patient approach and algorithm in hypernatremia.pptx
mohithA9
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Apr 21, 2024
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About This Presentation
about algorith clinical features and managem,ent of hypernatremia
Slide Content
APPROACH TO HYPERNATREMIA -By DR HARITHA MAM
DEFINITION Hypernatremia is defined as a plasma sodium >145 mEq /L
Hypernatremia is seen in about 1% of hospitalized patients and is more common (7%) in intensive care unit patients. Mortality rate as high as 40% is reported with hypernatremia , though it is uncommonly identified as the primary cause of death.
Etiology Hypernatremia may be caused by a primary Na gain or a water deficit, the latter being much more common. Normally , this hyperosmolar state stimulates thirst and the excretion of a maximally concentrated urine. For hypernatremia to persist, one or both of these compensatory mechanisms must also be impaired.
Impaired thirst response may occur in situations where access to water is limited, often due to physical restrictions (institutionalized, handicapped, postoperative, or intubated patients) or the mentally impaired (delirium, dementia). Elderly individuals with reduced thirst and/or diminished access to fluids are at the highest risk of developing hypernatremia .
Hypernatremia due to water loss The loss of water must occur in excess of electrolyte losses in order to raise [Na]. Nonrenal water loss may be due to evaporation from the skin and respiratory tract (insensible losses) or loss from the GI tract. Diarrhea is the most common GI cause of hypernatremia .
Osmotic diarrhea (induced by lactulose , sorbitol , or malabsorption of carbohydrate) and viral gastroenteritis , in particular, result in disproportional water loss. Insensible losses of water may increase in the setting of fever, exercise, heat exposure, severe burns, or mechanical ventilation.
Renal water loss results from either osmotic diuresis or diabetes insipidus (DI). Osmotic diuresis is frequently associated with glycosuria and high osmolar feeds. In addition, increased urea generation from accelerated catabolism, high protein feeds, and stress-dose steroids can also result in an osmotic diuresis .
Hypernatremia secondary to nonosmotic urinary water loss is usually caused by (a) impaired vasopressin secretion ( central diabetes insipidus [ CDI ]) or (b) resistance to the actions of vasopressin ( nephrogenic diabetes insipidus [ NDI ]) . Partial defects occur more commonly than complete defects in both types. Patients with DI generally do not develop hypernatremia if they are able to maintain fluid intake adequate to compensate for the water loss.
The most common cause of CDI is destruction of the neurohypophysis from trauma, neurosurgery, granulomatous disease, neoplasms , vascular accidents, or infection. In many cases, CDI is idiopathic.
NDI may either be inherited or acquired. The latter often results from a disruption to the renal concentrating mechanism due to drugs (lithium, demeclocycline , amphotericin ), electrolyte disorders ( hypercalcemia , hypokalemia ), medullary washout (loop diuretics), and intrinsic renal diseases.
Gestational diabetes insipidus is a rare complication of late-term pregnancy in which increased activity of a circulating placental protease with vasopressinase activity leads to reduced circulating AVP and polyuria , often accompanied by hypernatremia . DDAVP is an effective therapy for this syndrome because of its resistance to the vasopressinase enzyme.
Hypernatremia due to primary Na gain occurs infrequently due to the kidney's capacity to excrete the retained Na. However, it can rarely occur after repetitive hypertonic saline administration or chronic mineralocorticoid excess. Transcellular water shift from ECF to ICF can occur in circumstances of transient intracellular hyperosmolality , as in seizures or rhabdomyolysis .
JAPI Dec 2008 edn
Clinical Presentation Hypernatremia results in contraction of brain cells as water shifts to attenuate the rising ECF osmolality . Thus, the most severe symptoms of hypernatremia are neurologic, including altered mental status, weakness, neuromuscular irritability, focal neurologic deficits, and, occasionally, coma or seizures. The presence of encephalopathy is a poor prognostic sign in hypernatremia , and carries a mortality rate as high as 50%. As with hyponatremia , the severity of the clinical manifestations is related to the acuity and magnitude of the rise in plasma [Na] .
The sudden shrinkage of brain cells in acute hypernatremia may lead to parenchymal or subarachnoid hemorrhages and/or subdural hematomas; however, these vascular complications are encountered primarily in pediatric and neonatal patients. Osmotic damage to muscle membranes also can lead to hypernatremic rhabdomyolysis .
Brain cells accommodate to a chronic increase in ECF osmolality (>48 h) by activating membrane transporters that mediate influx and intracellular accumulation of organic osmolytes ( creatine , betaine , glutamate, myo-inositol , and taurine ); this results in an increase in ICF water and normalization of brain parenchymal volume.
Chronic hypernatremia is generally less symptomatic as a result of adaptive mechanisms designed to defend cell volume. However, the cellular response to chronic hypernatremia predisposes these patients to the development of cerebral edema and seizures during overly rapid hydration (overcorrection of plasma Na + concentration by >10 m M /d).
