Disease, metabolism and energy : NMR studies of the brain

Bolas, N. M.

January 1986

No description available.

612

Brain energy metabolism

Clinical Studies in the Acute Phase of Subarachnoid Haemorrhage

Zetterling, Maria

January 2010

Patients admitted in similar clinical condition after spontaneous SAH can develop very different clinical courses. This could depend on the severity of the initial global ischemic brain injury at ictus. In the present study, we explored relations between clinical and radiological parameters at admission that indicate a more severe initial impact, and the following days hormone levels and brain metabolism. Early global cerebral oedema (GCE) on computed tomography occurred in 57 % of SAH patients and was associated with a more severe clinical condition. The brain’s glucose metabolism, measured with intracerebral microdialysis (MD), changed the first days. MD-glucose was initially high and MD-pyruvate low. MD-glucose gradually decreased and MD-pyruvate and MD-lactate increased, suggesting a transition to a hyperglycolytic state. This was more pronounced in patients with GCE. Similar patterns were seen for interstitial non-transmitter amino acids. From initial low concentrations, they gradually increased in parallel with MD-pyruvate. The amino acid concentrations were higher for patients admitted in better clinical condition. Insulin lowered MD-glucose and MD-pyruvate even when plasma glucose values remained high. P-ACTH and S-cortisol were elevated early after SAH. GCE was associated with higher S-cortisol acutely. Urine cortisol excretion, indicating levels of free cortisol, were higher in patients in a better clinical condition. Suppressed P-ACTH occurred in periods of brain ischemia. We suggest that GCE on the first CT scan is a warning sign indicating increased vulnerability if the patient is exposed to compromised energy supply or increased energy demand. Reduction of blood glucose after SAH should be done with caution. The temporal change of the glucose metabolism and the amino acid concentrations probably reflect activated repair mechanisms. This should be considered in the intensive care treatment of SAH patients. Finally, our results support earlier observations that the response of the hypothalamic-pituitary-adrenal system is important in critical care.

Subarachnoid haemorrhage

microdialysis

brain energy metabolism

brain glucose

pyruvate

amino acids

cerebral oedema

ACTH

cortisol

Neurosurgery

Neurokirurgi

Computational Models of Brain Energy Metabolism at Different Scales

Cheng, Yougan

11 June 2014

No description available.

Applied Mathematics

Biology

Mathematics

Multi-domain

Reaction-Diffusion Equations

Brain Energy Metabolism

MCMC

Spatially Distributed Models

Optimization