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Clinical Trial Details — Status: Not yet recruiting

Administrative data

NCT number NCT04696523
Other study ID # 109/2019 Xe-SAH
Secondary ID 2019-001542-17
Status Not yet recruiting
Phase Phase 2
First received
Last updated
Start date October 1, 2023
Est. completion date December 31, 2027

Study information

Verified date April 2023
Source Turku University Hospital
Contact Timo T Laitio, MD, PhD
Phone +358504653201
Email timo.laitio@tyks.fi
Is FDA regulated No
Health authority
Study type Interventional

Clinical Trial Summary

An investigator-initiated clinical drug study Main Objective: To explore neuroprotective properties of xenon in patients after aneurysmal subarachnoid hemorrhage (SAH). Primary endpoint: Global fractional anisotropy of white matter of diffusion tensor imaging (DTI). Hypothesis: White matter damage is less severe in xenon treated patients, i.e. global fractional anisotropy is significantly higher in the xenon group than in the control group as assessed with the 1st magnetic resonance imaging (MRI). After confirmation of aSAH and obtaining a signed assent subjects will be randomized to the following groups: Control group: Standard of Care (SOC) group: Air/oxygen and Normothermia 36.5-37.5°C; Xenon group: Normothermia 36.5-37.5°C +Xenon inhalation in air/oxygen for 24 hours. Brain magnetic resonance imaging techniques will be undertaken to evaluate the effects of the intervention on white and grey matter damage and neuronal loss. Neurological outcome will be evaluated at 3, 12 and 24 months after onset of aSAH symptoms Investigational drug/treatment, dose and mode of administration: 50±2 % end tidal concentration of inhaled xenon in oxygen/air. Comparative drug(s)/placebo/treatment, dose and mode of administration: Standard of care treatment according to local and international consensus reports. Duration of treatment: 24 hours Assessments: Baseline data Information that characterizes the participant's condition prior to initiation of experimental treatment is obtained as soon as is clinically reasonable. These include participant demographics, medical history, vital signs, oxygen saturation, and concentration of oxygen administered. Acute data The collected information will contain quantitative and qualitative data of aSAH patients, as recommended by recent recommendations of the working group on subject characteristics, and including all relevant Common Data Elements (CDE) can be applied. Specific definitions, measurements tools, and references regarding each SAH CDE can be found on the weblink here: https://www.commondataelements.ninds.nih.gov/SAH.aspx#tab=Data_Standards.


Description:

Assessments of efficacy: 1. A brain Computer tomography angiography (CTA) and / or 3 D Digital subtraction angiography (DSA) (whenever possible instead of 2D DSA) will be performed at hospital arrival and whenever clinically indicated. 2. 1st 3 Tesla MRI 72 ± 24 hours after onset of aSAH symptoms; 2nd 3 Tesla MRI 42 ± 4 days after onset of aSAH symptoms. 3. 3D DSA: Computational fluid dynamic simulations (CFD), artificial intelligence and machine learning. 4. Brain Positron emission tomography (PET): The 1st 4 ± 1 weeks and the 2nd at 3 months after onset of aSAH symptoms. 5. Biochemical assessment: A blood samples of 20 ml for determination of plasma catecholamines, plasma metabolomics (see details of metabolomics in section 18.4.7), cardiac enzyme release (P-hs-troponin-T and heart fatty-acid binding protein), selected biomarkers will be analysed at intensive crae unit (ICU) arrival and at 24h, at 48h and at 72h after onset of SAH symptoms. In addition, a sample of spinal fluid will be collected through external ventricular drainage (EVD) at ICU arrival or as soon as it is in place and at 24h, at 48h and at 72h after onset of SAH symptoms for assessment of metabolomics 6. Electrocardiograph (ECG) at ICU arrival and at 24h, at 48h and at 72h after onset of aSAH symptoms. 7. Neurological evaluation: at 3, 12 and at 24 months after aSAH with GOSe, Modified ranking score (mRS). Statistical methods: 1) Basic statistical tests (t-tests, Mann-Whitney, Chi square, etc); 2) Survival analysis methods; 3) An analysis of variance for repeated measurements; 4) A sample size of 100 is estimated on the basis of a recent studies in SAH patients to provide 80% power with a 2-sided α level of 0.05 to detect a mean difference of 0.02 (SD 0.035) in the global fractional anisotropy of white matter between the xenon group and the control group (98). Accordingly, this mean difference is estimated to have a predictive value for DCI and poor neurological outcome (i.e. mRS 3-6).Significance level of 0.05 and an estimation of 95 % confidence intervals will be used in the statistical analyses.


