Diabetes insipidus

Diabetes insipidus
Synonyms pituitary diabetes insipidus
Vasopressin
Classification and external resources
Specialty Endocrinology
ICD-10 E23.2 N25.1
ICD-9-CM 253.5 588.1
OMIM 304800 125800
DiseasesDB 3639
MedlinePlus 000377
Central000460
Congenital000461
Nephrogenic 000511
eMedicine med/543 ped/580
MeSH D003919

Diabetes insipidus (DI) is a condition characterized by excessive thirst and excretion of large amounts of severely dilute urine, with reduction of fluid intake having no effect on the concentration of the urine.[1]

There are different types of DI, each with a different set of causes. The most common type in humans is the neurological form, called central DI (CDI), which involves a deficiency of arginine vasopressin (AVP), also known as antidiuretic hormone (ADH). The second common type of DI is nephrogenic diabetes insipidus (NDI), which is due to kidney or nephron dysfunction caused by an insensitivity of the kidneys or nephrons to ADH. DI can also be gestational, or caused by alcohol or some types of drug abuse. DI should not be confused with nocturia.

Although they have a common name, diabetes mellitus and diabetes insipidus are two entirely separate conditions with unrelated mechanisms. Both cause large amounts of urine to be produced (polyuria). However, diabetes insipidus is either a problem with the production of antidiuretic hormone (central diabetes insipidus) or kidney's response to antidiuretic hormone (nephrogenic diabetes insipidus), whereas diabetes mellitus causes polyuria via a process called osmotic diuresis, due to the high blood sugar leaking into the urine and taking excess water along with it.

The number of new cases of diabetes insipidus each year is 3 in 100,000.[2] Diabetes insipidus usually starts in childhood or early adulthood and affects men more commonly than women.[3] The term "diabetes" is derived from the Greek word meaning siphon.

Signs and symptoms

Excessive urination and extreme thirst and increased fluid intake (especially for cold water and sometimes ice or ice water) are typical for DI.[4] The symptoms of excessive urination and extreme thirst are similar to what is seen in untreated diabetes mellitus, with the distinction that the urine does not contain glucose. Blurred vision is a rarity. Signs of dehydration may also appear in some individuals, since the body cannot conserve much (if any) of the water it takes in.

Extreme urination continues throughout the day and the night. In children, DI can interfere with appetite, eating, weight gain, and growth, as well. They may present with fever, vomiting, or diarrhea. Adults with untreated DI may remain healthy for decades as long as enough water is consumed to offset the urinary losses. However, there is a continuous risk of dehydration and loss of potassium that may lead to hypokalemia.

Diagnosis

To distinguish DI from other causes of excess urination, blood glucose levels, bicarbonate levels, and calcium levels need to be tested. Measurement of blood electrolytes can reveal a high sodium level (hypernatremia as dehydration develops). Urinalysis demonstrates a dilute urine with a low specific gravity. Urine osmolarity and electrolyte levels are typically low.

A fluid deprivation test is another way of distinguishing DI from other causes of excessive urination. It is also used to help determine what DI is caused by:

  1. a defect in ADH production
  2. a defect in the kidneys' response to ADH

This test measures the changes in body weight, urine output, and urine composition when fluids are withheld to induce dehydration. The body's normal response to dehydration is to conserve water by concentrating the urine. Those with DI continue to urinate large amounts of dilute urine in spite of water deprivation. In primary polydipsia, the urine osmolality should increase and stabilize at above 280 Osm/kg with fluid restriction, while a stabilization at a lower level indicates diabetes insipidus.[5] Stabilization in this test means, more specifically, when the increase in urine osmolality is less than 30 Osm/kg per hour for at least three hours.[5] Sometimes measuring blood levels of ADH toward the end of this test is also necessary, but is more time consuming to perform.[5]

To distinguish between the main forms, desmopressin stimulation is also used; desmopressin can be taken by injection, a nasal spray, or a tablet. While taking desmopressin, a patient should drink fluids or water only when thirsty and not at other times, as this can lead to sudden fluid accumulation in the central nervous system. If desmopressin reduces urine output and increases urine osmolarity, the hypothalamic production of ADH is deficient, and the kidney responds normally to exogenous vasopressin (desmopressin). If the DI is due to renal pathology, desmopressin does not change either urine output or osmolarity (since the endogenous vasopressin levels are already high).

