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Query: UNIPROT:P50583 (
asymmetrical
)
12,197
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
A 56-year-old, hypertensive man was admitted to our hospital because of confusion. He had been well unit half an hour before admission, when he had suddenly developed left hemiplegia. Although he became deep coma soon after admission, his vital signs were preserved. CT scan revealed a large right putaminal hemorrhage and a ventricular perforation. The condition was too severe for surgical approaches and conservative therapy for
brain edema
was performed. On the 2nd hospital day, corneal and light reflexes were disappeared and an anisocolia appeared. On the 3rd hospital day, right papilledema appeared. Doll's head-eye movements and ciliospinal reflexes were absent. CT scan demonstrated marked
brain edema
and collapsed ambient cisterns. Tentorial herniation were suspected. On the 4th hospital day, respiratory arrest occurred and ventilatory assistance began. On the 11th hospital day, electroencephalograms (EEG's) showed electrocerebral silence. EEG's performed next day showed still electrocerebral silence. On the 13th hospital day, brainstem auditory evoked potentials were recorded without any responses. He was thought to be in condition of brain death. On the 17th hospital day, multifocal myoclonus involving lower limbs and abdominal muscles appeared. The myoclonus lasted for about 15 hours occurred on both sides, but was
asymmetrical
. The myoclonus consisted of intermittent, brief, arrhythmic, stereotype, jerking contractions of the muscles. Sometimes, the contractions were sufficient enough to jump his body over the bed. These symptoms provided the characteristics of spinal myoclonus. Etiologies of spinal myoclonus are varied, but the primary abnormality exists within the spinal cord.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:[Spinal myoclonus in association with brain death]. 262 31
The physicochemical properties of water enable it to act as a solvent for electrolytes, and to influence the molecular configuration and hence the function--enzymatic in particular--of polypeptide chains in biological systems. The association of water with electrolytes determines the osmotic regulation of cell volume and allows the establishment of the transmembrane ion concentration gradients that underlie nerve excitation and impulse conduction. Fluid in the central nervous system is distributed in the intracellular and extracellular spaces (ICS, ECS) of the brain parenchyma, the cerebrospinal fluid, and the vascular compartment--the brain capillaries and small arteries and veins. Regulated exchange of fluid between these various compartments occurs at the blood-brain barrier (BBB), and at the ventricular ependyma and choroid plexus, and, on the brain surface, at the pia mater. The normal BBB is relatively permeable to water, but considerably less so to ions, including the principal electrolytes Brain fluid regulation takes place within the context of systemic fluid volume control, which depends on the mutual interaction of osmo-, volume-, and pressure-receptors in the hypothalamus, heart and kidney, hormones such as vasopressin, renin-angiotensin, aldosterone, atriopeptins, and digitalis-like immunoreactive substance, and their respective sites of action. Evidence for specific transport capabilities of the cerebral capillary endothelium, for example high Na+K(+)-ATPase activity and the presence at the abluminal surface of a Na(+)--H+ antiporter, suggests that cerebral microvessels play a more active part in brain volume regulation and ion homoeostasis than do capillaries in other vascular beds. The normal brain ECS amounts to 12-19% of brain volume, and is markedly reduced in anoxia, ischaemia, metabolic poisoning, spreading depression, and conventional procedures for histological fixation. The
asymmetrical
distributions of Na+ K+ and Ca2+ between ICS and ECS underlie the roles of these cations in nerve excitation and conduction, and in signal transduction. The relatively large volume of the CSF, and extensive diffusional exchange of many substances between brain ECS and CSF, augment the ion-homeostasing capacity of the ECS. The choroid plexus, in addition to secreting CSF principally by biochemical mechanisms (there is an additional small component from the extracellular fluid), actively transports some substances from the blood (e.g. nucleotides and ascorbic acid), and actively removes others from the CSF. In contrast with CSF secretion, CSF reabsorption is principally a biomechanical process, passively dependent on the CSF-dural sinus pressure gradient. Pathological increases in intracranial water content imply development of an intracranial mass lesion. The additional water may be distributed diffusely within the brain parenchyma as brain oedema, as a cyst, or as increase in ventricular volume due to hydrocephalus.
Brain oedema
is classified on the basis of pathophysiology into four categories, vasogenic, cytotoxic, osmotic and hydrostatic. The clinical conditions in which brain oedema presents the greatest problems are tumour, ischaemia, and head injury. Peritumoural oedema is predominantly vasogenic and related to BBB dysfunction. Ischaemic oedema is initially cytotoxic, with a shift of Na+ and CI- ions from ECS to ICS, followed by osmotically obliged water, this shift can be detected by diffusion-weighted MRI. Later in the evolution of an ischaemic lesion the oedema becomes vasogenic, with disruption of the BBB. Recent imaging studies in patients with head injury suggest that the development of traumatic brain oedema may follow a biphasic time course similar to that of ischaemic oedema. Hydrocephalus is associated in the great majority of cases with an obstruction to the circulation or drainage of CSF, or, occasionally, with overproduction of CSF by a choroid plexus papilloma. In either case, the consequence is a ris
...
PMID:The normal and pathological physiology of brain water. 907 71
We recently experienced a case with
asymmetrical
cortical abnormality on MRI with focal status epilepticus following severe hypoglycemia. The cerebral blood flow and metabolisms for oxygen and glucose were determined using positron emission tomography (PET) during focal status epilepticus following severe hypoglycemia and at the follow-up period. Prolonged seizure activity produced profound glucose hypermetabolism and mild hyperemia in the region of the presumed cortical focus of epilepsy and in structures anatomically remote from the focus, corresponding to the areas of abnormal signal intensity on the MRI. The patient remained comatose and exhibited a diffuse hypoperfusion/hypometabolism and symmetrical brain atrophy on the follow-up PET and MRI, respectively. Cytotoxic
brain edema
due to profound glucose metabolism without compensatory increase of the blood flow during status epilepticus may account for the brain abnormality observed on the early MRI. Simultaneous examination of the cerebral blood flow and metabolism using PET can provide useful information about the pathology in patients with status epilepticus.
...
PMID:Magnetic resonance imaging and positron emission tomography findings in status epilepticus following severe hypoglycemia. 1687 11
