Oxygen Transport in Brain Tissue

2009 ◽  
Vol 131 (7) ◽  
Author(s):  
Kazuto Masamoto ◽  
Kazuo Tanishita
Keyword(s):  
Blood Flow ◽  
Brain Tissue ◽  
Oxygen Transport ◽  
Brain Activity ◽  
Critical Role ◽  
Large Body ◽  
Physiological Mechanism ◽  
Normal Brain ◽  
Demand And Supply ◽  
Tissue Po2

Oxygen is essential to maintaining normal brain function. A large body of evidence suggests that the partial pressure of oxygen (pO2) in brain tissue is physiologically maintained within a narrow range in accordance with region-specific brain activity. Since the transportation of oxygen in the brain tissue is mainly driven by a diffusion process caused by a concentration gradient of oxygen from blood to cells, the spatial organization of the vascular system, in which the oxygen content is higher than in tissue, is a key factor for maintaining effective transportation. In addition, a local mechanism that controls energy demand and blood flow supply plays a critical role in moment-to-moment adjustment of tissue pO2 in response to dynamically varying brain activity. In this review, we discuss the spatiotemporal structures of brain tissue oxygen transport in relation to local brain activity based on recent reports of tissue pO2 measurements with polarographic oxygen microsensors in combination with simultaneous recordings of neural activity and local cerebral blood flow in anesthetized animal models. Although a physiological mechanism of oxygen level sensing and control of oxygen transport remains largely unknown, theoretical models of oxygen transport are a powerful tool for better understanding the short-term and long-term effects of local changes in oxygen demand and supply. Finally, emerging new techniques for three-dimensional imaging of the spatiotemporal dynamics of pO2 map may enable us to provide a whole picture of how the physiological system controls the balance between demand and supply of oxygen during both normal and pathological brain activity.

Brain adaptation to chronic hypobaric hypoxia in rats

1992 ◽  
Vol 72 (6) ◽  
pp. 2238-2243 ◽  
Author(s):  
J. C. LaManna ◽  
L. M. Vendel ◽  
R. M. Farrell
Keyword(s):  
Blood Flow ◽  
Motor Cortex ◽  
Microvessel Density ◽  
Hypobaric Hypoxia ◽  
Regional Blood Flow ◽  
Oxygen Availability ◽  
Sensory Cortex ◽  
Hypoxic Exposure ◽  
Normal Brain ◽  
Tissue Po2

Rats were exposed to hypobaric hypoxia (0.5 atm) for up to 3 wk. Hypoxic rats failed to gain weight but maintained normal brain water and ion content. Blood hematocrit was increased by 48% to a level of 71% after 3 wk of hypoxia compared with littermate controls. Brain blood flow was increased by an average of 38% in rats exposed to 15 min of 10% normobaric oxygen and by 23% after 3 h but was not different from normobaric normoxic rats after 3 wk of hypoxia. Sucrose space, as a measure of brain plasma volume, was not changed under any hypoxic conditions. The mean brain microvessel density was increased by 76% in the frontopolar cerebral cortex, 46% in the frontal motor cortex, 54% in the frontal sensory cortex, 65% in the parietal motor cortex, 68% in the parietal sensory cortex, 68% in the hippocampal CA1 region, 57% in the hippocampal CA3 region, 26% in the striatum, and 56% in the cerebellum. The results indicate that hypoxia elicits three main responses that affect brain oxygen availability. The acute effect of hypoxia is an increase in regional blood flow, which returns to control levels on continued hypoxic exposure. Longer-term effects of continued moderate hypoxic exposure are erythropoiesis and a decrease in intercapillary distance as a result of angiogenesis. The rise in hematocrit and the increase in microvessel density together increase oxygen availability to the brain to within normal limits, although this does not imply that tissue PO2 is restored to normal.

scholarly journals Cerebral Blood Flow in Normal Brain Tissue of Patients with Intracranial Tumors

1996 ◽  
Vol 36 (10) ◽  
pp. 709-715 ◽  
Author(s):  
Yoshiya NAKAYAMA ◽  
Akira TANAKA ◽  
Shigehiko KUMATE ◽  
Shinya YOSHINAGA
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Brain Tissue ◽  
Normal Brain ◽  
Intracranial Tumors ◽  
Normal Brain Tissue

The Study of Cerebral Blood Flow Variations Following Radiation Dose Gradients for Brain Metastasis Patients During Radiotherapy