Recruitment information / eligibility

Status Not yet recruiting
Enrollment 160
Est. completion date December 31, 2027
Est. primary completion date December 31, 2026
Accepts healthy volunteers No
Gender All
Age group 18 Years and older
Eligibility Inclusion Criteria: To be considered eligible to participate in this study, a SAH subject must meet the inclusion criteria listed below: 1. Informed consent obtained from the next of kin or legal representative 2. Aneurysmal subarachnoid hemorrhage visible on CTA or DSA. 3. Deterioration of consciousness to Hunt-Hess 3-5 4. Age of = 18 years 5. Intubated. 6. GCS 3-12 obtained off neuromuscular blocking agents 7. Xenon treatment can be started within 6 hours after onset of SAH symptoms Exclusion Criteria: An aSAH subject may not be enrolled in the trial if he/she meets any one of the exclusion criteria below: 1. Acute or chronic traumatic brain injury 2. Maximum diameter of intracerebral hemorrhage > 2.5 cm 3. Pneumothorax or pneumomediastinum, 4. Acute lung injury requiring = 60% FIO2 (fraction of inspired oxygen). 5. Systolic arterial pressure < 80 mmHg or mean arterial pressure < 60 mmHg for over 30 min period 6. Bilaterally fixed and dilated pupils 7. Positive pregnancy test, known pregnancy, or current breast-feeding 8. Neurological deficiency due to traumatic brain injury or other neurological illness 9. Imminent death or current life-threatening disease 10. Current enrollment in another interventional study 11. The subject is known to have clinically significant laboratory abnormality, medical condition (such as decompensated liver disease or severe chronic obstructive pulmonary disease), or social circumstance that, in the investigator's opinion, makes it inappropriate for the subject to participate in this clinical trial. 12. Presence of implants or foreign bodies which are not known to be MRI safe

Study Design


Intervention

Drug:
Xenon
Xenon arm will be treated with xenon inhalation with endtidal concentration of 50 % in air/oxygen and with standard of care
air/oxygen
Control group will be treated with air/oxygen

Locations

Country Name City State
Finland Aalto University School of Science Helsinki
Finland Kuopio University Hospital Kuopio
Finland Tampere University Hospital Tampere
Finland Elomatic Turku
Finland Turku University Hospital Turku
Finland University of Turku, Turku Bioscience, Analysis of the metabolomics Turku
Sweden Örebro University Örebro

Sponsors (2)

Lead Sponsor Collaborator
Turku University Hospital Academy of Finland

Countries where clinical trial is conducted

Finland,  Sweden, 

References & Publications (2)

Arola O, Saraste A, Laitio R, Airaksinen J, Hynninen M, Backlund M, Ylikoski E, Wennervirta J, Pietila M, Roine RO, Harjola VP, Niiranen J, Korpi K, Varpula M, Scheinin H, Maze M, Vahlberg T, Laitio T; Xe-HYPOTHECA Study Group. Inhaled Xenon Attenuates My — View Citation

Laitio R, Hynninen M, Arola O, Virtanen S, Parkkola R, Saunavaara J, Roine RO, Gronlund J, Ylikoski E, Wennervirta J, Backlund M, Silvasti P, Nukarinen E, Tiainen M, Saraste A, Pietila M, Airaksinen J, Valanne L, Martola J, Silvennoinen H, Scheinin H, Har — View Citation

