Hyponatremia 2007Treatment guidelines

The American Journal of Medicine, 2007

Although hyponatremia is a common, usually mild, and relatively asymptomatic disorder of electrolytes, acute severe hyponatremia can cause substantial morbidity and mortality, particularly in patients with concomitant disease. In addition, overly rapid correction of chronic hyponatremia can cause severe neurologic deficits and death, and optimal treatment strategies for such cases are not established. An expert panel assessed the potential contributions of aquaretic nonpeptide small-molecule arginine vasopressin receptor (AVPR) antagonists to hyponatremia therapies. This review presents their conclusions, including identification of appropriate treatment populations and possible future indications for aquaretic AVPR antagonists.

2007

Although hyponatremia is a common, usually mild, and relatively asymptomatic disorder of electrolytes, acute severe hyponatremia can cause substantial morbidity and mortality, particularly in patients with concomitant disease. In addition, overly rapid correction of chronic hyponatremia can cause severe neurologic deficits and death, and optimal treatment strategies for such cases are not established. An expert panel assessed the potential contributions of aquaretic nonpeptide small-molecule arginine vasopressin receptor (AVPR) antagonists to hyponatremia therapies. This review presents their conclusions, including identification of appropriate treatment populations and possible future indications for aquaretic AVPR antagonists. © 2007 Elsevier Inc. All rights reserved.

The American Journal of the Medical Sciences, 2007

Hyponatremia, the most common electrolyte disorder in hospitalized patients, has been associated with high rate of mortality among both this population and nonhospitalized patients. This review describes briefly the classification and pathogenesis of hyponatremia, and, in greater detail, the management of hyponatremia with a particular emphasis on the clinical pharmacology of arginine vasopressin (AVP) antagonists. This review includes more in-depth discussion on the pharmacology of conivaptan, an AVP antagonist recently approved by the United States Food and Drug Administration. KEY INDEXING TERMS: Hyponatremia; Management of hyponatremia; AVP-receptor antagonists. [Am J Med Sci 2007;333(2):101-105.]

Nature Clinical Practice Nephrology, 2007

American Journal of Kidney Diseases, 2006

is a common electrolyte disorder that frequently is overlooked and undertreated. Although the pathophysiological process of hyponatremia is complex, arginine vasopressin (AVP) is a common etiologic factor. Excess AVP release by osmotic or nonosmotic stimuli or both can lead to sodium and water imbalance. Conventional treatment options for hyponatremia, including water restriction and administration of sodium chloride with or without loop diuretics, do not directly address the underlying water retention induced by excess AVP in many cases. Clinical trials showed that AVP-receptor antagonists, including lixivaptan, tolvaptan, and conivaptan, produce aquaresis, the electrolyte-sparing excretion of free water, to correct serum sodium concentration. We review results from recent clinical trials involving AVP-receptor antagonists in the treatment of hyponatremia associated with AVP excess.

Annals of neurology, 2006

Hyponatremia is frequently associated with neurological disease, neurosurgical procedures, and use of psychoactive drugs. Arginine vasopressin (AVP), or antidiuretic hormone, is the principal physiological regulator of water and electrolyte balance, and disruption of the normal AVP response to osmotic stimuli is a common cause of dilutional hyponatremia in neurological disorders. The hyponatremia-induced shift in water from the extracellular to the intracellular compartment can lead to cerebral edema and serious neurological complications, especially if the decrease in serum sodium concentration ([Na ؉ ]) is large or rapid. Overly rapid correction of the serum [Na ؉ ] may lead to osmotic demyelination and irreversible brain injury. Fluid restriction is considered first-line treatment and pharmacological agents currently used in the treatment of hyponatremia are limited by inconsistent response and adverse side effects. AVP receptor antagonists represent a new approach to the treatment of hyponatremia by blocking tubular reabsorption of water by binding to V 2 receptors in the renal collecting ducts, resulting in aquaresis. Initial clinical experience with AVP receptor antagonists for hyponatremia has shown that these agents augment free water clearance, decrease urine osmolality, and correct serum [Na ؉ ] and serum osmolality. Controlled clinical trials now underway will help elucidate the role of AVP receptor antagonism in the treatment of hyponatremia.

