IL-1ra Dose-range Study for Moderate-to-severe TBI Patients

Overview

Traumatic brain injury (TBI) is a common condition with high degree of morbidity and mortality (Hyder et al., 2007). Current treatment paradigms for TBI focus on mitigating secondary injury and maintaining cerebral physiology (Carney et al., 2016), however, there are currently no approved drugs that target the underlying conditions for patients suffering from TBI (Bullock et al., 1999). It is increasingly recognised that the innate inflammatory response to TBI may inflict injury (Lucas et al., 2006), and one of the most prominent mediators of inflammation in the injured brain is the Interleukin-1 (IL-1) receptor pathway (Allan et al., 2005). An endogenous antagonist to IL-1, is available in recombinant form (IL-1ra, Kineret), and is known to be safe in TBI (Helmy et al., 2014). In order to fully understand, and potentially optimize, the effect of Kineret, the investigators wish to conduct a dose-response study by giving three cohorts (n=20 per group) either placebo (isotonic saline), 1.5g or 3.0g of active substance administered intravenously in a double-blind, randomized setting. The concentrations have in previous studies not been shown to present any side-effects (Singh et al., 2014). The drug will be provided within 12 hours after trauma. The goal will be to provide a dose-response effect on the cerebral inflammatory response. As secondary goals, the investigators will assess the brain damage by measuring proteins in blood and cerebrospinal fluid, functional outcome and inflammation in the brain using positron emission tomography.

Aim The hypothesis is that an increasing dose of the anti-inflammatory drug recombinant human Interleukin-1 receptor antagonist (IL-1ra, Kineret) will modulate the inflammatory state of the traumatically injured brain, which will attenuate the injurious processes that occur following TBI. Study Design While different doses of Anakinra have been used in trials, there is no knowledge of what constitutes an optimized concentration of the drug. To address this limitation, the current study will be a dose-response study in a double blind randomised clinical fashion, using placebo (n=20), 1.5 g ("intermediate dose") or (n=20) and 3.0 g ("high dose")(n=20) of Anakinra provided the first 48 hours (drug/placebo administered initially as 500 mg infusion bolus and later as an 1g or 2.5g infusion for 48 hours). Thus, a total of n=60 patients will be included. Sample-size analyses have indicated that the number of patients is sufficient to detect differences in the inflammatory response as gauged with cytokine measurements using cerebral microdialysis. As surrogate markers of outcome for these patients, several protein biomarkers of brain injury and proteins of the innate immune responses will be quantified using techniques called ELISA and multiplex assay technology. The investigators also wish to use radiological techniques, such as magnetic resonance imaging to study damages in white matter tracts in the brain and positron emission tomography to assess the degree of microglial activation. All these methods will be used to assess the potential benefit of the treatment vs placebo. By this type of study design, it will minimize bias and confounders that may influence the study. Patient Recruitment Patients with a clinical diagnosis of severe and moderate TBI will be identified by the research team at the daily departmental neuro-critical care unit meeting. Patients meeting the inclusion criteria will be approached for consent/assent if conscious or if next of kin is present. If not, consent will be assumed as we know Anakinra to be safe and there is likely to be a narrow therapeutic window. With the current patient load at Addenbrooke's Hospital, Cambridge, the investigators deem it possible to recruit one patient per week, thus estimating that the recruiting phase will take approximately two years to complete. Sampling All the sampling will be conducted during the acute phase when the patient is unconscious in the neuro-critical care unit. Microdialysis probes are sampled hourly. To assess inflammatory activity in the brain, positron emission tomography will be performed within the first week and after 2-3 weeks. Magnetic resonance imaging will be performed the first 2-3 weeks and then after 6 months. To measure the patient's adaptive immune response to brain specific proteins, specialised auto-immunisation assays will be performed on patient blood at day 1-3 following injury as well as after 2-3 weeks. During the intensive care phase, blood and cerebrospinal fluid will be sampled twice per day (approximately 3mL per sampling time per compartment, volumes that we do not deem harmful to the patient) and will be collected together with hourly microdialysate fluid samples the first 7 days from admission. Blood will also be sampled at an outpatient clinic follow up at 6 and 12 months following injury. Patient samples will be anonymised and stored at -80degC in the Division of Neurosurgery, Department of Clinical Neurosciences, University of Cambridge before analysis. It will not to be possible to measure cytokines, the drug and biomarkers from all microdialysis samples due to volume constraints. Moreover, we believe that a temporal resolution of 6 hours is probably adequate for the brain concentration of the drug while 12 hours is sufficient in serum. APP and tau will also be measured every 6 hours. The only parameter that will be hourly analysed in microdialysis is cytokine and chemokines through a luminex panel. Clinical Follow-up Patients will be followed up at a clinic visit at 6 and 12 months after trauma by questionnaire survey using standardised outcome measures in neurosurgical patients including the golden standard extended Glasgow Outcome Score and Short Form 36.