Whilst diabetes insipidus usually occurs with polydipsia, it can also rarely occur not only in the absence of polydipsia but in the presence of its opposite, adipsia (or hypodipsia). "Adipsic diabetes insipidus" is recognised[6] as a marked absence of thirst even in response to hyperosmolality.[7] In some cases of adipsic DI, the patient may also fail to respond to desmopressin.[8]

If central DI is suspected, testing of other hormones of the pituitary, as well as magnetic resonance imaging, particularly a pituitary MRI, is necessary to discover if a disease process (such as a prolactinoma, or histiocytosis, syphilis, tuberculosis or other tumor or granuloma) is affecting pituitary function. Most people with this form have either experienced past head trauma or have stopped ADH production for an unknown reason.

Habit drinking (in its severest form termed psychogenic polydipsia) is the most common imitator of diabetes insipidus at all ages. While many adult cases in the medical literature are associated with mental disorders, most patients with habit polydipsia have no other detectable disease. The distinction is made during the water deprivation test, as some degree of urinary concentration above isoosmolar is usually obtained before the patient becomes dehydrated.

Pathophysiology

Electrolyte and volume homeostasis is a complex mechanism that balances the body's requirements for blood pressure and the main electrolytes sodium and potassium. In general, electrolyte regulation precedes volume regulation. When the volume is severely depleted, however, the body will retain water at the expense of deranging electrolyte levels.

The regulation of urine production occurs in the hypothalamus, which produces ADH in the supraoptic and paraventricular nuclei. After synthesis, the hormone is transported in neurosecretory granules down the axon of the hypothalamic neuron to the posterior lobe of the pituitary gland, where it is stored for later release. In addition, the hypothalamus regulates the sensation of thirst in the ventromedial nucleus by sensing increases in serum osmolarity and relaying this information to the cortex.

Neurogenic/central DI results from a lack of ADH; occasionally it can present with decreased thirst as regulation of thirst and ADH production occur in close proximity in the hypothalamus. It is encountered as a result of hypoxic encephalopathy, neurosurgery, autoimmunity or cancer, or sometimes without an underlying cause (idiopathic).

The main effector organ for fluid homeostasis is the kidney. ADH acts by increasing water permeability in the collecting ducts and distal convoluted tubules; specifically, it acts on proteins called aquaporins and more specifically aquaporin 2 in the following cascade. When released, ADH binds to V2 G-protein coupled receptors within the distal convoluted tubules, increasing cyclic AMP, which couples with protein kinase A, stimulating translocation of the aquaporin 2 channel stored in the cytoplasm of the distal convoluted tubules and collecting ducts into the apical membrane. These transcribed channels allow water into the collecting duct cells. The increase in permeability allows for reabsorption of water into the bloodstream, thus concentrating the urine.

Nephrogenic DI results from lack of aquaporin channels in the distal collecting duct (decreased surface expression and transcription). It is seen in lithium toxicity, hypercalcemia, hypokalemia, or release of ureteral obstruction.

Hereditary forms of diabetes insipidus account for less than 10% of the cases of diabetes insipidus seen in clinical practice.[9]

Classification

The several forms of DI are:

Neurogenic

Neurogenic diabetes insipidus, more commonly known as central diabetes insipidus, is due to the lack of vasopressin production in the hypothalamus due to a range of causes. The underlying causes of Central DI can include vascular, autoimmune, infection, sarcoidosis, some drugs, surgery, head trauma, benign or metastatic pituitary-hypothalamic tumor (particularly originating from breast and lung), although 50% of cases are found to be idiopathic.

