Quantification of whole‐brain oxygenation extraction fraction and cerebral metabolic rate of oxygen consumption in adults with sickle cell anemia using individual T
            2
            ‐based oxygenation calibrations

Abstract Introduction Chronic Transfusion Therapy (CTT) has been successful in decreasing stroke frequency in patients with sickle cell disease (SCD). Despite this, indication for CTT is largely based on empirical evidence and the mechanisms by which CTT protects the brain remain unclear. CTT improves oxygen carrying capacity and lowers hemoglobin S%, but the corresponding impact on cerebral blood flow(CBF), cerebral metabolic rate (CMRO2), and oxygen extraction fraction (OEF) is unknown. Understanding the impact of these competing influences in non-transfused (NT) and chronically transfused (CT) SCD patients will inform stroke prevention. Thus, we measured CBF, CMRO2, and OEF, in NT and CT patients with SCD using magnetic resonance imaging (MRI). Methods All patients were recruited with informed consent or assent and this study was approved by the CHLA IRB. Fourteen (6 NT, 8 CT) patients with SCD and 12 healthy ethnicity matched controls (CTL) were studied. Exclusion criteria included pregnancy, previous stroke, acute chest or pain crisis hospitalization within one month. Complete blood count and hemoglobin electrophoresis were performed. Arterial oxygen saturation (SaO2) was measured via peripheral pulse oximetery. CaO2 was calculated as the product of hemoglobin, SaO2 and the oxygen density of hemoglobin (1.36 ml/g). Phase contrast imaging of the carotid and vertebral arteries was used to measure global CBF. T2 Relaxation Under Spin Tagging (TRUST) was used to measured T2 relaxation of blood within the sagittal sinus. T2 relaxation was converted to SvO2 via previously validated calibration curves. OEF represented the difference of SaO2 andSvO2 divided bySaO2. CMRO2 was calculated as the product of CBF and OEF. High resolution, 3D, T1 weighted images were used for brain volume calculation using BrainSuiteñ software. Results Table 1 summarizes the results. Hemoglobin and oxygen content were well matched between transfused and non transfused SCD patients. Cerebral metabolic rate was also nearly identical in the two groups. However, CT patients exhibited 25% higher CBF than NT SCD patients, allowing them to have a normal oxygen extraction fraction ~30%. In contrast, OEF in NT SCD patients was abnormally high (37.8%), suggesting a decreased extraction reserve. Total oxygenation index (TOI) by NIRS also trended lower in NT SCD patients, consistent with the greater oxygen extraction and lower cerebral venous saturations observed. Abstract 1387. TableCTL (reference)NTCTp value (NT vs CT)Hemoglobin (g/dl)13.5 ± 1.229.7 ± 1.259.7 ± 1.05nsCaO2 (umol O2/ml)9.85 ± .996.84 ± 1.176.95 ±.71nsCMRO2 (umol O2/100g/min)193.1 ± 44.9239.7 ± 35.3238.6 ± 38.3nsCBF (ml/100g/min)70.0 ± 12.8101.5 ± 16.6127.1 ± 23.5< 0.05OEF (%)30.0 ± 7.137.8. ± 3.0629.7 ± 7.53< 0.05NIRS TOI56.0 ± 4.0948.5 ± 4.2153.5 ± 8.760.076SvO2 (%)65.6 ± 6.856.2 ± 5.267.1 ± 6.7< 0.05 Discussion: Chronically transfused SCD patients achieve normal brain oxygenation metrics (SvO2, OEF, and NIRS) but require very high CBF to achieve this balance (lowering flow reserve). In contrast, NT SCD patients have smaller increases in CBF but require greater oxygen extraction to meet cerebrovascular demands (lowering extraction reserve). Hemoglobin S mediate changes in oxygen dissociation, blood viscosity, red cell deformability and microvascular damage potentially mediate these differences but their interplay is complicated and requires further study. Disclosures Coates: novartis: Consultancy, Honoraria, Speakers Bureau; shire: Consultancy, Honoraria; apo pharma: Consultancy, Honoraria; acceleron: Consultancy, Honoraria.

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Effect of ephedrine and phenylephrine on brain oxygenation and microcirculation in anaesthetised patients with cerebral tumours: study protocol for a randomised controlled trial

BMJ Open ◽

10.1136/bmjopen-2017-018560 ◽

2017 ◽

Vol 7 (11) ◽

pp. e018560 ◽

Cited By ~ 2

Author(s):

Klaus Ulrik Koch ◽

Anna Tietze ◽

Joel Aanerud ◽

Gorm von Öettingen ◽

Niels Juul ◽

...

