Salt-Losing Syndrome in a Girl with Type I and II Pseudohypoaldosteronism.

BACKGROUND Pseudohypoaldosteronism (PHA) is characterized by renal tubular resistance to aldosterone and leads to hyponatremia, hyperkalemia, and metabolic acidosis. PHA is divided into 2 types: PHAI and PHAII. PHAI can be dominant (systemic disease) or recessive (renal form). PHAII causes hypertension with hyperkalemia and is recognized mostly in adults. PHA can be a life-threatening disease due to salt-wasting syndrome and severe hypovolemia. CASE REPORT We describe the case of a 2-month-old girl who was admitted to our hospital with hypovolemic shock due to salt-wasting syndrome. Laboratory tests revealed severe electrolyte abnormalities: hyponatremia (Na-116 mmol/L), hyperkalemia (K-10 mmol/L) and metabolic acidosis (pH-7.27; HCO3-12 mmol/L). Serum aldosterone was >100 ng/dL. Genetic analysis confirmed mutations in SCNN1A and CUL3 gene responsible for PHAI and PHAII. Supplementation with NaCl, pharmacological treatment of hyperkalemia, and restriction of potassium in the diet resulted in the normalization of serum electrolytes and proper future development. CONCLUSIONS Pseudohypoaldosteronism should always be considered in the differential diagnosis of hyponatremia and hyperkalemia in children. Salt loss syndrome can lead to hypovolemic shock and, when unrecognized and untreated, to death of a child due to arrythmias and brain edema. The presence of 2 types of PHA in the same patient increases the risk of salt loss and at the same time significantly increases the risk of hypertension because of genetic predisposition and regular diet. Increased salt concentration in sweat and saliva may suggest pseudohypoaldosteronism.

TRANSIENT PSEUDOHYPOALDOSTERONISM SECONDARY TO URINARY TRACT INFECTION IN A MALE INFANT WITH UNILATERAL HYDRONEPHROSIS DUE TO PRIMARY OBSTRUCTIVE MEGAURETER: A CASE REPORT.

We present a case of transient form of type 1 pseudohypoaldosteronism (S-PHA) in a 1.5-month-old male infant who presented with lethargy, failure to thrive, severe hyponatremia (Na=118 mmol/L), hypochloremia (Cl=93 mmol/L) and fever due to urinary tract infection. Potassium levels were normal. Markedly elevated serum aldosterone level and elevated serum renin confirmed the diagnosis of pseudohypoaldosteronism. Renal ultrasound showed grade III hydronephrosis on the left kidney while contrast-enhanced voiding urosonography excluded the existence of vesicoureteral reflux, which raised suspicion of obstructive uropathy at the level of vesicoureteral junction. Serum sodium normalized after several days of intravenous fluids and antibiotic therapy, after which oral supplementation of sodium was introduced. The levels of 17-hydroxyprogesterone, adrenocorticotropic hormone, cortisol and thyroid-stimulating hormone were normal. Functional magnetic resonance urography conducted at the age of 3 months confirmed the diagnosis of primary congenital obstructive megaureter and the infant was referred to a pediatric surgeon. Although a rare occurrence, S-PHA can be a potentially life-threatening condition in infants if not recognized and treated appropriately. Therefore, serum concentrations of electrolytes should be obtained in every child diagnosed with obstructive anomaly of the urinary tract and/or acute cystopyelonephritis. On the other hand, every child diagnosed with S-PHA should be evaluated for obstructive anomaly of the urinary tract.

Metabolic Acidosis, Hyperkalemia, and Renal Unresponsiveness to Aldosterone Syndrome: Response to Treatment with Low-Potassium Diet.

