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Query: UMLS:C0036572 (
seizures
)
80,221
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The "transurethral resection of prostate" syndrome (TURPS) is the clinical manifestation of the resorption into the patient's body of a large amount of glycocolle-containing irrigating fluid used for this procedure. The full clinical picture, which is seldom seen, consists of dyspnoea, nausea, arterial hypertension, an increased central venous pressure, cerebral oedema, cardiogenic shock and renal failure. Improved surgical techniques, as well as incomplete and atypical forms of the syndrome could explain this low incidence. Absorption into the blood stream may be rapid, by way of the prostatic venous plexi, or slower, from the spaces around the prostate and under the peritoneum. The present-day pathophysiological theory explains this syndrome by an acute hyponatraemia, sometimes dissociated from the hypoosmolality, the toxicity of glycocolle, and the neurological effects of hyperammonemia.
Acute hyponatraemia
, with blood sodium concentrations below 115 to 120 mmol.l-1, should be considered as potentially serious. The different mechanisms involved may act alone or together, thus explaining that the minor forms of the syndrome mostly consist of a neurological picture. The emergency treatment depends on the natraemia. It includes diuretics and progressive reloading of the patient with sodium in case of severe hyponatraemia with
seizures
. The best prevention is a correct surgical indication and technique. The resection should not last for more than 90 to 120 min. The major problem remains the early diagnosis of TURPS. Carrying out this surgery under regional anaesthesia is helpful for this purpose, but, in the near future, the best means might be the monitoring of expired ethanol concentrations.
...
PMID:[Prostate transurethral resection syndrome]. 150 91
Cerebral cell volume regulatory mechanisms are activated by sustained disturbances in plasma osmolality. Acute hypernatremia causes a predictable shrinkage of brain cells due to the sudden imposition of a plasma-to-cell osmolal gradient. However, during chronic hypernatremia cerebral cell volume is maintained close to the normal range as a result of the accumulation of electrolytes and organic osmolytes including myo-inositol, taurine, glutamine, glycerophosphorylcholine, and betaine. The increased cytosolic level of these molecules is generally accomplished via increased activity of sodium (Na+)-dependent cotransport systems. The slow dissipation of these additional osmotically active solutes from the cell during treatment of hypernatremia necessitates gradual correction of this electrolyte abnormality.
Acute hyponatremia
leads to cerebral cell swelling and severe neurological dysfunction. However, prolonged hyponatremia is associated with significant reductions in brain cell electrolyte and organic osmolyte content so that cerebral cell volume is restored to normal. While acute hyponatremia can be treated with the administration of moderate doses of hypertonic saline in order to control
seizure
activity, chronic hyponatremia should be corrected slowly in order to prevent subsequent neurological deterioration. If the rate of correction exceeds 0.5 mmol/l per hour, or if the total increment in serum [Na+] exceeds 25 mmol/l in the first 48 h of therapy, then there is an increased risk of the development of cerebral demyelinating lesions. Chronic hyperglycemia activates the brain cell volume regulatory adaptations in the same manner as hypernatremia. Therefore, during the treatment of diabetic ketoacidosis, it is imperative to restore normoglycemia gradually in order to prevent the occurrence of cerebral edema.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Cell volume regulation: a review of cerebral adaptive mechanisms and implications for clinical treatment of osmolal disturbances: II. 153 29
Patients with hyponatremia are exposed to major neurological complications. On the one hand hyponatremia itself produces brain edema, increased intracranial pressure which potentially leads to subsequent neuropathological sequelae or death. On the other hand excessive correction could be followed by development of brain demyelinating lesions (central pontine or extrapontine myelinolysis) with major disability or fatal outcome. Understanding of brain adaptative mechanisms to changes in osmolality largely contributes to explain these neurological events. When serum sodium decreases, the brain prevents swelling by extruding electrolytes and organic osmolytes, a process almost fully achieved after 48 h. Conversely, during subsequent increase in serum sodium, reestablishment of intracerebral osmolytes occurs but their reuptake is more delayed (+/- 5 days). In both circumstances, these mechanisms can be overwhelmed, leading to brain damage.