Keyword(s):

Blood Pressure ◽

Blood Flow ◽

Metabolic Rate ◽

Transit Time ◽

Oxygen Extraction Fraction ◽

Oxygen Extraction ◽

Brain Oxygenation ◽

Cerebral Metabolic Rate ◽

Arterial Blood ◽

Extraction Fraction

IntroductionDuring brain tumour surgery, vasopressor drugs are commonly administered to increase mean arterial blood pressure with the aim of maintaining sufficient cerebral perfusion pressure. Studies of the commonly used vasopressors show that brain oxygen saturation is reduced after phenylephrine administration, but unaltered by ephedrine administration. These findings may be explained by different effects of phenylephrine and ephedrine on the cerebral microcirculation, in particular the capillary transit-time heterogeneity, which determines oxygen extraction efficacy. We hypothesised that phenylephrine is associated with an increase in capillary transit-time heterogeneity and a reduction in cerebral metabolic rate of oxygen compared with ephedrine. Using MRI and positron emission tomography (PET) as measurements in anaesthetised patients with brain tumours, this study will examine whether phenylephrine administration elevates capillary transit-time heterogeneity more than ephedrine, thereby reducing brain oxygenation.Methods and analysisThis is a double-blind, randomised clinical trial including 48 patients scheduled for surgical brain tumour removal. Prior to imaging and surgery, anaesthetised patients will be randomised to receive either phenylephrine or ephedrine infusion until mean arterial blood pressure increases to above 60 mm Hg or 20% above baseline. Twenty-four patients were allocated to MRI and another 24 patients to PET examination. MRI measurements include cerebral blood flow, capillary transit-time heterogeneity, cerebral blood volume, blood mean transit time, and calculated oxygen extraction fraction and cerebral metabolic rate of oxygen for negligible tissue oxygen extraction. PET measurements include cerebral metabolic rate of oxygen, cerebral blood flow and oxygen extraction fraction. Surgery is initiated after MRI/PET measurements and subdural intracranial pressure is measured.Ethics and disseminationThis study was approved by the Central Denmark Region Committee on Health Research Ethics (12 June 2015; 1-10-72-116-15). Results will be disseminated via peer-reviewed publication and presentation at international conferences.Trial registration numberNCT02713087; Pre-results. 2015-001359-60; Pre-results.

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Dual-calibrated fMRI measurement of absolute cerebral metabolic rate of oxygen consumption and effective oxygen diffusivity

NeuroImage ◽

10.1016/j.neuroimage.2018.09.035 ◽

2019 ◽

Vol 184 ◽

pp. 717-728 ◽

Cited By ~ 13

Author(s):

M. Germuska ◽

H.L. Chandler ◽

R.C. Stickland ◽

C. Foster ◽

F. Fasano ◽

...

Keyword(s):

Oxygen Consumption ◽

Metabolic Rate ◽

Cerebral Metabolic Rate ◽

Oxygen Diffusivity ◽

Rate Of Oxygen Consumption ◽

Calibrated Fmri

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Rapid magnetic resonance measurement of global cerebral metabolic rate of oxygen consumption in humans during rest and hypercapnia

Journal of Cerebral Blood Flow & Metabolism ◽

10.1038/jcbfm.2011.34 ◽

2011 ◽

Vol 31 (7) ◽

pp. 1504-1512 ◽

Cited By ~ 73

Author(s):

Varsha Jain ◽

Michael C Langham ◽

Thomas F Floyd ◽

Gaurav Jain ◽

Jeremy F Magland ◽

...

Keyword(s):

Carbon Dioxide ◽

Oxygen Consumption ◽

Magnetic Resonance ◽

Metabolic Rate ◽

Vascular Reactivity ◽

Cerebral Metabolism ◽

Metabolic Effects ◽

Cerebral Metabolic Rate ◽

Rate Of Oxygen Consumption ◽

End Tidal

The effect of hypercapnia on cerebral metabolic rate of oxygen consumption ( CMRO2) has been a subject of intensive investigation and debate. Most applications of hypercapnia are based on the assumption that a mild increase in partial pressure of carbon dioxide has negligible effect on cerebral metabolism. In this study, we sought to further investigate the vascular and metabolic effects of hypercapnia by simultaneously measuring global venous oxygen saturation ( Sv O2) and total cerebral blood flow ( tCBF), with a temporal resolution of 30 seconds using magnetic resonance susceptometry and phase-contrast techniques in 10 healthy awake adults. While significant increases in Sv O2 and tCBF were observed during hypercapnia ( P < 0.005), no change in CMRO2 was noted ( P > 0.05). Additionally, fractional changes in tCBF and end-tidal carbon dioxide ( R2 = 0.72, P < 0.005), as well as baseline Sv O2 and tCBF ( R2 = 0.72, P < 0.005), were found to be correlated. The data also suggested a correlation between cerebral vascular reactivity ( CVR) and baseline tCBF ( R2 = 0.44, P = 0.052). A CVR value of 6.1% ± 1.6%/mm Hg was determined using a linear-fit model. Additionally, an average undershoot of 6.7% ± 4% and 17.1% ± 7% was observed in Sv O2 and tCBF upon recovery from hypercapnia in six subjects.

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Reduced Cerebral Metabolic Rate of Oxygen in Adults with Sickle Cell Disease

Blood ◽

10.1182/blood-2018-99-116194 ◽

2018 ◽

Vol 132 (Supplement 1) ◽

pp. 11-11

Author(s):

Lena Vaclavu ◽

Esben Thade Petersen ◽

Ed T VanBavel ◽

Charles BL Majoie ◽

Aart J Nederveen ◽

...