American Journal of Health-System Pharmacy, 2007

Purpose. An overview of hyponatremia is provided, including its pathophysiology, clinical manifestations, signs and symptoms, and treatment, particularly with arginine vasopressin (AVP)-receptor antagonists. Summary. Hyponatremia (generally defined as a serum sodium concentration of <135 meq/L) is one of the most common electrolyte disorders in hospitalized and clinic patients. It may be caused by a number of conditions, including infections, heart disease, surgery, malignancy, and medication use. Clinical signs and symptoms such as hallucinations, lethargy, weakness, bradycardia, respiratory depression, seizures, coma, and death have been reported. Conventional treatment consists of fluid restriction and administration of hypertonic saline and pharmacologic agents, such as demeclocycline, lithium carbonate, and urea. These treatment options are often of limited effectiveness or difficult for patients to tolerate. AVP promotes the reabsorption of water in the renal collecting ducts by activation of V 2 receptors, resulting in water retention and dilution of serum solutes. The AVP-receptor antagonists , conivaptan, lixivaptan, and tolvaptan, are being studied for the treatment of hyponatremia. Conivaptan has been shown in clinical trials to increase freewater excretion and safely normalize serum sodium concentrations in patients with hyponatremia and is well tolerated. Also in clinical trials, lixivaptan and tolvaptan have safely improved serum sodium concentrations in patients with hyponatremia. Conclusion. Hyponatremia is a serious health condition for which treatment should be carefully performed. As new agents for treating hyponatremia, AVPreceptor antagonists have demonstrated efficacy and safety in clinical trials and may serve as significant improvements in the current treatment options for managing this disorder.

The American Journal of Medicine, 2013

Hyponatremia is a serious, but often overlooked, electrolyte imbalance that has been independently associated with a wide range of deleterious changes involving many different body systems. Untreated acute hyponatremia can cause substantial morbidity and mortality as a result of osmotically induced cerebral edema, and excessively rapid correction of chronic hyponatremia can cause severe neurologic impairment and death as a result of osmotic demyelination. The diverse etiologies and comorbidities associated with hyponatremia pose substantial challenges in managing this disorder. In 2007, a panel of experts in hyponatremia convened to develop the Hyponatremia Treatment Guidelines 2007: Expert Panel Recommendations that defined strategies for clinicians caring for patients with hyponatremia. In the 6 years since the publication of that document, the field has seen several notable developments, including new evidence on morbidities and complications associated with hyponatremia, the importance of treating mild to moderate hyponatremia, and the efficacy and safety of vasopressin receptor antagonist therapy for hyponatremic patients. Therefore, additional guidance was deemed necessary and a panel of hyponatremia experts (which included all of the original panel members) was convened to update the previous recommendations for optimal current management of this disorder. The updated expert panel recommendations in this document represent recommended approaches for multiple etiologies of hyponatremia that are based on both consensus opinions of experts in hyponatremia and the most recent published data in this field.

Hepatology, 2003

for The North American VPA-985 Study Group Hyponatremia in advanced cirrhosis and ascites or congestive heart failure (CHF) is the result of an inappropriate increase in vasopressin secretion, which acts through activation of specific V 2 receptors in the distal renal nephron to increase water reabsorption. This study investigates the efficacy and safety of 3 different doses of the V 2 receptor antagonist, VPA-985, in correcting hyponatremia over a 7-day inpatient study period. Forty-four hospitalized patients (33 patients with cirrhosis, 6 with CHF, and 5 with syndrome of inappropriate antidiuretic hormone (SIADH) were studied on a constant sodium intake, with VPA doses of 25, 125, and 250 mg twice daily or placebo. Serum sodium measurements were repeated after every daily dose, and the next dose withheld for excessive serum sodium rises. Fluid intake was adjusted according to previous 24-hour urinary outputs. Adverse events were based on clinical signs of dehydration or encephalopathy. VPA-985 produced a significant overall aquaretic response compared with placebo, with significant dose related increases in free water clearance (P < .05) and serum sodium (P < .05), without significant changes in orthostatic blood pressure or serum creatinine levels. Five patients (50%) on 250 mg twice daily had to have medication withheld on multiple occasions. End-of-study plasma vasopressin levels increased significantly in the 2 larger dose groups. In conclusion, VPA-985 appears effective and safe in appropriate doses in correcting abnormal renal water handling and hyponatremia in conditions associated with water retention. Higher doses of VPA-985 may produce significant dehydration and will require close monitoring with their use.

International journal of applied & basic medical research, 2012

Arginine vasopressin (AVP) plays an important role in water and sodium homeostasis. It acts via three receptor subtypes-V1a, V1b, and V2-distributed widely throughout the body. Vaptans are nonpeptide vasopressin receptor antagonists (VRA). By property of aquaresis, VRAs offer a novel therapy of water retention. Conivaptan is a V1a/V2 nonselective VRA approved for euvolemic and hypervolemic hyponatremia. Tolvaptan is the first oral VRA. Other potential uses of this new class of drugs include congestive heart failure (CHF), cirrhosis of liver, syndrome of inappropriate secretion of antidiuretic hormone, polycystic kidney disease, and so on. These novel drugs score over diuretics as they are not associated with electrolyte abnormalities. Though much remains to be elucidated before the VRAs are applied clinically, the future holds much promise.