Acute hyponatremia
(< 48 h) is generally hospital-acquired, mainly in the postoperative state and/or after excessive fluid administration. After abrupt fall in serum sodium,
seizure
, respiratory arrest and coma may develop and these manifestations are sometimes explosive in nature. Recognition of even minor symptoms is crucial and implies prompt correction. There is generally no risk of brain myelinolysis in acute hyponatremia. Some factors are suspected to aggravate the prognosis of hyponatremic encephalopathy, including female gender (menstruant women), hypoxia and young age. Chronic hyponatremia (> 48 h) usually develops outside the hospital and is generally better tolerated. The risks of brain myelinolysis can be largely reduced by limiting the correction level to < or = 15 mEq/1/24 h. However, if necessary, the initial rate of correction can be rapid provided that the final correction remains < 15 mEq/1/24 h. However, when other recognized risk factors for myelinolysis (hypokalemia, liver disease, poor nutritional state, burns) are present, correction should not exceed 10 mEq/1/24 h. Demyelinization is also observed in hypernatremia but it follows greater (50%) increase in serum sodium than from hyponatremic baseline. For symptomatic hyponatremia, rapid correction is usually obtained by hypertonic saline (3%) infusion. Another option consists in administration of intravenous or oral urea. Urea allows a rapid reduction of brain edema and intracranial pressure which is followed by subsequent correction of hyponatremia. Experimental data also suggest that treatment of hyponatremia with urea is associated with a lower incidence of myelinolysis. In hyponatremic patients without symptoms, there is no need for rapid correction and the treatment should be more conservative. Close monitoring of the serum sodium is indicated initially and if necessary, correction must be stopped and diuresis interrupted with dDAVP. Given recent experimental data, in patients overly corrected (delta SNa > 15 mEq/1/24 h), the risk of myelinolysis could be greatly reduced by rapidly decreasing the serum sodium through hypotonic fluids administration and dDAVP.
...
PMID:Therapeutic recommendations for management of severe hyponatremia: current concepts on pathogenesis and prevention of neurologic complications. 887 50
Status epilepticus (SE) is a dreaded neurological emergency. A reignited interest in SE has resulted in a more adaptive use of treatment protocols. More knowledge on SE of various aetiologies is therefore needed. We are interested in treatment of SE under hyponatremia, and have here evaluated whether SE induced by systemic kainic acid could be a suitable platform for such studies.
Acute hyponatremia
was induced in C57/BL6 mice by intraperitoneal injection of dDAVP and water loading. Hyponatremic mice displayed an increased frequency of epileptiform spikes on EEG and 5/9 hyponatremic mice displayed electrographic
seizures
. After kainic acid (20mg/kg) treatment, hyponatremic mice displayed significantly longer time with electrographic
seizure
activity, which was also seen after treatment with diazepam (20mg/kg). We conclude that hyponatremia augments kainic acid-induced SE, This model might be a valuable platform for studies on treatment of SE in hyponatremia.
...
PMID:Hyponatremia augments kainic-acid induced status epilepticus in the mouse: a model for dysmetabolic status epilepticus. 2379 Sep 65
Hyponatremia is a frequent electrolyte imbalance in hospital inpatients. Acute onset hyponatremia is particularly common in patients who have undergone any type of brain insult, including traumatic brain injury, subarachnoid hemorrhage and brain tumors, and is a frequent complication of intracranial procedures.
Acute hyponatremia
is more clinically dangerous than chronic hyponatremia, as it creates an osmotic gradient between the brain and the plasma, which promotes the movement of water from the plasma into brain cells, causing cerebral edema and neurological compromise. Unless acute hyponatremia is corrected promptly and effectively, cerebral edema may manifest through impaired consciousness level,
seizures
, elevated intracranial pressure, and, potentially, death due to cerebral herniation. The pathophysiology of hyponatremia in neurotrauma is multifactorial, but most cases appear to be due to the syndrome of inappropriate antidiuretic hormone secretion (SIADH). Classical treatment of SIADH with fluid restriction is frequently ineffective, and in some circumstances, such as following subarachnoid hemorrhage, contraindicated. However, the recently developed vasopressin receptor antagonist class of drugs provides a very useful tool in the management of neurosurgical SIADH. In this review, we summarize the existing literature on the clinical features, causes, and management of hyponatremia in the neurosurgical patient.
