A randomised open labeled, parallel-group, controlled trial to assess the efficacy of paracetamol to reduce kidney dysfunction caused by cell-free haemoglobin-mediated oxidative damage in paediatric patients with falciparum malaria complicated by intravascular haemolysis.
Kidney dysfunction is an independent predictor of mortality in both adults and children with severe malaria. In the largest studies of paediatric severe malaria, approximately 25% of children had kidney dysfunction and these patients accounted for roughly 50% of total deaths. Although the multifactorial mechanism of severe malaria-associated AKI has primarily been studied in adults, evidence suggests that similar mechanisms of renal injury are involved in paediatric severe malaria. Cell-free haemoglobin (CFH) -mediated oxidative damage has recently been recognized as an important pathway in a range of common conditions, including rhabdomyolysis, primary pulmonary graft dysfunction, and haemolytic disorders, such as post-cardiac surgery, and malaria. During malaria infection, there is haemolysis of parasitized and uninfected red blood cells (RBCs). CFH-mediated lipid peroxidation generates F2-isoprostanes (F2-IsoPs) and isofurans (IsoFs), which are considered robust in vivo measures of oxidative stress. F2-IsoPs are potent renal vasoconstrictors that act via thromboxane A2 receptors. Both F2-IsoPs and IsoFs have been associated with AKI in patients with rhabdomyolysis, sepsis, adults with severe malaria and haemolysis post-cardiopulmonary bypass (CPB). Further, elevated haemin and CFH concentrations were associated with mortality. In a cohort of children with severe malaria, elevated haem-to-haemopexin ratio was associated with stage 3 AKI, and 6-month mortality. These studies demonstrate that intravascular haemolysis occurs with increasing severity in paediatric malaria. Haem redox cycling between ferric (Fe3+) and ferryl (Fe4+) states generates globin radicals, inducing lipid peroxidation. These data suggested that haemolysis induces oxidative damage, and CFH-mediated oxidative damage contributes to AKI complicating paediatric malaria. A novel mechanism of paracetamol was recently demonstrated, showing that paracetamol acts as a potent inhibitor of haemoprotein-catalyzed lipid peroxidation, by reducing ferryl haem to its less toxic ferric state and quenching globin radicals. We hypothesize that this novel inhibitory mechanism of paracetamol may provide renal protection in children with severe malaria by reducing the haemoprotein-induced lipid peroxidation. As there is currently no consensus that exists concerning adequate medical treatment for severe malaria complicated by intravascular haemolysis and AKI, the potential application of this safe and extensively used drug would be of great benefit. The study will be a randomised, open-labelled, controlled trial. Randomisation will be stratified into two groups : (i) Patients with no acute kidney injury (AKI) at enrolment, and (ii) Patients with AKI at enrolment. Both groups will be randomised into two arms: Arm 1: Paracetamol 15 mg/kg/dose 6 hourly for 72 hours Arm 2: Mechanical antipyresis if fever in the first 72 hours. All patients will receive intravenous artesunate followed by artemether-lumefantrine as soon as they are able to take oral medication or according to medical judgment. The study will be conducted at the Kinshasa Medical Oxford Research Unit (KIMORU, Democratic Republic of the Congo, DRC). The recruitment phase of the study is expected to last 18 months, from September 2021 - February 2022. The total time to complete the study will be approximately 3 years. Funder: Canadian Institutes of Health Research CIHR grant reference number : PJT-162116 UBC grant number: 20R01487
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
PREVENTION
Masking
NONE
Enrollment
460
Paracetamol 15 mg/kg/dose IV 6 hourly for 72 hours
Mechanical antipyresis (i.e. loose clothing, tepid sponging, fanning and cooling blanket) if fever in the first 72 hours. If a temperature \>38.5°C persists despite mechanical antipyresis, or if deemed necessary by the treating clinician, then paracetamol can be administered according to local practice (paracetamol IV 15 mg/kg as needed).
The Kinshasa Medical Oxford Research Unit (KIMORU)
Kinshasa, Congo, Democratic Republic of the Congo
RECRUITINGAcute kidney injury (AKI) or death among patients enrolled without AKI (Composite outcome)
Composite outcome of development of AKI (defined as creatinine ≥26.5 µmol/L or ≥1.5x baseline), or death at any timepoint
Time frame: during first 7 days of enrolment
Acute kidney injury (AKI) progression or death among patients enrolled with AKI (Composite outcome)
Composite outcome of worsening of AKI (defined as creatinine ≥2x baseline, or ≥3x baseline, or initiation of RRT or eGFR \<35 ml/min/ 1.73 m2) or death at any timepoint.