CDI and NDI generally present with complaints of polyuria and thirst. Signs of volume depletion or neurologic dysfunction are generally absent unless the patient has an associated thirst abnormality.
Diagnostic Approach The history should focus on the presence or absence of thirst, polyuria , and/or an extrarenal source for water loss, such as diarrhea. The physical examination should include a detailed neurologic exam and an assessment of the ECFV; patients with a particularly large water deficit and/or a combined deficit in electrolytes and water may be hypovolemic , with reduced JVP and orthostasis . Accurate documentation of daily fluid intake and daily urine output is also critical for the diagnosis and management of hypernatremia .
Adequate differentiation between nephrogenic and central causes of DI requires the measurement of the response in urinary osmolality to DDAVP, combined with measurement of circulating AVP in the setting of hypertonicity .
By definition, patients with baseline hypernatremia are hypertonic, with an adequate stimulus for AVP by the posterior pituitary. Therefore, in contrast to polyuric patients with a normal or reduced baseline plasma Na + concentration and osmolality , a water deprivation test is unnecessary in hypernatremia ; indeed, water deprivation is absolutely contraindicated in this setting because of the risk for worsening the hypernatremia .
Reference- Brenner and Rector’s THE KIDNEY
Patients with NDI will fail to respond to DDAVP, with a urine osmolality that increases by <50% or <150 mosmol /kg from baseline, in combination with a normal or high circulating AVP level. Patients with central DI will respond to DDAVP, with a reduced circulating AVP. Patients may exhibit a partial response to DDAVP, with a >50% rise in urine osmolality that nonetheless fails to reach 800 mosmol /kg; the level of circulating AVP will help differentiate the underlying cause, i.e., nephrogenic versus central DI.
In pregnant patients, AVP assays should be drawn in tubes containing the protease inhibitor 1,10-phenanthroline to prevent in vitro degradation of AVP by placental vasopressinase .
Treatment Management requires one to determine the rate of correction, the appropriate intervention, and the presence of other underlying disorders. The goal of correction should be to bring Na+ to 145 meq /L.
Symptomatic hypernatremia As in hyponatremia , aggressive correction of hypernatremia is potentially dangerous. The rapid shift of water into brain cells increases the risk of seizures or permanent neurologic damage. Therefore, the water deficit should be reduced gradually by roughly 10 to 12 mEq /L/d.
C hronic asymptomatic hypernatremia The risk of treatment-related complication is increased due to the cerebral adaptation to the chronic hyperosmolar state, and the plasma [Na] should be lowered at a more moderate rate (between 5 and 8 mEq /L/d).
Intervention The mainstay of management is the administration of water, preferably by mouth or nasogastric tube. Alternatively, 5% dextrose in water (D5W) or quarter NS can be given intravenously.
Traditionally, correction of hypernatremia has been accomplished by calculating free water deficit by the equation: Free water deficit = {([Na] - 140)/140} X (TBW)
Alternatively, The change in [Na] from the administration of 1000 ml fluid can be estimated as follows: Because hypernatremia suggests a contraction in water content, TBW is estimated by multiplying lean weight (in kilograms) by 0.5 in men (rather than 0.6) and 0.4 in women .
Adrogué HJ, Madias NE. Hypernatremia . N Engl J Med 2000;342:1493-9.
Hypovolemic hypernatremia In patients with mild volume depletion , Na-containing solutions, such as 0.45% NS, can be used to replenish the ECF as well as the water deficit. If patients have severe or symptomatic volume depletion, correction of volume status with isotonic fluid should take precedence over correction of the hyperosmolar state. Once the patient is hemodynamically stable, administration of hypotonic fluid can be given to replace the free water deficit. Hypernatremia from primary Na gain is unusual. Cessation of iatrogenic Na is typically sufficient.
DI without hypernatremia DI is best treated by removing the underlying cause. Despite the renal water loss, DI should not result in hypernatremia if the thirst mechanism remains intact. Therefore, therapy, if required at all, is directed toward symptomatic polyuria .
CDI Because the polyuria is the result of impaired secretion of vasopressin, treatment is best accomplished with the administration of DDAVP, a vasopressin analog.
NDI A low-Na diet combined with thiazide diuretics will decrease polyuria through inducing mild volume depletion. This enhances proximal reabsorption of salt and water, thus decreasing urinary free water loss. Decreasing protein intake will further decrease urine output by minimizing the solute load that must be excreted.
Patients with NDI due to lithium may reduce their polyuria with amiloride (2.5–10 mg/d)); in practice, however, most patients with lithium-associated DI are able to compensate for their polyuria simply by increasing their daily water intake. Occasionally, nonsteroidal anti-inflammatory drugs (NSAIDs) have been used to treat polyuria associated with NDI; however, this creates the risk of NSAID-associated gastric and/or renal toxicity.
It must be emphasized that thiazides , amiloride , and NSAIDs are appropriate only for chronic management of polyuria from NDI and have no role in the acute management of associated hypernatremia , in which the focus is on replacing free-water deficits and ongoing free-water loss.
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