...
PMID:Neurosurgical Hyponatremia. 2623 93
Hyponatraemia is the most common electrolyte imbalance in neurosurgical patients.
Acute hyponatraemia
is particularly common in neurosurgical patients after any type of brain insult, including brain tumours and their treatment, pituitary surgery, subarachnoid haemorrhage or traumatic brain injury.
Acute hyponatraemia
is an emergency condition, as it leads to cerebral oedema due to passive osmotic movement of water from the hypotonic plasma to the relatively hypertonic brain which ultimately is the cause of the symptoms associated with hyponatraemia. These include decreased level of consciousness,
seizures
, non-cardiogenic pulmonary oedema or transtentorial brain herniation. Prompt treatment is mandatory to prevent such complications, minimize permanent brain damage and therefore permit rapid recovery after brain insult. The infusion of 3% hypertonic saline is the treatment of choice with different rates of administration based on the severity of symptoms and the rate of drop in plasma sodium concentration. The pathophysiology of hyponatraemia in neurotrauma is multifactorial; although the syndrome of inappropriate antidiuresis (SIADH) and central adrenal insufficiency are the commonest causes encountered. Fluid restriction has historically been the classical treatment for SIADH, although it is relatively contraindicated in some neurosurgical patients such as those with subarachnoid haemorrhage. Furthermore, many cases admitted have acute onset hyponatraemia, who require hypertonic saline infusion. The recently developed vasopressin receptor 2 antagonist class of drug is a promising and effective tool but more evidence is needed in neurosurgical patients. Central adrenal insufficiency may also cause acute hyponatraemia in neurosurgical patients; this responds clinically and biochemically to hydrocortisone. The rare cerebral salt wasting syndrome is treated with large volume normal saline infusion. In this review, we summarize the current evidence based on the clinical presentation, causes and treatment of different types of hyponatraemia in neurosurgical patients.
...
PMID:Diagnosis and treatment of hyponatraemia in neurosurgical patients. 2696 74
Hypotonic hyponatremia is caused by a serum sodium level of <135 mEq/L in the setting of excess solute loss accompanied by free water retention because of antidiuretic hormone release, subsequent to decreased effective arterial blood volume.
Acute hyponatremia
can have various neurological manifestations, including drowsiness, lethargy, coma,
seizures
, respiratory depression, and even death. In this article, we present a case of a 41-year-old man who presented with hyponatremia as a result of sodium containing biliary fluid loss and resultant renal free water retention in response to increased antidiuretic hormone secretion. He underwent placement of a cholecystostomy tube for acalculous cholecystitis and was found to be persistently hyponatremic despite repletion with sodium-containing fluids. Once the cholecystostomy tube was removed, the patient's sodium levels improved, and his symptoms resolved. Our case highlights choleuresis as an unusual but significant cause of hyponatremia in patients who have external biliary drainage.
...
PMID:Severe Persistent Hyponatremia: A Rare Presentation of Biliary Fluid Loss. 3142 52
Hyponatremia is a frequent occurrence in patients with neurosurgical disorders. Acute onset hyponatremia is particularly common in patients who have any type of cerebral insult, including traumatic brain injury, subarachnoid hemorrhage, and brain tumors. Furthermore, it is a common complication of intracranial procedures.
Acute hyponatremia
creates an osmotic gradient between the brain and the plasma, which promotes the movement of water from the plasma into brain cells, causing cerebral edema and neurological compromise. It is therefore far more likely to be symptomatic, and to have adverse outcomes, than chronic hyponatremia. Uncorrected acute hyponatremia with consequent cerebral edema may manifest through impaired consciousness level,
seizures
, elevated intracranial pressure, and, potentially, death due to cerebral herniation. The majority of cases of hyponatremia due to neurosurgical pathology are caused by the syndrome of inappropriate antidiuresis, but acute glucocorticoid insufficiency is increasingly being recognized as an important contributing factor. In this chapter, we summarize the existing literature on the clinical features and differential diagnosis of hyponatremia in the neurosurgical patient, and briefly discuss the management options.
...
PMID:Hyponatremia in Neurosurgical Patients. 3209 24