Nephrogenic

Nephrogenic diabetes insipidus is due to the inability of the kidney to respond normally to vasopressin.

Dipsogenic

Dipsogenic DI or primary polydipsia results from excessive intake of fluids as opposed to deficiency of arginine vasopressin. It may be due to a defect or damage to the thirst mechanism, located in the hypothalamus;[10] or due to mental illness. Treatment with DDAVP may lead to water intoxication.

Gestational

Gestational DI occurs only during pregnancy and the postpartum period. During pregnancy, women produce vasopressinase in the placenta, which breaks down ADH. Gestational DI is thought to occur with excessive production and/or impaired clearance of vasopressinase.[11]

Most cases of gestational DI can be treated with desmopressin (ddAVP), but not vasopressin. In rare cases, however, an abnormality in the thirst mechanism causes gestational DI, and desmopressin should not be used.

Diabetes insipidus is also associated with some serious diseases of pregnancy, including pre-eclampsia, HELLP syndrome and acute fatty liver of pregnancy. These cause DI by impairing hepatic clearance of circulating vasopressinase. It is important to consider these diseases if a woman presents with diabetes insipidus in pregnancy, because their treatments require delivery of the baby before the disease will improve. Failure to treat these diseases promptly can lead to maternal or perinatal mortality.

Treatment

Central DI

Central DI and gestational DI respond to desmopressin which is given as intranasal or oral tablets. Carbamazepine, an anticonvulsive medication, has also had some success in this type of DI. Also, gestational DI tends to abate on its own four to six weeks following labor, though some women may develop it again in subsequent pregnancies. In dipsogenic DI, desmopressin is not usually an option.

Nephrogenic DI

Desmopressin will be ineffective in nephrogenic DI and is treated by reversing the underlying cause (if possible) and replacing the free water deficit. The diuretic hydrochlorothiazide (a thiazide diuretic) or indomethacin can be used to create mild hypovolemia which encourages salt and water uptake in proximal tubule and thus improve nephrogenic diabetes insipidus. Amiloride has additional benefit of blocking Li uptake. Thiazide diuretics are sometimes combined with amiloride to prevent hypokalemia. It seems paradoxical to treat an extreme diuresis with a diuretic, and the exact mechanism of action is unknown but the thiazide diuretics will decrease distal convoluted tubule reabsorption of sodium and water, thereby causing diuresis. This decreases plasma volume, thus lowering the glomerular filtration rate and enhancing the absorption of sodium and water in the proximal nephron. Less fluid reaches the distal nephron, so overall fluid conservation is obtained.[12]

Lithium-induced nephrogenic DI may be effectively managed with the administration of amiloride, a potassium-sparing diuretic often used in conjunction with thiazide or loop diuretics. Clinicians have been aware of lithium toxicity for many years, and traditionally have administered thiazide diuretics for lithium-induced polyuria and nephrogenic diabetes insipidus. However, amiloride has recently been shown to be a successful treatment for this condition.[13]

Etymology

The word "diabetes" (/ˌd.əˈbtz/ or /ˌd.əˈbts/) comes from Latin diabētēs, which in turn comes from Ancient Greek διαβήτης (diabētēs) which literally means "a passer through; a siphon".[14] Ancient Greek physician Aretaeus of Cappadocia (fl. in the first century CE) used that word, with the intended meaning "excessive discharge of urine", as the name for the disease.[15][16] Ultimately, the word comes from Greek διαβαίνειν (diabainein), meaning "to pass through",[14] which is composed of δια- (dia-), meaning "through" and βαίνειν (bainein), meaning "to go".[15] The word "diabetes" is first recorded in English, in the form "diabete", in a medical text written around 1425.

"Insipidus" comes from Latin language insipidus (tasteless), from Latin: in- "not" + sapidus "tasty" from sapere "have a taste" — the full meaning is "lacking flavor or zest; not tasty". Application of this name to DI arose from the fact that diabetes insipidus does not cause glycosuria (excretion of glucose into the urine).