Outcome

Type Measure Description Time frame Safety issue
Primary Fractional anisotropy of the white matter Global fractional anisotropy of white matter of diffusion tensor imaging (DTI). Hypothesis: White matter damage is less severe in xenon treated patients, i.e. global fractional anisotropy is significantly higher in the xenon group than in the control group as assessed with the 1st MRI. 48-96 hours after start of aSAH symptoms
Secondary Fractional anisotropy of white matter at cerebellum and/or at corpus callosum as assessed with the 1st MRI. Fractional anisotropy of white matter at cerebellum and/or at corpus callosum as assessed with the 1st MRI. 48-96 hours after start of aSAH symptoms
Secondary Safety and tolerability of xenon Safety and tolerability of xenon as assessed with a ratio of adverse events, serious adverse events and suspected unexpected serious adverse reactions (SUSARs) during the follow-up of one year between the xenon group and the control group. during the follow-up of one year
Secondary Composite of radiological early brain injury (EBI) and delayed cerebral ischemia (DCI) Composite of radiological EBI (within 72 hours after start of SAH symptoms) and DCI (Criterion of DCI: 1. a new focal neurological deficit (such as hemiparesis, aphasia, apraxia, hemianopia, or neglect) /decrease in level of consciousness (i.e. decrease of at least 2 points on the Glasgow Coma Scale; either on the total score or on one of its individual components, such as eye, motor on either side, or verbal). This should last for at least 1 hour and not is due to other causes (e.g. hydrocephalus, seizures, metabolic derangement, infection, sedation) and is not apparent immediately after aneurysm occlusion, and cannot be attributed to other causes by means of clinical assessment, CT or MRI scanning of the brain, and appropriate laboratory studies, 2. a new infarct on follow-up imaging (i.e. in any of the following: 2nd MRI, CT, CTA, DSA and perfusion CT) after 4 days post-SAH, or 3. both 1 and 2), and poor outcome at 3-months (good: mRS 0-2; poor: mRS 3-6) at 3-months and at 1 year EBI: within first 72 hours after start of aSAH symptoms; mRS at 3 months and at 1 year and at 2 years after onset of aSAH symptoms
Secondary Neurogenic Stress Cardiomyopathy and Stunned Myocardium Neurogenic Stress Cardiomyopathy and Stunned Myocardium (i.e. myocardial injury caused by sympathetic storm and autonomic dysregulation with hs-troponin elevation, left ventricular dysfunction or ECG changes) follow-up of 1 year
Secondary Intracerebral pressure (ICP) ICP level
Duration of therapy for ICP control/monitoring
during ICU stay up to 14 days after onset of aSAH symptoms
Secondary Intracerebral pressure (ICP) Need for ICP therapies (hypothermia, decompressive craniotomy) during ICU stay up to 14 days after onset of aSAH symptoms
Secondary Intracerebral pressure (ICP) Duration of therapy for ICP control/monitoring during ICU stay up to 14 days after onset of aSAH symptoms
Secondary Plasma catecholamine level Plasma level of noradrenaline , adrenaline, and dopamine within 3 hours of ICU arrival, at 24h, 48h and 72 h after onset of aSAH symptoms
Secondary Selected biomarkers Selected biomarkers of brain injury: neurofilament light (NF-L), glial fibrillary acidic protein (GFAP), calcium binding protein S100B (S100B), ubiquitin carboxyterminal hydrolase L1 (UCH-L1), total tau, cytokines (tumour necrosis factor alpha, interleukins 6 and 10) within 3 hours of ICU arrival and at 24h, at 48h and at 72h after onset of aSAH symptoms
Secondary Development of prognostication models Development of prognostication models with a selected combination of brain imaging, clinical data, biomarkers and metabolomics by applying artificial intelligence and machine learning for long-term outcome after aSAH long-term outcome at 3 months, at 1 and at 2 years after onset of aSAH symptoms
Secondary Development of prognostication models Development of prognostication models with a selected combination of brain imaging, clinical data, biomarkers and metabolomics by applying artificial intelligence and machine learning for DCI after aSAH between day 4 and 6 weeks after onset of aSAH symtoms
Secondary Development of prognostication models Development of prognostication models with a selected combination of brain imaging, clinical data, biomarkers and metabolomics by applying artificial intelligence and machine learning for vasospasm after aSAH within 21 days after onset of aSAH symptoms
Secondary Development of prognostication models Development of prognostication models with a selected combination of brain imaging, clinical data, biomarkers and metabolomics by applying artificial intelligence and machine learning for EBI after aSAH within 72 hours after onset of aSAH symtoms
Secondary Difference of MRI parameters between xenon and control group Difference of MRI parameters (fractional anisotropy, axial diffucivity, radial diffucivity of diffusion tensor imaging, DTI) between xenon and control group and in predicting risk for EBI within 72 hours after onset of aSAH symptoms
