Acute kidney injury is a common complication of severe Plasmodium knowlesi malaria, and an important contributor to mortality. The exact pathogenic mechanisms of AKI in knowlesi malaria are not known, however it is hypothesised that haemolysis of red blood cells and subsequent release of cell-free haemoglobin leads to oxidative stress and lipid peroxidation in the renal tubules. A novel mechanism of paracetamol was recently demonstrated, showing that paracetamol acts as a potent inhibitor of hemoprotein-catalyzed lipid peroxidation. In a proof of concept trial, paracetamol at therapeutic levels was shown to significantly decrease oxidative kidney injury and improve renal function by inhibiting the hemoprotein-catalyzed lipid peroxidation in a rat model of rhabdomyolysis-induced renal injury. The investigators hypothesize that this novel inhibitory mechanism of paracetamol may provide renal protection in adults with knowlesi malaria by reducing the hemoprotein-induced lipid peroxidation that occurs in haemolytic conditions. 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 paracetamol would be of benefit, especially as it is safe and widely available.
Plasmodium knowlesi is the most common cause of malaria, and malaria deaths, in Sabah, Malaysia. Acute kidney injury (AKI) is a common feature of severe knowlesi malaria; however the mechanisms of AKI in knowlesi malaria are unknown. In falciparum malaria, recent evidence suggests that oxidative stress from haemolysis-related cell-free haemoglobin (CFHb) may contribute to pathogenesis of AKI. Cell-free haemoglobin and oxidative stress: CFHb is released during intravascular haemolysis, and when exceeding the binding capacity of plasma haptoglobin, is filtered by the glomeruli and enters the renal tubules. CFHb is pathogenic as the ferrous heme can be oxidized to the ferric state, conferring peroxidase activity to the hemoglobin. Consequently, the hemoglobin can reduce hydroperoxides, such as hydrogen peroxide (H2O2) and lipid hydroperoxides, which generate the ferryl state of heme (FeIV=O) and a protein radical. The ferryl heme and protein radical can then generate lipid radicals by oxidation of free and phospholipid-esterified unsaturated fatty acids. The arachidonic side chains of membrane phospholipids are particularly vulnerable to this free radical-mediated damage in the complex cascade of lipid oxidation leading to the generation of F2-isoprostanes (F2-IsoPs) and isofurans (IsoFs). F2-IsoPs and IsFs are increased in severe falciparum malaria, and have been shown to induce vasoconstriction associated with renal injury in other haemolytic conditions including rhabdomyolysis, sepsis and post-operatively. Paracetamol and oxidative stress: A novel mechanism of paracetamol was recently demonstrated, showing that paracetamol acts as a potent inhibitor of hemoprotein-catalyzed lipid peroxidation by reducing ferryl heme to its less toxic ferric state and quenching globin radicals. In a proof of concept trial, paracetamol at therapeutic levels was shown to significantly decrease oxidative kidney injury and improve renal function by inhibiting the hemoprotein-catalyzed lipid peroxidation in a rat model of rhabdomyolysis-induced renal injury. In a retrospective study of patients with sepsis, receiving paracetamol in the setting of raised CFHb was associated with reduced lipid peroxidation, and reduced risk of death. More recently, in a randomized placebo-controlled trial, paracetamol was associated with a reduction in F2-IsoPs and improved renal function in adults with sepsis and detectable CFHb. Rationale: The investigators hypothesize that paracetamol may provide renal protection in patients with severe knowlesi malaria by reducing the hemoprotein-induced lipid peroxidation that occurs in haemolytic conditions. 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 paracetamol would be of great benefit, especially as it is safe and widely available. Proposed activities: The main activity proposed is a randomised, open label, controlled trial of regularly-dosed paracetamol, versus no paracetamol, in patients with knowlesi malaria, to assess the effect of paracetamol on renal function and oxidative stress.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
TREATMENT
Masking
NONE
Enrollment
360
\>50kg: Paracetamol 1gm PO/NG 6 hourly for 72 hours (maximum dose 4g/24h) plus IV artesunate or oral artemether/lumefantrine. \<50kg: Paracetamol 12.5-15mg/kg/dose 6 hourly for 72 hours (maximum total dose 5doses/24hours;75mg/kg) plus IV artesunate or oral artemether/lumefantrine.
Keningau District Hospital
Keningau, Sabah, Malaysia
Queen Elizabeth Hospital
Kota Kinabalu, Sabah, Malaysia
Kota Marudu District Hospital
Kota Marudu, Sabah, Malaysia
Ranau District Hospital
Ranau, Sabah, Malaysia
Effect of Paracetamol on kidney function
Change in creatinine concentration (umol/L) at 72 hours from enrolment in patients receiving regularly-dosed paracetamol compared to those not receiving regular paracetamol, stratified by the level of intravascular haemolysis (cell-free haemoglobin).
Time frame: 72 hours
Longitudinal change in creatinine
Longitudinal change in creatinine, as measured by the area under the creatinine-time curve, with creatinine measured 12 hourly from enrolment to 72 hours; and the effect of enrolment cell-free haemoglobin on longitudinal change in creatinine
Time frame: 72 hours
Change in creatinine in severe malaria
Change in creatinine at 72 hours and longitudinal change in creatinine over 72 hours, including the effect of enrolment CFHb, in patients with severe knowlesi malaria.
Time frame: 72 hours
Development of AKI
Development of AKI over 72 hours: i) an absolute increase in serum creatinine of \>26.5 umol/L from enrolment creatinine; ii) a percentage increase in serum creatinine of \>50% from enrolment; iii) post-enrolment onset of oliguria of less than 0.5ml/kg/hour for more than 6 hours; iv) 24 hour urine output of \<400ml after rehydration and urinary obstruction excluded. AKI on enrolment will also be described by the Kidney Disease Improving Global Outcomes (KDIGO) criteria (with baseline creatinine estimated using the MDRD equation).