Gordon syndrome involves hyperkalemia, acidosis, and severe hypertension (HTN) with hypercalciuria, low renin and aldosterone levels. It is commonly observed in children and adolescents. Such patients respond successfully to sodium restriction and thiazide diuretics. In this article, we present three cases of metabolic acidosis, hyperkalemia, and renal unresponsiveness to aldosterone (MeHandRU Syndrome). All three patients did not have HTN or hypercalciuria and demonstrated normal renin and aldosterone levels. These patients did not respond to thiazide-type diuretic therapy and salt restriction. Two males (aged 55- and 62-year) and a female patient (aged 68-year) presented to the clinic with unexplained hyperkalemia (5.9 mEq/L, 5.9 mEq/L and 6.2 mEq/L, respectively). On physical examination, blood pressure (BP) was found to be normal (<140/90 mm Hg). Over the counter potassium supplement, nonsteroidal anti-inflammatory drugs, angiotensin converting enzyme inhibitors, angiotensin receptor blockers, potassium sparing diuretic use, as well as hyporeninemic hypoaldosteronism states such as diabetes mellitus were excluded. Plasma renin and aldosterone levels were normal. All three patients had low transtubular potassium gradient, despite high serum potassium levels. None of the patients reported a family history of hyperkalemia or kidney failure. All failed to demonstrate a response to hydrochlorothiazide and salt restriction. After careful consideration, strict low potassium diet (<2 g/day) was initiated in consultation with the dietician. Diuretic therapy was discontinued while BP remained within normal range (<140/90 mm Hg). At eight weeks, all three patients demonstrated normalization of potassium and correction of acidosis. At follow-up of six months, all patients are maintaining a normal potassium level. We suggest that potassium restriction can be successful in patients presenting with MeHandRU syndrome.

Life threatening hyperkalemia in a neonate with pseudo-hypoaldosteronism.

Pseudohypoaldosteronism type 1 is a rare disorder characterized by renal resistance to aldosterone which may present with a salt wasting crisis in infancy. We report a neonate with hyponatremia, severe dehydration and refractory life threatening hyperkalemia who was treated with dietary sodium chloride supplementation, potassium binding resins and fluid replacement therapy which proved to be lifesaving.

Critical points in the management of pseudohypoaldosteronism type 1.

Pseudohypoaldosteronism type 1 (PHA-1, MIM #264350) is caused by defective transepithelial sodium transport. Affected patients develop life-threatening neonatal-onset salt loss, hyperkalemia, acidosis, and elevated aldosterone levels due to end-organ resistance to aldosterone. In this report, we present a patient diagnosed as PHA-1 who had clinical and laboratory findings compatible with the diagnosis and had genetically proven autosomal recessive PHA-1. The patient received high doses of sodium supplementation and potassium-lowering therapies; however, several difficulties were encountered in the management of this case. The aim of this presentation was to point out the potential pitfalls in the treatment of such patients in the clinical practice and to recommend solutions.

Case report: severe neonatal hyperkalemia due to pseudohypoaldosteronism type 1.

Hyponatremia and hyperkalemia in infancy can represent a variety of renal and genetic disorders with significant long-term health implications. We report a newborn with severe hyperkalemia and hyponatremia from autosomal recessive pseudohypoaldosteronism type 1 requiring aggressive therapy. The evaluation and treatment of children with disorders of mineralocorticoid action are discussed.

Pseudohypoaldosteronisms, report on a 10-patient series.

BACKGROUND: Type 1 pseudohypoaldosteronism (PHA1) is a salt-wasting syndrome caused by mineralocorticoid resistance. Autosomal recessive and dominant hereditary forms are caused by Epithelial Na Channel and Mineralocorticoid Receptor mutation respectively, while secondary PHA1 is usually associated with urological problems. METHODS: Ten patients were studied in four French pediatric units in order to characterize PHA1 spectrum in infants. Patients were selected by chart review. Genetic, clinical and biochemistry data were collected and analyzed. RESULTS: Autosomal recessive PHA1 (n = 3) was diagnosed at 6 and 7 days of life in three patients presenting with severe hyperkalaemia and weight loss. After 8 months, 3 and 5 years on follow-up, neurological development and longitudinal growth was normal with high sodium supplementation. Autosomal dominant PHA1 (n = 4) was revealed at 15, 19, 22 and 30 days of life because of failure to thrive. At 8 months, 3 and 21 years of age, longitudinal growth was normal in three patients who were given salt supplementation; no significant catch-up growth was obtained in the last patient at 20 months of age. Secondary PHA1 (n = 3) was diagnosed at 11, 26 days and 5 months of life concomitantly with acute pyelonephritis in three children with either renal hypoplasia, urinary duplication or bilateral megaureter. The outcome was favourable and salt supplementation was discontinued after 3, 11 and 13 months. CONCLUSIONS: PHA1 should be suspected in case of severe hyperkalemia and weight loss in infants and need careful management. Pathogenesis of secondary PHA1 is still challenging and further studies are mandatory to highlight the link between infection, developing urinary tract and pseudohypoaldosteronism.