References

  1. Tamparo, Carol (2011). Fifth Edition : Diseases of the Human Body. Philadelphia, PA: F.A. Davis Company. p. 288. ISBN 978-0-8036-2505-1.
  2. Saborio P, Tipton GA, Chan JC (2000). "Diabetes Insipidus". Pediatrics in Review. 21 (4): 122–129. doi:10.1542/pir.21-4-122. PMID 10756175.
  3. Tamparo, Carol; Lewis, Marcia (2011). Diseases of the Human Body. Philadelphia, PA: F.A. Davis Company. p. 289. ISBN 9780803625051.
  4. USE. "Diabetes insipidus - PubMed Health". Ncbi.nlm.nih.gov. Retrieved 2012-05-28.
  5. 1 2 3 Elizabeth D Agabegi; Agabegi, Steven S. (2008). Step-Up to Medicine (Step-Up Series). Hagerstwon, MD: Lippincott Williams & Wilkins. ISBN 0-7817-7153-6.
  6. Crowley RK, Sherlock M, Agha A, Smith D, Thompson CJ (2007). "Clinical insights into adipsic diabetes insipidus: a large case series". Clin. Endocrinol. (Oxf). 66 (4): 475–82. doi:10.1111/j.1365-2265.2007.02754.x. PMID 17371462.
  7. Sinha A, Ball S, Jenkins A, Hale J, Cheetham T (2011). "Objective assessment of thirst recovery in patients with adipsic diabetes insipidus". Pituitary. 14 (4): 307–11. doi:10.1007/s11102-011-0294-3. PMID 21301966.
  8. Smith D, McKenna K, Moore K, Tormey W, Finucane J, Phillips J, Baylis P, Thompson CJ (2002). "Baroregulation of vasopressin release in adipsic diabetes insipidus". J. Clin. Endocrinol. Metab. 87 (10): 4564–8. doi:10.1210/jc.2002-020090. PMID 12364435.
  9. Fujiwara TM, Bichet DG (2005). "Molecular Biology of Hereditary Diabetes Insipidus". Journal of the American Society of Nephrology. 16 (10): 2836–2846. doi:10.1681/ASN.2005040371. PMID 16093448.
  10. Perkins RM, Yuan CM, Welch PG (March 2006). "Dipsogenic diabetes insipidus: report of a novel treatment strategy and literature review". Clin. Exp. Nephrol. 10 (1): 63–7. doi:10.1007/s10157-005-0397-0. PMID 16544179.
  11. Kalelioglu I, Kubat Uzum A, Yildirim A, Ozkan T, Gungor F, Has R (2007). "Transient gestational diabetes insipidus diagnosed in successive pregnancies: review of pathophysiology, diagnosis, treatment, and management of delivery". Pituitary. 10 (1): 87–93. doi:10.1007/s11102-007-0006-1. PMID 17308961.
  12. Loffing J (November 2004). "Paradoxical antidiuretic effect of thiazides in diabetes insipidus: another piece in the puzzle". J. Am. Soc. Nephrol. 15 (11): 2948–50. doi:10.1097/01.ASN.0000146568.82353.04. PMID 15504949.
  13. Finch CK, Kelley KW, Williams RB (April 2003). "Treatment of lithium-induced diabetes insipidus with amiloride". Pharmacotherapy. 23 (4): 546–50. doi:10.1592/phco.23.4.546.32121. PMID 12680486.
  14. 1 2 Oxford English Dictionary. diabetes. Retrieved 2011-06-10.
  15. 1 2 Harper, Douglas (2001–2010). "Online Etymology Dictionary. diabetes.". Retrieved 2011-06-10
  16. Dallas, John (2011). "Royal College of Physicians of Edinburgh. Diabetes, Doctors and Dogs: An exhibition on Diabetes and Endocrinology by the College Library for the 43rd St. Andrew's Day Festival Symposium"
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