2020 ◽  
Author(s):  
Chuanke Hou ◽  
Guanzhong Gong ◽  
Lizhen Wang ◽  
Ya Su ◽  
Jie Lu ◽  
...  
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Radiation Dose ◽  
Brain Metastases ◽  
Brain Tissue ◽  
Normal Brain ◽  
Peritumoral Edema ◽  
Sectional Area ◽  
Normal Brain Tissue ◽  
Cross Sectional

Abstract Brackground: Changes of cereberal blood flow in different brain regions of patients with brain metastases after radiotherapy are worth exploring. This study aims to investigate the radiation dose range of normal brain tissue and tumor target area by evaluating the cerebral blood flow(CBF) for brain metastases (BMs) patients applying with 3D arterial spin labeling (ASL).Methods: A total of 26 patients harboring 54 BMs treated with radiotherapy (RT) were imaged with magnetic resonance (MR) before and 30-40Gy post RT. The high signal area of BMs on enhanced T1-weighted images (T1WI), normal brain tissue, and peritumoral edema region were defined as regions of interest (ROIs). Changes and correlation of largest cross-sectional area and maximum CBF in BMs before and after RT were analyzed. Maximum CBF change in the three ROIs under different gradients created by thresholding the individual dose maps at 10 Gy steps were assessed.Results: In terms of 54 BMs, a significant decrease of CBF of 29.64% (P<0.05) compared to largest cross-sectional area of 26.46% (P<0.05). The decrease of CBF was more pronounced for 30-40 Gy (33.75%) than for 40-50Gy and >50Gy (24.61% and 27.55%). In normal brain tissue with dose gradients of 30-40Gy, CBF decreased to the maximum, 20.23% (P<0.05),which was similar to BMs. In contrast, the decrement rate of CBF in the peritumoral edema region increased as the dose gradients increased.Conclusions: CBF decreased significantly during the course of RT. According to CBF variations, the dose to the normal brain tissue should be controlled below 30 Gy as much as possible, whereas tumor with high perfusion and peritumoral edema region should be given a higher dose.

The Study of Cerebral Blood Flow Variations during Brain Metastasis Radiotherapy

2021 ◽  
Author(s):  
Chuanke Hou ◽  
Guanzhong Gong ◽  
Lizhen Wang ◽  
Ya Su ◽  
Jie Lu ◽  
...  
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Brain Tissue ◽  
Critical Factor ◽  
Brain Regions ◽  
Normal Brain ◽  
Peritumoral Edema ◽  
Normal Brain Tissue ◽  
Cross Sectional ◽  
Contrast Enhanced

Purpose: To investigate the cerebral blood flow (CBF) variations during brain metastases (BMs) radiotherapy (RT) applying with MR 3D-arterial spin labeling (ASL). Materials and Methods: A total of 26 BMs patients with 54 tumors were retrospectively enrolled. MR examinations were performed before and during RT (30-50 Gy) with a total dose of 36-60 Gy (12-30 fractions) including contrast-enhanced T1-weighted, T2 Flair and 3D-ASL images. The relationship between CBF changes and the largest cross-sectional area changes in BMs was investigated. And CBF changes in BMs, normal brain tissue, and peritumoral edema areas were analyzed under different dose gradients that was divided into 10 Gy intervals. Results: The largest cross-sectional areas and CBF of 54 BMs decreased by 26.46% and 29.64% respectively during RT (P<0.05), but there was no correlation between the two changes (P>0.05). The rates of CBF decrease in BMs were 33.75%, 24.61% and 27.55% at 30-40, 40-50 and >50 Gy, respectively (P<0.05). In normal brain tissue with dose gradients of 0-10, 10-20, 20-30, 30-40, 40-50 and > 50 Gy, the CBF decreased by 7.65%, 11.12%, 18.42%, 20.23%, 19.79% and 17.89%, respectively (P <0.05). The CBF decreases reached a maximum at 30-40 Gy in normal brain tissue as well as BMs. In contrast, the CBF decreases of peritumoral edema areas increased as the dose gradients increased. Moreover, the CBF changes of BMs were more notable than those in normal brain tissue and peritumoral edema areas. Conclusion: CBF changes can be feasibly assessed in different brain regions during RT based on 3D-ASL. The changes should be considered as a critical factor to determine the personal radiation dose for BMs, normal brain tissue and peritumoral edema areas.