[Pseudohypoaldosteronism in infants with salt wasting syndrome. Two case reports]. / Pseudohipoaldosteronizm u niemowlat jako przyczyna zespolu utraty soli. Opis dwóch przypadków.

The paper discusses two cases of male infants, who developed a markedly elevated salt wasting syndrome in early infancy, resistant to treatment with mineralocorticoids. Steroid urinary profiles excluded congenital adrenal hyperplasia. However, both patients presented with extremely high excretion of aldosterone metabolite THAldo without effects of aldosterone action, what resulted in pseudohypoaldosteronism (PHA) diagnosis. The patients were treated with sodium supplementation, which normalized their clinical state and serum electrolytes. In the first patient the sporadic form of renal PHA1 is suspected. In the second patient congenital urinary tract anomalies and infection resulted in transient PHA1. Pseudohypoaldosteronism should be considered in the differential diagnosis of a salt wasting syndrome in infants, especially when it is accompanied by infections or congenital defects of the urinary tract.

[Multiple type I pseudohypoaldosteronism: neonatal management and outcome]. / Seudohipoaldosteronismo tipo I múltiple: presentación y seguimiento.

UNLABELLED: Multiple type I pseudohypoaldosteronism (PHA-I) is an autosomal recessive condition with multiple target-organ unresponsiveness to aldosterone, manifested early after birth with severe salt-wasting and hyperkalemia. Case 1. Female infant born at term after an uneventful pregnancy. One female sibling died in the first week of life with hyperkalemia. The diagnosis of multiple PHA-I resulted from a picture of dehydratation, hyperkalemia and hyponatremia with increased plasma renin activity (PRA), plasma aldosterone and sweat electrolytes. The treatment consisted of salt and sodium bicarbonate supplements, restricted potassium intake, cation exchange resins and high fluid intake. During first year she was hospitalized for severe salt-losing crises. At 7 years of age, she needs salt and sodium bicarbonate supplements and cation exchange resins. She has a normal growth and neurodevelopment. Case 2. Seven-day female newborn with consanguinity in maternal family. Pregnancy and delivery were uncomplicated. On admission she was severely dehydrated with hyponatremia, hyperkalemia, metabolic acidosis and elevated PRA, plasma aldosterone and sweat electrolytes. She remained hospitalized for six months and she was dependent on high amounts of salt and sodium bicarbonate supplements, fluid intake and cation exchange resins. Growth and neurodevelopment are normal. CONCLUSIONS: Multiple PHA-I may be suspected in a newborn with salt-loss and hyperkalemia without glucocorticoid defect. The frequent episodes of dehydratation during the first year of life require long hospitalization. The improvement with age make possible an ambulatory control after the first year of life.

Pseudohypoaldosteronism: mineralocorticoid unresponsiveness syndrome.

We described a 10 day old boy who presented with hyponatremia, hyperkalemia, and metabolic acidosis. Therapeutic treatment with exogenous glucocorticoid and mineralocorticoid for 8 months failed to correct the electrolyte abnormalities. The elevated serum cortisol up to 44.34 micrograms/dl along with the absence of skin hyperpigmentation excluded defects in the glucocorticoid pathway. Pseudohypoaldosteronism was diagnosed on the basis of hyponatremia, severe urinary salt loss despite the markedly elevated serum aldosterone up to 6,500 pg/ml (normal range 50-800 pg/ml). The patient responded very well to oral salt supplementation and cation exchange resin therapy shown by normal physical growth and normal levels of serum electrolytes.