Time frame: during first 7 days of enrolment
Number of patients with serious adverse events
Number of patients with serious adverse events (mortality and/or hepatotoxicity, as defined by Hy's Law).
Time frame: AST/ALT/total bilirubin during the first 5 days from enrolment; mortality assessed Day 0 to 7.
Proportion of patients who develop Major Adverse Kidney Events (MAKE) composite
Major Adverse Kidney Events (MAKE) composite, defined as ≥ 1 efficacy renal endpoints: (i) death, (ii) need for renal replacement therapy, (iii)≥ 50% reduction in eGFR from baseline to 90 days.
Time frame: 90 days
Fever clearance time
Time taken for aural temperature: (i) to fall \< 37.5°C (FCT-A), and (ii) to fall \< 37.5°C and remain there for \>24 h (FCT-B)
Time frame: 6-hourly temperature assessments during first 7 days from enrolment
Coma recovery
Time until Glasgow Coma Score (GCS) return to 15 (or Blantyre Coma Score (BCS) return to 5 in preverbal children)
Time frame: 6-hourly GCS/BCS assessments during first 7 days from enrolment
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Longitudinal change in renal function
As measured by creatinine concentration (umol/L)
Time frame: During the first 7 days from enrolment
Longitudinal change in markers of hemolysis
As measured by cell-free haemoglobin (ug/mL), haemopexin (ug/mL), haptoglobin (ug/mL), haem (uM), F2-isoprostane (pg/mL) and isofurans (pg/mL) concentrations
Time frame: during the first 3 days from enrolment
Longitudinal change of endothelial activation
As measured by concentrations of angiopoietin-Tie2 pathway markers (i.e. Ang-1, Ang-2, sTie2, sTie1)
Time frame: during the first 3 days from enrolment
Longitudinal change of immune activation
As measured by soluble triggering receptor expressed on myeloid cells concentration (sTREM-1; pg/mL)
Time frame: during the first 3 days from enrolment
Longitudinal change of AKI biomarker
As measured by cystatin-C concentration (Cys-C; ug/mL)
Time frame: during the first 3 days from enrolment
Parasite (parasites/ul) clearance
as measured by time until two consecutive negative smears (hours), and by rate using the parasite clearance estimator to determine slope half-life (hours) from 12-hourly parasite counts.
Time frame: 12-hourly parasitemia assessments during first 7 days from enrolment
Exploratory analysis with sex
Primary efficacy analyses will be analysed using a logistic regression model to obtain odds ratios, comparing the odds of a combined endpoint of kidney function deterioration or death between treatment groups. A multivariable model including an interaction term (sex and treatment) will be assessed in the primary analyses to explore potential differences between males and females.
Time frame: During first 7 days from enrolment
Pharmacokinetic properties
Population pharmacokinetic model (relative bioavailability, mean transit absorption time (hours), apparent oral elimination clearance (L/hours), apparent volume of distribution (L)
Time frame: during the first 24 hours from enrolment
Pharmacokinetic properties
Peak plasma concentration (Cmax; mg/L)
Time frame: during the first 24 hours from enrolment
Pharmacokinetic properties
Time to peak plasma concentration (Tmax; hours)
Time frame: during the first 24 hours from enrolment
Pharmacokinetic properties
Terminal elimination (t1/2; hours)
Time frame: during the first 24 hours from enrolment
Pharmacokinetic properties
Area under the plasma drug concentration-time curve (AUC0-24; mg×h×L-1)
Time frame: during the first 24 hours from enrolment
Pharmacodynamic relationships
Pharmacodynamic effects on creatinine concentration (mol/L)
Time frame: during first 7 days from enrolment
Pharmacodynamic relationships
Pharmacodynamic effects on liver toxicity, as measured by AST and ALT (U/L)
Time frame: during first 7 days from enrolment
Pharmacodynamic relationships
Pharmacodynamic effects on temperature (Celsius)
Time frame: during first 7 days from enrolment
Pharmacodynamic relationships
Pharmacodynamic effects on parasitemia, as measured by parasites/ul and slope half-life
Time frame: during first 7 days from enrolment
Pharmacodynamic relationships
Pharmacodynamic effects on GCS (or BCS in pre-verbal children)
Time frame: during first 7 days from enrolment