Keyword(s):

Sickle Cell Disease ◽

Metabolic Rate ◽

Sickle Cell ◽

Carrying Capacity ◽

Oxygen Extraction Fraction ◽

Healthy Controls ◽

Cell Disease ◽

Whole Brain ◽

Cerebral Metabolic Rate ◽

Oxygen Carrying Capacity

Abstract Introduction: Cerebral blood flow (CBF) is increased in sickle cell disease (SCD) to compensate for chronic hemolytic anemia. Since the brain is strongly dependent on adequate oxygen levels, severe anemia may result in ischemia and silent cerebral infarctions (SCIs), which are present in the majority of patients with SCD. Besides CBF, the cerebral metabolic rate of oxygen (CMRO2), representing the cerebral oxygen consumption, can be measured using specialized MRI techniques. CMRO2 is dependent on CBF, OEF oxygen extraction fraction (OEF) and the hematocrit in the cerebral circulation. In order to maintain stable CMRO2 the OEF changes to compensate for fluctuations in CBF. Previous studies found either elevated or reduced rather than stable CMRO2 in SCD. To further explore the regulation of cerebral oxygenation in SCD, we measured CMRO2, OEF and CBF using MRI at rest and upon administration of acetazolamide (ACZ), a non-metabolic vasodilator. In addition, we related the CMRO2 to the prevalence and location of SCIs and to laboratory parameters of hemolysis. Methods: Adult SCD patients (HbSS/HbSβ0) without a history of stroke, and healthy age-, sex, and race-matched controls were recruited for this IRB-approved MRI study with ACZ-induced vasodilation and venous blood sampling. MRI images were acquired at 3T (Philips Healthcare, Best, NL). Sequences included 3D FLAIR with 1mm isotropic resolution for lesion evaluation, longitudinal and transverse relaxation times of blood (T1b and T2b) in the cerebral sagittal sinus using a T2 prepared tissue relaxation with inversion recovery sequence (T2-TRIR), and pseudo-continuous arterial spin labeling (ASL) for whole brain CBF measurements. T1b was used to correct ASL-based CBF values. T2b was converted to venous saturation (Yv) using a recently published SCD-specific model, which was calibrated in sickle blood rather than bovine blood. CBF was measured at baseline and 10 min post acetazolamide (ACZ) (16mg/kg intravenous infusion over 3min). Images were co-registered and quantified using the ExploreASL toolbox. CMRO2 was calculated as follows: CMRO2 = CBF * OEF * Ca, where CBF is the whole brain CBF map from ASL, OEF is the arteriovenous oxygen saturation (Y) difference (Ya-Yv/Ya) derived from T2 measurements, and Ca is the oxygen carrying capacity of blood calculated from hematocrit sampled immediately prior to MRI. Blood markers of hemolysis (reticulocyte count and bilirubin) were correlated to MRI hemodynamic markers using bivariate Spearman's rho (ρ). Group comparisons were tested using Student's t-tests. P values <0.05 were considered statistically significant. Results: As expected, CBF was significantly higher in patients with SCD (69 ± 16 mL/100g/min) compared to healthy controls (42 ± 4 mL/100g/min, P <0.001), whereas oxygen carrying capacity (Ca) was significantly lower in patients with SCD vs healthy controls due to lower hematocrit (485 ± 83 vs 794 ± 66 μmol O2/100ml blood, P=0.001). At baseline, mean CMRO2 was lower in patients with SCD compared to healthy controls (88 ± 20 vs 117 ± 18 μmol/100 g/min, P = 0.002), contrary to our hypothesis, indicating a reduced oxygen metabolism in patients with SCD. After acetazolamide, CMRO2 remained the same due to an increase in CBF (P<0.001) and a compensatory reduction in OEF. The reduction in OEF in patients with SCD and healthy controls (20 ± 7 vs 19 ± 6, respectively P= 0.76) indicates that OEF adjusts appropriately according to the increased flow. By mapping CMRO2 and the locations of SCIs, we found that lesions were most prevalent in the regions with the lowest CMRO2 corresponding to the deep white matter and borderzone regions, supporting an ischemic etiology of lesions. High hemolytic rate was associated with higher CMRO2 most likely due to an increased CBF. Conclusion: We observed reduced CMRO2 in patients with SCD compared to healthy controls due to low OEF. A reduced CMRO2 could pose a risk for ischemia, despite high flow rate delivering oxygen, because of low OEF. This is supported by the fact that the silent cerebral infarcts are located in regions with the lowest CMRO2. We postulate that patients with SCD have a reduced capacity to increase the OEF in regions with inadequate CBF resulting in local ischemia and local infarction. The pathogenesis of the reduced OEF remains unclear but could be related to arteriovenous shunting whereby there is insufficient time for oxygen to dissociate. Figure Figure. Disclosures No relevant conflicts of interest to declare.

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