Brain Tumor Clinical Trial
Official title:
Influence of Vasopressors on Brain Oxygenation and Microcirculation in Anesthetized Patients With Cerebral Tumors
Project title: Influence of Vasopressors on Brain Oxygenation and Microcirculation in
Anesthetized Patients with Cerebral Tumors
Sponsor-investigator: Klaus Ulrik Koch M.D.
Sponsor: Department of Anesthesia Aarhus University Hospital, Nørrebrogade 44, 8000 Aarhus C,
Denmark
Objective:
To investigate whether phenylephrine and ephedrine causes different alterations in
microcirculation and oxygenation, as measured with MRI and PET, in anesthetized patients with
brain tumors. Using MRI and PET, the study will assess whether there is a difference in
deoxyhemoglobin concentration (Bold signal), CTTH, cerebral blood flow (CBF) and cerebral
metabolic rate of oxygen (CMRO2) between ephedrine and phenylephrine
Method:
Double blinded controlled randomized clinical trial. Either phenylephrine or ephedrine are
infused intravenously under general anesthesia. MRI is performed in 20 patients before and
after infusion. PET/CT is performed in 20 patients before and after infusion. BIS and NIRS
monitoring will be used in either scanner. After scanning patients are transported to the
operating theatre and the craniotomy is performed. After removal of the bone flap subdural
ICP is measured and recorded.
MRI to analyze CBF, CTH, max.CMRO2, maxOEF, CBV and grey-scale ADC before and after ephedrine
and phenylephrine. PET/CT to analyze CBF and CMRO2 before and after ephedrine and
phenylephrine and calculation of OEF. During each PET/CT scan session oxygen saturation and
hemoglobin concentration is measured.
Data from the proposed studies will add substantial new knowledge to the investigators
current understanding of the effects of vasopressors on cerebral circulation. This
information will aid the neuroanesthesiologist, neurointensivist and the neurosurgeon in the
choice of the optimal method to manage cerebral perfusion pressure during craniotomy for
brain tumor.
Background:
During brain tumor surgery the main objective for the neuroanesthesiologist is to maintain a
low intracranial pressure (ICP) and a sufficient cerebral perfusion pressure (CPP) (CPP =
mean arterial blood pressure [MABP] − ICP) to ensure adequate cerebral oxygenation. Brain
tumors are often associated with edema and increased ICP and a specific recommendation for
CPP thresholds during brain tumor surgery does not exist. In daily practice vasopressors are
used to increase MABP to maintain a CPP between 50-70 mmHg in accordance with current
guidelines for management of patients with traumatic brain pathology.
However, recent studies show that arterial blood pressure correlates only poorly with
microcirculatory flow. Elevation of blood pressure may result in reduced capillary perfusion
and oxygen delivery despite reaching resuscitation end-points with CPP within 50-70 mmHg.
This is supported by an experimental study demonstrating vasopressor-induced mismatch between
cerebral perfusion and oxygenation, possibly due to microvascular heterogeneity, as suggested
by the authors. In addition, recent studies in healthy anesthetized subjects demonstrate
that, despite an increase in MABP, cerebral oxygenation simultaneously decreases after
phenylephrine but remains unchanged after administration of ephedrine. Thus, increasing CPP
with vasopressors may lead to paradoxical microcirculatory response with vasopressor-induced
tissue hypo-perfusion and hindered tissue oxygenation.
Brain microcirculation is the primary site of oxygen exchange. The investigators have
recently proposed that red blood cell capillary transit time heterogeneity (CTTH) may affect
tissue oxygen tension in patients with ischemic stroke, subarachnoid hemorrhage and traumatic
brain injury. According to this theory capillary compression due to edema and elevated ICP
may cause redistribution of capillary flows into patterns with functional shunting of
oxygenated blood through the cerebral capillary bed. This capillary dysfunction may further
hinder oxygen diffusion into cerebral tissue and ultimately cause cerebral ischemic damage.
The dissimilar effects of phenylephrine and ephedrine on cerebral oxygenation may be caused
by a different influence on brain capillary perfusion or alternated CTTH. Currently there are
no studies available on the effects of commonly used vasopressors on brain microcirculation
and oxygenation in patients undergoing craniotomy for brain tumors.