[Type Ib pseudohypoaldosteronism: clinical aspects and nosological problems. Apropos of 3 cases]. / Pseudo-hypoaldostéronisme de type Ib: particularités cliniques et problèmes nosologiques. A propos de trois cas.

BACKGROUND: Type Ib pseudohypoaldosteronism is a congenital disorder characterized in the newborn by salt loss caused by multiple end-organ resistance to aldosterone. An autosomal recessive mode of inheritance has been reported. Its particularity is the spontaneous improvement by 18 months to 2 years, due to an improved tubular response of the kidneys to mineralocorticoids, or earlier when given salt supplements once the diagnosis is made. OBSERVATIONS: We observed three children with this disease, which was revealed by day 8 to day 15 of life; one of these presented respiratory symptoms identical to those of cystic fibrosis, and another one an apparently chance association with a rod myopathy. CONCLUSION: Recent findings in the literature demonstrate the molecular aspects of pseudohypoaldosteronism and lead to an interesting comparison with cystic fibrosis by explaining their similar physiopathology through the activity of epithelial sodium channels.

Transient pseudo-hypoaldosteronism following resection of the ileum: normal level of lymphocytic aldosterone receptors outside the acute phase.

Pseudo-hypoaldosteronism (PHA) is due to mineralocorticoid resistance and manifests as hyponatremia and hyperkalemia with increased plasma aldosterone levels. It may be familial or secondary to abnormal renal sodium handling. We report the case of a 54-year-old woman with multifocal cancer of the colon, who developed PHA after subtotal colectomy, ileal resection and jejunostomy. She was treated with 6 g of salt daily to prevent dehydration, which she stopped herself because of reduced fecal losses. One month later she was admitted with signs of acute adrenal failure, i.e. fatigue, severe nausea, blood pressure of 80/60 mmHg, extracellular dehydration, hyponatremia (118 mmol/l); hyperkalemia (7.6 mmol/l), increased blood urea nitrogen (BUN) (200 mg/dl) and creatininemia (2.5 mg/dl), and decreased plasma bicarbonates level (HCO3-: 16 mmol/l; N: 27-30). However, the plasma cortisol was high (66 microg/100 ml at 10:00 h; N: 8-15) and the ACTH was normal (13 pg/ml, N: 10-60); there was a marked increase in plasma renin activity (>37 ng/ml/h; N supine <3), active renin (869 pg/ml; N supine: 1.120), aldosterone (>2000 pg/ml; N supine <150) and plasma AVP (20 pmol/l; N: 0.5-2.5). The plasma ANH level was 38 pmol/l (N supine: 5-25). A urinary steroidogram resulted in highly elevated tetrahydrocortisol (THF: 13.3 mg/24h; N: 1.4+/-0.8) with no increase in tetrahydrocortisone (THE: 3.16 mg/24h; N: 2.7+/-2.0) excretion, and with low THE/THF (0.24; N: 1.87+/-0.36) and alpha THF/THF (0.35; N: 0.92+/-0.42) ratios. The number of mineralocorticoid receptors in mononuclear leukocytes was in the lower normal range for age, while the number of glucocorticoid receptors was reduced. Small-bowel resection in ileostomized patients causes excessive fecal sodium losses and results in chronic sodium depletion with contraction of the plasma volume and severe secondary hyperaldosteronism. Nevertheless, this hyperaldosteronism may be associated with hyponatremia and hyperkalemia suggesting PHA related to the major importance of the colon for the absorption of sodium. In conclusion, this case report emphasizes 1) the possibility of a syndrome of acquired PHA with severe hyperkalemia after resection of the ileum and colon responding to oral salt supplementation; 2) the major increase in AVP and the small increase in ANH; 3) the strong increase in urinary THF with low THE/THF and alpha THF/THF ratios; 4) the normal number of lymphocytic mineralocorticoid receptors outside the acute episode.

Pseudohypoaldosteronism: report of a case presenting as failure to thrive.