Compartmental analysis of regional cerebral blood flow in patients with acute severe head injuries

1977 ◽  
Vol 47 (5) ◽  
pp. 699-712 ◽  
Author(s):  
Erna M. Enevoldsen ◽  
Finn Taagehøj Jensen
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Brain Tissue ◽  
Regional Cerebral Blood Flow ◽  
Head Injuries ◽  
Initial Slope ◽  
Flow Index ◽  
Normal Brain ◽  
Regional Cerebral Blood ◽  
The Brain

✓ Bicompartmental analysis for the calculation of regional cerebral blood flow (rCBF) from 133Xe clearance in brain tissue has not been thoroughly explored in clinical studies. Most authors rely either on the average rCBF obtained by height/area analysis of the clearance curves or on the initial-slope flow index. Possibly the reason is that the validity of the bimodal flow distribution in abnormal brain tissue is considered questionable. In the present study, bicompartmental analysis, performed by a least-square computerized iterative approach, was used in the calculation of the flow and weight of the tissue of the brain of patients with severe head injuries. The analysis was found to give important information of the nature and course of the brain lesions even if the clearance curves did not have the normal bi-exponential shape, provided the results obtained were properly interpreted. In such cases, the values of the flow and relative weight could not be taken as flow and weight values of gray and white matter, but rather as indices of fast and slower flow components. The interpretation of the results was based on the identification of three types of 13-minute clearance curves, each being characteristic of a type of brain lesion. The clearance curves from fairly normal brain tissue appeared to be bi-exponential; curves from areas of severe cortical contusion had, in addition, an initial and rapid “third” component, a tissue peak, whereas curves from severely edematous brain tissue approached the monoexponential shape.

Brain Tissue PO2: Correlation with Cerebral Blood Flow

2002 ◽  
pp. 299-301
Author(s):  
Alex B. Valadka ◽  
R. Hlatky ◽  
Y. Furuya ◽  
C. S. Robertson
Keyword(s):  
Blood Flow ◽  
Cerebral Blood Flow ◽  
Brain Tissue ◽  
Tissue Po2

scholarly journals Position of Probe Determines Prognostic Information of Brain Tissue PO2 in Severe Traumatic Brain Injury

Neurosurgery ◽  
2012 ◽  
Vol 70 (6) ◽  
pp. 1492-1503 ◽  
Author(s):  
Lucido L. Ponce ◽  
Shibu Pillai ◽  
Jovany Cruz ◽  
Xiaoqi Li ◽  
H. Julia ◽  
...  
Keyword(s):  
Traumatic Brain Injury ◽  
Brain Injury ◽  
Brain Tissue ◽  
Severe Traumatic Brain Injury ◽  
Neurological Outcome ◽  
Normal Brain ◽  
Probe Position ◽  
Tissue Po2 ◽  
The Relationship ◽  
Abnormal Brain

Abstract BACKGROUND: Monitoring brain tissue PO2 (PbtO2) is part of multimodality monitoring of patients with traumatic brain injury (TBI). However, PbtO2 measurement is a sampling of only a small area of tissue surrounding the sensor tip. OBJECTIVE: To examine the effect of catheter location on the relationship between PbtO2 and neurological outcome. METHODS: A total of 405 patients who had PbtO2 monitoring as part of standard management of severe traumatic brain injury were studied. The relationships between probe location and resulting PbtO2 and outcome were examined. RESULTS: When the probe was located in normal brain, PbtO2 averaged 30.8 ± 18.2 compared with 25.6 ± 14.8 mm Hg when placed in abnormal brain (P &lt; .001). Factors related to neurological outcome in the best-fit logistic regression model were age, PbtO2 probe position, postresuscitation motor Glasgow Coma Scale score, and PbtO2 trend pattern. Although average PbtO2 was significantly related to outcome in univariate analyses, it was not significant in the final logistic model. However, the interaction between PbtO2 and probe position was statistically significant. When the PbtO2 probe was placed in abnormal brain, the average PbtO2 was higher in those with a favorable outcome, 28.8 ± 12.0 mm Hg, compared with those with an unfavorable outcome, 19.5 ± 13.7 mm Hg (P = .01). PbtO2 and outcome were not related when the probe was placed in normal-appearing brain. CONCLUSION: These results suggest that the location of the PbtO2 probe determines the PbtO2 values and the relationship of PbtO2 to neurological outcome.

scholarly journals Pharmacological Increase of Hb-O2 Affinity with a Voxelotor Analog Does Not Decrease Brain Tissue pO2 or Limit O2 Extraction in Brain Tissues of Sickle Cell Mice

Blood ◽  
2019 ◽  
Vol 134 (Supplement_1) ◽  
pp. 3564-3564
Author(s):  
Kobina Dufu ◽  
Alfredo Lucas ◽  
Cynthia Rodrigues Muller ◽  
Alexander T Williams ◽  
Xinchun Zhang ◽  
...  
Keyword(s):  
Blood Flow ◽  
Brain Tissue ◽  
Research Funding ◽  
Tissue Oxygenation ◽  
Underlying Mechanism ◽  
Employment Equity ◽  
Brain Tissue Oxygenation ◽  
Hypoxic Conditions ◽  
Tissue Po2 ◽  
Equity Ownership

