich; Brian M McCrindle; Jennifer S Li; Wilbert Mason; Steven D Colan; Andrew M Atz; Beth F Printz; Annette Baker; Victoria L Vetter; Jane W Newburger Journal: J Pediatr Date: 2010-12-18 Impact factor: 4.406
Authors: Jane W Newburger; Lynn A Sleeper; Brian W McCrindle; L LuAnn Minich; Welton Gersony; Victoria L Vetter; Andrew M Atz; Jennifer S Li; Masato Takahashi; Annette L Baker; Steven D Colan; Paul D Mitchell; Gloria L Klein; Robert P Sundel Journal: N Engl J Med Date: 2007-02-15 Impact factor: 91.245
Authors: Jane W Newburger; Masato Takahashi; Michael A Gerber; Michael H Gewitz; Lloyd Y Tani; Jane C Burns; Stanford T Shulman; Ann F Bolger; Patricia Ferrieri; Robert S Baltimore; Walter R Wilson; Larry M Baddour; Matthew E Levison; Thomas J Pallasch; Donald A Falace; Kathryn A Taubert Journal: Pediatrics Date: 2004-12 Impact factor: 7.124
Authors: Adriana H Tremoulet; Sonia Jain; Preeti Jaggi; Susan Jimenez-Fernandez; Joan M Pancheri; Xiaoying Sun; John T Kanegaye; John P Kovalchin; Beth F Printz; Octavio Ramilo; Jane C Burns Journal: Lancet Date: 2014-02-24 Impact factor: 79.321
Authors: Adriana H Tremoulet; Brookie M Best; Sungchan Song; Susan Wang; Elena Corinaldesi; Julia R Eichenfield; Danielle D Martin; Jane W Newburger; Jane C Burns Journal: J Pediatr Date: 2008-03-04 Impact factor: 4.406