Hypothesis:
The use of phenylephrine is associated with a reduction in brain oxygenation and
microcirculation compared to ephedrine in anesthetized patients with brain tumors.
Specifically the investigators hypothesize that:
1. In peritumoral areas phenylephrine is associated with a local increase in CBF, increased
CTTH, decreased oxygen extraction fraction and increase in the BOLD signal compared to
ephedrine
2. Phenylephrine is associated with a reduction in oxygen extraction fraction (OEF)
compared to ephedrine
Materials and methods:
Overall Study design:
Double blinded controlled randomized clinical trial.
Studies:
Study 1 (MRI study). 20 patients are randomized to infusion of either ephedrine or
phenylephrine until MAP >60 mmHg
Study 2 (PET study). 20 patients are randomized to infusion of either ephedrine or
phenylephrine until MAP >60mmHg
MRI and PET measurements are performed after induction of general anesthesia with propofol
and remifentanil. The MRI or PET sequence is then performed before administration of
study-drug and again after the infusion of either phenylephrine or ephedrine results in MAP >
60mmHg. Depth of anesthesia is monitored with BIS in both studies to ensure equal level of
anesthetic depth in the two groups. NIRS is monitored in both studies to compare measurements
of brain oxygenation determined by PET/CT. NIRS measurements are not possible during MR scan
and will be measured either before or after the scan. BIS and NIRS are registered in each
patients case report form (CRF). After the MRI/PET study the patient is transported to the
operating theatre and the craniotomy is performed. After removal of the bone-flap, subdural
ICP is measured and recorded as previously described.
The overall experimental setup is the same for the two studies. The patient is anesthetized
and MRI or PET is performed before and after administration of a study-drug. The specific MRI
and PET protocols are mentioned below
- MRI protocol
- Conventional MRI sequences on a high quality research scanner
- Diffusion-weighted MRI incl. diffusion kurtosis imaging
- Perfusion-weighted MRI before and after ephedrine or phenylephrine, respectively
- The duration of the entire MRI scan is estimated to 60 min. Two and a half standard
doses of gadolinium MRI contrast are administered ( 0.25 mmol/kg).
- PET protocol
- Cerebral Blood Flow (CBF): 500 MBq of [15O]H2O is injected intravenously. At injection a
three minute PET image acquisition of the brain is started together with arterial blood
sampling (also three minutes) with an automated blood radioactivity sampler that draws 7
ml blood per minute. The PET acquisition is done on a Siemens High Resolution Research
Tomograph (HRRT) in list mode.
- Cerebral Metabolic Rate of Oxygen (CMRO2): 1000 MBq of [15O]O2 is inhaled and
immediately exhaled. At inhalation PET acquisition and blood sampling are performed with
protocols identical to CBF.
- During each scan session oxygen saturation and haemoglobin concentration will be
measured.
Physiological parameters (blood pressure and ICP) are documented in the CRF corresponding to
each patient. BIS and NIRS data are stored on a portable computer and subjected to offline
analysis. Parametric and non-parametric statistics will be used to compare MRI and PET.
Physiological data will be recorded during stimulation with study-drugs. The sample size is
based on previous publications where a MRI protocol was performed before and after drug
administration in anesthetized patients. The exact form of applied statistics are not yet
decided. This kind of study with new parameters from MRI and PET has never been done and
statistical help will be consulted along the process.
Perspectives:
Data from the proposed studies will add to the investigators understanding of the cerebral
microcirculation and its importance for brain oxygenation in patients of different age and
comorbidity. Meanwhile, the study will provide new insights into the effects of vasopressors
on the cerebral circulation. The study will thus provide direct observations for the
investigators recent efforts to understand the role of the microcirculation in neurological
disorders, and help the investigators chose the optimal method to manage CPP during
craniotomy for brain tumor.
These insights may have implications for the future management of increased intracranial
pressure and CPP after TBI and SAH.
Applicant´s part in the research:
Applicant Klaus Ulrik Koch is sponsor-investigator on this study and the responsible person
of finishing the PhD thesis.
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