Secondary Difference of MRI parameters between xenon and control group Difference of MRI parameters (fractional anisotropy, axial diffucivity, radial diffucivity of DTI) between xenon and control group and in predicting risk for vasospasm within 21 days after onset of aSAH symptoms
Secondary Difference of MRI parameters between xenon and control group Difference of MRI parameters (fractional anisotropy, axial diffucivity, radial diffucivity of DTI) between xenon and control group and in predicting risk for DCI between day 4 and 6 weeks after onset of aSAH symptoms
Secondary Difference of MRI parameters between xenon and control group Difference of MRI parameters (fractional anisotropy, axial diffucivity, radial diffucivity of DTI) between xenon and control group and in predicting risk for good/poor neurological outcome at 3 moths, at 1 year and at 2 years after onset of aSAH symptoms (mRS 0-2/mRS 3-6). at 3 months, at 1 year and at 2 years after onset of aSAH symptoms
Secondary Difference of CTA findings Difference of CTA ischemic findings between xenon and control group and in predicting risk for EBI within 72 hours after onset of aSAH symptoms
Secondary Difference of CTA findings Difference of ischemic findings in CTA between xenon and control group and in predicting risk for vasospasm within 21 days after onset of aSAH symptoms
Secondary Difference of CTA findings Difference of ischemic findings in CTA between xenon and control group and in predicting risk for DCI between day 4 and 6 weeks after onset of aSAH symptoms
Secondary Difference of CTA findings between xenon and control group Difference of ischemic findings in CTA between xenon and control group and in predicting risk for good/poor neurological outcome at 3 moths, at 1 year and at 2 years after onset of aSAH symptoms (mRS 0-2/mRS 3-6). at 3 months, at 1 year and at 2 years after onset of aSAH symptoms
Secondary Difference of DSA findings between xenon and control group Difference of DSA findings indicating ischemic pattern of perfusion between xenon and control group and in predicting risk for EBI within 72 hours after onset of aSAH symptoms
Secondary Difference of DSA findings between xenon and control group Difference of DSA findings indicating ischemic pattern of perfusion between xenon and control group and in predicting risk for vasospasm within 21 days after onset of aSAH symptoms
Secondary Difference of DSA findings between xenon and control group Difference of DSA findings indicating ischemic pattern of perfusion between xenon and control group and in predicting risk for DCI between day 4 and 6 weeks after onset of aSAH symptoms
Secondary Difference of DSA findings between xenon and control group Difference of DSA findings indicating ischemic pattern of perfusion between xenon and control group and in predicting risk for good/poor neurological outcome at 3 moths, at 1 year and at 2 years after onset of aSAH symptoms (mRS 0-2/mRS 3-6). at 3 months, at 1 year and at 2 years after onset of aSAH symptoms
Secondary Activity of microglia cells assessed with PET It will be explored whether [11C](R)-PK11195 can be used to test the hypothesis of neuroprotective effect of xenon and to explore the role of inflammatory process for DCI after SAH. This could be demonstrated by showing less microglial activation in xenon group than in the reference therapy group and in the patients with good outcome, i.e. no DCI; Difference of activity of microglia cells between xenon and control group and in predicting risk for DCI DCI between day 4 and 6 weeks after onset of aSAH symptoms; The 1st PETscan 4 ±1 weeks after onset of aSAH symptoms and the 2nd scan at 3 months after onset of SAH symptoms.
Secondary Activity of microglia cells assessed with PET It will be explored whether [11C](R)-PK11195 can be used to test the hypothesis of neuroprotective effect of xenon and to explore the role of inflammatory process for neurological outcome after SAH. This could be demonstrated by showing less microglial activation in xenon group than in the reference therapy group and in the patients with good outcome, i.e. mRS 0-2; The 1st scan at 4 ±1 weeks after and the 2nd scan at 3 months after onset of SAH symptoms. Outcome: at 3 months, at 1 year and at 2 years after onset of aSAH symptoms
Secondary Cerebral fluid dynamics Predictive value of CFD simulations assessed with 3 dimensional DSA within 4 days of ICU arrival in predicting risk for EBI within 72 hours after onset of aSAH symptoms Measures performed within 72 hours of ICU arrival
Secondary Cerebral fluid dynamics Predictive value of CFD simulations assessed with 3 dimensional DSA within 21 days of ICU arrival in predicting risk for neurological outcome at 3 months, at 1 year and at 2 years after SAH (mRS 0-2) Measures performed within 21 days of ICU arrival; outcome at 3 months, at 1 year and at 2 years after onset of aSAH symptoms
Secondary Cerebral fluid dynamics Predictive value of CFD simulations assessed with 3 dimensional DSA within 21 days of ICU arrival in predicting risk for DCI within 6 weeks after onset of aSAH symptoms Measures performed within 21 days of ICU arrival; DCI within 6 weeks after onset of aSAH symptoms
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