We report a 2 month-old infant referred for failure to thrive. At birth, weight was 3820 g and length 52 cm. After physiologic weight loss, the patient showed no further weight gain for the next two months. On admittance (age 2 mo), weight was 3340 g and length 53 cm; the infant had severe dystrophy, generalized hypotonia and dehydration; blood chemistry showed hyponatremia, hyperkalemia and hypochloremia. A salt losing syndrome of adrenal origin was hypothesized. However, rehydration and hydrocortisone administration failed to correct hyponatremia and hyperkalemia. Endocrine assessment showed high levels of aldosterone and plasma renin activity, suggesting pseudohypoaldosteronism. Oral sodium chloride supplementation normalized electrolyte balance and the patient showed progressive weight gain and catch-up growth, confirming the diagnosis.

Physiological and molecular aspects of mineralocorticoid receptor action in pseudohypoaldosteronism: a responsiveness test and therapy.

Pseudohypoaldosteronism (PHA), characterized by congenital resistance to aldosterone and excessive salt loss, has been traditionally treated with salt replacement. Although the mineralocorticoid receptor (MR) has been suggested as a potential locus of the defect in this disease, no such abnormality has been identified as yet. We studied a 17-yr-old male patient with congenital multifocal target organ resistance to aldosterone. Both carbenoxolone, an 11 beta-hydroxysteroid dehydrogenase inhibitor, and a high dose of fludrocortisone normalized the patient's serum electrolyte concentrations and decreased his urinary excretion of sodium, suggesting that this patient's resistance was partial and could be overcome by high concentrations of endogenous or exogenous mineralocorticoids. We hypothesized that the beneficial effect of these treatments was mostly mediated by the MR, because the administration of dexamethasone, while this patient was receiving a therapeutic dose of carbenoxolone, caused its reversal. These findings convinced us that there was functional, albeit possibly defective, MR in this patient and led us to perform molecular studies. Both alleles of the MR gene were expressed in the patient and his clinically and biochemically normal father. A conservative heterozygous mutation (A760-->G760, Ileu180-->Val180) and a nonconservative homozygous mutation (C944-->T944, Ala241-->Val241) were identified in the complementary DNA of both the patient and his father. The first untranslated exon and 0.9 kilobase of the 5'-regulatory region were also identical in the two men. It appears that the mutations causing amino acid substitutions represent polymorphisms, as we found high frequencies of both in the general population. We conclude that carbenoxolone and fludrocortisone may help define the presence of functional MR in patients with PHA and that the former could be used in the long term therapy of this disease. We hypothesize that the defect causing PHA in this patient might be in a post-MR step of aldosterone action.

Long term observations in a patient with pseudohypoaldosteronism.

This paper describes a patient with severe pseudohypoaldosteronism (PHA) for over 12 years. The patient presented at 10 days of age with a serum sodium of 118 mEq/l and potassium of 12 mEq/l. After failing to maintain normal fluid and electrolyte status with standard therapy, including maximal mineralocorticoid stimulation, he was given a special formula containing minimal potassium plus salt supplements which normalized his electrolyte status. However, when he was 4.5 years of age, an acute gastrointestinal illness led to severe volume depletion, hyperkalemia, and cardiopulmonary arrest. This resulted in significant neurological impairment. At 12.5 years of age, the patient continues to require massive sodium supplements and his diet contains less than 0.5 mEq/kg potassium daily; his height and weight are at the 95th percentile, thus demonstrating that normal growth may be achieved with strict dietary manipulation in a patient with persistent, severe PHA. Serial studies to further define the lesion in this patient have demonstrated: (1) normal binding of aldosterone to aldosterone binding globulin (5.1% bound); (2) normal mineralocorticoid "activity"; (2) suppressible renin and aldosterone levels; (4) increased prostaglandin excretion (3.15 micrograms/g creatinine); (5) lack of benefit of prostaglandin inhibition with indomethacin; (6) normal proximal tubule function (CNa + CH2O = 18.0 ml/100 ml glomerular filtration rate; (7) impaired distal tubule function (CH2O/CNa + CH2O = 79.8%) during water diuresis.