Time frame: 72 hours
Duration of AKI
Length of time elapsed until serum creatinine returns to normal (estimated using MDRD equation) in the absence of renal replacement therapy in those with AKI on enrolment and those that develop AKI after enrolment.
Time frame: 28 days
Longitudinal changes in haemolysis: plasma cell-free haemoglobin
Longitudinal changes in plasma cell-free haemoglobin over 72 hours.
Time frame: 72 hours
Longitudinal changes in haemolysis: plasma cell-free haem
Longitudinal changes in plasma cell-free haem over 72 hours.
Time frame: 72 hours
Longitudinal changes in haemolysis: haem-to-protein cross-links
Longitudinal changes in haem-to-protein cross-links over 72 hours.
Time frame: 72 hours
Longitudinal changes in markers of oxidative stress: F2-IsoP
Longitudinal changes in plasma F2-isoprostanes \[F2-IsoP\] over 72 hours.
Time frame: 72 hours
Longitudinal changes in markers of oxidative stress: IsoF
Longitudinal changes in plasma isofurans \[IsoF\]) over 72 hours.
Time frame: 72 hours
Longitudinal changes in F2-IsoPs according to G6PD enzyme activity
Longitudinal changes in F2-IsoPs according to G6PD enzyme activity, assessed qualitatively by fluorescent spot test.
Time frame: 72 hours
Longitudinal changes in IsoFs according to G6PD enzyme activity
Longitudinal changes in IsoFs and CFHb according to G6PD enzyme activity, assessed qualitatively by fluorescent spot test.
Time frame: 72 hours
Longitudinal changes in CFHb according to G6PD enzyme activity
Longitudinal changes in CFHb according to G6PD enzyme activity, assessed qualitatively by fluorescent spot test.
Time frame: 72 hours
Longitudinal changes in F2-IsoPs according to G6PD genotype
Longitudinal changes in F2-IsoPs according to G6PD genotype
Time frame: 72 hours
Longitudinal changes in IsoFs according to G6PD genotype
Longitudinal changes in IsoFs according to G6PD genotype
Time frame: 72 hours
Longitudinal changes in CFHb according to G6PD genotype
Longitudinal changes in CFHb according to G6PD genotype
Time frame: 72 hours
Population pharmacokinetics of paracetamol: Cmax
Peak plasma concentration (Cmax)
Time frame: 72 hours
Population pharmacokinetics of paracetamol: Tmax
Time to peak plasma concentration (Tmax)
Time frame: 72 hours
Population pharmacokinetics of paracetamol: AUC
Area under the plasma drug concentration-time curve (AUC)
Time frame: 72 hours
Population pharmacodynamics of paracetamol
Paracetamol dose-response curve
Time frame: 72 hours
Fever clearance time
Defined as the time taken for the aural temperature to fall below 37.5°C, and the time taken for the temperature to fall below 37.5°C and remain there for at least 24hours
Time frame: 72 hours
Fever duration
Defined as the duration in hours that an individual's temperature is above 37.5°C
Time frame: 72 hours
Area above the fever versus time curve (AUC-T°)
Area above the 37.5°C temperature versus time curve (AUC-T°) within first 24 hours of treatment.
Time frame: 72 hours
Parasite clearance time (hours)
Parasite clearance time, defined as (i) the time from commencement of antimalarial treatment to the first of 2 consecutive negative blood films, with blood films assessed by microscopy every 6 hours for the presence of asexual parasitaemia, and (ii) the linear portion of the slope of the log-parasitemia versus time relationship.
Time frame: 72 hours
Blood and urine biomarkers of pre-renal and renal injury
Neutrophil gelatinase-associated lipocalcin (NGAL), kidney injury molecule (KIM), urinalysis, urine microscopy, urine electrolytes, and urine creatinine.
Time frame: 72 hours
Longitudinal urine colour
Longitudinal urine colour (assessed by standardized urine colour charts). The proportion of patients with enrolment urine pH less than 6 together with a urine color of 6 or greater who develop AKI will be compared between groups.
Time frame: 72 hours
Longitudinal urine pH
Longitudinal urinalysis dipstick test-strip: urine pH. The proportion of patients with enrolment urine pH less than 6 together with a urine color of 6 or greater who develop AKI will be compared between groups.
Time frame: 72 hours
Longitudinal urine specific gravity
Longitudinal urinalysis dipstick test-strip: urine specific gravity
Time frame: 72 hours
Longitudinal urine haemoglobin
Longitudinal urinalysis dipstick test-strip: urine haemoglobin
Time frame: 72 hours
Change in creatinine (umol/L) between therapeutic concentrations of paracetamol vs those with absent or low.
Change in creatinine at 72 hours and longitudinal change in creatinine over 72 hours in patients with therapeutic concentrations of paracetamol, compared to patients with absent or low concentrations of paracetamol
Time frame: 72 hours
Number of participants with treatment-related adverse events as assessed by CTCAE v4.0
Reporting of any unfavourable and unintended sign (including an abnormal laboratory finding), symptom, or disease temporally associated with paracetamol administration
Time frame: 28 days
Longitudinal red cell deformability
Longitudinal red cell deformability, as measured by laser-assisted optical rotational red cell analyser (LORCA) elongation index.
Time frame: 72 hours
Longitudinal changes in markers of endothelial dysfunction
Longitudinal changes in markers of weibel palade body exocytosis including angiopoietin-2
Time frame: 72 hours
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