Sickle Cell Disease (SCD) is characterized by hemolytic anemia, vaso-occlusion, and progressive end-organ damage. The underlying mechanism of SCD is the polymerization of sickle hemoglobin (HbS) that occurs when sickle erythrocytes (SS RBCs) are partially deoxygenated in microcirculation, leading to SCD pathophysiologic features. One of the most devastating complications of SCD occurs in the central nervous system (CNS), where overt stroke or repeated silent cerebral infarcts lead to significant physical and neurocognitive consequences. In SCD, the brain's response to insufficient oxygen (O2) delivery is balanced by increased blood flow to preserve O2 supply. However, the systemic endothelial dysfunction in SCD limits the capacity for vascular regulatory and compensatory changes to preserve appropriate tissue oxygenation, especially in tissues with high O2 demand like the brain. Low hemoglobin (Hb) levels and increased cerebral blood flow (CBF) are associated with increased stroke risk, suggesting that anemia-induced tissue hypoxia is an important factor contributing to subsequent morbidity in SCD patients. Voxelotor (GBT440) is a small molecule, HbS polymerization inhibitor being developed by Global Blood Therapeutics (GBT) for the treatment of SCD. By addressing the underlying mechanism of SCD, voxelotor has the potential to be disease-modifying and alleviate the clinical manifestations of SCD. Mechanistically, voxelotor increases Hb-O2 affinity and delays the transition from oxyHb to deoxyHb under hypoxic conditions. This study assessed the impact of a pharmacologically mediated increase in Hb-O2 affinity on brain tissue oxygenation under both normoxic and hypoxic conditions in Townes transgenic sickle mice (SCD mice). Two compounds that increase the Hb-O2 affinity with similar potency, voxelotor and an analog to voxelotor, GBT1118, were considered for the study. The target for Hb occupancy with test compounds was ≥30% based on the therapeutic target occupancies observed with voxelotor in clinical studies. The effects of increased Hb-O2 affinity on brain tissue oxygenation were assessed directly with O2-specific microelectrodes in a cranial window and indirectly with hypoxyprobe staining (pimonidazole) of brain tissue. Unique to this SCD model, the targeted Hb occupancy (≥30%) could not be consistently achieved by voxelotor. In contrast, repeat oral dosing of GBT1118 at 200 mg/kg/day for 2 weeks in SCD mice achieved steady state concentrations of 802 ± 81 µM (mean ± SD; n=5), corresponding to a Hb occupancy of 44 ± 5%. Consequently, GBT1118 decreased the p50 (partial pressure of O2 at which Hb is 50% saturated) values of SCD mouse blood from 39 ± 0.8 mmHg (Vehicle-dosed) to 21 ± 1.6 mmHg (GBT1118-dosed). While we could not achieve the desired Hb occupancy (≥30%) with voxelotor in this model, the Hb occupancy and change in p50 achieved with GBT1118 afforded us the opportunity to ask whether significantly increasing Hb-O2 affinity affects brain O2 tension. Measurements of cortical O2 tension (pO2) showed no difference in pO2 values under normoxia (21% O2) (Figure A), and slightly higher pO2 values under hypoxia (10% O2) (Figure B) for GBT1118-dosed SCD mice compared with vehicle-dosed SCD mice. Collectively across all brain tissues, the GBT1118-induced increase in Hb-O2 affinity reduced tissue hypoxia in SCD mice under hypoxia as measured by pimonidazole staining (Figure C). Together, these results indicate that a pharmacological increase of Hb-O2 affinity does not decrease cortical tissue pO2 in SCD mice and may reduce brain hypoxia under hypoxic conditions. Figure Disclosures Dufu: Global Blood Therapeutics: Employment, Equity Ownership. Lucas:Global Blood Therapeutics: Research Funding. Muller:Global Blood Therapeutics: Research Funding. Williams:Global Blood Therapeutics: Research Funding. Zhang:Global Blood Therapeutics: Employment, Equity Ownership. Rademacher:Global Blood Therapeutics: Employment, Equity Ownership. Alt:Global Blood Therapeutics: Employment, Equity Ownership. Oksenberg:Global Blood Therapeutics: Employment, Equity Ownership. Cabrales:Global Blood Therapeutics: Research Funding.

Sign in / Sign up

Export Citation Format

Share Document